MES-4: an autosome-associated histone methyltransferase that participates in silencing the X chromosomes in the<i>C. elegans</i>germ line

Bender, Laurel; Suh, Jinkyo; Carroll, Coleen R.; Fong, Youyi; Fingerman, Ian M.; Briggs, Scott; Cao, Ran; Zhang, Yi; Reinke, V; Strome, Susan

doi:10.1242/dev.02584

Cited by 117 publications

(231 citation statements)

References 68 publications

(83 reference statements)

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“…MES-4 is a histone methyltransferase that, among other functions, is required for X chromosome transcriptional silencing. 17,18 Previous work has shown that loss of MES-4 activates transcription on the X chromosomes, 17,18 and we were able to detect a clear H5 signal on the X chromosomes in Z2/Z3 after feeding in mes-4(RNAi) animals. 5 Importantly, mes-4 RNAi also caused a significant increase in RAD-51 foci formation on the X chromosome (2% in control samples, 29% in mes-4 (RNAi) samples).…”

Section: Dna Damage Arises In Z2/z3 In a Nutrient-dependent Mannersupporting

confidence: 48%

Trouble in transitioning: activation of zygotic transcription can lead to DNA breakage and genome instability

Butuči

Wong²,

Michael

2015

Worm

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Section: Dna Damage Arises In Z2/z3 In a Nutrient-dependent Mannersupporting

confidence: 48%

Trouble in transitioning: activation of zygotic transcription can lead to DNA breakage and genome instability

Butuči

Wong²,

Michael

2015

Worm

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“…In-depth analysis in early embryos suggests instead that low H3K36me3 on X-linked genes reflects the distributions and activities of the two H3K36 histone methyltransferases, MES-4 and MET-1 ). MES-4, which can catalyze H3K36 methylation independently of RNA Pol II, associates preferentially with autosomal genes (Bender et al 2006;Rechtsteiner et al 2010). MET-1, which is presumed to depend on RNA Pol II like other H3K36 histone methyltransferases, can methylate genes on the X but is present at low levels in early embryos (Furuhashi et al 2010;Rechtsteiner et al 2010).…”

Section: Broad Chromatin Domains In C Elegansmentioning

confidence: 99%

Broad chromosomal domains of histone modification patterns in C. elegans

Liu¹,

Rechtsteiner²,

Egelhofer³

et al. 2010

Genome Res.

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266

331

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Chromatin immunoprecipitation identifies specific interactions between genomic DNA and proteins, advancing our understanding of gene-level and chromosome-level regulation. Based on chromatin immunoprecipitation experiments using validated antibodies, we define the genome-wide distributions of 19 histone modifications, one histone variant, and eight chromatin-associated proteins in Caenorhabditis elegans embryos and L3 larvae. Cluster analysis identified five groups of chromatin marks with shared features: Two groups correlate with gene repression, two with gene activation, and one with the X chromosome. The X chromosome displays numerous unique properties, including enrichment of monomethylated H4K20 and H3K27, which correlate with the different repressive mechanisms that operate in somatic tissues and germ cells, respectively. The data also revealed striking differences in chromatin composition between the autosomes and between chromosome arms and centers. Chromosomes I and III are globally enriched for marks of active genes, consistent with containing more highly expressed genes, compared to chromosomes II, IV, and especially V. Consistent with the absence of cytological heterochromatin and the holocentric nature of C. elegans chromosomes, markers of heterochromatin such as H3K9 methylation are not concentrated at a single region on each chromosome. Instead, H3K9 methylation is enriched on chromosome arms, coincident with zones of elevated meiotic recombination. Active genes in chromosome arms and centers have very similar histone mark distributions, suggesting that active domains in the arms are interspersed with heterochromatin-like structure. These data, which confirm and extend previous studies, allow for in-depth analysis of the organization and deployment of the C. elegans genome during development.

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“…Loss of either set of genes leads to transcription activation of X chromosome in the PGCs and eventual loss of germ cells in developing larvae. 10,11,34 In our analysis, we discovered that a significant fraction of xnd-1 embryos showed dramatic increase in the accumulation of H3K4me2 in the Z2/Z3. 15 The claim of increased accumulation of H3K4me2 in PGCs of xnd-1 mutant embryos is further strengthened by the misexpression of at least 2 neuronal markers in the germline of xnd-1 adults.…”

Section: Transcriptional Repression In Germ Cell Precursorsmentioning

confidence: 70%

“…The X chromosome is repressed by the activity of 2 classes of chromatin proteins: the Polycomb group (PcG) chromatin repressors E(Z) MES-2/MES-3 and MES-6 10 ; and the autosomeenriched proteins MES-4 and MRG-1. 11,34 The former impose H3K27 methylation on the X chromosome, leading to its silencing. The latter proteins methylate H3K36 on autosomes to prevent MES-2/3/6 binding.…”

Section: Transcriptional Repression In Germ Cell Precursorsmentioning

confidence: 99%

“…However, the X chromosome remains transcriptionally silenced in oocytes, a repression that is required for normal germ cell development. 10,11 XND-1 is among the earliest proteins to be expressed in the PGCs During early embryogenesis, germ cell determinants are segregated away from the somatic lineage. Both active localization to the P lineage and degradation in the somatic cells lead to PGC enrichment of key determinants including P-granules, NOS-2, and the transcriptional repressor PIE-1.…”

Section: Introductionmentioning

confidence: 99%

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A twist of fate: How a meiotic protein is providing new perspectives on germ cell development

Rana

Yanowitz

2016

Worm

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The molecular pathways that govern how germ line fate is acquired is an area of intense investigation that has major implications for the development of assisted reproductive technologies, infertility interventions, and treatment of germ cell cancers. Transcriptional repression has emerged as a primary mechanism to ensure suppression of somatic growth programs in primordial germ cells. In this commentary, we address how xnd-1 illuminates our understanding of transcriptional repression and how it is coordinated with the germ cell differentiation program. We recently identified xnd-1 as a novel, early determinant of germ cell fates in Caenorhabditis elegans. Our study revealed that XND-1 is maternally deposited into early embryos where it is selectively enriched in the germ lineage and then exclusively found on chromatin in the germ lineage throughout development and into adulthood when it dissociates from chromosomes in late pachytene. This localization is consistent with a range of interesting germ cell defects that suggest xnd-1 is a pivotal determinant of germ cell characteristics. Loss of xnd-1 results in a unique "one PGC (primordial germ cell)" phenotype due to G2 cell cycle arrest of the germline precursor blastomere, P 4 , which predisposes the animal and its progeny for reduced fecundity. The sterility in xnd-1 mutants is correlated with an increase in the transcriptional activationassociated histone modification, dimethylation of histone H3 lysine 4 (H3K4me2), and aberrant expression of somatic transgenes but overlapping roles with nos-2 and nos-1 suggest that transcriptional repression is achieved by multiple redundant mechanisms.

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MES-4: an autosome-associated histone methyltransferase that participates in silencing the X chromosomes in theC. elegansgerm line

Cited by 117 publications

References 68 publications

Trouble in transitioning: activation of zygotic transcription can lead to DNA breakage and genome instability

Trouble in transitioning: activation of zygotic transcription can lead to DNA breakage and genome instability

Broad chromosomal domains of histone modification patterns in C. elegans

A twist of fate: How a meiotic protein is providing new perspectives on germ cell development

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