Synaptonemal complex disassembly activates Rad51-mediated double strand break repair during budding yeast meiosis

<p> Meiosis is a highly conserved specialized cell division that occurs in many organisms, including budding yeast and mammals. Meiosis divides the chromosome number of the cell in half to create gametes for sexual reproduction. A single round of chromosome duplication is followed by two rou...

Full description

Bibliographic Details
Main Author: Prugar, Evelyn
Language:EN
Published: State University of New York at Stony Brook 2016
Subjects:
Online Access:http://pqdtopen.proquest.com/#viewpdf?dispub=10170526
id ndltd-PROQUEST-oai-pqdtoai.proquest.com-10170526
record_format oai_dc
collection NDLTD
language EN
sources NDLTD
topic Molecular biology|Genetics|Cellular biology
spellingShingle Molecular biology|Genetics|Cellular biology
Prugar, Evelyn
Synaptonemal complex disassembly activates Rad51-mediated double strand break repair during budding yeast meiosis
description <p> Meiosis is a highly conserved specialized cell division that occurs in many organisms, including budding yeast and mammals. Meiosis divides the chromosome number of the cell in half to create gametes for sexual reproduction. A single round of chromosome duplication is followed by two rounds of chromosome segregation, Meiosis I (homologs segregate) and Meiosis II (sister chromatids segregate). Proper segregation at Meiosis I requires that homologs are connected by both crossovers and sister chromatid cohesion. Crossovers are formed by the repair of double strand breaks (DSBs) preferentially by the homolog. The choice of repair template is determined at the time of strand invasion, which is mediated by two recombinases, Rad51 and the meiosis-specific Dmc1. Rad51 is necessary for Dmc1 to function properly but its strand exchange activity is inhibited both by Dmc1 and Mek1, a meiosis-specific kinase, which is activated by DSBs. Mek1 suppresses interaction between Rad51 and its accessory factor Rad54 in two ways. First, phosphorylation of Rad54 lowers its affinity for Rad51. Second, phosphorylation stabilizes Hed1, a meiosis-specific protein that binds to Rad51 and excludes Rad54. Although <i>RAD54</i> is not required for wild-type levels of interhomolog recombination, <i> rad54</i>&Delta; diploids exhibit decreased sporulation and spore viability, indicating the presence of unrepaired DSBs. My thesis tested the idea that Mek1 kinase activity is down-regulated after interhomolog recombination to allow Rad51-mediated repair of any remaining DSBs. </p><p> Meiotic recombination occurs in the context of a proteinaecous structure called the synaptonemal complex (SC). The SC is formed when sister chromatids condense along protein cores called axial elements (AEs) comprised of the meiosis-specific proteins, Hop1, Red1 and Rec8. AEs are brought together by interhomolog recombination, which creates stable connections and the gluing together of the AEs by the insertion of the transverse filament protein, Zip1, in a process called synapsis. Pachynema is the stage of meiotic prophase in which chromosomes are fully synapsed and where interhomolog recombination has proceeded to the double Holliday junction (dHJ) stage. </p><p> Meiotic progression requires transcription factor <i>NDT80</i>, a middle meiosis transcription factor required to express >200 genes, including the polo-like kinase, CDC5 (required for Holliday junction resolution and SC disassembly) and <i>CLB1</i> (required for meiotic progression). Diploids deleted for <i>NDT80</i> arrest in pachynema with unresolved dHJs. I used an inducible version of <i>NDT80</i> (<i>NDT80-IN </i>) to separate prophase into two phases: pre-<i>NDT80</i>, when interhomolog recombination occurs and post-<i>NDT80</i>, when it is proposed that inactivation of Mek1 allows intersister recombination to repair residual DSBs. <i>RAD54</i> is sufficient to function after interhomolog recombination, as inducing both <i>RAD54</i> and <i>NDT80</i> simultaneously rescues the spore inviability defects observed in <i>NDT80-IN rad54&Delta;</i> diploids. Using an antibody specific for phosphorylated Hed1 as an indicator of Mek1 kinase activity, I showed that Mek1 is constitutively active in <i>ndt80</i>-arrested cells and that induction of <i>NDT80</i> is sufficient to abolish Mek1 activity. Furthermore, inactivation of Mek1 by Ndt80 can occur in the absence of interhomolog strand invasion and synapsis. Mek1 inactivation correlates with the appearance of <i>CDC5</i> and the degradation of Red1. My work demonstrates that the sole target of <i>NDT80</i> responsible for inactivating Mek1 is <i>CDC5</i>. </p><p> Unrepaired DSBs trigger the meiotic recombination checkpoint resulting in prophase arrest, which requires Mek1 and works by sequestering Ndt80 in the cytoplasm. Mek1 also delays meiotic progression in wild-type cells, likely through inactivation of Ndt80. My work shows that Ndt80 in turn negatively regulates Mek1. Based on my observations, as well as published work showing that synapsis results in the removal of Mek1 from chromosomes, I propose that recombination and meiotic progression are coordinated by regulation of Mek1. </p>
author Prugar, Evelyn
author_facet Prugar, Evelyn
author_sort Prugar, Evelyn
title Synaptonemal complex disassembly activates Rad51-mediated double strand break repair during budding yeast meiosis
title_short Synaptonemal complex disassembly activates Rad51-mediated double strand break repair during budding yeast meiosis
title_full Synaptonemal complex disassembly activates Rad51-mediated double strand break repair during budding yeast meiosis
title_fullStr Synaptonemal complex disassembly activates Rad51-mediated double strand break repair during budding yeast meiosis
title_full_unstemmed Synaptonemal complex disassembly activates Rad51-mediated double strand break repair during budding yeast meiosis
title_sort synaptonemal complex disassembly activates rad51-mediated double strand break repair during budding yeast meiosis
publisher State University of New York at Stony Brook
publishDate 2016
url http://pqdtopen.proquest.com/#viewpdf?dispub=10170526
work_keys_str_mv AT prugarevelyn synaptonemalcomplexdisassemblyactivatesrad51mediateddoublestrandbreakrepairduringbuddingyeastmeiosis
_version_ 1718390807035117568
spelling ndltd-PROQUEST-oai-pqdtoai.proquest.com-101705262016-11-03T16:01:32Z Synaptonemal complex disassembly activates Rad51-mediated double strand break repair during budding yeast meiosis Prugar, Evelyn Molecular biology|Genetics|Cellular biology <p> Meiosis is a highly conserved specialized cell division that occurs in many organisms, including budding yeast and mammals. Meiosis divides the chromosome number of the cell in half to create gametes for sexual reproduction. A single round of chromosome duplication is followed by two rounds of chromosome segregation, Meiosis I (homologs segregate) and Meiosis II (sister chromatids segregate). Proper segregation at Meiosis I requires that homologs are connected by both crossovers and sister chromatid cohesion. Crossovers are formed by the repair of double strand breaks (DSBs) preferentially by the homolog. The choice of repair template is determined at the time of strand invasion, which is mediated by two recombinases, Rad51 and the meiosis-specific Dmc1. Rad51 is necessary for Dmc1 to function properly but its strand exchange activity is inhibited both by Dmc1 and Mek1, a meiosis-specific kinase, which is activated by DSBs. Mek1 suppresses interaction between Rad51 and its accessory factor Rad54 in two ways. First, phosphorylation of Rad54 lowers its affinity for Rad51. Second, phosphorylation stabilizes Hed1, a meiosis-specific protein that binds to Rad51 and excludes Rad54. Although <i>RAD54</i> is not required for wild-type levels of interhomolog recombination, <i> rad54</i>&Delta; diploids exhibit decreased sporulation and spore viability, indicating the presence of unrepaired DSBs. My thesis tested the idea that Mek1 kinase activity is down-regulated after interhomolog recombination to allow Rad51-mediated repair of any remaining DSBs. </p><p> Meiotic recombination occurs in the context of a proteinaecous structure called the synaptonemal complex (SC). The SC is formed when sister chromatids condense along protein cores called axial elements (AEs) comprised of the meiosis-specific proteins, Hop1, Red1 and Rec8. AEs are brought together by interhomolog recombination, which creates stable connections and the gluing together of the AEs by the insertion of the transverse filament protein, Zip1, in a process called synapsis. Pachynema is the stage of meiotic prophase in which chromosomes are fully synapsed and where interhomolog recombination has proceeded to the double Holliday junction (dHJ) stage. </p><p> Meiotic progression requires transcription factor <i>NDT80</i>, a middle meiosis transcription factor required to express >200 genes, including the polo-like kinase, CDC5 (required for Holliday junction resolution and SC disassembly) and <i>CLB1</i> (required for meiotic progression). Diploids deleted for <i>NDT80</i> arrest in pachynema with unresolved dHJs. I used an inducible version of <i>NDT80</i> (<i>NDT80-IN </i>) to separate prophase into two phases: pre-<i>NDT80</i>, when interhomolog recombination occurs and post-<i>NDT80</i>, when it is proposed that inactivation of Mek1 allows intersister recombination to repair residual DSBs. <i>RAD54</i> is sufficient to function after interhomolog recombination, as inducing both <i>RAD54</i> and <i>NDT80</i> simultaneously rescues the spore inviability defects observed in <i>NDT80-IN rad54&Delta;</i> diploids. Using an antibody specific for phosphorylated Hed1 as an indicator of Mek1 kinase activity, I showed that Mek1 is constitutively active in <i>ndt80</i>-arrested cells and that induction of <i>NDT80</i> is sufficient to abolish Mek1 activity. Furthermore, inactivation of Mek1 by Ndt80 can occur in the absence of interhomolog strand invasion and synapsis. Mek1 inactivation correlates with the appearance of <i>CDC5</i> and the degradation of Red1. My work demonstrates that the sole target of <i>NDT80</i> responsible for inactivating Mek1 is <i>CDC5</i>. </p><p> Unrepaired DSBs trigger the meiotic recombination checkpoint resulting in prophase arrest, which requires Mek1 and works by sequestering Ndt80 in the cytoplasm. Mek1 also delays meiotic progression in wild-type cells, likely through inactivation of Ndt80. My work shows that Ndt80 in turn negatively regulates Mek1. Based on my observations, as well as published work showing that synapsis results in the removal of Mek1 from chromosomes, I propose that recombination and meiotic progression are coordinated by regulation of Mek1. </p> State University of New York at Stony Brook 2016-10-28 00:00:00.0 thesis http://pqdtopen.proquest.com/#viewpdf?dispub=10170526 EN