Distinct roles for Rev1p and Rev7p during translesion synthesis in Saccharomyces cerevisiae.

Translesion synthesis (TLS) in Saccharomyces cerevisiae requires at least Rev1p and polymerase zeta (Pol zeta), a complex of the Rev3 polymerase and its accessory factor Rev7p. Although their precise role(s) are poorly characterized, in vitro studies suggest that each protein contributes to TLS in a manner dependent on the particular lesion and surrounding DNA sequence. In the present study, strand segregation analysis is used to attempt to identify the role(s) of the Rev1 and Rev7 proteins during TLS. This assay uses double-stranded plasmids containing a genetic marker opposite to a replication blocking lesion (N-2-acetylaminofluorene; AAF) to measure TLS quantitatively and qualitatively in vivo. The AAF adduct is localized within a repetitive sequence in a manner that allows the formation of misaligned primer-template replication intermediates. Elongation from a misaligned intermediate fixes a frameshift mutation (slipped TLS), while extension of the correctly aligned lesion terminus yields error-free (non-slipped) TLS. The results indicate that there is a strong requirement for Rev7p during Pol zeta-mediated TLS measured in vivo. Furthermore, Rev1p is needed only for non-slipped TLS; slipped TLS remains efficient in its absence, revealing a previously uncharacterized Rev1p activity similar to Escherichia coli UmuDC function. Specifically, this activity is required for elongation from a correctly aligned lesion terminus.

Analysis of damage tolerance pathways in Saccharomyces cerevisiae: a requirement for Rev3 DNA polymerase in translesion synthesis.

The replication of double-stranded plasmids containing a single N-2-acetylaminofluorene (AAF) adduct located in a short, heteroduplex sequence was analyzed in Saccharomyces cerevisiae. The strains used were proficient or deficient for the activity of DNA polymerase zeta (REV3 and rev3delta, respectively) in a mismatch and nucleotide excision repair-defective background (msh2delta rad10delta). The plasmid design enabled the determination of the frequency with which translesion synthesis (TLS) and mechanisms avoiding the adduct by using the undamaged, complementary strand (damage avoidance mechanisms) are invoked to complete replication. To this end, a hybridization technique was implemented to probe plasmid DNA isolated from individual yeast transformants by using short, 32P-end-labeled oligonucleotides specific to each strand of the heteroduplex. In both the REV3 and rev3delta strains, the two strands of an unmodified heteroduplex plasmid were replicated in approximately 80% of the transformants, with the remaining 20% having possibly undergone prereplicative MSH2-independent mismatch repair. However, in the presence of the AAF adduct, TLS occurred in only 8% of the REV3 transformants, among which 97% was mostly error free and only 3% resulted in a mutation. All TLS observed in the REV3 strain was abolished in the rev3delta mutant, providing for the first time in vivo biochemical evidence of a requirement for the Rev3 protein in TLS.

Comparative analysis of the cya locus in enterobacteria and related gram-negative facultative anaerobes.

Comparison of the cya loci (cya codes for adenylyl cyclase (AC)) from a variety of phylogenetically divergent facultative anaerobic Gram-negative bacteria reveals conserved sequence features. The entire locus structure in enterobacteria is preserved, including two major promoters (a conserved cya strong promoter, P2, and a divergent promoter for a heme biosynthetic operon, hemCD) present in the upstream region of the cya gene. The region between hemC and cya is much longer in Proteus mirabilis than in other enterobacteria, and lacks the P1 upstream cya promoter. In Aeromonas hydrophila the cya promoter (the strong P2 promoter in E coli) is preserved, including a putative GATC methylation site situated immediately downstream from the -10 box. Each cya frame analyzed uses TTG as the translation start codon and is preceded by an unusual ribosome binding site. This suggests that a lower translation efficiency of the cya transcript could be the result of some selection pressure. This has been substantiated by in vitro mutagenesis and by selection of up mutations which all map at the cya ribosome binding site. In enterobacteria the cyaY frame is the only conserved reading frame downstream of cya, with the orientation opposite to that of cya. This organization is not preserved in Aeromonas. Experiments involving fusions with the lacZ gene demonstrated that cyaY is expressed. Finally, comparison of the different polypeptide sequences of ACs permits discussion of important features of the catalytic and regulatory centers of the protein.