Abstract

The long range goals of the proposed research are: 1) to elucidate the molecular mechanisms of DNA double-strand break (DSB) induced recombination between homologous genes in various chromosomal environments, and 2) to investigate the relationships between genetic recombination, transcription, and DNA repair. Recombination processes are involved in a variety of important biological phenomena, such as the regulation of gene expression, antigenic variation, repair of DNA DSBs, chromosomal translocations, and in mammals, antibody gene assembly. There is strong evidence linking genetic recombination to the development of a wide range of cancers in humans. DNA damage, such as that produced by ionizing radiation or chemical agents, stimulates recombination which may result in gene restoration, or produce mutagenic/carcinogenic alterations. Both DNA repair processes and homologous recombination are influenced by transcriptional activity. Although the effects of transcription on these processes are not well understood, they may play important roles in determining the genetic consequences of DNA repair. For example, differential processing of DNA damage in actively transcribed and silent regions of a genome may account for the diverse responses of various cell types, or of cells in different developmental states, to particular DNA damaging agents. The proposed studies will utilize the yeast Saccharomyces cerevisiae HO nuclease to introduce DSBs at defined loci within or near repeated genes and centromere DNA, and in transcriptionally active and silent genes. The fate of DSBs in different chromosomal contexts will be monitored by using four complementary approaches, including measurements of recombination frequencies, genetic and physical analyses of recombinant products, and kinetic analyses of DSB induction and repair. Specific questions to be addressed include the following: 1. How does the relative position of a DSB to duplicated DNA affect the genetic consequences of DSB-repair? 2. What are the lengths and origins of gene conversion tracts induced by DSBs? 3. What are the properties and consequences of DSB-induced recombination near and within centromeres? 4. What effect does transcription have on the formation of heteroduplex DNA, and on the repair of mismatches within heteroduplex DNA? 5. What are the roles of specific DNA-repair gene products in spontaneous and DSB-induced recombination, and in the correction of mismatches in heteroduplex DNA? These studies will clarify the mechanisms and genetic consequences of spontaneous and DSB-induced recombination in a variety of chromosomal environments, further our understanding of the roles of specific DNA repair gene products in these processes, and provide a basis for understanding the relationships between DNA damage repair, transcription, and recombination.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA055302-02
Application #
3199802
Study Section
Radiation Study Section (RAD)
Project Start
1992-07-01
Project End
1995-06-30
Budget Start
1993-07-01
Budget End
1994-06-30
Support Year
2
Fiscal Year
1993
Total Cost
Indirect Cost

  Institution

Name
Harvard University
Department
Type
Schools of Public Health
DUNS #
082359691
City
Boston
State
MA
Country
United States
Zip Code
02115

  Publications

Krishna, Sanchita; Wagener, Brant M; Liu, Hui Ping et al. (2007) Mre11 and Ku regulation of double-strand break repair by gene conversion and break-induced replication. DNA Repair (Amst) 6:797-808
Lo, Yi-Chen; Paffett, Kimberly S; Amit, Or et al. (2006) Sgs1 regulates gene conversion tract lengths and crossovers independently of its helicase activity. Mol Cell Biol 26:4086-94
Lo, Yi-Chen; Kurtz, Richard B; Nickoloff, Jac A (2005) Analysis of chromosome/allele loss in genetically unstable yeast by quantitative real-time PCR. Biotechniques 38:685-6, 688, 690
Paffett, Kimberly S; Clikeman, Jennifer A; Palmer, Sean et al. (2005) Overexpression of Rad51 inhibits double-strand break-induced homologous recombination but does not affect gene conversion tract lengths. DNA Repair (Amst) 4:687-98
Tsukuda, Toyoko; Fleming, Alastair B; Nickoloff, Jac A et al. (2005) Chromatin remodelling at a DNA double-strand break site in Saccharomyces cerevisiae. Nature 438:379-83
Palmer, Sean; Schildkraut, Ezra; Lazarin, Raquel et al. (2003) Gene conversion tracts in Saccharomyces cerevisiae can be extremely short and highly directional. Nucleic Acids Res 31:1164-73
Kim, Perry M; Paffett, Kimberly S; Solinger, Jachen A et al. (2002) Spontaneous and double-strand break-induced recombination, and gene conversion tract lengths, are differentially affected by overexpression of wild-type or ATPase-defective yeast Rad54. Nucleic Acids Res 30:2727-35
Clikeman, J A; Khalsa, G J; Barton, S L et al. (2001) Homologous recombinational repair of double-strand breaks in yeast is enhanced by MAT heterozygosity through yKU-dependent and -independent mechanisms. Genetics 157:579-89
Weng, Y; Barton, S L; Cho, J W et al. (2001) Marker structure and recombination substrate environment influence conversion preference of broken and unbroken alleles in Saccharomyces cerevisiae. Mol Genet Genomics 265:461-8
Clikeman, J A; Wheeler, S L; Nickoloff, J A (2001) Efficient incorporation of large (>2 kb) heterologies into heteroduplex DNA: Pms1/Msh2-dependent and -independent large loop mismatch repair in Saccharomyces cerevisiae. Genetics 157:1481-91

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