Characterization of template switching and recombination during Moloney murine leukemia virus replication

Retroviruses uniquely co-package two copies of their genomic RNA within each virion. The two copies are used as templates for synthesis of the proviral DNA during the process of reverse transcription. Two template switches are required to complete retroviral DNA synthesis by the retroviral enzyme, reverse transcriptase. With two RNA genomes present in the virion, reverse transcriptase can make template switches utilizing only one of the RNA templates (intramolecular) or utilizing both RNA templates (intermolecular) during the process of reverse transcription. The results presented in this study show that during a single cycle of Moloney murine leukemia virus replication, both nonrecombinant and recombinant proviruses predominantly underwent intramolecular minus- and plus-strand transfers during the process of reverse transcription. This is the first study to examine the nature of the required template switches occurring during MLV replication and these results support the previous findings for SNV, and the hypothesis that the required template switches are ordered events. This study also determined rates for deletion and a rate of recombination for a single cycle of MLV replication. The rates reported here are comparable to the rates previously reported for both SNV and MLV. ^

A systematic analysis of INO80 in DNA replication

ATP-dependent chromatin remodeling has been shown to be critical for transcription and DNA repair. However, the involvement of ATP-dependent chromatin remodeling in DNA replication remains poorly defined. Interestingly, we found that the INO80 chromatin-remodeling complex is directly involved in the DNA damage tolerance pathways activated during DNA replication. DNA damage tolerance is important for genomic stability and is controlled by formation of either mono-ubiquitinated or multi-ubiquitinated PCNA, which respectively induce error prone or error-free replication bypass of the lesions. In addition, homologous recombination (HR) mediated by the Rad51 pathway is also involved in the DNA damage tolerance pathways. ^ We found that INO80 is specifically recruited to replication origins during S phase in a genome-wide fashion. In addition, DNA combing analysis shows INO80 is required for the resumption of replication at stalled forks induced by methyl methane-sulfonate (MMS). Mechanistically, we find that INO80 is required for PCNA ubiquitination as well as for Rad51 mediated processing of replication forks after MMS treatment. Furthermore, chromatin immunoprecipitation at specific ARSs indicates INO80 is necessary for Rad18 and Rad51 recruitment to replication forks after MMS treatment. Moreover, 2D gel analysis shows INO80 is necessary to process Rad51 mediated intermediates at impeded replication forks. ^ In conclusion, our findings establish a novel role of a chromatin-remodeling complex in DNA damage tolerance pathways and suggest that chromatin remodeling is fundamentally important to ensure faithful replication of DNA and genome stability in eukaryotes. ^

Analysis of the mechanism of replication inhibition of the tumor suppressor gene p53

p53 plays a role in cell cycle arrest and apoptosis. p53 has also been shown to be involved in DNA replication. To study the effect of p53 on DNA replication, we utilized a SV40 based shuttle vector system. The pZ402 shuttle vector, was constructed with a mutated T-antigen unable to interact with p53 but able to support replication of the shuttle vector. When a transcriptional activation domain p53 mutant was tested for its ability to inhibit DNA replication no inhibition was observed. Competition assays with the DNA binding domain of p53 was also able to block the inhibition of DNA replication by p53 suggesting that p53 can inhibit DNA replication through the transcriptional activation of a target gene. One likely target gene, p21$\sp{\rm cip/waf}$ was tested to determine whether p53 inhibited DNA replication by transcriptionally activating p21$\sp{\rm cip/waf}$. Two independent approaches utilizing p21$\sp{\rm cip/waf}$ null cells or the expression of an anti-sense p21$\sp{\rm cip/waf}$ expression vector were utilized. p53 was able to inhibit pZ402 replication independently of p21$\sp{\rm cip/waf}$. p53 was also able to inhibit DNA replication independent of the p53 target genes Gadd45 and the replication processivity factor PCNA. The inhibition of DNA replication by p53 was also independent of direct DNA binding to a consensus site on the replicating plasmid. p53 mutants can be classified into two categories: conformational and DNA contact mutants. The two types of p53 mutants were tested for their effects on DNA replication. While all conformational mutants were unable to inhibit DNA replication three out of three DNA contact mutants tested were able to inhibit DNA replication. The work here studies the effect wild-type and mutant p53 has on DNA replication and demonstrated a possible mechanism by which wild-type p53 could inhibit DNA replication through the transcriptional activation of a target gene. ^