The Mre11-Rad50-Nbs1 (MRN) complex has many biological functions: processing of double-strand breaks in meiosis, homologous recombination, telomere maintenance, S-phase checkpoint, and genome stability during replication. In the S-phase DNA damage checkpoint, MRN acts both in activation of checkpoint signaling and downstream of the checkpoint kinases to slow DNA replication. Mechanistically, MRN, along with its cofactor Ctp1, is involved in 5' resection to create single-stranded DNA that is required for both signaling and homologous recombination. However, it is unclear whether resection is essential for all of the cellular functions of MRN. To dissect the various roles of MRN, we performed a structure-function analysis of nuclease dead alleles and potential separation-of-function alleles analogous to those found in the human disease ataxia telangiectasia-like disorder, which is caused by mutations in Mre11. We find that several alleles of rad32 (the fission yeast homologue of mre11), along with ctp1Delta, are defective in double-strand break repair and most other functions of the complex, but they maintain an intact S phase DNA damage checkpoint. Thus, the MRN S-phase checkpoint role is separate from its Ctp1- and resection-dependent role in double-strand break repair. This observation leads us to conclude that other functions of MRN, possibly its role in replication fork metabolism, are required for S-phase DNA damage checkpoint function.

The main focus of my work has been the role of the MRN in the S-phase DNA damage checkpoint. The MRN plays many roles in cellular metabolism; some are checkpoint dependent and some are checkpoint independent. The multiple roles in cellular metabolism complicate study of the role of the MRN in the checkpoint. MRN mutations in budding yeast and mammals may display separation of function. Mechanistically, MRN, along with its cofactor Ctp1, is involved in 5’ resection to create single stranded DNA that is required for both signaling and homologous recombination. However, it is unclear if resection is essential for all of the cellular functions of MRN. Therefore I have made mutations to mimic those in budding yeast and mammals. I found that several alleles of rad32, as well as ctp1Δ, are defective in double-strand break repair and most other functions of the complex but maintain an intact S-phase DNA damage checkpoint. Thus, the MRN S-phase checkpoint role is separate from its Ctp1- and resection-dependent role in double-strand break repair. This observation leads me to conclude that other functions of MRN, possibly its role in replication fork metabolism, are required for S-phase DNA damage checkpoint function. One of the potential roles of Rad32 and the rest of the MRN complex is in sister chromatid exchange. The genetic requirements of sister chromatid exchange have been examined using unequal sister chromatid assays which only are able to assay exchanges that are illegitimate and produce changes in the genome. Most sister chromatid exchange must be equal to maintain genomic integrity and thus far there is no good assay for equal sister chromatid exchange. Yeast cells expressing the human equilibrative nucleoside transporter 1 (hENT1) and the herpes simplex virus thymidine kinase (tk) are able to incorporate exogenous thymidine into their DNA. This strain makes it possible for the fission yeast DNA to be labeled with halogenated thymidine analogs. This strain is being used to design an assay that will label one sister with BrdU and then DNA combing will be used to see equal sister chromatid exchange.

In vivo labeling of DNA with thymidine and thymidine analogs has long been a cornerstone of replication studies. Unfortunately, yeast lack a thymidine salvage pathway and thus do not incorporate exogenous thymidine. Specifically, yeast neither efficiently take up exogenous thymidine from their growth media nor phosphorylate it to thymidylate, the precursor of dTTP. We have overcome these problems in fission yeast by expressing the human equilibrative nucleoside transporter 1 (hENT1) along with herpes simplex virus thymidine kinase (tk). hENT1 tk cells are healthy and efficiently incorporate exogenous thymidine and thymidine analogs. We present protocols for labeling DNA with tritiated thymidine, for in situ detection of incorporated BrdU by immunofluorescence, for double labeling with CldU and IdU, for CsCl gradient separation of IdU-labeled DNA, and for using hENT1 and tk as both positive and negative selection markers.