Your search keyword '"Hendrik Marks"' showing total 3 results

1. STARR-seq identifies active, chromatin-masked, and dormant enhancers in pluripotent mouse embryonic stem cells

Author

Tianran Peng, Yanan Zhai, Yaser Atlasi, Menno ter Huurne, Hendrik Marks, Hendrik G. Stunnenberg, and Wout Megchelenbrink

Subjects

Biology (General), QH301-705.5, Genetics, QH426-470

Abstract

Abstract Background Enhancers are distal regulators of gene expression that shape cell identity and control cell fate transitions. In mouse embryonic stem cells (mESCs), the pluripotency network is maintained by the function of a complex network of enhancers, that are drastically altered upon differentiation. Genome-wide chromatin accessibility and histone modification assays are commonly used as a proxy for identifying putative enhancers and for describing their activity levels and dynamics. Results Here, we applied STARR-seq, a genome-wide plasmid-based assay, as a read-out for the enhancer landscape in “ground-state” (2i+LIF; 2iL) and “metastable” (serum+LIF; SL) mESCs. This analysis reveals that active STARR-seq loci show modest overlap with enhancer locations derived from peak calling of ChIP-seq libraries for common enhancer marks. We unveil ZIC3-bound loci with significant STARR-seq activity in SL-ESCs. Knock-out of Zic3 removes STARR-seq activity only in SL-ESCs and increases their propensity to differentiate towards the endodermal fate. STARR-seq also reveals enhancers that are not accessible, masked by a repressive chromatin signature. We describe a class of dormant, p53 bound enhancers that gain H3K27ac under specific conditions, such as after treatment with Nocodazol, or transiently during reprogramming from fibroblasts to pluripotency. Conclusions In conclusion, loci identified as active by STARR-seq often overlap with those identified by chromatin accessibility and active epigenetic marking, yet a significant fraction is epigenetically repressed or display condition-specific enhancer activity.

Published

2020

2. Allele-specific RNA-seq expression profiling of imprinted genes in mouse isogenic pluripotent states

Author

René A. M. Dirks, Guido van Mierlo, Hindrik H. D. Kerstens, Andreia S. Bernardo, Julianna Kobolák, István Bock, Julien Maruotti, Roger A. Pedersen, András Dinnyés, Martijn A. Huynen, Alice Jouneau, and Hendrik Marks

Subjects

Genomic imprinting, Allele-specific RNA-seq, Mouse embryo, Embryonic stem cells, ESCs, EpiSCs, Genetics, QH426-470

Abstract

Abstract Background Genomic imprinting, resulting in parent-of-origin specific gene expression, plays a critical role in mammalian development. Here, we apply allele-specific RNA-seq on isogenic B6D2F1 mice to assay imprinted genes in tissues from early embryonic tissues between E3.5 and E7.25 and in pluripotent cell lines to evaluate maintenance of imprinted gene expression. For the cell lines, we include embryonic stem cells (ESCs) and epiblast stem cells (EpiSCs) derived from fertilized embryos and from embryos obtained after nuclear transfer (NT) or parthenogenetic activation (PGA). Results As homozygous genomic regions of PGA-derived cells are not compatible with allele-specific RNA-seq, we developed an RNA-seq-based genotyping strategy allowing identification of informative heterozygous regions. Global analysis shows that proper imprinted gene expression as observed in embryonic tissues is largely lost in the ESC lines included in this study, which mainly consisted of female ESCs. Differentiation of ESC lines to embryoid bodies or NPCs does not restore monoallelic expression of imprinted genes, neither did reprogramming of the serum-cultured ESCs to the pluripotent ground state by the use of 2 kinase inhibitors. Fertilized EpiSC and EpiSC-NT lines largely maintain imprinted gene expression, as did EpiSC-PGA lines that show known paternally expressed genes being silent and known maternally expressed genes consistently showing doubled expression. Notably, two EpiSC-NT lines show aberrant silencing of Rian and Meg3, two critically imprinted genes in mouse iPSCs. With respect to female EpiSC, most of the lines displayed completely skewed X inactivation suggesting a (near) clonal origin. Conclusions Altogether, our analysis provides a comprehensive overview of imprinted gene expression in pluripotency and provides a benchmark to allow identification of cell lines that faithfully maintain imprinted gene expression and therefore retain full developmental potential.

Published

2019

3. In silico identification of putative promoter motifs of White Spot Syndrome Virus

Author

Mariëlle C. W. van Hulten, Xin-Ying Ren, Just M. Vlak, Hans Sandbrink, and Hendrik Marks

Subjects

Transcription, Genetic, genome sequence, White spot syndrome, Laboratory of Virology, Herpesvirus 1, Human, Biochemistry, Genome, Conserved sequence, baculovirus, White spot syndrome virus 1, Structural Biology, Promoter Regions, Genetic, lcsh:QH301-705.5, Conserved Sequence, Oligonucleotide Array Sequence Analysis, Genetics, biology, Applied Mathematics, structural proteins, PE&RC, proteomic analysis, TATA Box, Computer Science Applications, lcsh:R858-859.7, penaeus-monodon, RNA Polymerase II, DNA microarray, shrimp, Research Article, Gene Expression Regulation, Viral, transcriptional analysis, Sequence analysis, Bioinformatics, virion protein genes, In silico, Molecular Sequence Data, Vaccinia virus, Polyadenylation, lcsh:Computer applications to medicine. Medical informatics, Laboratorium voor Virologie, Open Reading Frames, Viral Proteins, Bioinformatica, RNA, Messenger, Molecular Biology, Gene, Base Sequence, swine-fever virus, Sequence Analysis, DNA, biology.organism_classification, lcsh:Biology (General), nuclear polyhedrosis-virus

Abstract

Background White Spot Syndrome Virus, a member of the virus family Nimaviridae, is a large dsDNA virus infecting shrimp and other crustacean species. Although limited information is available on the mode of transcription, previous data suggest that WSSV gene expression occurs in a coordinated and cascaded fashion. To search in silico for conserved promoter motifs (i) the abundance of all 4 through 8 nucleotide motifs in the upstream sequences of WSSV genes relative to the complete genome was determined, and (ii) a MEME search was performed in the upstream sequences of either early or late WSSV genes, as assigned by microarray analysis. Both methods were validated by alignments of empirically determined 5' ends of various WSSV mRNAs. Results The collective information shows that the upstream region of early WSSV genes, containing a TATA box and an initiator, is similar to Drosophila RNA polymerase II core promoter sequences, suggesting utilization of the cellular transcription machinery for generating early transcripts. The alignment of the 5' ends of known well-established late genes, including all major structural protein genes, identified a degenerate motif (ATNAC) which could be involved in WSSV late transcription. For these genes, only one contained a functional TATA box. However, almost half of the WSSV late genes, as previously assigned by microarray analysis, did contain a TATA box in their upstream region. Conclusion The data may suggest the presence of two separate classes of late WSSV genes, one exploiting the cellular RNA polymerase II system for mRNA synthesis and the other generating messengers by a new virus-induced transcription mechanism.

Published

2006