Browsing by Subject "Meiosis"
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Item Open Access Across the meiotic divide - CSF activity in the post-Emi2/XErp1 era.(J Cell Sci, 2008-11-01) Wu, Judy Qiju; Kornbluth, SallyVertebrate eggs are arrested at the metaphase stage of meiosis II. Only upon fertilization will the metaphase-II-arrested eggs exit meiosis II and enter interphase. In 1971, Masui and Markert injected egg extracts into a two-cell-stage embryo and found that the injected blastomere arrested at the next mitosis. On the basis of these observations, they proposed the existence of an activity present in the eggs that is responsible for meiosis-II arrest and can induce mitotic arrest, and named this activity cytostatic factor (CSF). Although the existence of CSF was hypothesized more than 35 years ago, its precise identity remained unclear until recently. The discovery of the Mos-MAPK pathway and characterization of the anaphase-promoting complex/cyclosome (APC/C) as a central regulator of M-phase exit provided the framework for a molecular understanding of CSF. These pathways have now been linked by the discovery and characterization of the protein Emi2, a meiotic APC/C inhibitor, the activity and stability of which are controlled by the Mos-MAPK pathway. Continued investigation into the mechanism of action and mode of regulation of Emi2 promises to shed light not only on CSF function, but also on the general principles of APC/C regulation and the control of protein function by MAPK pathways.Item Open Access Control of Emi2 activity and stability through Mos-mediated recruitment of PP2A.(Proc Natl Acad Sci U S A, 2007-10-16) Wu, Judy Qiju; Hansen, David V; Guo, Yanxiang; Wang, Michael Zhuo; Tang, Wanli; Freel, Christopher D; Tung, Jeffrey J; Jackson, Peter K; Kornbluth, SallyBefore fertilization, vertebrate eggs are arrested in meiosis II by cytostatic factor (CSF), which holds the anaphase-promoting complex (APC) in an inactive state. It was recently reported that Mos, an integral component of CSF, acts in part by promoting the Rsk-mediated phosphorylation of the APC inhibitor Emi2/Erp1. We report here that Rsk phosphorylation of Emi2 promotes its interaction with the protein phosphatase PP2A. Emi2 residues adjacent to the Rsk phosphorylation site were important for PP2A binding. An Emi2 mutant that retained Rsk phosphorylation but lacked PP2A binding could not be modulated by Mos. PP2A bound to Emi2 acted on two distinct clusters of sites phosphorylated by Cdc2, one responsible for modulating its stability during CSF arrest and one that controls binding to the APC. These findings provide a molecular mechanism for Mos action in promoting CSF arrest and also define an unusual mechanism, whereby protein phosphorylation recruits a phosphatase for dephosphorylation of distinct sites phosphorylated by another kinase.Item Open Access Functional epialleles at an endogenous human centromere.(Proc Natl Acad Sci U S A, 2012-08-21) Maloney, Kristin A; Sullivan, Lori L; Matheny, Justyne E; Strome, Erin D; Merrett, Stephanie L; Ferris, Alyssa; Sullivan, Beth AHuman centromeres are defined by megabases of homogenous alpha-satellite DNA arrays that are packaged into specialized chromatin marked by the centromeric histone variant, centromeric protein A (CENP-A). Although most human chromosomes have a single higher-order repeat (HOR) array of alpha satellites, several chromosomes have more than one HOR array. Homo sapiens chromosome 17 (HSA17) has two juxtaposed HOR arrays, D17Z1 and D17Z1-B. Only D17Z1 has been linked to CENP-A chromatin assembly. Here, we use human artificial chromosome assembly assays to show that both D17Z1 and D17Z1-B can support de novo centromere assembly independently. We extend these in vitro studies and demonstrate, using immunostaining and chromatin analyses, that in human cells the centromere can be assembled at D17Z1 or D17Z1-B. Intriguingly, some humans are functional heterozygotes, meaning that CENP-A is located at a different HOR array on the two HSA17 homologs. The site of CENP-A assembly on HSA17 is stable and is transmitted through meiosis, as evidenced by inheritance of CENP-A location through multigenerational families. Differences in histone modifications are not linked clearly with active and inactive D17Z1 and D17Z1-B arrays; however, we detect a correlation between the presence of variant repeat units of D17Z1 and CENP-A assembly at the opposite array, D17Z1-B. Our studies reveal the presence of centromeric epialleles on an endogenous human chromosome and suggest genomic complexities underlying the mechanisms that determine centromere identity in humans.Item Open Access Gene expression in oogenesis and implications for transgenerational effects of environmental toxicants.(Biology of reproduction, 2011-01) Foster, Warren G; Hughes, Claude LItem Open Access Genomic and functional variation of human centromeres.(Experimental cell research, 2020-04) Sullivan, Lori L; Sullivan, Beth ACentromeres are central to chromosome segregation and genome stability, and thus their molecular foundations are important for understanding their function and the ways in which they go awry. Human centromeres typically form at large megabase-sized arrays of alpha satellite DNA for which there is little genomic understanding due to its repetitive nature. Consequently, it has been difficult to achieve genome assemblies at centromeres using traditional next generation sequencing approaches, so that centromeres represent gaps in the current human genome assembly. The role of alpha satellite DNA has been debated since centromeres can form, albeit rarely, on non-alpha satellite DNA. Conversely, the simple presence of alpha satellite DNA is not sufficient for centromere function since chromosomes with multiple alpha satellite arrays only exhibit a single location of centromere assembly. Here, we discuss the organization of human centromeres as well as genomic and functional variation in human centromere location, and current understanding of the genomic and epigenetic mechanisms that underlie centromere flexibility in humans.Item Open Access Kinesins at a glance.(J Cell Sci, 2010-10-15) Endow, Sharyn A; Kull, F Jon; Liu, HongleiItem Open Access The prevalence and regulation of antisense transcripts in Schizosaccharomyces pombe.(PLoS One, 2010-12-20) Ni, Ting; Tu, Kang; Wang, Zhong; Song, Shen; Wu, Han; Xie, Bin; Scott, Kristin C; Grewal, Shiv I; Gao, Yuan; Zhu, JunA strand-specific transcriptome sequencing strategy, directional ligation sequencing or DeLi-seq, was employed to profile antisense transcriptome of Schizosaccharomyces pombe. Under both normal and heat shock conditions, we found that polyadenylated antisense transcripts are broadly expressed while distinct expression patterns were observed for protein-coding and non-coding loci. Dominant antisense expression is enriched in protein-coding genes involved in meiosis or stress response pathways. Detailed analyses further suggest that antisense transcripts are independently regulated with respect to their sense transcripts, and diverse mechanisms might be potentially involved in the biogenesis and degradation of antisense RNAs. Taken together, antisense transcription may have profound impacts on global gene regulation in S. pombe.Item Open Access Uncoupling of genomic and epigenetic signals in the maintenance and inheritance of heterochromatin domains in fission yeast.(Genetics, 2012-02) Wheeler, Bayly S; Ruderman, Brandon T; Willard, Huntington F; Scott, Kristin CMany essential aspects of genome function, including gene expression and chromosome segregation, are mediated throughout development and differentiation by changes in the chromatin state. Along with genomic signals encoded in the DNA, epigenetic processes regulate heritable gene expression patterns. Genomic signals such as enhancers, silencers, and repetitive DNA, while required for the establishment of alternative chromatin states, have an unclear role in epigenetic processes that underlie the persistence of chromatin states throughout development. Here, we demonstrate in fission yeast that the maintenance and inheritance of ectopic heterochromatin domains are independent of the genomic sequences necessary for their de novo establishment. We find that both structural heterochromatin and gene silencing can be stably maintained over an ~10-kb domain for up to hundreds of cell divisions in the absence of genomic sequences required for heterochromatin establishment, demonstrating the long-term persistence and stability of this chromatin state. The de novo heterochromatin, despite the absence of nucleation sequences, is also stably inherited through meiosis. Together, these studies provide evidence for chromatin-dependent, epigenetic control of gene silencing that is heritable, stable, and self-sustaining, even in the absence of the originating genomic signals.