Datasheet DiaMag protein G-coated magnetic beads DATASHEET Datasheet description | Download |
The protein G-coated magnetic beads have been extensively validated in chromatin immunoprecipitation assay (ChIP). These beads are intended for isolation of immune complexes (chromatin and specific antibody) in ChIP experiments. The beads are suitable for immunoprecipitation of mouse IgG1, IgG2a, IgG2b and IgG3, rat IgG1, IgG2a, IgG2b and IgG3, rabbit and goat polyclonal Abs and human IgG1, IgG2, IgG3 and IgG4. The beads should be washed before use.
Datasheet DiaMag protein G-coated magnetic beads DATASHEET Datasheet description | Download |
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Identification of an E3 ligase that targets the catalytic subunit ofRNA polymerase I upon transcription stress. |
Inhibition of HIV-1 gene transcription by KAP1 in myeloid lineage. |
ZNF354C is a transcriptional repressor that inhibits endothelialangiogenic sprouting. |
AP-1 controls the p11-dependent antidepressant response. |
Aging-regulated anti-apoptotic long non-coding RNA Sarrah augments recovery from acute myocardial infarction. |
Inhibition of histone deacetylation rescues phenotype in a mouse model of Birk-Barel intellectual disability syndrome. |
H3K4me1 Supports Memory-like NK Cells Induced by Systemic Inflammation. |
Epigenetic remodelling licences adult cholangiocytes for organoid formation and liver regeneration. |
Interaction of Sox2 with RNA binding proteins in mouse embryonic stem cells. |
The Itaconate Pathway Is a Central Regulatory Node Linking Innate Immune Tolerance and Trained Immunity |
The histone demethylase Jarid1b mediates angiotensin II-induced endothelial dysfunction by controlling the 3'UTR of soluble epoxide hydrolase. |
Epigenetic regulation of brain region-specific microglia clearance activity. |
Episomal HBV persistence within transcribed host nuclear chromatin compartments involves HBx. |
Long noncoding RNA LISPR1 is required for S1P signaling and endothelial cell function. |
Metabolic Induction of Trained Immunity through the Mevalonate Pathway. |
BCG Vaccination Protects against Experimental Viral Infection in Humans through the Induction of Cytokines Associated with Trained Immunity. |
Polycomb repressive complex 2 (PRC2) silences genes responsible for neurodegeneration |
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Factors governing the stability of the polymerase complex are not known. Previous studies characterizing the Pol I inhibitor BMH-21 revealed a transcriptional stress-dependent pathway for degradation of the largest subunit of Pol I, RPA194. To identify the E3 ligase(s) involved, we conducted a cell-based RNAi screen for ubiquitin pathway genes. We establish Skp-Cullin-F-box protein complex (SCF complex) F-box protein FBXL14 as an E3 ligase for RPA194. We show that FBXL14 binds to RPA194 and mediates RPA194 ubiquitination and degradation in cancer cells treated with BMH-21. Mutation analysis in yeast identified lysines 1150, 1153 and 1156 on Rpa190 relevant for the protein degradation. These results reveal the regulated turnover of Pol I, showing that the stability of the catalytic subunit is controlled by the F-box protein FBXL14 in response to transcription stress.</p>', 'date' => '2022-11-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/36372232', 'doi' => '10.1016/j.jbc.2022.102690', 'modified' => '2022-11-24 10:19:52', 'created' => '2022-11-24 08:49:52', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '4188', 'name' => 'Inhibition of HIV-1 gene transcription by KAP1 in myeloid lineage.', 'authors' => 'Ait-Ammar A. et al.', 'description' => '<p>HIV-1 latency generates reservoirs that prevent viral eradication by the current therapies. To find strategies toward an HIV cure, detailed understandings of the molecular mechanisms underlying establishment and persistence of the reservoirs are needed. The cellular transcription factor KAP1 is known as a potent repressor of gene transcription. Here we report that KAP1 represses HIV-1 gene expression in myeloid cells including microglial cells, the major reservoir of the central nervous system. Mechanistically, KAP1 interacts and colocalizes with the viral transactivator Tat to promote its degradation via the proteasome pathway and repress HIV-1 gene expression. In myeloid models of latent HIV-1 infection, the depletion of KAP1 increased viral gene elongation and reactivated HIV-1 expression. Bound to the latent HIV-1 promoter, KAP1 associates and cooperates with CTIP2, a key epigenetic silencer of HIV-1 expression in microglial cells. In addition, Tat and CTIP2 compete for KAP1 binding suggesting a dynamic modulation of the KAP1 cellular partners upon HIV-1 infection. Altogether, our results suggest that KAP1 contributes to the establishment and the persistence of HIV-1 latency in myeloid cells.</p>', 'date' => '2021-01-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/33514850', 'doi' => '10.1038/s41598-021-82164-w', 'modified' => '2022-01-05 15:08:41', 'created' => '2021-12-06 15:53:19', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '4095', 'name' => 'ZNF354C is a transcriptional repressor that inhibits endothelialangiogenic sprouting.', 'authors' => 'Oo, James A and Irmer, Barnabas and Günther, Stefan and Warwick, Timothyand Pálfi, Katalin and Izquierdo Ponce, Judit and Teichmann, Tom andPflüger-Müller, Beatrice and Gilsbach, Ralf and Brandes, Ralf P andLeisegang, Matthias S', 'description' => '<p>Zinc finger proteins (ZNF) are a large group of transcription factors with diverse functions. We recently discovered that endothelial cells harbour a specific mechanism to limit the action of ZNF354C, whose function in endothelial cells is unknown. Given that ZNF354C has so far only been studied in bone and tumour, its function was determined in endothelial cells. ZNF354C is expressed in vascular cells and localises to the nucleus and cytoplasm. Overexpression of ZNF354C in human endothelial cells results in a marked inhibition of endothelial sprouting. RNA-sequencing of human microvascular endothelial cells with and without overexpression of ZNF354C revealed that the protein is a potent transcriptional repressor. ZNF354C contains an active KRAB domain which mediates this suppression as shown by mutagenesis analysis. ZNF354C interacts with dsDNA, TRIM28 and histones, as observed by proximity ligation and immunoprecipitation. Moreover, chromatin immunoprecipitation revealed that the ZNF binds to specific endothelial-relevant target-gene promoters. ZNF354C suppresses these genes as shown by CRISPR/Cas knockout and RNAi. Inhibition of endothelial sprouting by ZNF354C is dependent on the amino acids DV and MLE of the KRAB domain. These results demonstrate that ZNF354C is a repressive transcription factor which acts through a KRAB domain to inhibit endothelial angiogenic sprouting.</p>', 'date' => '2020-11-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/33154469', 'doi' => '10.1038/s41598-020-76193-0', 'modified' => '2021-03-17 17:19:53', 'created' => '2021-02-18 10:21:53', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '3956', 'name' => 'AP-1 controls the p11-dependent antidepressant response.', 'authors' => 'Chottekalapanda RU, Kalik S, Gresack J, Ayala A, Gao M, Wang W, Meller S, Aly A, Schaefer A, Greengard P', 'description' => '<p>Selective serotonin reuptake inhibitors (SSRIs) are the most widely prescribed drugs for mood disorders. While the mechanism of SSRI action is still unknown, SSRIs are thought to exert therapeutic effects by elevating extracellular serotonin levels in the brain, and remodel the structural and functional alterations dysregulated during depression. To determine their precise mode of action, we tested whether such neuroadaptive processes are modulated by regulation of specific gene expression programs. Here we identify a transcriptional program regulated by activator protein-1 (AP-1) complex, formed by c-Fos and c-Jun that is selectively activated prior to the onset of the chronic SSRI response. The AP-1 transcriptional program modulates the expression of key neuronal remodeling genes, including S100a10 (p11), linking neuronal plasticity to the antidepressant response. We find that AP-1 function is required for the antidepressant effect in vivo. Furthermore, we demonstrate how neurochemical pathways of BDNF and FGF2, through the MAPK, PI3K, and JNK cascades, regulate AP-1 function to mediate the beneficial effects of the antidepressant response. Here we put forth a sequential molecular network to track the antidepressant response and provide a new avenue that could be used to accelerate or potentiate antidepressant responses by triggering neuroplasticity.</p>', 'date' => '2020-05-21', 'pmid' => 'http://www.pubmed.gov/32439846', 'doi' => '10.1038/s41380-020-0767-8', 'modified' => '2020-08-17 09:17:39', 'created' => '2020-08-10 12:12:25', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '3938', 'name' => 'Aging-regulated anti-apoptotic long non-coding RNA Sarrah augments recovery from acute myocardial infarction.', 'authors' => 'Trembinski DJ, Bink DI, Theodorou K, Sommer J, Fischer A, van Bergen A, Kuo CC, Costa IG, Schürmann C, Leisegang MS, Brandes RP, Alekseeva T, Brill B, Wietelmann A, Johnson CN, Spring-Connell A, Kaulich M, Werfel S, Engelhardt S, Hirt MN, Yorgan K, Eschen', 'description' => '<p>Long non-coding RNAs (lncRNAs) contribute to cardiac (patho)physiology. Aging is the major risk factor for cardiovascular disease with cardiomyocyte apoptosis as one underlying cause. Here, we report the identification of the aging-regulated lncRNA Sarrah (ENSMUST00000140003) that is anti-apoptotic in cardiomyocytes. Importantly, loss of SARRAH (OXCT1-AS1) in human engineered heart tissue results in impaired contractile force development. SARRAH directly binds to the promoters of genes downregulated after SARRAH silencing via RNA-DNA triple helix formation and cardiomyocytes lacking the triple helix forming domain of Sarrah show an increase in apoptosis. One of the direct SARRAH targets is NRF2, and restoration of NRF2 levels after SARRAH silencing partially rescues the reduction in cell viability. Overexpression of Sarrah in mice shows better recovery of cardiac contractile function after AMI compared to control mice. In summary, we identified the anti-apoptotic evolutionary conserved lncRNA Sarrah, which is downregulated by aging, as a regulator of cardiomyocyte survival.</p>', 'date' => '2020-04-27', 'pmid' => 'http://www.pubmed.gov/32341350', 'doi' => '10.1038/s41467-020-15995-2', 'modified' => '2020-08-17 10:30:19', 'created' => '2020-08-10 12:12:25', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '3866', 'name' => 'Inhibition of histone deacetylation rescues phenotype in a mouse model of Birk-Barel intellectual disability syndrome.', 'authors' => 'Cooper A, Butto T, Hammer N, Jagannath S, Fend-Guella DL, Akhtar J, Radyushkin K, Lesage F, Winter J, Strand S, Roeper J, Zechner U, Schweiger S', 'description' => '<p>Mutations in the actively expressed, maternal allele of the imprinted KCNK9 gene cause Birk-Barel intellectual disability syndrome (BBIDS). Using a BBIDS mouse model, we identify here a partial rescue of the BBIDS-like behavioral and neuronal phenotypes mediated via residual expression from the paternal Kcnk9 (Kcnk9) allele. We further demonstrate that the second-generation HDAC inhibitor CI-994 induces enhanced expression from the paternally silenced Kcnk9 allele and leads to a full rescue of the behavioral phenotype suggesting CI-994 as a promising molecule for BBIDS therapy. Thus, these findings suggest a potential approach to improve cognitive dysfunction in a mouse model of an imprinting disorder.</p>', 'date' => '2020-01-24', 'pmid' => 'http://www.pubmed.gov/31980599', 'doi' => '10.1038/s41467-019-13918-4', 'modified' => '2020-03-20 17:50:11', 'created' => '2020-03-13 13:45:54', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '3837', 'name' => 'H3K4me1 Supports Memory-like NK Cells Induced by Systemic Inflammation.', 'authors' => 'Rasid O, Chevalier C, Camarasa TM, Fitting C, Cavaillon JM, Hamon MA', 'description' => '<p>Natural killer (NK) cells are unique players in innate immunity and, as such, an attractive target for immunotherapy. NK cells display immune memory properties in certain models, but the long-term status of NK cells following systemic inflammation is unknown. Here we show that following LPS-induced endotoxemia in mice, NK cells acquire cell-intrinsic memory-like properties, showing increased production of IFNγ upon specific secondary stimulation. The NK cell memory response is detectable for at least 9 weeks and contributes to protection from E. coli infection upon adoptive transfer. Importantly, we reveal a mechanism essential for NK cell memory, whereby an H3K4me1-marked latent enhancer is uncovered at the ifng locus. Chemical inhibition of histone methyltransferase activity erases the enhancer and abolishes NK cell memory. Thus, NK cell memory develops after endotoxemia in a histone methylation-dependent manner, ensuring a heightened response to secondary stimulation.</p>', 'date' => '2019-12-17', 'pmid' => 'http://www.pubmed.gov/31851924', 'doi' => '10.1016/j.celrep.2019.11.043', 'modified' => '2020-02-20 11:24:10', 'created' => '2020-02-13 10:02:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 7 => array( 'id' => '3807', 'name' => 'Epigenetic remodelling licences adult cholangiocytes for organoid formation and liver regeneration.', 'authors' => 'Aloia L, McKie MA, Vernaz G, Cordero-Espinoza L, Aleksieva N, van den Ameele J, Antonica F, Font-Cunill B, Raven A, Aiese Cigliano R, Belenguer G, Mort RL, Brand AH, Zernicka-Goetz M, Forbes SJ, Miska EA, Huch M', 'description' => '<p>Following severe or chronic liver injury, adult ductal cells (cholangiocytes) contribute to regeneration by restoring both hepatocytes and cholangiocytes. We recently showed that ductal cells clonally expand as self-renewing liver organoids that retain their differentiation capacity into both hepatocytes and ductal cells. However, the molecular mechanisms by which adult ductal-committed cells acquire cellular plasticity, initiate organoids and regenerate the damaged tissue remain largely unknown. Here, we describe that ductal cells undergo a transient, genome-wide, remodelling of their transcriptome and epigenome during organoid initiation and in vivo following tissue damage. TET1-mediated hydroxymethylation licences differentiated ductal cells to initiate organoids and activate the regenerative programme through the transcriptional regulation of stem-cell genes and regenerative pathways including the YAP-Hippo signalling. Our results argue in favour of the remodelling of genomic methylome/hydroxymethylome landscapes as a general mechanism by which differentiated cells exit a committed state in response to tissue damage.</p>', 'date' => '2019-11-04', 'pmid' => 'http://www.pubmed.gov/31685987', 'doi' => '10.1038/s41556-019-0402-6', 'modified' => '2019-12-05 11:19:34', 'created' => '2019-12-02 15:25:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 8 => array( 'id' => '3735', 'name' => 'Interaction of Sox2 with RNA binding proteins in mouse embryonic stem cells.', 'authors' => 'Samudyata , Amaral PP, Engström PG, Robson SC, Nielsen ML, Kouzarides T, Castelo-Branco G', 'description' => '<p>Sox2 is a master transcriptional regulator of embryonic development. In this study, we determined the protein interactome of Sox2 in the chromatin and nucleoplasm of mouse embryonic stem (mES) cells. Apart from canonical interactions with pluripotency-regulating transcription factors, we identified interactions with several chromatin modulators, including members of the heterochromatin protein 1 (HP1) family, suggesting a role for Sox2 in chromatin-mediated transcriptional repression. Sox2 was also found to interact with RNA binding proteins (RBPs), including proteins involved in RNA processing. RNA immunoprecipitation followed by sequencing revealed that Sox2 associates with different messenger RNAs, as well as small nucleolar RNA Snord34 and the non-coding RNA 7SK. 7SK has been shown to regulate transcription at gene regulatory regions, which could suggest a functional interaction with Sox2 for chromatin recruitment. Nevertheless, we found no evidence of Sox2 modulating recruitment of 7SK to chromatin when examining 7SK chromatin occupancy by Chromatin Isolation by RNA Purification (ChIRP) in Sox2 depleted mES cells. In addition, knockdown of 7SK in mES cells did not lead to any change in Sox2 occupancy at 7SK-regulated genes. Thus, our results show that Sox2 extensively interacts with RBPs, and suggest that Sox2 and 7SK co-exist in a ribonucleoprotein complex whose function is not to regulate chromatin recruitment, but could rather regulate other processes in the nucleoplasm.</p>', 'date' => '2019-08-01', 'pmid' => 'http://www.pubmed.gov/31077711', 'doi' => '10.1016/j.yexcr.2019.05.006', 'modified' => '2019-08-06 17:01:21', 'created' => '2019-07-31 13:35:50', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 9 => array( 'id' => '3396', 'name' => 'The Itaconate Pathway Is a Central Regulatory Node Linking Innate Immune Tolerance and Trained Immunity', 'authors' => 'Domínguez-Andrés Jorge, Novakovic Boris, Li Yang, Scicluna Brendon P., Gresnigt Mark S., Arts Rob J.W., Oosting Marije, Moorlag Simone J.C.F.M., Groh Laszlo A., Zwaag Jelle, Koch Rebecca M., ter Horst Rob, Joosten Leo A.B., Wijmenga Cisca, Michelucci Ales', 'description' => '<p>Sepsis involves simultaneous hyperactivation of the immune system and immune paralysis, leading to both organ dysfunction and increased susceptibility to secondary infections. Acute activation of myeloid cells induced itaconate synthesis, which subsequently mediated innate immune tolerance in human monocytes. In contrast, induction of trained immunity by b-glucan counteracted tolerance induced in a model of human endotoxemia by inhibiting the expression of immune-responsive gene 1 (IRG1), the enzyme that controls itaconate synthesis. b-Glucan also increased the expression of succinate dehydrogenase (SDH), contributing to the integrity of the TCA cycle and leading to an enhanced innate immune response after secondary stimulation. The role of itaconate was further validated by IRG1 and SDH polymorphisms that modulate induction of tolerance and trained immunity in human monocytes. These data demonstrate the importance of the IRG1-itaconateSDH axis in the development of immune tolerance and training and highlight the potential of b-glucaninduced trained immunity to revert immunoparalysis.</p>', 'date' => '2018-10-01', 'pmid' => 'http://www.pubmed.gov/30293776', 'doi' => '10.1016/j.cmet.2018.09.003', 'modified' => '2018-11-22 15:18:30', 'created' => '2018-11-08 12:59:45', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 10 => array( 'id' => '3407', 'name' => 'The histone demethylase Jarid1b mediates angiotensin II-induced endothelial dysfunction by controlling the 3'UTR of soluble epoxide hydrolase.', 'authors' => 'Vasconez AE, Janetzko P, Oo JA, Pflüger-Müller B, Ratiu C, Gu L, Helin K, Geisslinger G, Fleming I, Schröder K, Fork C, Brandes RP, Leisegang MS', 'description' => '<p>AIM: The histone demethylase Jarid1b limits gene expression by removing the active methyl mark from histone3 lysine4 at gene promoter regions. A vascular function of Jarid1b is unknown, but a vasoprotective function to inflammatory and hypertrophic stimuli, like angiotensin II (AngII) could be inferred. This hypothesis was tested using Jarid1b knockout mice and the inhibitor PBIT. METHODS: Mice or aortic segments were treated with AngII to induce endothelial dysfunction. Aortae from WT and Jarid1b knockout were studied in organ chambers and endothelium-dependent dilator responses to acetylcholine and endothelium-independent responses to DetaNONOate were recorded after pre-constriction with phenylephrine in the presence or absence of the NO-synthase inhibitor nitro-L-arginine. Molecular mechanisms were investigated with chromatin immunoprecipitation, RNA-Seq, RNA-3'-adaptor-ligation, actinomycin D and RNA-immunoprecipitation. RESULTS: Knockout or inhibition of Jarid1b prevented the development of endothelial dysfunction in response to AngII. This effect was not a consequence of altered nitrite oxide availability but accompanied by a loss of the inflammatory response to AngII. As Jarid1b mainly inhibits gene expression, an indirect effect should account for this observation. AngII induced the soluble epoxide hydrolase (sEH), which degrades anti-inflammatory lipids, and thus promotes inflammation. Knockout or inhibition of Jarid1b prevented the AngII-mediated sEH induction. Mechanistically, Jarid1b maintained the length of the 3'untranslated region of the sEH mRNA, thereby increasing its stability and thus sEH protein expression. Loss of Jarid1b activity therefore resulted in sEH mRNA destabilization. CONCLUSION: Jarid1b contributes to the pro-inflammatory effects of AngII by stabilizing sEH expression. Jarid1b inhibition might be an option for future therapeutics against cardiovascular dysfunction.</p>', 'date' => '2018-08-04', 'pmid' => 'http://www.pubmed.gov/30076673', 'doi' => '10.1111/apha.13168', 'modified' => '2018-11-09 11:18:29', 'created' => '2018-11-08 12:59:45', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 11 => array( 'id' => '3632', 'name' => 'Epigenetic regulation of brain region-specific microglia clearance activity.', 'authors' => 'Ayata P, Badimon A, Strasburger HJ, Duff MK, Montgomery SE, Loh YE, Ebert A, Pimenova AA, Ramirez BR, Chan AT, Sullivan JM, Purushothaman I, Scarpa JR, Goate AM, Busslinger M, Shen L, Losic B, Schaefer A', 'description' => '<p>The rapid elimination of dying neurons and nonfunctional synapses in the brain is carried out by microglia, the resident myeloid cells of the brain. Here we show that microglia clearance activity in the adult brain is regionally regulated and depends on the rate of neuronal attrition. Cerebellar, but not striatal or cortical, microglia exhibited high levels of basal clearance activity, which correlated with an elevated degree of cerebellar neuronal attrition. Exposing forebrain microglia to apoptotic cells activated gene-expression programs supporting clearance activity. We provide evidence that the polycomb repressive complex 2 (PRC2) epigenetically restricts the expression of genes that support clearance activity in striatal and cortical microglia. Loss of PRC2 leads to aberrant activation of a microglia clearance phenotype, which triggers changes in neuronal morphology and behavior. Our data highlight a key role of epigenetic mechanisms in preventing microglia-induced neuronal alterations that are frequently associated with neurodegenerative and psychiatric diseases.</p>', 'date' => '2018-08-01', 'pmid' => 'http://www.pubmed.gov/30038282', 'doi' => '10.1038/s41593-018-0192-3', 'modified' => '2019-06-07 10:34:03', 'created' => '2019-06-06 12:11:18', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 12 => array( 'id' => '3621', 'name' => 'Episomal HBV persistence within transcribed host nuclear chromatin compartments involves HBx.', 'authors' => 'Hensel KO, Cantner F, Bangert F, Wirth S, Postberg J', 'description' => '<p>BACKGROUND: In hepatocyte nuclei, hepatitis B virus (HBV) genomes occur episomally as covalently closed circular DNA (cccDNA). The HBV X protein (HBx) is required to initiate and maintain HBV replication. The functional nuclear localization of cccDNA and HBx remains unexplored. RESULTS: To identify virus-host genome interactions and the underlying nuclear landscape for the first time, we combined circular chromosome conformation capture (4C) with RNA-seq and ChIP-seq. Moreover, we studied HBx-binding to HBV episomes. In HBV-positive HepaRG hepatocytes, we observed preferential association of HBV episomes and HBx with actively transcribed nuclear domains on the host genome correlating in size with constrained topological units of chromatin. Interestingly, HBx alone occupied transcribed chromatin domains. Silencing of native HBx caused reduced episomal HBV stability. CONCLUSIONS: As part of the HBV episome, HBx might stabilize HBV episomal nuclear localization. Our observations may contribute to the understanding of long-term episomal stability and the facilitation of viral persistence. The exact mechanism by which HBx contributes to HBV nuclear persistence warrants further investigations.</p>', 'date' => '2018-06-22', 'pmid' => 'http://www.pubmed.gov/29933745', 'doi' => '10.1186/s13072-018-0204-2', 'modified' => '2019-05-16 11:23:59', 'created' => '2019-04-25 11:11:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 13 => array( 'id' => '3541', 'name' => 'Long noncoding RNA LISPR1 is required for S1P signaling and endothelial cell function.', 'authors' => 'Josipovic I, Pflüger B, Fork C, Vasconez AE, Oo JA, Hitzel J, Seredinski S, Gamen E, Heringdorf DMZ, Chen W, Looso M, Pullamsetti SS, Brandes RP, Leisegang MS', 'description' => '<p>Sphingosine-1-Phosphate (S1P) is a potent signaling lipid. The effects of S1P are mediated by the five S1P receptors (S1PR). In the endothelium S1PR1 is the predominant receptor and thus S1PR1 abundance limits S1P signaling. Recently, lncRNAs were identified as a novel class of molecules regulating gene expression. Interestingly, the lncRNA NONHSAT004848 (LISPR1, Long intergenic noncoding RNA antisense to S1PR1), is closely positioned to the S1P1 receptors gene and in part shares its promoter region. We hypothesize that LISPR1 controls endothelial S1PR1 expression and thus S1P-induced signaling in endothelial cells. In vitro transcription and translation as well as coding potential assessment showed that LISPR1 is indeed noncoding. LISPR1 was localized in both cytoplasm and nucleus and harbored a PolyA tail at the 3'end. In human umbilical vein endothelial cells, as well as human lung tissue, qRT-PCR and RNA-Seq revealed high expression of LISPR1. S1PR1 and LISPR1 were downregulated in human pulmonary diseases such as COPD. LISPR1 but also S1PR1 were induced by inflammation, shear stress and statins. Knockdown of LISPR1 attenuated endothelial S1P-induced migration and spheroid outgrowth of endothelial cells. LISPR1 knockdown decreased S1PR1 expression, which was paralleled by an increase of the binding of the transcriptional repressor ZNF354C to the S1PR1 promoter and a reduction of the recruitment of RNA Polymerase II to the S1PR1 5'end. This resulted in attenuated S1PR1 expression and attenuated S1P downstream signaling. Collectively, the disease relevant lncRNA LISPR1 acts as a novel regulatory unit important for S1PR1 expression and endothelial cell function.</p>', 'date' => '2018-03-01', 'pmid' => 'http://www.pubmed.gov/29408197', 'doi' => '10.1016/j.yjmcc.2018.01.015', 'modified' => '2019-02-28 10:52:59', 'created' => '2019-02-27 12:54:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 14 => array( 'id' => '3446', 'name' => 'Metabolic Induction of Trained Immunity through the Mevalonate Pathway.', 'authors' => 'Bekkering S, Arts RJW, Novakovic B, Kourtzelis I, van der Heijden CDCC, Li Y, Popa CD, Ter Horst R, van Tuijl J, Netea-Maier RT, van de Veerdonk FL, Chavakis T, Joosten LAB, van der Meer JWM, Stunnenberg H, Riksen NP, Netea MG', 'description' => '<p>Innate immune cells can develop long-term memory after stimulation by microbial products during infections or vaccinations. Here, we report that metabolic signals can induce trained immunity. Pharmacological and genetic experiments reveal that activation of the cholesterol synthesis pathway, but not the synthesis of cholesterol itself, is essential for training of myeloid cells. Rather, the metabolite mevalonate is the mediator of training via activation of IGF1-R and mTOR and subsequent histone modifications in inflammatory pathways. Statins, which block mevalonate generation, prevent trained immunity induction. Furthermore, monocytes of patients with hyper immunoglobulin D syndrome (HIDS), who are mevalonate kinase deficient and accumulate mevalonate, have a constitutive trained immunity phenotype at both immunological and epigenetic levels, which could explain the attacks of sterile inflammation that these patients experience. Unraveling the role of mevalonate in trained immunity contributes to our understanding of the pathophysiology of HIDS and identifies novel therapeutic targets for clinical conditions with excessive activation of trained immunity.</p>', 'date' => '2018-01-11', 'pmid' => 'http://www.pubmed.gov/29328908', 'doi' => '10.1016/j.cell.2017.11.025', 'modified' => '2019-02-15 21:37:39', 'created' => '2019-02-14 15:01:22', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 15 => array( 'id' => '3408', 'name' => 'BCG Vaccination Protects against Experimental Viral Infection in Humans through the Induction of Cytokines Associated with Trained Immunity.', 'authors' => 'Arts RJW, Moorlag SJCFM, Novakovic B, Li Y, Wang SY, Oosting M, Kumar V, Xavier RJ, Wijmenga C, Joosten LAB, Reusken CBEM, Benn CS, Aaby P, Koopmans MP, Stunnenberg HG, van Crevel R, Netea MG', 'description' => '<p>The tuberculosis vaccine bacillus Calmette-Guérin (BCG) has heterologous beneficial effects against non-related infections. The basis of these effects has been poorly explored in humans. In a randomized placebo-controlled human challenge study, we found that BCG vaccination induced genome-wide epigenetic reprograming of monocytes and protected against experimental infection with an attenuated yellow fever virus vaccine strain. Epigenetic reprogramming was accompanied by functional changes indicative of trained immunity. Reduction of viremia was highly correlated with the upregulation of IL-1β, a heterologous cytokine associated with the induction of trained immunity, but not with the specific IFNγ response. The importance of IL-1β for the induction of trained immunity was validated through genetic, epigenetic, and immunological studies. In conclusion, BCG induces epigenetic reprogramming in human monocytes in vivo, followed by functional reprogramming and protection against non-related viral infections, with a key role for IL-1β as a mediator of trained immunity responses.</p>', 'date' => '2018-01-10', 'pmid' => 'http://www.pubmed.gov/29324233', 'doi' => '10.1016/j.chom.2017.12.010', 'modified' => '2018-11-22 15:15:09', 'created' => '2018-11-08 12:59:45', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 16 => array( 'id' => '3013', 'name' => 'Polycomb repressive complex 2 (PRC2) silences genes responsible for neurodegeneration', 'authors' => 'von Schimmelmann M et al.', 'description' => '<p>Normal brain function depends on the interaction between highly specialized neurons that operate within anatomically and functionally distinct brain regions. Neuronal specification is driven by transcriptional programs that are established during early neuronal development and remain in place in the adult brain. The fidelity of neuronal specification depends on the robustness of the transcriptional program that supports the neuron type-specific gene expression patterns. Here we show that polycomb repressive complex 2 (PRC2), which supports neuron specification during differentiation, contributes to the suppression of a transcriptional program that is detrimental to adult neuron function and survival. We show that PRC2 deficiency in striatal neurons leads to the de-repression of selected, predominantly bivalent PRC2 target genes that are dominated by self-regulating transcription factors normally suppressed in these neurons. The transcriptional changes in PRC2-deficient neurons lead to progressive and fatal neurodegeneration in mice. Our results point to a key role of PRC2 in protecting neurons against degeneration.</p>', 'date' => '2016-08-15', 'pmid' => 'http://www.nature.com/neuro/journal/vaop/ncurrent/full/nn.4360.html', 'doi' => '', 'modified' => '2016-08-31 09:10:11', 'created' => '2016-08-31 09:10:11', 'ProductsPublication' => array( [maximum depth reached] ) ) ), 'Testimonial' => array(), 'Area' => array(), 'SafetySheet' => array( (int) 0 => array( 'id' => '312', 'name' => 'DiaMag protein G-coated magnetic beads SDS US en', 'language' => 'en', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-US-en-GHS_1_0.pdf', 'countries' => 'US', 'modified' => '2020-06-09 12:24:02', 'created' => '2020-06-09 12:24:02', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '310', 'name' => 'DiaMag protein G-coated magnetic beads SDS GB en', 'language' => 'en', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-GB-en-GHS_1_0.pdf', 'countries' => 'GB', 'modified' => '2020-06-09 12:22:54', 'created' => '2020-06-09 12:22:54', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '305', 'name' => 'DiaMag protein G-coated magnetic beads SDS BE fr', 'language' => 'fr', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-BE-fr-GHS_1_0.pdf', 'countries' => 'BE', 'modified' => '2020-06-09 12:19:06', 'created' => '2020-06-09 12:19:06', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '309', 'name' => 'DiaMag protein G-coated magnetic beads SDS FR fr', 'language' => 'fr', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-FR-fr-GHS_1_0.pdf', 'countries' => 'FR', 'modified' => '2020-06-09 12:22:18', 'created' => '2020-06-09 12:22:18', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '308', 'name' => 'DiaMag protein G-coated magnetic beads SDS ES es', 'language' => 'es', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-ES-es-GHS_1_0.pdf', 'countries' => 'ES', 'modified' => '2020-06-09 12:21:36', 'created' => '2020-06-09 12:21:36', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '307', 'name' => 'DiaMag protein G-coated magnetic beads SDS DE de', 'language' => 'de', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-DE-de-GHS_1_0.pdf', 'countries' => 'DE', 'modified' => '2020-06-09 12:21:03', 'created' => '2020-06-09 12:21:03', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '311', 'name' => 'DiaMag protein G-coated magnetic beads SDS JP ja', 'language' => 'ja', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-JP-ja-GHS_2_0.pdf', 'countries' => 'JP', 'modified' => '2020-06-09 12:23:28', 'created' => '2020-06-09 12:23:28', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 7 => array( 'id' => '306', 'name' => 'DiaMag protein G-coated magnetic beads SDS BE nl', 'language' => 'nl', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-BE-nl-GHS_1_0.pdf', 'countries' => 'BE', 'modified' => '2020-06-09 12:20:21', 'created' => '2020-06-09 12:20:21', 'ProductsSafetySheet' => array( [maximum depth reached] ) ) ) ) $meta_canonical = 'https://www.diagenode.com/en/p/diamag-protein-g-coated-magnetic-beads-220-ul' $country = 'US' $countries_allowed = array( (int) 0 => 'CA', (int) 1 => 'US', (int) 2 => 'IE', (int) 3 => 'GB', (int) 4 => 'DK', (int) 5 => 'NO', (int) 6 => 'SE', (int) 7 => 'FI', (int) 8 => 'NL', (int) 9 => 'BE', (int) 10 => 'LU', (int) 11 => 'FR', (int) 12 => 'DE', (int) 13 => 'CH', (int) 14 => 'AT', (int) 15 => 'ES', (int) 16 => 'IT', (int) 17 => 'PT' ) $outsource = false $other_formats = array( (int) 0 => array( 'id' => '1908', 'antibody_id' => null, 'name' => 'DiaMag protein G-coated magnetic beads (ChIP-seq grade)', 'description' => '<p>The protein G-coated magnetic beads have been extensively validated in chromatin immunoprecipitation assay (ChIP). 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Neuronal specification is driven by transcriptional programs that are established during early neuronal development and remain in place in the adult brain. The fidelity of neuronal specification depends on the robustness of the transcriptional program that supports the neuron type-specific gene expression patterns. Here we show that polycomb repressive complex 2 (PRC2), which supports neuron specification during differentiation, contributes to the suppression of a transcriptional program that is detrimental to adult neuron function and survival. We show that PRC2 deficiency in striatal neurons leads to the de-repression of selected, predominantly bivalent PRC2 target genes that are dominated by self-regulating transcription factors normally suppressed in these neurons. The transcriptional changes in PRC2-deficient neurons lead to progressive and fatal neurodegeneration in mice. Our results point to a key role of PRC2 in protecting neurons against degeneration.</p>', 'date' => '2016-08-15', 'pmid' => 'http://www.nature.com/neuro/journal/vaop/ncurrent/full/nn.4360.html', 'doi' => '', 'modified' => '2016-08-31 09:10:11', 'created' => '2016-08-31 09:10:11', 'ProductsPublication' => array( 'id' => '1555', 'product_id' => '1907', 'publication_id' => '3013' ) ) $externalLink = ' <a href="http://www.nature.com/neuro/journal/vaop/ncurrent/full/nn.4360.html" target="_blank"><i class="fa fa-external-link"></i></a>'include - APP/View/Products/view.ctp, line 755 View::_evaluate() - CORE/Cake/View/View.php, line 971 View::_render() - CORE/Cake/View/View.php, line 933 View::render() - CORE/Cake/View/View.php, line 473 Controller::render() - CORE/Cake/Controller/Controller.php, line 963 ProductsController::slug() - APP/Controller/ProductsController.php, line 1052 ReflectionMethod::invokeArgs() - [internal], line ?? 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Factors governing the stability of the polymerase complex are not known. Previous studies characterizing the Pol I inhibitor BMH-21 revealed a transcriptional stress-dependent pathway for degradation of the largest subunit of Pol I, RPA194. To identify the E3 ligase(s) involved, we conducted a cell-based RNAi screen for ubiquitin pathway genes. We establish Skp-Cullin-F-box protein complex (SCF complex) F-box protein FBXL14 as an E3 ligase for RPA194. We show that FBXL14 binds to RPA194 and mediates RPA194 ubiquitination and degradation in cancer cells treated with BMH-21. Mutation analysis in yeast identified lysines 1150, 1153 and 1156 on Rpa190 relevant for the protein degradation. These results reveal the regulated turnover of Pol I, showing that the stability of the catalytic subunit is controlled by the F-box protein FBXL14 in response to transcription stress.</p>', 'date' => '2022-11-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/36372232', 'doi' => '10.1016/j.jbc.2022.102690', 'modified' => '2022-11-24 10:19:52', 'created' => '2022-11-24 08:49:52', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '4188', 'name' => 'Inhibition of HIV-1 gene transcription by KAP1 in myeloid lineage.', 'authors' => 'Ait-Ammar A. et al.', 'description' => '<p>HIV-1 latency generates reservoirs that prevent viral eradication by the current therapies. To find strategies toward an HIV cure, detailed understandings of the molecular mechanisms underlying establishment and persistence of the reservoirs are needed. The cellular transcription factor KAP1 is known as a potent repressor of gene transcription. Here we report that KAP1 represses HIV-1 gene expression in myeloid cells including microglial cells, the major reservoir of the central nervous system. Mechanistically, KAP1 interacts and colocalizes with the viral transactivator Tat to promote its degradation via the proteasome pathway and repress HIV-1 gene expression. In myeloid models of latent HIV-1 infection, the depletion of KAP1 increased viral gene elongation and reactivated HIV-1 expression. Bound to the latent HIV-1 promoter, KAP1 associates and cooperates with CTIP2, a key epigenetic silencer of HIV-1 expression in microglial cells. In addition, Tat and CTIP2 compete for KAP1 binding suggesting a dynamic modulation of the KAP1 cellular partners upon HIV-1 infection. Altogether, our results suggest that KAP1 contributes to the establishment and the persistence of HIV-1 latency in myeloid cells.</p>', 'date' => '2021-01-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/33514850', 'doi' => '10.1038/s41598-021-82164-w', 'modified' => '2022-01-05 15:08:41', 'created' => '2021-12-06 15:53:19', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '4095', 'name' => 'ZNF354C is a transcriptional repressor that inhibits endothelialangiogenic sprouting.', 'authors' => 'Oo, James A and Irmer, Barnabas and Günther, Stefan and Warwick, Timothyand Pálfi, Katalin and Izquierdo Ponce, Judit and Teichmann, Tom andPflüger-Müller, Beatrice and Gilsbach, Ralf and Brandes, Ralf P andLeisegang, Matthias S', 'description' => '<p>Zinc finger proteins (ZNF) are a large group of transcription factors with diverse functions. We recently discovered that endothelial cells harbour a specific mechanism to limit the action of ZNF354C, whose function in endothelial cells is unknown. Given that ZNF354C has so far only been studied in bone and tumour, its function was determined in endothelial cells. ZNF354C is expressed in vascular cells and localises to the nucleus and cytoplasm. Overexpression of ZNF354C in human endothelial cells results in a marked inhibition of endothelial sprouting. RNA-sequencing of human microvascular endothelial cells with and without overexpression of ZNF354C revealed that the protein is a potent transcriptional repressor. ZNF354C contains an active KRAB domain which mediates this suppression as shown by mutagenesis analysis. ZNF354C interacts with dsDNA, TRIM28 and histones, as observed by proximity ligation and immunoprecipitation. Moreover, chromatin immunoprecipitation revealed that the ZNF binds to specific endothelial-relevant target-gene promoters. ZNF354C suppresses these genes as shown by CRISPR/Cas knockout and RNAi. Inhibition of endothelial sprouting by ZNF354C is dependent on the amino acids DV and MLE of the KRAB domain. These results demonstrate that ZNF354C is a repressive transcription factor which acts through a KRAB domain to inhibit endothelial angiogenic sprouting.</p>', 'date' => '2020-11-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/33154469', 'doi' => '10.1038/s41598-020-76193-0', 'modified' => '2021-03-17 17:19:53', 'created' => '2021-02-18 10:21:53', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '3956', 'name' => 'AP-1 controls the p11-dependent antidepressant response.', 'authors' => 'Chottekalapanda RU, Kalik S, Gresack J, Ayala A, Gao M, Wang W, Meller S, Aly A, Schaefer A, Greengard P', 'description' => '<p>Selective serotonin reuptake inhibitors (SSRIs) are the most widely prescribed drugs for mood disorders. While the mechanism of SSRI action is still unknown, SSRIs are thought to exert therapeutic effects by elevating extracellular serotonin levels in the brain, and remodel the structural and functional alterations dysregulated during depression. To determine their precise mode of action, we tested whether such neuroadaptive processes are modulated by regulation of specific gene expression programs. Here we identify a transcriptional program regulated by activator protein-1 (AP-1) complex, formed by c-Fos and c-Jun that is selectively activated prior to the onset of the chronic SSRI response. The AP-1 transcriptional program modulates the expression of key neuronal remodeling genes, including S100a10 (p11), linking neuronal plasticity to the antidepressant response. We find that AP-1 function is required for the antidepressant effect in vivo. Furthermore, we demonstrate how neurochemical pathways of BDNF and FGF2, through the MAPK, PI3K, and JNK cascades, regulate AP-1 function to mediate the beneficial effects of the antidepressant response. Here we put forth a sequential molecular network to track the antidepressant response and provide a new avenue that could be used to accelerate or potentiate antidepressant responses by triggering neuroplasticity.</p>', 'date' => '2020-05-21', 'pmid' => 'http://www.pubmed.gov/32439846', 'doi' => '10.1038/s41380-020-0767-8', 'modified' => '2020-08-17 09:17:39', 'created' => '2020-08-10 12:12:25', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '3938', 'name' => 'Aging-regulated anti-apoptotic long non-coding RNA Sarrah augments recovery from acute myocardial infarction.', 'authors' => 'Trembinski DJ, Bink DI, Theodorou K, Sommer J, Fischer A, van Bergen A, Kuo CC, Costa IG, Schürmann C, Leisegang MS, Brandes RP, Alekseeva T, Brill B, Wietelmann A, Johnson CN, Spring-Connell A, Kaulich M, Werfel S, Engelhardt S, Hirt MN, Yorgan K, Eschen', 'description' => '<p>Long non-coding RNAs (lncRNAs) contribute to cardiac (patho)physiology. Aging is the major risk factor for cardiovascular disease with cardiomyocyte apoptosis as one underlying cause. Here, we report the identification of the aging-regulated lncRNA Sarrah (ENSMUST00000140003) that is anti-apoptotic in cardiomyocytes. Importantly, loss of SARRAH (OXCT1-AS1) in human engineered heart tissue results in impaired contractile force development. SARRAH directly binds to the promoters of genes downregulated after SARRAH silencing via RNA-DNA triple helix formation and cardiomyocytes lacking the triple helix forming domain of Sarrah show an increase in apoptosis. One of the direct SARRAH targets is NRF2, and restoration of NRF2 levels after SARRAH silencing partially rescues the reduction in cell viability. Overexpression of Sarrah in mice shows better recovery of cardiac contractile function after AMI compared to control mice. In summary, we identified the anti-apoptotic evolutionary conserved lncRNA Sarrah, which is downregulated by aging, as a regulator of cardiomyocyte survival.</p>', 'date' => '2020-04-27', 'pmid' => 'http://www.pubmed.gov/32341350', 'doi' => '10.1038/s41467-020-15995-2', 'modified' => '2020-08-17 10:30:19', 'created' => '2020-08-10 12:12:25', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '3866', 'name' => 'Inhibition of histone deacetylation rescues phenotype in a mouse model of Birk-Barel intellectual disability syndrome.', 'authors' => 'Cooper A, Butto T, Hammer N, Jagannath S, Fend-Guella DL, Akhtar J, Radyushkin K, Lesage F, Winter J, Strand S, Roeper J, Zechner U, Schweiger S', 'description' => '<p>Mutations in the actively expressed, maternal allele of the imprinted KCNK9 gene cause Birk-Barel intellectual disability syndrome (BBIDS). Using a BBIDS mouse model, we identify here a partial rescue of the BBIDS-like behavioral and neuronal phenotypes mediated via residual expression from the paternal Kcnk9 (Kcnk9) allele. We further demonstrate that the second-generation HDAC inhibitor CI-994 induces enhanced expression from the paternally silenced Kcnk9 allele and leads to a full rescue of the behavioral phenotype suggesting CI-994 as a promising molecule for BBIDS therapy. Thus, these findings suggest a potential approach to improve cognitive dysfunction in a mouse model of an imprinting disorder.</p>', 'date' => '2020-01-24', 'pmid' => 'http://www.pubmed.gov/31980599', 'doi' => '10.1038/s41467-019-13918-4', 'modified' => '2020-03-20 17:50:11', 'created' => '2020-03-13 13:45:54', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '3837', 'name' => 'H3K4me1 Supports Memory-like NK Cells Induced by Systemic Inflammation.', 'authors' => 'Rasid O, Chevalier C, Camarasa TM, Fitting C, Cavaillon JM, Hamon MA', 'description' => '<p>Natural killer (NK) cells are unique players in innate immunity and, as such, an attractive target for immunotherapy. NK cells display immune memory properties in certain models, but the long-term status of NK cells following systemic inflammation is unknown. Here we show that following LPS-induced endotoxemia in mice, NK cells acquire cell-intrinsic memory-like properties, showing increased production of IFNγ upon specific secondary stimulation. The NK cell memory response is detectable for at least 9 weeks and contributes to protection from E. coli infection upon adoptive transfer. Importantly, we reveal a mechanism essential for NK cell memory, whereby an H3K4me1-marked latent enhancer is uncovered at the ifng locus. Chemical inhibition of histone methyltransferase activity erases the enhancer and abolishes NK cell memory. Thus, NK cell memory develops after endotoxemia in a histone methylation-dependent manner, ensuring a heightened response to secondary stimulation.</p>', 'date' => '2019-12-17', 'pmid' => 'http://www.pubmed.gov/31851924', 'doi' => '10.1016/j.celrep.2019.11.043', 'modified' => '2020-02-20 11:24:10', 'created' => '2020-02-13 10:02:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 7 => array( 'id' => '3807', 'name' => 'Epigenetic remodelling licences adult cholangiocytes for organoid formation and liver regeneration.', 'authors' => 'Aloia L, McKie MA, Vernaz G, Cordero-Espinoza L, Aleksieva N, van den Ameele J, Antonica F, Font-Cunill B, Raven A, Aiese Cigliano R, Belenguer G, Mort RL, Brand AH, Zernicka-Goetz M, Forbes SJ, Miska EA, Huch M', 'description' => '<p>Following severe or chronic liver injury, adult ductal cells (cholangiocytes) contribute to regeneration by restoring both hepatocytes and cholangiocytes. We recently showed that ductal cells clonally expand as self-renewing liver organoids that retain their differentiation capacity into both hepatocytes and ductal cells. However, the molecular mechanisms by which adult ductal-committed cells acquire cellular plasticity, initiate organoids and regenerate the damaged tissue remain largely unknown. Here, we describe that ductal cells undergo a transient, genome-wide, remodelling of their transcriptome and epigenome during organoid initiation and in vivo following tissue damage. TET1-mediated hydroxymethylation licences differentiated ductal cells to initiate organoids and activate the regenerative programme through the transcriptional regulation of stem-cell genes and regenerative pathways including the YAP-Hippo signalling. Our results argue in favour of the remodelling of genomic methylome/hydroxymethylome landscapes as a general mechanism by which differentiated cells exit a committed state in response to tissue damage.</p>', 'date' => '2019-11-04', 'pmid' => 'http://www.pubmed.gov/31685987', 'doi' => '10.1038/s41556-019-0402-6', 'modified' => '2019-12-05 11:19:34', 'created' => '2019-12-02 15:25:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 8 => array( 'id' => '3735', 'name' => 'Interaction of Sox2 with RNA binding proteins in mouse embryonic stem cells.', 'authors' => 'Samudyata , Amaral PP, Engström PG, Robson SC, Nielsen ML, Kouzarides T, Castelo-Branco G', 'description' => '<p>Sox2 is a master transcriptional regulator of embryonic development. In this study, we determined the protein interactome of Sox2 in the chromatin and nucleoplasm of mouse embryonic stem (mES) cells. Apart from canonical interactions with pluripotency-regulating transcription factors, we identified interactions with several chromatin modulators, including members of the heterochromatin protein 1 (HP1) family, suggesting a role for Sox2 in chromatin-mediated transcriptional repression. Sox2 was also found to interact with RNA binding proteins (RBPs), including proteins involved in RNA processing. RNA immunoprecipitation followed by sequencing revealed that Sox2 associates with different messenger RNAs, as well as small nucleolar RNA Snord34 and the non-coding RNA 7SK. 7SK has been shown to regulate transcription at gene regulatory regions, which could suggest a functional interaction with Sox2 for chromatin recruitment. Nevertheless, we found no evidence of Sox2 modulating recruitment of 7SK to chromatin when examining 7SK chromatin occupancy by Chromatin Isolation by RNA Purification (ChIRP) in Sox2 depleted mES cells. In addition, knockdown of 7SK in mES cells did not lead to any change in Sox2 occupancy at 7SK-regulated genes. Thus, our results show that Sox2 extensively interacts with RBPs, and suggest that Sox2 and 7SK co-exist in a ribonucleoprotein complex whose function is not to regulate chromatin recruitment, but could rather regulate other processes in the nucleoplasm.</p>', 'date' => '2019-08-01', 'pmid' => 'http://www.pubmed.gov/31077711', 'doi' => '10.1016/j.yexcr.2019.05.006', 'modified' => '2019-08-06 17:01:21', 'created' => '2019-07-31 13:35:50', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 9 => array( 'id' => '3396', 'name' => 'The Itaconate Pathway Is a Central Regulatory Node Linking Innate Immune Tolerance and Trained Immunity', 'authors' => 'Domínguez-Andrés Jorge, Novakovic Boris, Li Yang, Scicluna Brendon P., Gresnigt Mark S., Arts Rob J.W., Oosting Marije, Moorlag Simone J.C.F.M., Groh Laszlo A., Zwaag Jelle, Koch Rebecca M., ter Horst Rob, Joosten Leo A.B., Wijmenga Cisca, Michelucci Ales', 'description' => '<p>Sepsis involves simultaneous hyperactivation of the immune system and immune paralysis, leading to both organ dysfunction and increased susceptibility to secondary infections. Acute activation of myeloid cells induced itaconate synthesis, which subsequently mediated innate immune tolerance in human monocytes. In contrast, induction of trained immunity by b-glucan counteracted tolerance induced in a model of human endotoxemia by inhibiting the expression of immune-responsive gene 1 (IRG1), the enzyme that controls itaconate synthesis. b-Glucan also increased the expression of succinate dehydrogenase (SDH), contributing to the integrity of the TCA cycle and leading to an enhanced innate immune response after secondary stimulation. The role of itaconate was further validated by IRG1 and SDH polymorphisms that modulate induction of tolerance and trained immunity in human monocytes. These data demonstrate the importance of the IRG1-itaconateSDH axis in the development of immune tolerance and training and highlight the potential of b-glucaninduced trained immunity to revert immunoparalysis.</p>', 'date' => '2018-10-01', 'pmid' => 'http://www.pubmed.gov/30293776', 'doi' => '10.1016/j.cmet.2018.09.003', 'modified' => '2018-11-22 15:18:30', 'created' => '2018-11-08 12:59:45', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 10 => array( 'id' => '3407', 'name' => 'The histone demethylase Jarid1b mediates angiotensin II-induced endothelial dysfunction by controlling the 3'UTR of soluble epoxide hydrolase.', 'authors' => 'Vasconez AE, Janetzko P, Oo JA, Pflüger-Müller B, Ratiu C, Gu L, Helin K, Geisslinger G, Fleming I, Schröder K, Fork C, Brandes RP, Leisegang MS', 'description' => '<p>AIM: The histone demethylase Jarid1b limits gene expression by removing the active methyl mark from histone3 lysine4 at gene promoter regions. A vascular function of Jarid1b is unknown, but a vasoprotective function to inflammatory and hypertrophic stimuli, like angiotensin II (AngII) could be inferred. This hypothesis was tested using Jarid1b knockout mice and the inhibitor PBIT. METHODS: Mice or aortic segments were treated with AngII to induce endothelial dysfunction. Aortae from WT and Jarid1b knockout were studied in organ chambers and endothelium-dependent dilator responses to acetylcholine and endothelium-independent responses to DetaNONOate were recorded after pre-constriction with phenylephrine in the presence or absence of the NO-synthase inhibitor nitro-L-arginine. Molecular mechanisms were investigated with chromatin immunoprecipitation, RNA-Seq, RNA-3'-adaptor-ligation, actinomycin D and RNA-immunoprecipitation. RESULTS: Knockout or inhibition of Jarid1b prevented the development of endothelial dysfunction in response to AngII. This effect was not a consequence of altered nitrite oxide availability but accompanied by a loss of the inflammatory response to AngII. As Jarid1b mainly inhibits gene expression, an indirect effect should account for this observation. AngII induced the soluble epoxide hydrolase (sEH), which degrades anti-inflammatory lipids, and thus promotes inflammation. Knockout or inhibition of Jarid1b prevented the AngII-mediated sEH induction. Mechanistically, Jarid1b maintained the length of the 3'untranslated region of the sEH mRNA, thereby increasing its stability and thus sEH protein expression. Loss of Jarid1b activity therefore resulted in sEH mRNA destabilization. CONCLUSION: Jarid1b contributes to the pro-inflammatory effects of AngII by stabilizing sEH expression. Jarid1b inhibition might be an option for future therapeutics against cardiovascular dysfunction.</p>', 'date' => '2018-08-04', 'pmid' => 'http://www.pubmed.gov/30076673', 'doi' => '10.1111/apha.13168', 'modified' => '2018-11-09 11:18:29', 'created' => '2018-11-08 12:59:45', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 11 => array( 'id' => '3632', 'name' => 'Epigenetic regulation of brain region-specific microglia clearance activity.', 'authors' => 'Ayata P, Badimon A, Strasburger HJ, Duff MK, Montgomery SE, Loh YE, Ebert A, Pimenova AA, Ramirez BR, Chan AT, Sullivan JM, Purushothaman I, Scarpa JR, Goate AM, Busslinger M, Shen L, Losic B, Schaefer A', 'description' => '<p>The rapid elimination of dying neurons and nonfunctional synapses in the brain is carried out by microglia, the resident myeloid cells of the brain. Here we show that microglia clearance activity in the adult brain is regionally regulated and depends on the rate of neuronal attrition. Cerebellar, but not striatal or cortical, microglia exhibited high levels of basal clearance activity, which correlated with an elevated degree of cerebellar neuronal attrition. Exposing forebrain microglia to apoptotic cells activated gene-expression programs supporting clearance activity. We provide evidence that the polycomb repressive complex 2 (PRC2) epigenetically restricts the expression of genes that support clearance activity in striatal and cortical microglia. Loss of PRC2 leads to aberrant activation of a microglia clearance phenotype, which triggers changes in neuronal morphology and behavior. Our data highlight a key role of epigenetic mechanisms in preventing microglia-induced neuronal alterations that are frequently associated with neurodegenerative and psychiatric diseases.</p>', 'date' => '2018-08-01', 'pmid' => 'http://www.pubmed.gov/30038282', 'doi' => '10.1038/s41593-018-0192-3', 'modified' => '2019-06-07 10:34:03', 'created' => '2019-06-06 12:11:18', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 12 => array( 'id' => '3621', 'name' => 'Episomal HBV persistence within transcribed host nuclear chromatin compartments involves HBx.', 'authors' => 'Hensel KO, Cantner F, Bangert F, Wirth S, Postberg J', 'description' => '<p>BACKGROUND: In hepatocyte nuclei, hepatitis B virus (HBV) genomes occur episomally as covalently closed circular DNA (cccDNA). The HBV X protein (HBx) is required to initiate and maintain HBV replication. The functional nuclear localization of cccDNA and HBx remains unexplored. RESULTS: To identify virus-host genome interactions and the underlying nuclear landscape for the first time, we combined circular chromosome conformation capture (4C) with RNA-seq and ChIP-seq. Moreover, we studied HBx-binding to HBV episomes. In HBV-positive HepaRG hepatocytes, we observed preferential association of HBV episomes and HBx with actively transcribed nuclear domains on the host genome correlating in size with constrained topological units of chromatin. Interestingly, HBx alone occupied transcribed chromatin domains. Silencing of native HBx caused reduced episomal HBV stability. CONCLUSIONS: As part of the HBV episome, HBx might stabilize HBV episomal nuclear localization. Our observations may contribute to the understanding of long-term episomal stability and the facilitation of viral persistence. The exact mechanism by which HBx contributes to HBV nuclear persistence warrants further investigations.</p>', 'date' => '2018-06-22', 'pmid' => 'http://www.pubmed.gov/29933745', 'doi' => '10.1186/s13072-018-0204-2', 'modified' => '2019-05-16 11:23:59', 'created' => '2019-04-25 11:11:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 13 => array( 'id' => '3541', 'name' => 'Long noncoding RNA LISPR1 is required for S1P signaling and endothelial cell function.', 'authors' => 'Josipovic I, Pflüger B, Fork C, Vasconez AE, Oo JA, Hitzel J, Seredinski S, Gamen E, Heringdorf DMZ, Chen W, Looso M, Pullamsetti SS, Brandes RP, Leisegang MS', 'description' => '<p>Sphingosine-1-Phosphate (S1P) is a potent signaling lipid. The effects of S1P are mediated by the five S1P receptors (S1PR). In the endothelium S1PR1 is the predominant receptor and thus S1PR1 abundance limits S1P signaling. Recently, lncRNAs were identified as a novel class of molecules regulating gene expression. Interestingly, the lncRNA NONHSAT004848 (LISPR1, Long intergenic noncoding RNA antisense to S1PR1), is closely positioned to the S1P1 receptors gene and in part shares its promoter region. We hypothesize that LISPR1 controls endothelial S1PR1 expression and thus S1P-induced signaling in endothelial cells. In vitro transcription and translation as well as coding potential assessment showed that LISPR1 is indeed noncoding. LISPR1 was localized in both cytoplasm and nucleus and harbored a PolyA tail at the 3'end. In human umbilical vein endothelial cells, as well as human lung tissue, qRT-PCR and RNA-Seq revealed high expression of LISPR1. S1PR1 and LISPR1 were downregulated in human pulmonary diseases such as COPD. LISPR1 but also S1PR1 were induced by inflammation, shear stress and statins. Knockdown of LISPR1 attenuated endothelial S1P-induced migration and spheroid outgrowth of endothelial cells. LISPR1 knockdown decreased S1PR1 expression, which was paralleled by an increase of the binding of the transcriptional repressor ZNF354C to the S1PR1 promoter and a reduction of the recruitment of RNA Polymerase II to the S1PR1 5'end. This resulted in attenuated S1PR1 expression and attenuated S1P downstream signaling. Collectively, the disease relevant lncRNA LISPR1 acts as a novel regulatory unit important for S1PR1 expression and endothelial cell function.</p>', 'date' => '2018-03-01', 'pmid' => 'http://www.pubmed.gov/29408197', 'doi' => '10.1016/j.yjmcc.2018.01.015', 'modified' => '2019-02-28 10:52:59', 'created' => '2019-02-27 12:54:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 14 => array( 'id' => '3446', 'name' => 'Metabolic Induction of Trained Immunity through the Mevalonate Pathway.', 'authors' => 'Bekkering S, Arts RJW, Novakovic B, Kourtzelis I, van der Heijden CDCC, Li Y, Popa CD, Ter Horst R, van Tuijl J, Netea-Maier RT, van de Veerdonk FL, Chavakis T, Joosten LAB, van der Meer JWM, Stunnenberg H, Riksen NP, Netea MG', 'description' => '<p>Innate immune cells can develop long-term memory after stimulation by microbial products during infections or vaccinations. Here, we report that metabolic signals can induce trained immunity. Pharmacological and genetic experiments reveal that activation of the cholesterol synthesis pathway, but not the synthesis of cholesterol itself, is essential for training of myeloid cells. Rather, the metabolite mevalonate is the mediator of training via activation of IGF1-R and mTOR and subsequent histone modifications in inflammatory pathways. Statins, which block mevalonate generation, prevent trained immunity induction. Furthermore, monocytes of patients with hyper immunoglobulin D syndrome (HIDS), who are mevalonate kinase deficient and accumulate mevalonate, have a constitutive trained immunity phenotype at both immunological and epigenetic levels, which could explain the attacks of sterile inflammation that these patients experience. Unraveling the role of mevalonate in trained immunity contributes to our understanding of the pathophysiology of HIDS and identifies novel therapeutic targets for clinical conditions with excessive activation of trained immunity.</p>', 'date' => '2018-01-11', 'pmid' => 'http://www.pubmed.gov/29328908', 'doi' => '10.1016/j.cell.2017.11.025', 'modified' => '2019-02-15 21:37:39', 'created' => '2019-02-14 15:01:22', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 15 => array( 'id' => '3408', 'name' => 'BCG Vaccination Protects against Experimental Viral Infection in Humans through the Induction of Cytokines Associated with Trained Immunity.', 'authors' => 'Arts RJW, Moorlag SJCFM, Novakovic B, Li Y, Wang SY, Oosting M, Kumar V, Xavier RJ, Wijmenga C, Joosten LAB, Reusken CBEM, Benn CS, Aaby P, Koopmans MP, Stunnenberg HG, van Crevel R, Netea MG', 'description' => '<p>The tuberculosis vaccine bacillus Calmette-Guérin (BCG) has heterologous beneficial effects against non-related infections. The basis of these effects has been poorly explored in humans. In a randomized placebo-controlled human challenge study, we found that BCG vaccination induced genome-wide epigenetic reprograming of monocytes and protected against experimental infection with an attenuated yellow fever virus vaccine strain. Epigenetic reprogramming was accompanied by functional changes indicative of trained immunity. Reduction of viremia was highly correlated with the upregulation of IL-1β, a heterologous cytokine associated with the induction of trained immunity, but not with the specific IFNγ response. The importance of IL-1β for the induction of trained immunity was validated through genetic, epigenetic, and immunological studies. In conclusion, BCG induces epigenetic reprogramming in human monocytes in vivo, followed by functional reprogramming and protection against non-related viral infections, with a key role for IL-1β as a mediator of trained immunity responses.</p>', 'date' => '2018-01-10', 'pmid' => 'http://www.pubmed.gov/29324233', 'doi' => '10.1016/j.chom.2017.12.010', 'modified' => '2018-11-22 15:15:09', 'created' => '2018-11-08 12:59:45', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 16 => array( 'id' => '3013', 'name' => 'Polycomb repressive complex 2 (PRC2) silences genes responsible for neurodegeneration', 'authors' => 'von Schimmelmann M et al.', 'description' => '<p>Normal brain function depends on the interaction between highly specialized neurons that operate within anatomically and functionally distinct brain regions. Neuronal specification is driven by transcriptional programs that are established during early neuronal development and remain in place in the adult brain. The fidelity of neuronal specification depends on the robustness of the transcriptional program that supports the neuron type-specific gene expression patterns. Here we show that polycomb repressive complex 2 (PRC2), which supports neuron specification during differentiation, contributes to the suppression of a transcriptional program that is detrimental to adult neuron function and survival. We show that PRC2 deficiency in striatal neurons leads to the de-repression of selected, predominantly bivalent PRC2 target genes that are dominated by self-regulating transcription factors normally suppressed in these neurons. The transcriptional changes in PRC2-deficient neurons lead to progressive and fatal neurodegeneration in mice. Our results point to a key role of PRC2 in protecting neurons against degeneration.</p>', 'date' => '2016-08-15', 'pmid' => 'http://www.nature.com/neuro/journal/vaop/ncurrent/full/nn.4360.html', 'doi' => '', 'modified' => '2016-08-31 09:10:11', 'created' => '2016-08-31 09:10:11', 'ProductsPublication' => array( [maximum depth reached] ) ) ), 'Testimonial' => array(), 'Area' => array(), 'SafetySheet' => array( (int) 0 => array( 'id' => '312', 'name' => 'DiaMag protein G-coated magnetic beads SDS US en', 'language' => 'en', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-US-en-GHS_1_0.pdf', 'countries' => 'US', 'modified' => '2020-06-09 12:24:02', 'created' => '2020-06-09 12:24:02', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '310', 'name' => 'DiaMag protein G-coated magnetic beads SDS GB en', 'language' => 'en', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-GB-en-GHS_1_0.pdf', 'countries' => 'GB', 'modified' => '2020-06-09 12:22:54', 'created' => '2020-06-09 12:22:54', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '305', 'name' => 'DiaMag protein G-coated magnetic beads SDS BE fr', 'language' => 'fr', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-BE-fr-GHS_1_0.pdf', 'countries' => 'BE', 'modified' => '2020-06-09 12:19:06', 'created' => '2020-06-09 12:19:06', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '309', 'name' => 'DiaMag protein G-coated magnetic beads SDS FR fr', 'language' => 'fr', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-FR-fr-GHS_1_0.pdf', 'countries' => 'FR', 'modified' => '2020-06-09 12:22:18', 'created' => '2020-06-09 12:22:18', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '308', 'name' => 'DiaMag protein G-coated magnetic beads SDS ES es', 'language' => 'es', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-ES-es-GHS_1_0.pdf', 'countries' => 'ES', 'modified' => '2020-06-09 12:21:36', 'created' => '2020-06-09 12:21:36', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '307', 'name' => 'DiaMag protein G-coated magnetic beads SDS DE de', 'language' => 'de', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-DE-de-GHS_1_0.pdf', 'countries' => 'DE', 'modified' => '2020-06-09 12:21:03', 'created' => '2020-06-09 12:21:03', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '311', 'name' => 'DiaMag protein G-coated magnetic beads SDS JP ja', 'language' => 'ja', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-JP-ja-GHS_2_0.pdf', 'countries' => 'JP', 'modified' => '2020-06-09 12:23:28', 'created' => '2020-06-09 12:23:28', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 7 => array( 'id' => '306', 'name' => 'DiaMag protein G-coated magnetic beads SDS BE nl', 'language' => 'nl', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-BE-nl-GHS_1_0.pdf', 'countries' => 'BE', 'modified' => '2020-06-09 12:20:21', 'created' => '2020-06-09 12:20:21', 'ProductsSafetySheet' => array( [maximum depth reached] ) ) ) ) $meta_canonical = 'https://www.diagenode.com/en/p/diamag-protein-g-coated-magnetic-beads-220-ul' $country = 'US' $countries_allowed = array( (int) 0 => 'CA', (int) 1 => 'US', (int) 2 => 'IE', (int) 3 => 'GB', (int) 4 => 'DK', (int) 5 => 'NO', (int) 6 => 'SE', (int) 7 => 'FI', (int) 8 => 'NL', (int) 9 => 'BE', (int) 10 => 'LU', (int) 11 => 'FR', (int) 12 => 'DE', (int) 13 => 'CH', (int) 14 => 'AT', (int) 15 => 'ES', (int) 16 => 'IT', (int) 17 => 'PT' ) $outsource = false $other_formats = array( (int) 0 => array( 'id' => '1908', 'antibody_id' => null, 'name' => 'DiaMag protein G-coated magnetic beads (ChIP-seq grade)', 'description' => '<p>The protein G-coated magnetic beads have been extensively validated in chromatin immunoprecipitation assay (ChIP). 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Neuronal specification is driven by transcriptional programs that are established during early neuronal development and remain in place in the adult brain. The fidelity of neuronal specification depends on the robustness of the transcriptional program that supports the neuron type-specific gene expression patterns. Here we show that polycomb repressive complex 2 (PRC2), which supports neuron specification during differentiation, contributes to the suppression of a transcriptional program that is detrimental to adult neuron function and survival. We show that PRC2 deficiency in striatal neurons leads to the de-repression of selected, predominantly bivalent PRC2 target genes that are dominated by self-regulating transcription factors normally suppressed in these neurons. The transcriptional changes in PRC2-deficient neurons lead to progressive and fatal neurodegeneration in mice. Our results point to a key role of PRC2 in protecting neurons against degeneration.</p>', 'date' => '2016-08-15', 'pmid' => 'http://www.nature.com/neuro/journal/vaop/ncurrent/full/nn.4360.html', 'doi' => '', 'modified' => '2016-08-31 09:10:11', 'created' => '2016-08-31 09:10:11', 'ProductsPublication' => array( 'id' => '1555', 'product_id' => '1907', 'publication_id' => '3013' ) ) $externalLink = ' <a href="http://www.nature.com/neuro/journal/vaop/ncurrent/full/nn.4360.html" target="_blank"><i class="fa fa-external-link"></i></a>'include - APP/View/Products/view.ctp, line 755 View::_evaluate() - CORE/Cake/View/View.php, line 971 View::_render() - CORE/Cake/View/View.php, line 933 View::render() - CORE/Cake/View/View.php, line 473 Controller::render() - CORE/Cake/Controller/Controller.php, line 963 ProductsController::slug() - APP/Controller/ProductsController.php, line 1052 ReflectionMethod::invokeArgs() - [internal], line ?? 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Factors governing the stability of the polymerase complex are not known. Previous studies characterizing the Pol I inhibitor BMH-21 revealed a transcriptional stress-dependent pathway for degradation of the largest subunit of Pol I, RPA194. To identify the E3 ligase(s) involved, we conducted a cell-based RNAi screen for ubiquitin pathway genes. We establish Skp-Cullin-F-box protein complex (SCF complex) F-box protein FBXL14 as an E3 ligase for RPA194. We show that FBXL14 binds to RPA194 and mediates RPA194 ubiquitination and degradation in cancer cells treated with BMH-21. Mutation analysis in yeast identified lysines 1150, 1153 and 1156 on Rpa190 relevant for the protein degradation. These results reveal the regulated turnover of Pol I, showing that the stability of the catalytic subunit is controlled by the F-box protein FBXL14 in response to transcription stress.</p>', 'date' => '2022-11-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/36372232', 'doi' => '10.1016/j.jbc.2022.102690', 'modified' => '2022-11-24 10:19:52', 'created' => '2022-11-24 08:49:52', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '4188', 'name' => 'Inhibition of HIV-1 gene transcription by KAP1 in myeloid lineage.', 'authors' => 'Ait-Ammar A. et al.', 'description' => '<p>HIV-1 latency generates reservoirs that prevent viral eradication by the current therapies. To find strategies toward an HIV cure, detailed understandings of the molecular mechanisms underlying establishment and persistence of the reservoirs are needed. The cellular transcription factor KAP1 is known as a potent repressor of gene transcription. Here we report that KAP1 represses HIV-1 gene expression in myeloid cells including microglial cells, the major reservoir of the central nervous system. Mechanistically, KAP1 interacts and colocalizes with the viral transactivator Tat to promote its degradation via the proteasome pathway and repress HIV-1 gene expression. In myeloid models of latent HIV-1 infection, the depletion of KAP1 increased viral gene elongation and reactivated HIV-1 expression. Bound to the latent HIV-1 promoter, KAP1 associates and cooperates with CTIP2, a key epigenetic silencer of HIV-1 expression in microglial cells. In addition, Tat and CTIP2 compete for KAP1 binding suggesting a dynamic modulation of the KAP1 cellular partners upon HIV-1 infection. Altogether, our results suggest that KAP1 contributes to the establishment and the persistence of HIV-1 latency in myeloid cells.</p>', 'date' => '2021-01-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/33514850', 'doi' => '10.1038/s41598-021-82164-w', 'modified' => '2022-01-05 15:08:41', 'created' => '2021-12-06 15:53:19', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '4095', 'name' => 'ZNF354C is a transcriptional repressor that inhibits endothelialangiogenic sprouting.', 'authors' => 'Oo, James A and Irmer, Barnabas and Günther, Stefan and Warwick, Timothyand Pálfi, Katalin and Izquierdo Ponce, Judit and Teichmann, Tom andPflüger-Müller, Beatrice and Gilsbach, Ralf and Brandes, Ralf P andLeisegang, Matthias S', 'description' => '<p>Zinc finger proteins (ZNF) are a large group of transcription factors with diverse functions. We recently discovered that endothelial cells harbour a specific mechanism to limit the action of ZNF354C, whose function in endothelial cells is unknown. Given that ZNF354C has so far only been studied in bone and tumour, its function was determined in endothelial cells. ZNF354C is expressed in vascular cells and localises to the nucleus and cytoplasm. Overexpression of ZNF354C in human endothelial cells results in a marked inhibition of endothelial sprouting. RNA-sequencing of human microvascular endothelial cells with and without overexpression of ZNF354C revealed that the protein is a potent transcriptional repressor. ZNF354C contains an active KRAB domain which mediates this suppression as shown by mutagenesis analysis. ZNF354C interacts with dsDNA, TRIM28 and histones, as observed by proximity ligation and immunoprecipitation. Moreover, chromatin immunoprecipitation revealed that the ZNF binds to specific endothelial-relevant target-gene promoters. ZNF354C suppresses these genes as shown by CRISPR/Cas knockout and RNAi. Inhibition of endothelial sprouting by ZNF354C is dependent on the amino acids DV and MLE of the KRAB domain. These results demonstrate that ZNF354C is a repressive transcription factor which acts through a KRAB domain to inhibit endothelial angiogenic sprouting.</p>', 'date' => '2020-11-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/33154469', 'doi' => '10.1038/s41598-020-76193-0', 'modified' => '2021-03-17 17:19:53', 'created' => '2021-02-18 10:21:53', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '3956', 'name' => 'AP-1 controls the p11-dependent antidepressant response.', 'authors' => 'Chottekalapanda RU, Kalik S, Gresack J, Ayala A, Gao M, Wang W, Meller S, Aly A, Schaefer A, Greengard P', 'description' => '<p>Selective serotonin reuptake inhibitors (SSRIs) are the most widely prescribed drugs for mood disorders. While the mechanism of SSRI action is still unknown, SSRIs are thought to exert therapeutic effects by elevating extracellular serotonin levels in the brain, and remodel the structural and functional alterations dysregulated during depression. To determine their precise mode of action, we tested whether such neuroadaptive processes are modulated by regulation of specific gene expression programs. Here we identify a transcriptional program regulated by activator protein-1 (AP-1) complex, formed by c-Fos and c-Jun that is selectively activated prior to the onset of the chronic SSRI response. The AP-1 transcriptional program modulates the expression of key neuronal remodeling genes, including S100a10 (p11), linking neuronal plasticity to the antidepressant response. We find that AP-1 function is required for the antidepressant effect in vivo. Furthermore, we demonstrate how neurochemical pathways of BDNF and FGF2, through the MAPK, PI3K, and JNK cascades, regulate AP-1 function to mediate the beneficial effects of the antidepressant response. Here we put forth a sequential molecular network to track the antidepressant response and provide a new avenue that could be used to accelerate or potentiate antidepressant responses by triggering neuroplasticity.</p>', 'date' => '2020-05-21', 'pmid' => 'http://www.pubmed.gov/32439846', 'doi' => '10.1038/s41380-020-0767-8', 'modified' => '2020-08-17 09:17:39', 'created' => '2020-08-10 12:12:25', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '3938', 'name' => 'Aging-regulated anti-apoptotic long non-coding RNA Sarrah augments recovery from acute myocardial infarction.', 'authors' => 'Trembinski DJ, Bink DI, Theodorou K, Sommer J, Fischer A, van Bergen A, Kuo CC, Costa IG, Schürmann C, Leisegang MS, Brandes RP, Alekseeva T, Brill B, Wietelmann A, Johnson CN, Spring-Connell A, Kaulich M, Werfel S, Engelhardt S, Hirt MN, Yorgan K, Eschen', 'description' => '<p>Long non-coding RNAs (lncRNAs) contribute to cardiac (patho)physiology. Aging is the major risk factor for cardiovascular disease with cardiomyocyte apoptosis as one underlying cause. Here, we report the identification of the aging-regulated lncRNA Sarrah (ENSMUST00000140003) that is anti-apoptotic in cardiomyocytes. Importantly, loss of SARRAH (OXCT1-AS1) in human engineered heart tissue results in impaired contractile force development. SARRAH directly binds to the promoters of genes downregulated after SARRAH silencing via RNA-DNA triple helix formation and cardiomyocytes lacking the triple helix forming domain of Sarrah show an increase in apoptosis. One of the direct SARRAH targets is NRF2, and restoration of NRF2 levels after SARRAH silencing partially rescues the reduction in cell viability. Overexpression of Sarrah in mice shows better recovery of cardiac contractile function after AMI compared to control mice. In summary, we identified the anti-apoptotic evolutionary conserved lncRNA Sarrah, which is downregulated by aging, as a regulator of cardiomyocyte survival.</p>', 'date' => '2020-04-27', 'pmid' => 'http://www.pubmed.gov/32341350', 'doi' => '10.1038/s41467-020-15995-2', 'modified' => '2020-08-17 10:30:19', 'created' => '2020-08-10 12:12:25', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '3866', 'name' => 'Inhibition of histone deacetylation rescues phenotype in a mouse model of Birk-Barel intellectual disability syndrome.', 'authors' => 'Cooper A, Butto T, Hammer N, Jagannath S, Fend-Guella DL, Akhtar J, Radyushkin K, Lesage F, Winter J, Strand S, Roeper J, Zechner U, Schweiger S', 'description' => '<p>Mutations in the actively expressed, maternal allele of the imprinted KCNK9 gene cause Birk-Barel intellectual disability syndrome (BBIDS). Using a BBIDS mouse model, we identify here a partial rescue of the BBIDS-like behavioral and neuronal phenotypes mediated via residual expression from the paternal Kcnk9 (Kcnk9) allele. We further demonstrate that the second-generation HDAC inhibitor CI-994 induces enhanced expression from the paternally silenced Kcnk9 allele and leads to a full rescue of the behavioral phenotype suggesting CI-994 as a promising molecule for BBIDS therapy. Thus, these findings suggest a potential approach to improve cognitive dysfunction in a mouse model of an imprinting disorder.</p>', 'date' => '2020-01-24', 'pmid' => 'http://www.pubmed.gov/31980599', 'doi' => '10.1038/s41467-019-13918-4', 'modified' => '2020-03-20 17:50:11', 'created' => '2020-03-13 13:45:54', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '3837', 'name' => 'H3K4me1 Supports Memory-like NK Cells Induced by Systemic Inflammation.', 'authors' => 'Rasid O, Chevalier C, Camarasa TM, Fitting C, Cavaillon JM, Hamon MA', 'description' => '<p>Natural killer (NK) cells are unique players in innate immunity and, as such, an attractive target for immunotherapy. NK cells display immune memory properties in certain models, but the long-term status of NK cells following systemic inflammation is unknown. Here we show that following LPS-induced endotoxemia in mice, NK cells acquire cell-intrinsic memory-like properties, showing increased production of IFNγ upon specific secondary stimulation. The NK cell memory response is detectable for at least 9 weeks and contributes to protection from E. coli infection upon adoptive transfer. Importantly, we reveal a mechanism essential for NK cell memory, whereby an H3K4me1-marked latent enhancer is uncovered at the ifng locus. Chemical inhibition of histone methyltransferase activity erases the enhancer and abolishes NK cell memory. Thus, NK cell memory develops after endotoxemia in a histone methylation-dependent manner, ensuring a heightened response to secondary stimulation.</p>', 'date' => '2019-12-17', 'pmid' => 'http://www.pubmed.gov/31851924', 'doi' => '10.1016/j.celrep.2019.11.043', 'modified' => '2020-02-20 11:24:10', 'created' => '2020-02-13 10:02:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 7 => array( 'id' => '3807', 'name' => 'Epigenetic remodelling licences adult cholangiocytes for organoid formation and liver regeneration.', 'authors' => 'Aloia L, McKie MA, Vernaz G, Cordero-Espinoza L, Aleksieva N, van den Ameele J, Antonica F, Font-Cunill B, Raven A, Aiese Cigliano R, Belenguer G, Mort RL, Brand AH, Zernicka-Goetz M, Forbes SJ, Miska EA, Huch M', 'description' => '<p>Following severe or chronic liver injury, adult ductal cells (cholangiocytes) contribute to regeneration by restoring both hepatocytes and cholangiocytes. We recently showed that ductal cells clonally expand as self-renewing liver organoids that retain their differentiation capacity into both hepatocytes and ductal cells. However, the molecular mechanisms by which adult ductal-committed cells acquire cellular plasticity, initiate organoids and regenerate the damaged tissue remain largely unknown. Here, we describe that ductal cells undergo a transient, genome-wide, remodelling of their transcriptome and epigenome during organoid initiation and in vivo following tissue damage. TET1-mediated hydroxymethylation licences differentiated ductal cells to initiate organoids and activate the regenerative programme through the transcriptional regulation of stem-cell genes and regenerative pathways including the YAP-Hippo signalling. Our results argue in favour of the remodelling of genomic methylome/hydroxymethylome landscapes as a general mechanism by which differentiated cells exit a committed state in response to tissue damage.</p>', 'date' => '2019-11-04', 'pmid' => 'http://www.pubmed.gov/31685987', 'doi' => '10.1038/s41556-019-0402-6', 'modified' => '2019-12-05 11:19:34', 'created' => '2019-12-02 15:25:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 8 => array( 'id' => '3735', 'name' => 'Interaction of Sox2 with RNA binding proteins in mouse embryonic stem cells.', 'authors' => 'Samudyata , Amaral PP, Engström PG, Robson SC, Nielsen ML, Kouzarides T, Castelo-Branco G', 'description' => '<p>Sox2 is a master transcriptional regulator of embryonic development. In this study, we determined the protein interactome of Sox2 in the chromatin and nucleoplasm of mouse embryonic stem (mES) cells. Apart from canonical interactions with pluripotency-regulating transcription factors, we identified interactions with several chromatin modulators, including members of the heterochromatin protein 1 (HP1) family, suggesting a role for Sox2 in chromatin-mediated transcriptional repression. Sox2 was also found to interact with RNA binding proteins (RBPs), including proteins involved in RNA processing. RNA immunoprecipitation followed by sequencing revealed that Sox2 associates with different messenger RNAs, as well as small nucleolar RNA Snord34 and the non-coding RNA 7SK. 7SK has been shown to regulate transcription at gene regulatory regions, which could suggest a functional interaction with Sox2 for chromatin recruitment. Nevertheless, we found no evidence of Sox2 modulating recruitment of 7SK to chromatin when examining 7SK chromatin occupancy by Chromatin Isolation by RNA Purification (ChIRP) in Sox2 depleted mES cells. In addition, knockdown of 7SK in mES cells did not lead to any change in Sox2 occupancy at 7SK-regulated genes. Thus, our results show that Sox2 extensively interacts with RBPs, and suggest that Sox2 and 7SK co-exist in a ribonucleoprotein complex whose function is not to regulate chromatin recruitment, but could rather regulate other processes in the nucleoplasm.</p>', 'date' => '2019-08-01', 'pmid' => 'http://www.pubmed.gov/31077711', 'doi' => '10.1016/j.yexcr.2019.05.006', 'modified' => '2019-08-06 17:01:21', 'created' => '2019-07-31 13:35:50', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 9 => array( 'id' => '3396', 'name' => 'The Itaconate Pathway Is a Central Regulatory Node Linking Innate Immune Tolerance and Trained Immunity', 'authors' => 'Domínguez-Andrés Jorge, Novakovic Boris, Li Yang, Scicluna Brendon P., Gresnigt Mark S., Arts Rob J.W., Oosting Marije, Moorlag Simone J.C.F.M., Groh Laszlo A., Zwaag Jelle, Koch Rebecca M., ter Horst Rob, Joosten Leo A.B., Wijmenga Cisca, Michelucci Ales', 'description' => '<p>Sepsis involves simultaneous hyperactivation of the immune system and immune paralysis, leading to both organ dysfunction and increased susceptibility to secondary infections. Acute activation of myeloid cells induced itaconate synthesis, which subsequently mediated innate immune tolerance in human monocytes. In contrast, induction of trained immunity by b-glucan counteracted tolerance induced in a model of human endotoxemia by inhibiting the expression of immune-responsive gene 1 (IRG1), the enzyme that controls itaconate synthesis. b-Glucan also increased the expression of succinate dehydrogenase (SDH), contributing to the integrity of the TCA cycle and leading to an enhanced innate immune response after secondary stimulation. The role of itaconate was further validated by IRG1 and SDH polymorphisms that modulate induction of tolerance and trained immunity in human monocytes. These data demonstrate the importance of the IRG1-itaconateSDH axis in the development of immune tolerance and training and highlight the potential of b-glucaninduced trained immunity to revert immunoparalysis.</p>', 'date' => '2018-10-01', 'pmid' => 'http://www.pubmed.gov/30293776', 'doi' => '10.1016/j.cmet.2018.09.003', 'modified' => '2018-11-22 15:18:30', 'created' => '2018-11-08 12:59:45', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 10 => array( 'id' => '3407', 'name' => 'The histone demethylase Jarid1b mediates angiotensin II-induced endothelial dysfunction by controlling the 3'UTR of soluble epoxide hydrolase.', 'authors' => 'Vasconez AE, Janetzko P, Oo JA, Pflüger-Müller B, Ratiu C, Gu L, Helin K, Geisslinger G, Fleming I, Schröder K, Fork C, Brandes RP, Leisegang MS', 'description' => '<p>AIM: The histone demethylase Jarid1b limits gene expression by removing the active methyl mark from histone3 lysine4 at gene promoter regions. A vascular function of Jarid1b is unknown, but a vasoprotective function to inflammatory and hypertrophic stimuli, like angiotensin II (AngII) could be inferred. This hypothesis was tested using Jarid1b knockout mice and the inhibitor PBIT. METHODS: Mice or aortic segments were treated with AngII to induce endothelial dysfunction. Aortae from WT and Jarid1b knockout were studied in organ chambers and endothelium-dependent dilator responses to acetylcholine and endothelium-independent responses to DetaNONOate were recorded after pre-constriction with phenylephrine in the presence or absence of the NO-synthase inhibitor nitro-L-arginine. Molecular mechanisms were investigated with chromatin immunoprecipitation, RNA-Seq, RNA-3'-adaptor-ligation, actinomycin D and RNA-immunoprecipitation. RESULTS: Knockout or inhibition of Jarid1b prevented the development of endothelial dysfunction in response to AngII. This effect was not a consequence of altered nitrite oxide availability but accompanied by a loss of the inflammatory response to AngII. As Jarid1b mainly inhibits gene expression, an indirect effect should account for this observation. AngII induced the soluble epoxide hydrolase (sEH), which degrades anti-inflammatory lipids, and thus promotes inflammation. Knockout or inhibition of Jarid1b prevented the AngII-mediated sEH induction. Mechanistically, Jarid1b maintained the length of the 3'untranslated region of the sEH mRNA, thereby increasing its stability and thus sEH protein expression. Loss of Jarid1b activity therefore resulted in sEH mRNA destabilization. CONCLUSION: Jarid1b contributes to the pro-inflammatory effects of AngII by stabilizing sEH expression. Jarid1b inhibition might be an option for future therapeutics against cardiovascular dysfunction.</p>', 'date' => '2018-08-04', 'pmid' => 'http://www.pubmed.gov/30076673', 'doi' => '10.1111/apha.13168', 'modified' => '2018-11-09 11:18:29', 'created' => '2018-11-08 12:59:45', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 11 => array( 'id' => '3632', 'name' => 'Epigenetic regulation of brain region-specific microglia clearance activity.', 'authors' => 'Ayata P, Badimon A, Strasburger HJ, Duff MK, Montgomery SE, Loh YE, Ebert A, Pimenova AA, Ramirez BR, Chan AT, Sullivan JM, Purushothaman I, Scarpa JR, Goate AM, Busslinger M, Shen L, Losic B, Schaefer A', 'description' => '<p>The rapid elimination of dying neurons and nonfunctional synapses in the brain is carried out by microglia, the resident myeloid cells of the brain. Here we show that microglia clearance activity in the adult brain is regionally regulated and depends on the rate of neuronal attrition. Cerebellar, but not striatal or cortical, microglia exhibited high levels of basal clearance activity, which correlated with an elevated degree of cerebellar neuronal attrition. Exposing forebrain microglia to apoptotic cells activated gene-expression programs supporting clearance activity. We provide evidence that the polycomb repressive complex 2 (PRC2) epigenetically restricts the expression of genes that support clearance activity in striatal and cortical microglia. Loss of PRC2 leads to aberrant activation of a microglia clearance phenotype, which triggers changes in neuronal morphology and behavior. Our data highlight a key role of epigenetic mechanisms in preventing microglia-induced neuronal alterations that are frequently associated with neurodegenerative and psychiatric diseases.</p>', 'date' => '2018-08-01', 'pmid' => 'http://www.pubmed.gov/30038282', 'doi' => '10.1038/s41593-018-0192-3', 'modified' => '2019-06-07 10:34:03', 'created' => '2019-06-06 12:11:18', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 12 => array( 'id' => '3621', 'name' => 'Episomal HBV persistence within transcribed host nuclear chromatin compartments involves HBx.', 'authors' => 'Hensel KO, Cantner F, Bangert F, Wirth S, Postberg J', 'description' => '<p>BACKGROUND: In hepatocyte nuclei, hepatitis B virus (HBV) genomes occur episomally as covalently closed circular DNA (cccDNA). The HBV X protein (HBx) is required to initiate and maintain HBV replication. The functional nuclear localization of cccDNA and HBx remains unexplored. RESULTS: To identify virus-host genome interactions and the underlying nuclear landscape for the first time, we combined circular chromosome conformation capture (4C) with RNA-seq and ChIP-seq. Moreover, we studied HBx-binding to HBV episomes. In HBV-positive HepaRG hepatocytes, we observed preferential association of HBV episomes and HBx with actively transcribed nuclear domains on the host genome correlating in size with constrained topological units of chromatin. Interestingly, HBx alone occupied transcribed chromatin domains. Silencing of native HBx caused reduced episomal HBV stability. CONCLUSIONS: As part of the HBV episome, HBx might stabilize HBV episomal nuclear localization. Our observations may contribute to the understanding of long-term episomal stability and the facilitation of viral persistence. The exact mechanism by which HBx contributes to HBV nuclear persistence warrants further investigations.</p>', 'date' => '2018-06-22', 'pmid' => 'http://www.pubmed.gov/29933745', 'doi' => '10.1186/s13072-018-0204-2', 'modified' => '2019-05-16 11:23:59', 'created' => '2019-04-25 11:11:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 13 => array( 'id' => '3541', 'name' => 'Long noncoding RNA LISPR1 is required for S1P signaling and endothelial cell function.', 'authors' => 'Josipovic I, Pflüger B, Fork C, Vasconez AE, Oo JA, Hitzel J, Seredinski S, Gamen E, Heringdorf DMZ, Chen W, Looso M, Pullamsetti SS, Brandes RP, Leisegang MS', 'description' => '<p>Sphingosine-1-Phosphate (S1P) is a potent signaling lipid. The effects of S1P are mediated by the five S1P receptors (S1PR). In the endothelium S1PR1 is the predominant receptor and thus S1PR1 abundance limits S1P signaling. Recently, lncRNAs were identified as a novel class of molecules regulating gene expression. Interestingly, the lncRNA NONHSAT004848 (LISPR1, Long intergenic noncoding RNA antisense to S1PR1), is closely positioned to the S1P1 receptors gene and in part shares its promoter region. We hypothesize that LISPR1 controls endothelial S1PR1 expression and thus S1P-induced signaling in endothelial cells. In vitro transcription and translation as well as coding potential assessment showed that LISPR1 is indeed noncoding. LISPR1 was localized in both cytoplasm and nucleus and harbored a PolyA tail at the 3'end. In human umbilical vein endothelial cells, as well as human lung tissue, qRT-PCR and RNA-Seq revealed high expression of LISPR1. S1PR1 and LISPR1 were downregulated in human pulmonary diseases such as COPD. LISPR1 but also S1PR1 were induced by inflammation, shear stress and statins. Knockdown of LISPR1 attenuated endothelial S1P-induced migration and spheroid outgrowth of endothelial cells. LISPR1 knockdown decreased S1PR1 expression, which was paralleled by an increase of the binding of the transcriptional repressor ZNF354C to the S1PR1 promoter and a reduction of the recruitment of RNA Polymerase II to the S1PR1 5'end. This resulted in attenuated S1PR1 expression and attenuated S1P downstream signaling. Collectively, the disease relevant lncRNA LISPR1 acts as a novel regulatory unit important for S1PR1 expression and endothelial cell function.</p>', 'date' => '2018-03-01', 'pmid' => 'http://www.pubmed.gov/29408197', 'doi' => '10.1016/j.yjmcc.2018.01.015', 'modified' => '2019-02-28 10:52:59', 'created' => '2019-02-27 12:54:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 14 => array( 'id' => '3446', 'name' => 'Metabolic Induction of Trained Immunity through the Mevalonate Pathway.', 'authors' => 'Bekkering S, Arts RJW, Novakovic B, Kourtzelis I, van der Heijden CDCC, Li Y, Popa CD, Ter Horst R, van Tuijl J, Netea-Maier RT, van de Veerdonk FL, Chavakis T, Joosten LAB, van der Meer JWM, Stunnenberg H, Riksen NP, Netea MG', 'description' => '<p>Innate immune cells can develop long-term memory after stimulation by microbial products during infections or vaccinations. Here, we report that metabolic signals can induce trained immunity. Pharmacological and genetic experiments reveal that activation of the cholesterol synthesis pathway, but not the synthesis of cholesterol itself, is essential for training of myeloid cells. Rather, the metabolite mevalonate is the mediator of training via activation of IGF1-R and mTOR and subsequent histone modifications in inflammatory pathways. Statins, which block mevalonate generation, prevent trained immunity induction. Furthermore, monocytes of patients with hyper immunoglobulin D syndrome (HIDS), who are mevalonate kinase deficient and accumulate mevalonate, have a constitutive trained immunity phenotype at both immunological and epigenetic levels, which could explain the attacks of sterile inflammation that these patients experience. Unraveling the role of mevalonate in trained immunity contributes to our understanding of the pathophysiology of HIDS and identifies novel therapeutic targets for clinical conditions with excessive activation of trained immunity.</p>', 'date' => '2018-01-11', 'pmid' => 'http://www.pubmed.gov/29328908', 'doi' => '10.1016/j.cell.2017.11.025', 'modified' => '2019-02-15 21:37:39', 'created' => '2019-02-14 15:01:22', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 15 => array( 'id' => '3408', 'name' => 'BCG Vaccination Protects against Experimental Viral Infection in Humans through the Induction of Cytokines Associated with Trained Immunity.', 'authors' => 'Arts RJW, Moorlag SJCFM, Novakovic B, Li Y, Wang SY, Oosting M, Kumar V, Xavier RJ, Wijmenga C, Joosten LAB, Reusken CBEM, Benn CS, Aaby P, Koopmans MP, Stunnenberg HG, van Crevel R, Netea MG', 'description' => '<p>The tuberculosis vaccine bacillus Calmette-Guérin (BCG) has heterologous beneficial effects against non-related infections. The basis of these effects has been poorly explored in humans. In a randomized placebo-controlled human challenge study, we found that BCG vaccination induced genome-wide epigenetic reprograming of monocytes and protected against experimental infection with an attenuated yellow fever virus vaccine strain. Epigenetic reprogramming was accompanied by functional changes indicative of trained immunity. Reduction of viremia was highly correlated with the upregulation of IL-1β, a heterologous cytokine associated with the induction of trained immunity, but not with the specific IFNγ response. The importance of IL-1β for the induction of trained immunity was validated through genetic, epigenetic, and immunological studies. In conclusion, BCG induces epigenetic reprogramming in human monocytes in vivo, followed by functional reprogramming and protection against non-related viral infections, with a key role for IL-1β as a mediator of trained immunity responses.</p>', 'date' => '2018-01-10', 'pmid' => 'http://www.pubmed.gov/29324233', 'doi' => '10.1016/j.chom.2017.12.010', 'modified' => '2018-11-22 15:15:09', 'created' => '2018-11-08 12:59:45', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 16 => array( 'id' => '3013', 'name' => 'Polycomb repressive complex 2 (PRC2) silences genes responsible for neurodegeneration', 'authors' => 'von Schimmelmann M et al.', 'description' => '<p>Normal brain function depends on the interaction between highly specialized neurons that operate within anatomically and functionally distinct brain regions. Neuronal specification is driven by transcriptional programs that are established during early neuronal development and remain in place in the adult brain. The fidelity of neuronal specification depends on the robustness of the transcriptional program that supports the neuron type-specific gene expression patterns. Here we show that polycomb repressive complex 2 (PRC2), which supports neuron specification during differentiation, contributes to the suppression of a transcriptional program that is detrimental to adult neuron function and survival. We show that PRC2 deficiency in striatal neurons leads to the de-repression of selected, predominantly bivalent PRC2 target genes that are dominated by self-regulating transcription factors normally suppressed in these neurons. The transcriptional changes in PRC2-deficient neurons lead to progressive and fatal neurodegeneration in mice. Our results point to a key role of PRC2 in protecting neurons against degeneration.</p>', 'date' => '2016-08-15', 'pmid' => 'http://www.nature.com/neuro/journal/vaop/ncurrent/full/nn.4360.html', 'doi' => '', 'modified' => '2016-08-31 09:10:11', 'created' => '2016-08-31 09:10:11', 'ProductsPublication' => array( [maximum depth reached] ) ) ), 'Testimonial' => array(), 'Area' => array(), 'SafetySheet' => array( (int) 0 => array( 'id' => '312', 'name' => 'DiaMag protein G-coated magnetic beads SDS US en', 'language' => 'en', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-US-en-GHS_1_0.pdf', 'countries' => 'US', 'modified' => '2020-06-09 12:24:02', 'created' => '2020-06-09 12:24:02', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '310', 'name' => 'DiaMag protein G-coated magnetic beads SDS GB en', 'language' => 'en', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-GB-en-GHS_1_0.pdf', 'countries' => 'GB', 'modified' => '2020-06-09 12:22:54', 'created' => '2020-06-09 12:22:54', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '305', 'name' => 'DiaMag protein G-coated magnetic beads SDS BE fr', 'language' => 'fr', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-BE-fr-GHS_1_0.pdf', 'countries' => 'BE', 'modified' => '2020-06-09 12:19:06', 'created' => '2020-06-09 12:19:06', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '309', 'name' => 'DiaMag protein G-coated magnetic beads SDS FR fr', 'language' => 'fr', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-FR-fr-GHS_1_0.pdf', 'countries' => 'FR', 'modified' => '2020-06-09 12:22:18', 'created' => '2020-06-09 12:22:18', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '308', 'name' => 'DiaMag protein G-coated magnetic beads SDS ES es', 'language' => 'es', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-ES-es-GHS_1_0.pdf', 'countries' => 'ES', 'modified' => '2020-06-09 12:21:36', 'created' => '2020-06-09 12:21:36', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '307', 'name' => 'DiaMag protein G-coated magnetic beads SDS DE de', 'language' => 'de', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-DE-de-GHS_1_0.pdf', 'countries' => 'DE', 'modified' => '2020-06-09 12:21:03', 'created' => '2020-06-09 12:21:03', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '311', 'name' => 'DiaMag protein G-coated magnetic beads SDS JP ja', 'language' => 'ja', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-JP-ja-GHS_2_0.pdf', 'countries' => 'JP', 'modified' => '2020-06-09 12:23:28', 'created' => '2020-06-09 12:23:28', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 7 => array( 'id' => '306', 'name' => 'DiaMag protein G-coated magnetic beads SDS BE nl', 'language' => 'nl', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-BE-nl-GHS_1_0.pdf', 'countries' => 'BE', 'modified' => '2020-06-09 12:20:21', 'created' => '2020-06-09 12:20:21', 'ProductsSafetySheet' => array( [maximum depth reached] ) ) ) ) $meta_canonical = 'https://www.diagenode.com/en/p/diamag-protein-g-coated-magnetic-beads-220-ul' $country = 'US' $countries_allowed = array( (int) 0 => 'CA', (int) 1 => 'US', (int) 2 => 'IE', (int) 3 => 'GB', (int) 4 => 'DK', (int) 5 => 'NO', (int) 6 => 'SE', (int) 7 => 'FI', (int) 8 => 'NL', (int) 9 => 'BE', (int) 10 => 'LU', (int) 11 => 'FR', (int) 12 => 'DE', (int) 13 => 'CH', (int) 14 => 'AT', (int) 15 => 'ES', (int) 16 => 'IT', (int) 17 => 'PT' ) $outsource = false $other_formats = array( (int) 0 => array( 'id' => '1908', 'antibody_id' => null, 'name' => 'DiaMag protein G-coated magnetic beads (ChIP-seq grade)', 'description' => '<p>The protein G-coated magnetic beads have been extensively validated in chromatin immunoprecipitation assay (ChIP). 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Factors governing the stability of the polymerase complex are not known. Previous studies characterizing the Pol I inhibitor BMH-21 revealed a transcriptional stress-dependent pathway for degradation of the largest subunit of Pol I, RPA194. To identify the E3 ligase(s) involved, we conducted a cell-based RNAi screen for ubiquitin pathway genes. We establish Skp-Cullin-F-box protein complex (SCF complex) F-box protein FBXL14 as an E3 ligase for RPA194. We show that FBXL14 binds to RPA194 and mediates RPA194 ubiquitination and degradation in cancer cells treated with BMH-21. Mutation analysis in yeast identified lysines 1150, 1153 and 1156 on Rpa190 relevant for the protein degradation. These results reveal the regulated turnover of Pol I, showing that the stability of the catalytic subunit is controlled by the F-box protein FBXL14 in response to transcription stress.</p>', 'date' => '2022-11-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/36372232', 'doi' => '10.1016/j.jbc.2022.102690', 'modified' => '2022-11-24 10:19:52', 'created' => '2022-11-24 08:49:52', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '4188', 'name' => 'Inhibition of HIV-1 gene transcription by KAP1 in myeloid lineage.', 'authors' => 'Ait-Ammar A. et al.', 'description' => '<p>HIV-1 latency generates reservoirs that prevent viral eradication by the current therapies. To find strategies toward an HIV cure, detailed understandings of the molecular mechanisms underlying establishment and persistence of the reservoirs are needed. The cellular transcription factor KAP1 is known as a potent repressor of gene transcription. Here we report that KAP1 represses HIV-1 gene expression in myeloid cells including microglial cells, the major reservoir of the central nervous system. Mechanistically, KAP1 interacts and colocalizes with the viral transactivator Tat to promote its degradation via the proteasome pathway and repress HIV-1 gene expression. In myeloid models of latent HIV-1 infection, the depletion of KAP1 increased viral gene elongation and reactivated HIV-1 expression. Bound to the latent HIV-1 promoter, KAP1 associates and cooperates with CTIP2, a key epigenetic silencer of HIV-1 expression in microglial cells. In addition, Tat and CTIP2 compete for KAP1 binding suggesting a dynamic modulation of the KAP1 cellular partners upon HIV-1 infection. 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ZNF354C suppresses these genes as shown by CRISPR/Cas knockout and RNAi. Inhibition of endothelial sprouting by ZNF354C is dependent on the amino acids DV and MLE of the KRAB domain. These results demonstrate that ZNF354C is a repressive transcription factor which acts through a KRAB domain to inhibit endothelial angiogenic sprouting.</p>', 'date' => '2020-11-01', 'pmid' => 'https://www.ncbi.nlm.nih.gov/pubmed/33154469', 'doi' => '10.1038/s41598-020-76193-0', 'modified' => '2021-03-17 17:19:53', 'created' => '2021-02-18 10:21:53', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '3956', 'name' => 'AP-1 controls the p11-dependent antidepressant response.', 'authors' => 'Chottekalapanda RU, Kalik S, Gresack J, Ayala A, Gao M, Wang W, Meller S, Aly A, Schaefer A, Greengard P', 'description' => '<p>Selective serotonin reuptake inhibitors (SSRIs) are the most widely prescribed drugs for mood disorders. While the mechanism of SSRI action is still unknown, SSRIs are thought to exert therapeutic effects by elevating extracellular serotonin levels in the brain, and remodel the structural and functional alterations dysregulated during depression. To determine their precise mode of action, we tested whether such neuroadaptive processes are modulated by regulation of specific gene expression programs. Here we identify a transcriptional program regulated by activator protein-1 (AP-1) complex, formed by c-Fos and c-Jun that is selectively activated prior to the onset of the chronic SSRI response. The AP-1 transcriptional program modulates the expression of key neuronal remodeling genes, including S100a10 (p11), linking neuronal plasticity to the antidepressant response. We find that AP-1 function is required for the antidepressant effect in vivo. Furthermore, we demonstrate how neurochemical pathways of BDNF and FGF2, through the MAPK, PI3K, and JNK cascades, regulate AP-1 function to mediate the beneficial effects of the antidepressant response. Here we put forth a sequential molecular network to track the antidepressant response and provide a new avenue that could be used to accelerate or potentiate antidepressant responses by triggering neuroplasticity.</p>', 'date' => '2020-05-21', 'pmid' => 'http://www.pubmed.gov/32439846', 'doi' => '10.1038/s41380-020-0767-8', 'modified' => '2020-08-17 09:17:39', 'created' => '2020-08-10 12:12:25', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '3938', 'name' => 'Aging-regulated anti-apoptotic long non-coding RNA Sarrah augments recovery from acute myocardial infarction.', 'authors' => 'Trembinski DJ, Bink DI, Theodorou K, Sommer J, Fischer A, van Bergen A, Kuo CC, Costa IG, Schürmann C, Leisegang MS, Brandes RP, Alekseeva T, Brill B, Wietelmann A, Johnson CN, Spring-Connell A, Kaulich M, Werfel S, Engelhardt S, Hirt MN, Yorgan K, Eschen', 'description' => '<p>Long non-coding RNAs (lncRNAs) contribute to cardiac (patho)physiology. Aging is the major risk factor for cardiovascular disease with cardiomyocyte apoptosis as one underlying cause. Here, we report the identification of the aging-regulated lncRNA Sarrah (ENSMUST00000140003) that is anti-apoptotic in cardiomyocytes. Importantly, loss of SARRAH (OXCT1-AS1) in human engineered heart tissue results in impaired contractile force development. SARRAH directly binds to the promoters of genes downregulated after SARRAH silencing via RNA-DNA triple helix formation and cardiomyocytes lacking the triple helix forming domain of Sarrah show an increase in apoptosis. One of the direct SARRAH targets is NRF2, and restoration of NRF2 levels after SARRAH silencing partially rescues the reduction in cell viability. Overexpression of Sarrah in mice shows better recovery of cardiac contractile function after AMI compared to control mice. In summary, we identified the anti-apoptotic evolutionary conserved lncRNA Sarrah, which is downregulated by aging, as a regulator of cardiomyocyte survival.</p>', 'date' => '2020-04-27', 'pmid' => 'http://www.pubmed.gov/32341350', 'doi' => '10.1038/s41467-020-15995-2', 'modified' => '2020-08-17 10:30:19', 'created' => '2020-08-10 12:12:25', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '3866', 'name' => 'Inhibition of histone deacetylation rescues phenotype in a mouse model of Birk-Barel intellectual disability syndrome.', 'authors' => 'Cooper A, Butto T, Hammer N, Jagannath S, Fend-Guella DL, Akhtar J, Radyushkin K, Lesage F, Winter J, Strand S, Roeper J, Zechner U, Schweiger S', 'description' => '<p>Mutations in the actively expressed, maternal allele of the imprinted KCNK9 gene cause Birk-Barel intellectual disability syndrome (BBIDS). Using a BBIDS mouse model, we identify here a partial rescue of the BBIDS-like behavioral and neuronal phenotypes mediated via residual expression from the paternal Kcnk9 (Kcnk9) allele. We further demonstrate that the second-generation HDAC inhibitor CI-994 induces enhanced expression from the paternally silenced Kcnk9 allele and leads to a full rescue of the behavioral phenotype suggesting CI-994 as a promising molecule for BBIDS therapy. Thus, these findings suggest a potential approach to improve cognitive dysfunction in a mouse model of an imprinting disorder.</p>', 'date' => '2020-01-24', 'pmid' => 'http://www.pubmed.gov/31980599', 'doi' => '10.1038/s41467-019-13918-4', 'modified' => '2020-03-20 17:50:11', 'created' => '2020-03-13 13:45:54', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '3837', 'name' => 'H3K4me1 Supports Memory-like NK Cells Induced by Systemic Inflammation.', 'authors' => 'Rasid O, Chevalier C, Camarasa TM, Fitting C, Cavaillon JM, Hamon MA', 'description' => '<p>Natural killer (NK) cells are unique players in innate immunity and, as such, an attractive target for immunotherapy. NK cells display immune memory properties in certain models, but the long-term status of NK cells following systemic inflammation is unknown. Here we show that following LPS-induced endotoxemia in mice, NK cells acquire cell-intrinsic memory-like properties, showing increased production of IFNγ upon specific secondary stimulation. The NK cell memory response is detectable for at least 9 weeks and contributes to protection from E. coli infection upon adoptive transfer. Importantly, we reveal a mechanism essential for NK cell memory, whereby an H3K4me1-marked latent enhancer is uncovered at the ifng locus. Chemical inhibition of histone methyltransferase activity erases the enhancer and abolishes NK cell memory. Thus, NK cell memory develops after endotoxemia in a histone methylation-dependent manner, ensuring a heightened response to secondary stimulation.</p>', 'date' => '2019-12-17', 'pmid' => 'http://www.pubmed.gov/31851924', 'doi' => '10.1016/j.celrep.2019.11.043', 'modified' => '2020-02-20 11:24:10', 'created' => '2020-02-13 10:02:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 7 => array( 'id' => '3807', 'name' => 'Epigenetic remodelling licences adult cholangiocytes for organoid formation and liver regeneration.', 'authors' => 'Aloia L, McKie MA, Vernaz G, Cordero-Espinoza L, Aleksieva N, van den Ameele J, Antonica F, Font-Cunill B, Raven A, Aiese Cigliano R, Belenguer G, Mort RL, Brand AH, Zernicka-Goetz M, Forbes SJ, Miska EA, Huch M', 'description' => '<p>Following severe or chronic liver injury, adult ductal cells (cholangiocytes) contribute to regeneration by restoring both hepatocytes and cholangiocytes. We recently showed that ductal cells clonally expand as self-renewing liver organoids that retain their differentiation capacity into both hepatocytes and ductal cells. However, the molecular mechanisms by which adult ductal-committed cells acquire cellular plasticity, initiate organoids and regenerate the damaged tissue remain largely unknown. Here, we describe that ductal cells undergo a transient, genome-wide, remodelling of their transcriptome and epigenome during organoid initiation and in vivo following tissue damage. TET1-mediated hydroxymethylation licences differentiated ductal cells to initiate organoids and activate the regenerative programme through the transcriptional regulation of stem-cell genes and regenerative pathways including the YAP-Hippo signalling. Our results argue in favour of the remodelling of genomic methylome/hydroxymethylome landscapes as a general mechanism by which differentiated cells exit a committed state in response to tissue damage.</p>', 'date' => '2019-11-04', 'pmid' => 'http://www.pubmed.gov/31685987', 'doi' => '10.1038/s41556-019-0402-6', 'modified' => '2019-12-05 11:19:34', 'created' => '2019-12-02 15:25:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 8 => array( 'id' => '3735', 'name' => 'Interaction of Sox2 with RNA binding proteins in mouse embryonic stem cells.', 'authors' => 'Samudyata , Amaral PP, Engström PG, Robson SC, Nielsen ML, Kouzarides T, Castelo-Branco G', 'description' => '<p>Sox2 is a master transcriptional regulator of embryonic development. In this study, we determined the protein interactome of Sox2 in the chromatin and nucleoplasm of mouse embryonic stem (mES) cells. Apart from canonical interactions with pluripotency-regulating transcription factors, we identified interactions with several chromatin modulators, including members of the heterochromatin protein 1 (HP1) family, suggesting a role for Sox2 in chromatin-mediated transcriptional repression. Sox2 was also found to interact with RNA binding proteins (RBPs), including proteins involved in RNA processing. RNA immunoprecipitation followed by sequencing revealed that Sox2 associates with different messenger RNAs, as well as small nucleolar RNA Snord34 and the non-coding RNA 7SK. 7SK has been shown to regulate transcription at gene regulatory regions, which could suggest a functional interaction with Sox2 for chromatin recruitment. Nevertheless, we found no evidence of Sox2 modulating recruitment of 7SK to chromatin when examining 7SK chromatin occupancy by Chromatin Isolation by RNA Purification (ChIRP) in Sox2 depleted mES cells. In addition, knockdown of 7SK in mES cells did not lead to any change in Sox2 occupancy at 7SK-regulated genes. Thus, our results show that Sox2 extensively interacts with RBPs, and suggest that Sox2 and 7SK co-exist in a ribonucleoprotein complex whose function is not to regulate chromatin recruitment, but could rather regulate other processes in the nucleoplasm.</p>', 'date' => '2019-08-01', 'pmid' => 'http://www.pubmed.gov/31077711', 'doi' => '10.1016/j.yexcr.2019.05.006', 'modified' => '2019-08-06 17:01:21', 'created' => '2019-07-31 13:35:50', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 9 => array( 'id' => '3396', 'name' => 'The Itaconate Pathway Is a Central Regulatory Node Linking Innate Immune Tolerance and Trained Immunity', 'authors' => 'Domínguez-Andrés Jorge, Novakovic Boris, Li Yang, Scicluna Brendon P., Gresnigt Mark S., Arts Rob J.W., Oosting Marije, Moorlag Simone J.C.F.M., Groh Laszlo A., Zwaag Jelle, Koch Rebecca M., ter Horst Rob, Joosten Leo A.B., Wijmenga Cisca, Michelucci Ales', 'description' => '<p>Sepsis involves simultaneous hyperactivation of the immune system and immune paralysis, leading to both organ dysfunction and increased susceptibility to secondary infections. Acute activation of myeloid cells induced itaconate synthesis, which subsequently mediated innate immune tolerance in human monocytes. In contrast, induction of trained immunity by b-glucan counteracted tolerance induced in a model of human endotoxemia by inhibiting the expression of immune-responsive gene 1 (IRG1), the enzyme that controls itaconate synthesis. b-Glucan also increased the expression of succinate dehydrogenase (SDH), contributing to the integrity of the TCA cycle and leading to an enhanced innate immune response after secondary stimulation. The role of itaconate was further validated by IRG1 and SDH polymorphisms that modulate induction of tolerance and trained immunity in human monocytes. These data demonstrate the importance of the IRG1-itaconateSDH axis in the development of immune tolerance and training and highlight the potential of b-glucaninduced trained immunity to revert immunoparalysis.</p>', 'date' => '2018-10-01', 'pmid' => 'http://www.pubmed.gov/30293776', 'doi' => '10.1016/j.cmet.2018.09.003', 'modified' => '2018-11-22 15:18:30', 'created' => '2018-11-08 12:59:45', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 10 => array( 'id' => '3407', 'name' => 'The histone demethylase Jarid1b mediates angiotensin II-induced endothelial dysfunction by controlling the 3'UTR of soluble epoxide hydrolase.', 'authors' => 'Vasconez AE, Janetzko P, Oo JA, Pflüger-Müller B, Ratiu C, Gu L, Helin K, Geisslinger G, Fleming I, Schröder K, Fork C, Brandes RP, Leisegang MS', 'description' => '<p>AIM: The histone demethylase Jarid1b limits gene expression by removing the active methyl mark from histone3 lysine4 at gene promoter regions. A vascular function of Jarid1b is unknown, but a vasoprotective function to inflammatory and hypertrophic stimuli, like angiotensin II (AngII) could be inferred. This hypothesis was tested using Jarid1b knockout mice and the inhibitor PBIT. METHODS: Mice or aortic segments were treated with AngII to induce endothelial dysfunction. Aortae from WT and Jarid1b knockout were studied in organ chambers and endothelium-dependent dilator responses to acetylcholine and endothelium-independent responses to DetaNONOate were recorded after pre-constriction with phenylephrine in the presence or absence of the NO-synthase inhibitor nitro-L-arginine. Molecular mechanisms were investigated with chromatin immunoprecipitation, RNA-Seq, RNA-3'-adaptor-ligation, actinomycin D and RNA-immunoprecipitation. RESULTS: Knockout or inhibition of Jarid1b prevented the development of endothelial dysfunction in response to AngII. This effect was not a consequence of altered nitrite oxide availability but accompanied by a loss of the inflammatory response to AngII. As Jarid1b mainly inhibits gene expression, an indirect effect should account for this observation. AngII induced the soluble epoxide hydrolase (sEH), which degrades anti-inflammatory lipids, and thus promotes inflammation. Knockout or inhibition of Jarid1b prevented the AngII-mediated sEH induction. Mechanistically, Jarid1b maintained the length of the 3'untranslated region of the sEH mRNA, thereby increasing its stability and thus sEH protein expression. Loss of Jarid1b activity therefore resulted in sEH mRNA destabilization. CONCLUSION: Jarid1b contributes to the pro-inflammatory effects of AngII by stabilizing sEH expression. Jarid1b inhibition might be an option for future therapeutics against cardiovascular dysfunction.</p>', 'date' => '2018-08-04', 'pmid' => 'http://www.pubmed.gov/30076673', 'doi' => '10.1111/apha.13168', 'modified' => '2018-11-09 11:18:29', 'created' => '2018-11-08 12:59:45', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 11 => array( 'id' => '3632', 'name' => 'Epigenetic regulation of brain region-specific microglia clearance activity.', 'authors' => 'Ayata P, Badimon A, Strasburger HJ, Duff MK, Montgomery SE, Loh YE, Ebert A, Pimenova AA, Ramirez BR, Chan AT, Sullivan JM, Purushothaman I, Scarpa JR, Goate AM, Busslinger M, Shen L, Losic B, Schaefer A', 'description' => '<p>The rapid elimination of dying neurons and nonfunctional synapses in the brain is carried out by microglia, the resident myeloid cells of the brain. Here we show that microglia clearance activity in the adult brain is regionally regulated and depends on the rate of neuronal attrition. Cerebellar, but not striatal or cortical, microglia exhibited high levels of basal clearance activity, which correlated with an elevated degree of cerebellar neuronal attrition. Exposing forebrain microglia to apoptotic cells activated gene-expression programs supporting clearance activity. We provide evidence that the polycomb repressive complex 2 (PRC2) epigenetically restricts the expression of genes that support clearance activity in striatal and cortical microglia. Loss of PRC2 leads to aberrant activation of a microglia clearance phenotype, which triggers changes in neuronal morphology and behavior. Our data highlight a key role of epigenetic mechanisms in preventing microglia-induced neuronal alterations that are frequently associated with neurodegenerative and psychiatric diseases.</p>', 'date' => '2018-08-01', 'pmid' => 'http://www.pubmed.gov/30038282', 'doi' => '10.1038/s41593-018-0192-3', 'modified' => '2019-06-07 10:34:03', 'created' => '2019-06-06 12:11:18', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 12 => array( 'id' => '3621', 'name' => 'Episomal HBV persistence within transcribed host nuclear chromatin compartments involves HBx.', 'authors' => 'Hensel KO, Cantner F, Bangert F, Wirth S, Postberg J', 'description' => '<p>BACKGROUND: In hepatocyte nuclei, hepatitis B virus (HBV) genomes occur episomally as covalently closed circular DNA (cccDNA). The HBV X protein (HBx) is required to initiate and maintain HBV replication. The functional nuclear localization of cccDNA and HBx remains unexplored. RESULTS: To identify virus-host genome interactions and the underlying nuclear landscape for the first time, we combined circular chromosome conformation capture (4C) with RNA-seq and ChIP-seq. Moreover, we studied HBx-binding to HBV episomes. In HBV-positive HepaRG hepatocytes, we observed preferential association of HBV episomes and HBx with actively transcribed nuclear domains on the host genome correlating in size with constrained topological units of chromatin. Interestingly, HBx alone occupied transcribed chromatin domains. Silencing of native HBx caused reduced episomal HBV stability. CONCLUSIONS: As part of the HBV episome, HBx might stabilize HBV episomal nuclear localization. Our observations may contribute to the understanding of long-term episomal stability and the facilitation of viral persistence. The exact mechanism by which HBx contributes to HBV nuclear persistence warrants further investigations.</p>', 'date' => '2018-06-22', 'pmid' => 'http://www.pubmed.gov/29933745', 'doi' => '10.1186/s13072-018-0204-2', 'modified' => '2019-05-16 11:23:59', 'created' => '2019-04-25 11:11:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 13 => array( 'id' => '3541', 'name' => 'Long noncoding RNA LISPR1 is required for S1P signaling and endothelial cell function.', 'authors' => 'Josipovic I, Pflüger B, Fork C, Vasconez AE, Oo JA, Hitzel J, Seredinski S, Gamen E, Heringdorf DMZ, Chen W, Looso M, Pullamsetti SS, Brandes RP, Leisegang MS', 'description' => '<p>Sphingosine-1-Phosphate (S1P) is a potent signaling lipid. The effects of S1P are mediated by the five S1P receptors (S1PR). In the endothelium S1PR1 is the predominant receptor and thus S1PR1 abundance limits S1P signaling. Recently, lncRNAs were identified as a novel class of molecules regulating gene expression. Interestingly, the lncRNA NONHSAT004848 (LISPR1, Long intergenic noncoding RNA antisense to S1PR1), is closely positioned to the S1P1 receptors gene and in part shares its promoter region. We hypothesize that LISPR1 controls endothelial S1PR1 expression and thus S1P-induced signaling in endothelial cells. In vitro transcription and translation as well as coding potential assessment showed that LISPR1 is indeed noncoding. LISPR1 was localized in both cytoplasm and nucleus and harbored a PolyA tail at the 3'end. In human umbilical vein endothelial cells, as well as human lung tissue, qRT-PCR and RNA-Seq revealed high expression of LISPR1. S1PR1 and LISPR1 were downregulated in human pulmonary diseases such as COPD. LISPR1 but also S1PR1 were induced by inflammation, shear stress and statins. Knockdown of LISPR1 attenuated endothelial S1P-induced migration and spheroid outgrowth of endothelial cells. LISPR1 knockdown decreased S1PR1 expression, which was paralleled by an increase of the binding of the transcriptional repressor ZNF354C to the S1PR1 promoter and a reduction of the recruitment of RNA Polymerase II to the S1PR1 5'end. This resulted in attenuated S1PR1 expression and attenuated S1P downstream signaling. Collectively, the disease relevant lncRNA LISPR1 acts as a novel regulatory unit important for S1PR1 expression and endothelial cell function.</p>', 'date' => '2018-03-01', 'pmid' => 'http://www.pubmed.gov/29408197', 'doi' => '10.1016/j.yjmcc.2018.01.015', 'modified' => '2019-02-28 10:52:59', 'created' => '2019-02-27 12:54:44', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 14 => array( 'id' => '3446', 'name' => 'Metabolic Induction of Trained Immunity through the Mevalonate Pathway.', 'authors' => 'Bekkering S, Arts RJW, Novakovic B, Kourtzelis I, van der Heijden CDCC, Li Y, Popa CD, Ter Horst R, van Tuijl J, Netea-Maier RT, van de Veerdonk FL, Chavakis T, Joosten LAB, van der Meer JWM, Stunnenberg H, Riksen NP, Netea MG', 'description' => '<p>Innate immune cells can develop long-term memory after stimulation by microbial products during infections or vaccinations. Here, we report that metabolic signals can induce trained immunity. Pharmacological and genetic experiments reveal that activation of the cholesterol synthesis pathway, but not the synthesis of cholesterol itself, is essential for training of myeloid cells. Rather, the metabolite mevalonate is the mediator of training via activation of IGF1-R and mTOR and subsequent histone modifications in inflammatory pathways. Statins, which block mevalonate generation, prevent trained immunity induction. Furthermore, monocytes of patients with hyper immunoglobulin D syndrome (HIDS), who are mevalonate kinase deficient and accumulate mevalonate, have a constitutive trained immunity phenotype at both immunological and epigenetic levels, which could explain the attacks of sterile inflammation that these patients experience. Unraveling the role of mevalonate in trained immunity contributes to our understanding of the pathophysiology of HIDS and identifies novel therapeutic targets for clinical conditions with excessive activation of trained immunity.</p>', 'date' => '2018-01-11', 'pmid' => 'http://www.pubmed.gov/29328908', 'doi' => '10.1016/j.cell.2017.11.025', 'modified' => '2019-02-15 21:37:39', 'created' => '2019-02-14 15:01:22', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 15 => array( 'id' => '3408', 'name' => 'BCG Vaccination Protects against Experimental Viral Infection in Humans through the Induction of Cytokines Associated with Trained Immunity.', 'authors' => 'Arts RJW, Moorlag SJCFM, Novakovic B, Li Y, Wang SY, Oosting M, Kumar V, Xavier RJ, Wijmenga C, Joosten LAB, Reusken CBEM, Benn CS, Aaby P, Koopmans MP, Stunnenberg HG, van Crevel R, Netea MG', 'description' => '<p>The tuberculosis vaccine bacillus Calmette-Guérin (BCG) has heterologous beneficial effects against non-related infections. The basis of these effects has been poorly explored in humans. In a randomized placebo-controlled human challenge study, we found that BCG vaccination induced genome-wide epigenetic reprograming of monocytes and protected against experimental infection with an attenuated yellow fever virus vaccine strain. Epigenetic reprogramming was accompanied by functional changes indicative of trained immunity. Reduction of viremia was highly correlated with the upregulation of IL-1β, a heterologous cytokine associated with the induction of trained immunity, but not with the specific IFNγ response. The importance of IL-1β for the induction of trained immunity was validated through genetic, epigenetic, and immunological studies. In conclusion, BCG induces epigenetic reprogramming in human monocytes in vivo, followed by functional reprogramming and protection against non-related viral infections, with a key role for IL-1β as a mediator of trained immunity responses.</p>', 'date' => '2018-01-10', 'pmid' => 'http://www.pubmed.gov/29324233', 'doi' => '10.1016/j.chom.2017.12.010', 'modified' => '2018-11-22 15:15:09', 'created' => '2018-11-08 12:59:45', 'ProductsPublication' => array( [maximum depth reached] ) ), (int) 16 => array( 'id' => '3013', 'name' => 'Polycomb repressive complex 2 (PRC2) silences genes responsible for neurodegeneration', 'authors' => 'von Schimmelmann M et al.', 'description' => '<p>Normal brain function depends on the interaction between highly specialized neurons that operate within anatomically and functionally distinct brain regions. Neuronal specification is driven by transcriptional programs that are established during early neuronal development and remain in place in the adult brain. The fidelity of neuronal specification depends on the robustness of the transcriptional program that supports the neuron type-specific gene expression patterns. Here we show that polycomb repressive complex 2 (PRC2), which supports neuron specification during differentiation, contributes to the suppression of a transcriptional program that is detrimental to adult neuron function and survival. We show that PRC2 deficiency in striatal neurons leads to the de-repression of selected, predominantly bivalent PRC2 target genes that are dominated by self-regulating transcription factors normally suppressed in these neurons. The transcriptional changes in PRC2-deficient neurons lead to progressive and fatal neurodegeneration in mice. Our results point to a key role of PRC2 in protecting neurons against degeneration.</p>', 'date' => '2016-08-15', 'pmid' => 'http://www.nature.com/neuro/journal/vaop/ncurrent/full/nn.4360.html', 'doi' => '', 'modified' => '2016-08-31 09:10:11', 'created' => '2016-08-31 09:10:11', 'ProductsPublication' => array( [maximum depth reached] ) ) ), 'Testimonial' => array(), 'Area' => array(), 'SafetySheet' => array( (int) 0 => array( 'id' => '312', 'name' => 'DiaMag protein G-coated magnetic beads SDS US en', 'language' => 'en', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-US-en-GHS_1_0.pdf', 'countries' => 'US', 'modified' => '2020-06-09 12:24:02', 'created' => '2020-06-09 12:24:02', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 1 => array( 'id' => '310', 'name' => 'DiaMag protein G-coated magnetic beads SDS GB en', 'language' => 'en', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-GB-en-GHS_1_0.pdf', 'countries' => 'GB', 'modified' => '2020-06-09 12:22:54', 'created' => '2020-06-09 12:22:54', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 2 => array( 'id' => '305', 'name' => 'DiaMag protein G-coated magnetic beads SDS BE fr', 'language' => 'fr', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-BE-fr-GHS_1_0.pdf', 'countries' => 'BE', 'modified' => '2020-06-09 12:19:06', 'created' => '2020-06-09 12:19:06', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 3 => array( 'id' => '309', 'name' => 'DiaMag protein G-coated magnetic beads SDS FR fr', 'language' => 'fr', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-FR-fr-GHS_1_0.pdf', 'countries' => 'FR', 'modified' => '2020-06-09 12:22:18', 'created' => '2020-06-09 12:22:18', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 4 => array( 'id' => '308', 'name' => 'DiaMag protein G-coated magnetic beads SDS ES es', 'language' => 'es', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-ES-es-GHS_1_0.pdf', 'countries' => 'ES', 'modified' => '2020-06-09 12:21:36', 'created' => '2020-06-09 12:21:36', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 5 => array( 'id' => '307', 'name' => 'DiaMag protein G-coated magnetic beads SDS DE de', 'language' => 'de', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-DE-de-GHS_1_0.pdf', 'countries' => 'DE', 'modified' => '2020-06-09 12:21:03', 'created' => '2020-06-09 12:21:03', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 6 => array( 'id' => '311', 'name' => 'DiaMag protein G-coated magnetic beads SDS JP ja', 'language' => 'ja', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-JP-ja-GHS_2_0.pdf', 'countries' => 'JP', 'modified' => '2020-06-09 12:23:28', 'created' => '2020-06-09 12:23:28', 'ProductsSafetySheet' => array( [maximum depth reached] ) ), (int) 7 => array( 'id' => '306', 'name' => 'DiaMag protein G-coated magnetic beads SDS BE nl', 'language' => 'nl', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-BE-nl-GHS_1_0.pdf', 'countries' => 'BE', 'modified' => '2020-06-09 12:20:21', 'created' => '2020-06-09 12:20:21', 'ProductsSafetySheet' => array( [maximum depth reached] ) ) ) ) $meta_canonical = 'https://www.diagenode.com/en/p/diamag-protein-g-coated-magnetic-beads-220-ul' $country = 'US' $countries_allowed = array( (int) 0 => 'CA', (int) 1 => 'US', (int) 2 => 'IE', (int) 3 => 'GB', (int) 4 => 'DK', (int) 5 => 'NO', (int) 6 => 'SE', (int) 7 => 'FI', (int) 8 => 'NL', (int) 9 => 'BE', (int) 10 => 'LU', (int) 11 => 'FR', (int) 12 => 'DE', (int) 13 => 'CH', (int) 14 => 'AT', (int) 15 => 'ES', (int) 16 => 'IT', (int) 17 => 'PT' ) $outsource = false $other_formats = array( (int) 0 => array( 'id' => '1908', 'antibody_id' => null, 'name' => 'DiaMag protein G-coated magnetic beads (ChIP-seq grade)', 'description' => '<p>The protein G-coated magnetic beads have been extensively validated in chromatin immunoprecipitation assay (ChIP). These beads are intended for isolation of immune complexes (chromatin and specific antibody) in ChIP experiments. The beads are suitable for immunoprecipitation of mouse IgG1, IgG2a, IgG2b and IgG3, rat IgG1, IgG2a, IgG2b and IgG3, rabbit and goat polyclonal Abs and human IgG1, IgG2, IgG3 and IgG4. The beads should be washed before use.</p>', 'label1' => '', 'info1' => '', 'label2' => '', 'info2' => '', 'label3' => '', 'info3' => '', 'format' => '220 µl', 'catalog_number' => 'C03010021-220', 'old_catalog_number' => 'kch-818-220', 'sf_code' => 'C03010021-D001-000572', 'type' => 'REF', 'search_order' => '04-undefined', 'price_EUR' => '100', 'price_USD' => '125', 'price_GBP' => '95', 'price_JPY' => '15665', 'price_CNY' => '', 'price_AUD' => '312', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => true, 'last_datasheet_update' => '0000-00-00', 'slug' => 'diamag-protein-g-coated-magnetic-beads-220-ul', 'meta_title' => 'DiaMag protein G-coated magnetic beads', 'meta_keywords' => '', 'meta_description' => 'DiaMag protein G-coated magnetic beads', 'modified' => '2020-05-27 13:51:03', 'created' => '2015-06-29 14:08:20' ), (int) 1 => array( 'id' => '1909', 'antibody_id' => null, 'name' => 'DiaMag protein G-coated magnetic beads (ChIP-seq grade)', 'description' => '<p>The protein G-coated magnetic beads have been extensively validated in chromatin immunoprecipitation assay (ChIP). These beads are intended for isolation of immune complexes (chromatin and specific antibody) in ChIP experiments. The beads are suitable for immunoprecipitation of mouse IgG1, IgG2a, IgG2b and IgG3, rat IgG1, IgG2a, IgG2b and IgG3, rabbit and goat polyclonal Abs and human IgG1, IgG2, IgG3 and IgG4. The beads should be washed before use.</p>', 'label1' => '', 'info1' => '', 'label2' => '', 'info2' => '', 'label3' => '', 'info3' => '', 'format' => '660 µl', 'catalog_number' => 'C03010021-660', 'old_catalog_number' => 'kch-818-660', 'sf_code' => 'C03010021-350', 'type' => 'REF', 'search_order' => '04-undefined', 'price_EUR' => '265', 'price_USD' => '250', 'price_GBP' => '245', 'price_JPY' => '41510', 'price_CNY' => '', 'price_AUD' => '625', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => false, 'last_datasheet_update' => '0000-00-00', 'slug' => 'diamag-protein-g-coated-magnetic-beads-660-ul', 'meta_title' => 'DiaMag protein G-coated magnetic beads', 'meta_keywords' => '', 'meta_description' => 'DiaMag protein G-coated magnetic beads', 'modified' => '2020-05-27 13:49:15', 'created' => '2015-06-29 14:08:20', 'ProductsGroup' => array( 'id' => '182', 'product_id' => '1909', 'group_id' => '168' ) ) ) $pro = array( 'id' => '1909', 'antibody_id' => null, 'name' => 'DiaMag protein G-coated magnetic beads (ChIP-seq grade)', 'description' => '<p>The protein G-coated magnetic beads have been extensively validated in chromatin immunoprecipitation assay (ChIP). These beads are intended for isolation of immune complexes (chromatin and specific antibody) in ChIP experiments. The beads are suitable for immunoprecipitation of mouse IgG1, IgG2a, IgG2b and IgG3, rat IgG1, IgG2a, IgG2b and IgG3, rabbit and goat polyclonal Abs and human IgG1, IgG2, IgG3 and IgG4. The beads should be washed before use.</p>', 'label1' => '', 'info1' => '', 'label2' => '', 'info2' => '', 'label3' => '', 'info3' => '', 'format' => '660 µl', 'catalog_number' => 'C03010021-660', 'old_catalog_number' => 'kch-818-660', 'sf_code' => 'C03010021-350', 'type' => 'REF', 'search_order' => '04-undefined', 'price_EUR' => '265', 'price_USD' => '250', 'price_GBP' => '245', 'price_JPY' => '41510', 'price_CNY' => '', 'price_AUD' => '625', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => false, 'last_datasheet_update' => '0000-00-00', 'slug' => 'diamag-protein-g-coated-magnetic-beads-660-ul', 'meta_title' => 'DiaMag protein G-coated magnetic beads', 'meta_keywords' => '', 'meta_description' => 'DiaMag protein G-coated magnetic beads', 'modified' => '2020-05-27 13:49:15', 'created' => '2015-06-29 14:08:20', 'ProductsGroup' => array( 'id' => '182', 'product_id' => '1909', 'group_id' => '168' ) ) $edit = '' $testimonials = '' $featured_testimonials = '' $related_products = '' $rrbs_service = array( (int) 0 => (int) 1894, (int) 1 => (int) 1895 ) $chipseq_service = array( (int) 0 => (int) 2683, (int) 1 => (int) 1835, (int) 2 => (int) 1836, (int) 3 => (int) 2684, (int) 4 => (int) 1838, (int) 5 => (int) 1839, (int) 6 => (int) 1856 ) $labelize = object(Closure) { } $old_catalog_number = ' <span style="color:#CCC">(kch-818-660)</span>' $country_code = 'US' $other_format = array( 'id' => '1909', 'antibody_id' => null, 'name' => 'DiaMag protein G-coated magnetic beads (ChIP-seq grade)', 'description' => '<p>The protein G-coated magnetic beads have been extensively validated in chromatin immunoprecipitation assay (ChIP). These beads are intended for isolation of immune complexes (chromatin and specific antibody) in ChIP experiments. The beads are suitable for immunoprecipitation of mouse IgG1, IgG2a, IgG2b and IgG3, rat IgG1, IgG2a, IgG2b and IgG3, rabbit and goat polyclonal Abs and human IgG1, IgG2, IgG3 and IgG4. The beads should be washed before use.</p>', 'label1' => '', 'info1' => '', 'label2' => '', 'info2' => '', 'label3' => '', 'info3' => '', 'format' => '660 µl', 'catalog_number' => 'C03010021-660', 'old_catalog_number' => 'kch-818-660', 'sf_code' => 'C03010021-350', 'type' => 'REF', 'search_order' => '04-undefined', 'price_EUR' => '265', 'price_USD' => '250', 'price_GBP' => '245', 'price_JPY' => '41510', 'price_CNY' => '', 'price_AUD' => '625', 'country' => 'ALL', 'except_countries' => 'None', 'quote' => false, 'in_stock' => false, 'featured' => false, 'no_promo' => false, 'online' => true, 'master' => false, 'last_datasheet_update' => '0000-00-00', 'slug' => 'diamag-protein-g-coated-magnetic-beads-660-ul', 'meta_title' => 'DiaMag protein G-coated magnetic beads', 'meta_keywords' => '', 'meta_description' => 'DiaMag protein G-coated magnetic beads', 'modified' => '2020-05-27 13:49:15', 'created' => '2015-06-29 14:08:20', 'ProductsGroup' => array( 'id' => '182', 'product_id' => '1909', 'group_id' => '168' ) ) $label = '<img src="/img/banners/banner-customizer-back.png" alt=""/>' $document = array( 'id' => '118', 'name' => 'Datasheet DiaMag protein G-coated magnetic beads', 'description' => 'Datasheet description', 'image_id' => null, 'type' => 'Datasheet', 'url' => 'files/products/reagents/Datasheet_DiaMag_protein_G-coated_magnetic_beads.pdf', 'slug' => 'datasheet-diamag-protein-g-coated-magnetic-beads', 'meta_keywords' => null, 'meta_description' => null, 'modified' => '2015-07-07 11:47:43', 'created' => '2015-07-07 11:47:43', 'ProductsDocument' => array( 'id' => '245', 'product_id' => '1907', 'document_id' => '118' ) ) $sds = array( 'id' => '306', 'name' => 'DiaMag protein G-coated magnetic beads SDS BE nl', 'language' => 'nl', 'url' => 'files/SDS/DiaMag_protein/SDS-C03010021-DiaMag_protein_G-coated_magnetic_beads-BE-nl-GHS_1_0.pdf', 'countries' => 'BE', 'modified' => '2020-06-09 12:20:21', 'created' => '2020-06-09 12:20:21', 'ProductsSafetySheet' => array( 'id' => '557', 'product_id' => '1907', 'safety_sheet_id' => '306' ) ) $publication = array( 'id' => '3013', 'name' => 'Polycomb repressive complex 2 (PRC2) silences genes responsible for neurodegeneration', 'authors' => 'von Schimmelmann M et al.', 'description' => '<p>Normal brain function depends on the interaction between highly specialized neurons that operate within anatomically and functionally distinct brain regions. Neuronal specification is driven by transcriptional programs that are established during early neuronal development and remain in place in the adult brain. The fidelity of neuronal specification depends on the robustness of the transcriptional program that supports the neuron type-specific gene expression patterns. Here we show that polycomb repressive complex 2 (PRC2), which supports neuron specification during differentiation, contributes to the suppression of a transcriptional program that is detrimental to adult neuron function and survival. We show that PRC2 deficiency in striatal neurons leads to the de-repression of selected, predominantly bivalent PRC2 target genes that are dominated by self-regulating transcription factors normally suppressed in these neurons. The transcriptional changes in PRC2-deficient neurons lead to progressive and fatal neurodegeneration in mice. Our results point to a key role of PRC2 in protecting neurons against degeneration.</p>', 'date' => '2016-08-15', 'pmid' => 'http://www.nature.com/neuro/journal/vaop/ncurrent/full/nn.4360.html', 'doi' => '', 'modified' => '2016-08-31 09:10:11', 'created' => '2016-08-31 09:10:11', 'ProductsPublication' => array( 'id' => '1555', 'product_id' => '1907', 'publication_id' => '3013' ) ) $externalLink = ' <a href="http://www.nature.com/neuro/journal/vaop/ncurrent/full/nn.4360.html" target="_blank"><i class="fa fa-external-link"></i></a>'include - APP/View/Products/view.ctp, line 755 View::_evaluate() - CORE/Cake/View/View.php, line 971 View::_render() - CORE/Cake/View/View.php, line 933 View::render() - CORE/Cake/View/View.php, line 473 Controller::render() - CORE/Cake/Controller/Controller.php, line 963 ProductsController::slug() - APP/Controller/ProductsController.php, line 1052 ReflectionMethod::invokeArgs() - [internal], line ?? Controller::invokeAction() - CORE/Cake/Controller/Controller.php, line 491 Dispatcher::_invoke() - CORE/Cake/Routing/Dispatcher.php, line 193 Dispatcher::dispatch() - CORE/Cake/Routing/Dispatcher.php, line 167 [main] - APP/webroot/index.php, line 118
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