A C. elegans LSD1 Demethylase Contributes to Germline Immortality by Reprogramming Epigenetic Memory

Katz, David J.; Edwards, Thomas M.; Reinke, V; Kelly, William G.

doi:10.1016/j.cell.2009.02.015

Cited by 314 publications

(370 citation statements)

References 46 publications

(57 reference statements)

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“…Altering this steady-state balance pushes either towards the accumulation of the mark or its erasure ). This has been described most clearly in embryonic reprogramming (Katz et al, 2009;VerMilyea et al, 2009).…”

Section: Discussionmentioning

confidence: 86%

“…Furthermore, it has been reported repeatedly that particular epigenetic modifications can be gradually changed over generations through a number of different settings. In particular, these include the progressive reduction of higher histone methylation levels to lower methylation forms (Katan-Khaykovich and Struhl, 2005), epigenetic reprogramming (Jeong et al, 2007;Katz et al, 2009), epigenetic silencing / heterochromatin formation (Mutskov and Felsenfeld, 2003;Millar and Grunstein, 2006), and transcription-coupled histone modifications (Tippmann et al, 2012). Furthermore, histone modification gradients for a number of different modifications have been observed along a particular genomic region (for a review, see Henikoff and Shilatifard, 2011).…”

Section: Introductionmentioning

confidence: 99%

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Chromatin computation: Epigenetic inheritance as a pattern reconstruction problem

Arnold

Stadler

Prohaska

2013

Journal of Theoretical Biology

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Eukaryotic histones carry a diverse set of specific chemical modifications that accumulate over the life-time of a cell and have a crucial impact on the cell state in general and the transcriptional program in particular. Replication constitutes a dramatic disruption of the chromatin states that effectively amounts to partial erasure of stored information. To preserve its epigenetic state the cell reconstructs (at least part of) the histone modifications by means of processes that are still very poorly understood. A plausible hypothesis is that the different combinations of reader and writer domains in histone-modifying enzymes implement local rewriting rules that are capable of "recomputing" the desired parental modification patterns on the basis of the partial information contained in that half of the nucleosomes that predate replication.To test whether such a mechanism is theoretically feasible, we have developed a flexible stochastic simulation system (available at http://www.bioinf.uni-leipzig.de/Software/StoChDyn) for studying the dynamics of histone modification states. The implementation is based on Gillespie's approach, i.e., it models the master equation of a detailed chemical model. It is efficient enough to use an evolutionary algorithm to find patterns across multiple cell divisions with high accuracy.We found that it is easy to evolve a system of enzymes that can maintain a particular chromatin state roughly stable, even without explicit boundary elements separating differentially modified chromatin domains. However, the success of this task depends on several previously unanticipated factors, such as the length of the initial state, the specific pattern that should be maintained, the time between replications, and chemical parameters such as enzymatic binding and dissociation rates. All these factors also influence the accumulation of errors in the wake of cell divisions.

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Section: Discussionmentioning

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Chromatin computation: Epigenetic inheritance as a pattern reconstruction problem

Arnold

Stadler

Prohaska

2013

Journal of Theoretical Biology

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“…[46][47][48] Likewise, loss of the LSD1 histone demethylase homolog spr-5 results in progressive failure to demethylate H3K4, impaired transcriptional repression, and cumulative sterility over multiple generations, while absence of the nanos homologs nos-1 and nos-2 causes premature reaccumulation of H3K4me2/3 in the embryonic germline and corresponding germline failure and sterility. 45,49 In D. melanogaster, germ cell precursors lacking nanos or the spr-5/LSD1…”

Section: Specification Of the Germlinementioning

confidence: 99%

“…81,[131][132][133] Because of these features, and because they retain the potential to In worms, mutations in the histone demethylase gene, spr-5 (an LSD1/KDM1 homolog), cause a weak sterility phenotype that is passed on and becomes progressively more severe in subsequent generations, although the spr-5 coding and promoter DNA sequence does not change. 49 Meanwhile, mutations in three genes encoding a histone methylase complex, ash-2, wdr-5, and set-2, increase longevity through several generations of offspring, even when only the founding parental animal carries the mutant allele. 140 In D. melanogaster, an osmotic or heat stress stimulus can disrupt the activity of the transcription factor ATF-2 and deposition of the repressive histone modification H3K9me2, and this disruption can be transmitted to the next generation in a non-Mendelian manner.…”

Section: Inheritance (Box 2)mentioning

confidence: 99%

Genetics of germ cell development

2012

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| The germ line represents a continuous cellular link between generations and between species, but the germ cells themselves develop in a specialized, organism-specific context. The three most common animal model organisms, C. elegans, Drosophila, and mouse, display striking similarities as well as major differences in the means by which they control germ cell development.Comparison of the germ cells of these three organisms sheds light not only on universal aspects of germline regulation, but also on control of the pluripotent state in vivo and on the earliest steps of embryogenesis. Taking a broad perspective, we will follow the germ cells from specification in the early embryo, through gametogenesis, to fertilization, and highlight themes from the comparison of three alternative strategies for navigating the fundamental cycle of sexual reproduction.

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“…spr-5 and met-2 mutants gradually accumulate H3K4me2 and lose H3K9me over many generations, leading to misexpression of spermatogenesis-enriched genes, reduced brood sizes, and sterility. 7,32,33 These studies highlight the importance of establishing an epigenetic "ground state" for germ cell development and illustrate the dramatic consequences of such an imbalance on fecundity.…”

Section: Transcriptional Repression In Germ Cell Precursorsmentioning

confidence: 99%

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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A C. elegans LSD1 Demethylase Contributes to Germline Immortality by Reprogramming Epigenetic Memory

Cited by 314 publications

References 46 publications

Chromatin computation: Epigenetic inheritance as a pattern reconstruction problem

Chromatin computation: Epigenetic inheritance as a pattern reconstruction problem

Genetics of germ cell development

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

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