Mitotic Expression of Spo13 Alters M-Phase Progression and Nucleolar Localization of Cdc14 in Budding Yeast

Varela, Elisa; Schlecht, Ulrich; Moina, Anca; Fackenthal, James D.; Washburn, Brian K.; Niederhauser-Wiederkehr, Christa; Tsai-Pflugfelder, Monika; Primig, Michael; Gasser, Susan M.; Esposito, Rochelle Easton

doi:10.1534/genetics.109.113746

Cited by 7 publications

(5 citation statements)

References 58 publications

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“…It means that the effect of Spo13 expression was more lethal as compared to Rec8 expression. Varela et al first reported that mitotic Spo13 expression altered cell cycle progression and was unable to exit anaphase with change in the cell morphology [27]. We also observed same morphological change (elongated cell) in Spo13 expression strain (Fig.…”

Section: Resultssupporting

confidence: 85%

Construction of strains to identify novel factors for regulation of centromeric cohesion protection (CCP) and sister kinetochore mono-orientation (SKM)

Bharati

Ghosh

2019

BMC Mol and Cell Biol

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BackgroundMeiosis-I is a unique type of chromosome segregation where each chromosome aligns and segregates from its homolog. The mechanism of meiosis I homolog separation in different eukaryotes depends on their centromere and kinetochore architecture which in turn relies mainly on two processes, first on a specialized four protein complex known as monopolin and second, the centromeric cohesion protection (CCP). However, in mammals the complex has not been identified. Furthermore, in budding yeast, there could be additional factors in this process which includes some meiosis specific and some non meiosis specific factors.ResultWe constructed two strains. In the first strain we expressed Mam1 and Cdc5 which leads to sister kinetochore monoorientation (SKM) and in the second case we expressed Rec8 and Spo13 which enhanced CCP even in mitosis. The expression of these proteins in mitotically dividing cells caused co-orientation of the chromosomes, which lead to the cell death followed by miss-segregation of chromosomes. Then we utilized these strains to screen the cDNA libraries from yeast and mammals to identify the novel factors which participate in CCP and SKM. Finally, SGY4119 strain expressing Spo13 and Rec8 was transformed with pRS316 gal cDNA library and transformants were screened for lethality on galactose. We screened ~ 105 transformants colonies. Out of these ~ 3000 colonies were able to survive on galactose plate which was narrow down to 6 on the basis of desired phenotype.ConclusionSo far, meiosis specific kinetochore proteins have been identified only in two yeasts. Recently, in mammals a meiosis specific kinetochore protein (MEIKIN) has been identified with similar function. Till now a single protein in mammals and four proteins monopolin complex in budding yeast has been identified to coorient the centromere. Many more novel factors have to be identified yet. That is why we wished to device genetic screen using a functional genomics approach. Since the list of proteins already identified in yeast is not exhaustive as the circumstantial evidence suggests, we wish to use the same yeast strains to identify additional novel yeast proteins that may be involved in the execution of meiosis.

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Section: Resultssupporting

confidence: 85%

Construction of strains to identify novel factors for regulation of centromeric cohesion protection (CCP) and sister kinetochore mono-orientation (SKM)

Bharati

Ghosh

2019

BMC Mol and Cell Biol

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“…The exact role of Spo13 in cohesin protection is currently unclear. Interestingly, SPO13 overexpression blocks cohesin cleavage during mitosis ( Lee et al ., 2002 ; Shonn et al ., 2002 ; Varela et al ., 2010 ), suggesting that Spo13 may also influence cohesin cleavage in meiosis, but how it might do so remains unresolved. Although Spo13 was implicated in ensuring the proper pericentromeric localization of Sgo1 ( Kiburz et al ., 2005 ), other studies have found no difference in chromosomally associated Sgo1 ( Galander et al ., 2019 ; Lee et al ., 2004 ).…”

Section: Introductionmentioning

confidence: 99%

Spo13 prevents premature cohesin cleavage during meiosis

et al. 2019

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Background: Meiosis produces gametes through two successive nuclear divisions, meiosis I and meiosis II. In contrast to mitosis and meiosis II, where sister chromatids are segregated, during meiosis I, homologous chromosomes are segregated. This requires the monopolar attachment of sister kinetochores and the loss of cohesion from chromosome arms, but not centromeres, during meiosis I. The establishment of both sister kinetochore mono-orientation and cohesion protection rely on the budding yeast meiosis I-specific Spo13 protein, the functional homolog of fission yeast Moa1 and mouse MEIKIN. Methods: Here we investigate the effects of loss of SPO13 on cohesion during meiosis I using a live-cell imaging approach. Results: Unlike wild type, cells lacking SPO13 fail to maintain the meiosis-specific cohesin subunit, Rec8, at centromeres and segregate sister chromatids to opposite poles during anaphase I. We show that the cohesin-destabilizing factor, Wpl1, is not primarily responsible for the loss of cohesion during meiosis I. Instead, premature loss of centromeric cohesin during anaphase I in spo13Δ cells relies on separase-dependent cohesin cleavage. Further, cohesin loss in spo13Δ anaphase I cells is blocked by forcibly tethering the regulatory subunit of protein phosphatase 2A, Rts1, to Rec8. Conclusions: Our findings indicate that separase-dependent cleavage of phosphorylated Rec8 causes premature cohesin loss in spo13Δ cells.

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“…Here, we report on the establishment of a system enabling controllable expression of a meiosisspecific complex in mitosis. Similar approaches have been used previously to investigate different aspects of meiosis, such as HR repair and chromosome segregation [8][9][10][11][12] . We express components of the trimeric, meiosis-specific Red1, Hop1 and Mek1 complex (i.e., the RHM complex), and show that this complex can self-assemble even when expressed outside of its natural, physiological environment, i.e., in mitotically-dividing cells.…”

Section: Discussionmentioning

confidence: 99%

“…Meiosis can thus be seen as an adaptation of the mitotic cell cycle. One approach to understand meiosis-specific mechanisms is via reconstitution in non-physiological environments, for example via in vitro biochemical reconstitutions (e.g., [2][3][4][5][6][7] ), or by expressing meiosis-specific factors in non-meiotic cells (e.g., [8][9][10][11][12] ).…”

Section: Introductionmentioning

confidence: 99%

Studying meiosis in mitosis: Activating the meiosis-specific Red1-Hop1-Mek1 complex in mitotic budding yeast cells

Nivsarkar

Chen

Funk

et al. 2022

Preprint

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In mitosis, sequences on sister chromatids are preferred as DNA repair templates, whereas in meiosis interhomolog-based repair is promoted. The switch of template preference during homologous recombinational (HR) repair of DNA breaks is a defining event in sexual reproduction. This preference is needed to establish linkages between homologous chromosomes that support meiotic chromosome segregation. In budding yeast, a central activity that enforces meiotic interhomolog bias is encoded in a meiosis-specific protein kinase complex, consisting of Red1, Hop1 and Mek1 (i.e., the RHM complex). Activation of Mek1 kinase in meiosis - dictated by complex formation and upstream DNA break-dependent signaling - leads to modification of HR factors and the establishment of interhomolog HR repair bias. How meiotic repair bias is established is a central question with implications for sexual reproduction, genetic diversity and genome stability. Studying the role of the RHM complex in DNA repair is complicated by the fact that Red1 and Hop1 are required for efficient meiotic DNA break formation. Here, we conditionally express RHM components in mitotically-dividing cells to show that these factors can autonomously establish the RHM complex outside of its physiological environment. In vivo analysis is complemented with in vitro biochemical reconstitution to analyze the composition of a Red1-Hop1 subcomplex. The RHM complex can be activated under DNA damaging conditions in mitotically-dividing cells, and activation depends on upstream Mec1 kinase function. We use this system to perform a structure-function analysis of RHM complex formation and Mek1 activation. Finally, we demonstrate that expressing active Mek1 in mitosis leads to rad51Δ-like DNA break sensitivity, suggesting that activation of the RHM complex is sufficient to reconstitute (parts of) its physiological function in mediating HR-based repair. This system should enable querying downstream effects of RHM complex action on DNA repair dynamics and template bias. Human homologs of Red1 and Hop1 are often aberrantly re-expressed in cancer cells. Our system has the potential to inform on (dys)functional effects of these genes on genome stability during human tumorigenesis.

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Mitotic Expression of Spo13 Alters M-Phase Progression and Nucleolar Localization of Cdc14 in Budding Yeast

Cited by 7 publications

References 58 publications

Construction of strains to identify novel factors for regulation of centromeric cohesion protection (CCP) and sister kinetochore mono-orientation (SKM)

Construction of strains to identify novel factors for regulation of centromeric cohesion protection (CCP) and sister kinetochore mono-orientation (SKM)

Spo13 prevents premature cohesin cleavage during meiosis

Studying meiosis in mitosis: Activating the meiosis-specific Red1-Hop1-Mek1 complex in mitotic budding yeast cells

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