CHD7 Targets Active Gene Enhancer Elements to Modulate ES Cell-Specific Gene Expression

CHD7 is one of nine members of the chromodomain helicase DNA–binding domain family of ATP–dependent chromatin remodeling enzymes found in mammalian cells. De novo mutation of CHD7 is a major cause of CHARGE syndrome, a genetic condition characterized by multiple congenital anomalies. To gain insights to the function of CHD7, we used the technique of chromatin immunoprecipitation followed by massively parallel DNA sequencing (ChIP–Seq) to map CHD7 sites in mouse ES cells. We identified 10,483 sites on chromatin bound by CHD7 at high confidence. Most of the CHD7 sites show features of gene enhancer elements. Specifically, CHD7 sites are predominantly located distal to transcription start sites, contain high levels of H3K4 mono-methylation, found within open chromatin that is hypersensitive to DNase I digestion, and correlate with ES cell-specific gene expression. Moreover, CHD7 co-localizes with P300, a known enhancer-binding protein and strong predictor of enhancer activity. Correlations with 18 other factors mapped by ChIP–seq in mouse ES cells indicate that CHD7 also co-localizes with ES cell master regulators OCT4, SOX2, and NANOG. Correlations between CHD7 sites and global gene expression profiles obtained from Chd7+/+, Chd7+/−, and Chd7−/− ES cells indicate that CHD7 functions at enhancers as a transcriptional rheostat to modulate, or fine-tune the expression levels of ES–specific genes. CHD7 can modulate genes in either the positive or negative direction, although negative regulation appears to be the more direct effect of CHD7 binding. These data indicate that enhancer-binding proteins can limit gene expression and are not necessarily co-activators. Although ES cells are not likely to be affected in CHARGE syndrome, we propose that enhancer-mediated gene dysregulation contributes to disease pathogenesis and that the critical CHD7 target genes may be subject to positive or negative regulation

Functional annotation of human long noncoding RNAs via molecular phenotyping

Long noncoding RNAs (lncRNAs) constitute the majority of transcripts in the mammalian genomes, and yet, their functions remain largely unknown. As part of the FANTOM6 project, we systematically knocked down the expression of 285 lncRNAs in human dermal fibroblasts and quantified cellular growth, morphological changes, and transcriptomic responses using Capped Analysis of Gene Expression (CAGE). Antisense oligonucleotides targeting the same lncRNAs exhibited global concordance, and the molecular phenotype, measured by CAGE, recapitulated the observed cellular phenotypes while providing additional insights on the affected genes and pathways. Here, we disseminate the largest-todate lncRNA knockdown data set with molecular phenotyping (over 1000 CAGE deep-sequencing libraries) for further exploration and highlight functional roles for ZNF213-AS1 and lnc-KHDC3L-2.Peer reviewe

Funktionelle Charakterisierung vom IGHMBP2, des Krankheitgenproduktes der Spinalen Muskelatrophie mit Atemnot Typ 1

Spinale Muskelatrophie mit Atemnot Type 1 (SMARD1) ist eine autosomal rezessive, neurodegenerative Erkrankung, die sich häufig schon im Säuglings- und Kleinkindalter manifestiert. Pathologisches Merkmal von SMARD1 ist eine frühe und akut einsetzende Atemnot und eine progrediente, zunächst distal betonte Muskelschwäche, die durch eine Lähmung des Zwerchfells und der Skelettmuskulatur aufgrund des Absterbens der motorischen Vordernhornzellen des Rückenmarks eintritt. SMARD1 ist eine monogene Krankheit, die durch Mutationen im Gen für das Immunoglobulin µ-bindende Protein 2“ (IGHMBP2) hervorgerufen wird. Obwohl Mutationen in IGHMBP2 ausschließlich die Degeneration von Motoneuronen auslösen, ist das Gen bei Menschen und Mäusen ubiquitär exprimiert. Deshalb scheint SMARD1 durch den Defekt eines „Haushaltsproteins“ statt eines Neuron-spezifischen Faktors verursacht zu werden. IGHMBP2 verfügt über eine N-terminale DEXDc-Helicase/ATPase-Domäne und gehört zur Superfamily 1 Helicase. Bislang war lediglich bekannt, dass das Protein in verschiedenen zellulären Aktivitäten wie DNA Replikation, Transkription und prä-mRNA Splicing zugewiesen wurde. Die präzise Funktion von IGHMBP2 in den obengenannten Prozessen, und damit auch die molekulare Ursache von SMARD1 sind jedoch noch völlig unklar. Das Ziel der vorliegenden Arbeit war es daher, das IGHMBP2 Protein sowohl enzymatisch zu charakterisieren als auch den Prozess zu identifizieren, in dem dieses Protein in vivo agiert. Mit diesem Wissen sollten dann pathogene Mutanten von IGHMBP2 auf Defekte hin untersucht werden. Ein Schlüssel für diese Arbeit war die Gewinnung von rekombinantem, biologisch aktivem IGHMBP2 durch eine zweistufige Aufreinigungsstrategie. Dieses hochreine Enzym zeigte eine ATP-abhängige Helikaseaktivität, die sowohl doppelsträngige DNA als auch RNA mit einer 5’→3’ Direktionalität entwindet. Interessanterweise zeigte sich, dass dieses Enzym -im Gegensatz zu früheren Befunden- nahezu ausschließlich im Zytoplasma von Zellen lokalisiert ist. Darüber hinaus wiesen die Affinitätsaufreinigungsexperimente und Grossenfraktionierungsuntersuchungen daraufhin, dass IGHMBP2 ein Bestandteil des RNase-empfindlichen Komplexes ist, der als Ribosomen identifiziert wurde. IGHMBP2 interagiert primär mit 80S Monosomen, wobei das Protein mit beiden Untereinheiten in Kontakt steht. Hingegen ist IGHMBP2 an Polysomen nur in geringen Mengen zu finden. Diese Befunde deuten stark auf eine Rolle von IGHMBP2 bei der mRNA Verarbeitung am Ribosom hin, wobei noch unklar ist, ob es sich um translationsrelevante Prozesse handelt oder die mRNA-Stabilität beeinflusst. Die biochemische und enzymatische Charakterisierung von IGHMBP2 erlaubte erstmals Einblicke in den Pathomechanismus von SMARD1. In den folgenden Untersuchungen wurden die enzymatischen Aktivitäten der SMARD1-erregenden Ighmbp2 Mutante und ihre Assoziation mit ribosomalen Untereinheiten nachgeforscht. Interessanterweise konnten pathogene Missense-Mutanten von IGHMBP2 noch genauso gut wie das Wildtyp-Protein mit ribosomalen Untereinheiten wechselwirken. Jedoch inhibierten alle bisher getesteten Mutanten die RNA Helikaseaktivität, allerdings über unterschiedliche Mechanismen. Diese Daten weisen darauf hin, dass ein Defekt in den enzymatischen Aktivitäten des IGHMBP2 direkt mit der Pathogenese der SMARD1 korreliert. Des Weiteren lassen die im Rahmen dieser Arbeit erhaltenen Ergebnisse vermuten, dass SMARD1 durch Defekte in der zellularen Translationsmaschinerie entsteht.Spinal muscular atrophy with respiratory distress type 1 (SMARD1) is an autosomal recessive neuronal disorder in infants. The disease is marked by early onset of respiratory distress and predominantly distal muscle weakness, as consequences of diaphragmatic paralysis and progressive degeneration of  motor neurons in the spinal cord, respectively. Genetically, SMARD1 is caused by mutations in the single gene encoding Immunoglobulin µ-Binding Protein 2 (IGHMBP2). Despite the tissue specific degeneration observed in SMARD1 patients, the disease gene product IGHMBP2 is ubiquitously expressed in human and mouse tissues. Therefore, SMARD1 appears to be a motor neuron disease caused by the malfunction of a “housekeeping” protein, rather than a neuron specific factor. IGHMBP2 harbors an N-terminal DEXDc-type helicase/ATPase domain and has been classified as a member of the Superfamily 1 (SF1) of helicases. This protein has been assigned to various cellular activities such as DNA replication, pre-mRNA splicing and transcription. However its precise function in either process has remained elusive. The study presented here aimed at the enzymatic characterization of IGHMBP2, the identification of a specific cellular process to which IGHMBP2 is connected and the role of this factor in the pathophysiology of SMARD1. As a first step toward this end, a two-step purification strategy was established, which enabled the large-scale purification of properly folded and enzymatically active IGHMBP2. In vitro enzymatic studies using this recombinant protein defined IGHMBP2 as an ATP-dependent helicase that catalyzes unwinding of duplices composed of either DNA or RNA in a 5’→3’ direction. In contrast to previous reports, indirect immunofluorescence studies revealed a predominantly cytoplasmic localization of IGHMBP2. Size-fractionation studies and affinity-purification experiments further showed that IGHMBP2 is part of an RNase-sensitive macromolecular complex, which was identified as the ribosome. Interestingly, IGHMBP2 was abundantly detected in both subunits as well as to 80S ribosomes but only in small amounts in actively translating polysomes. These data strongly point to a role of IGHMBP2 in ribosomes-associated gene regulation control, such as in mRNA stabilization or mRNA translation. However, its precise function in those pathways remains to be identified. The biochemical and enzymatic characterization of IGHMBP2 allowed for the first time insights into the pathomechanism of SMARD1. SMARD1-causing pathogenic IGHMBP2 variants were investigated for their enzymatic activities and interaction with ribosomal subunits. Interestingly, among all missense mutations that have been tested thus far, none obstructs association with ribosomal subunits. However, these mutants exhibit specific defects in either the ATPase or RNA helicase activity or both. The data suggest that defects in the enzymatic activity of IGHMBP2 directly correlate with the pathogenesis of SMARD1. Furthermore, these data also raise the possibility that the disease SMARD1 is caused by alterations in the cellular translation machinery

In vitro synthesized small interfering RNAs elicit RNA interference in african trypanosomes: an in vitro and in vivo analysis.

RNA interference (RNAi) describes an epigenetic gene silencing reaction by which gene-specific double-stranded RNA acts as a trigger to induce the ribonucleolytic degradation of homologous transcripts. RNAi in African trypanosomes has been shown to be involved in regulating the transcript abundance of retroposons, and the process currently represents the method of choice in gene function studies of the parasite. However, little is known concerning the mechanistic and structural aspects of the processing reaction. This is in part due to the absence of a trypanosome-specific RNAi in vitro system. Here we demonstrate that both the Dicer and the RNA-induced silencing complex steps of the RNAi reaction pathway can be monitored in vitro using cell-free trypanosome extracts. The two in vitro activities and the generated small interfering RNAs (siRNAs) are characterized by features known from other organisms, and we demonstrate that chemically as well as enzymatically synthesized siRNAs are functional in the parasite. Thus, the transfection of synthetic siRNAs can be used to rapidly monitor gene knockdown phenotypes in Trypanosoma brucei, which should be helpful in genome-wide, RNAi-based screening experiments

Evaluating Capture Sequence Performance for Single-Cell CRISPR Activation Experiments

10.1021/acssynbio.0c00499ACS SYNTHETIC BIOLOGY103640-64

EpiMogrify models H3K4me3 data to identify signaling molecules that improve cell fate control and maintenance

The need to derive and culture diverse cell or tissue types in vitro has prompted investigations on how changes in culture conditions affect cell states. However, the identification of the optimal conditions (e.g., signaling molecules and growth factors) required to maintain cell types or convert between cell types remains a time-consuming task. Here, we developed EpiMogrify, an approach that leverages data from ∼100 human cell/tissue types available from ENCODE and Roadmap Epigenomics consortia to predict signaling molecules and factors that can either maintain cell identity or enhance directed differentiation (or cell conversion). EpiMogrify integrates protein-protein interaction network information with a model of the cell's epigenetic landscape based on H3K4me3 histone modifications. Using EpiMogrify-predicted factors for maintenance conditions, we were able to better potentiate the maintenance of astrocytes and cardiomyocytes in vitro. We report a significant increase in the efficiency of astrocyte and cardiomyocyte differentiation using EpiMogrify-predicted factors for conversion conditions.</p

A signal-noise model for significance analysis of ChIP-seq with negative control

10.1093/bioinformatics/btq128Bioinformatics2691199-1204BOIN

JQ1 affects BRD2-dependent and independent transcription regulation without disrupting H4-hyperacetylated chromatin states

<p>The bromodomain and extra-terminal domain (BET) proteins are promising drug targets for cancer and immune diseases. However, BET inhibition effects have been studied more in the context of bromodomain-containing protein 4 (BRD4) than BRD2, and the BET protein association to histone H4-hyperacetylated chromatin is not understood at the genome-wide level. Here, we report transcription start site (TSS)-resolution integrative analyses of ChIP-seq and transcriptome profiles in human non-small cell lung cancer (NSCLC) cell line H23. We show that di-acetylation at K5 and K8 of histone H4 (H4K5acK8ac) co-localizes with H3K27ac and BRD2 in the majority of active enhancers and promoters, where BRD2 has a stronger association with H4K5acK8ac than H3K27ac. Although BET inhibition by JQ1 led to complete reduction of BRD2 binding to chromatin, only local changes of H4K5acK8ac levels were observed, suggesting that recruitment of BRD2 does not influence global histone H4 hyperacetylation levels. This finding supports a model in which recruitment of BET proteins via histone H4 hyperacetylation is predominant over hyperacetylation of histone H4 by BET protein-associated acetyltransferases. In addition, we found that a remarkable number of BRD2-bound genes, including MYC and its downstream target genes, were transcriptionally upregulated upon JQ1 treatment. Using BRD2-enriched sites and transcriptional activity analysis, we identified candidate transcription factors potentially involved in the JQ1 response in BRD2-dependent and -independent manner.</p