Dissection of the Functions of the Saccharomyces cerevisiae RAD6 Postreplicative Repair Group in Mutagenesis and UV Sensitivity

The RAD6 postreplicative repair group participates in various processes of DNA metabolism. To elucidate the contribution of RAD6 to starvation-associated mutagenesis, which occurs in nongrowing cells cultivated under selective conditions, we analyzed the phenotype of strains expressing various alleles of the RAD6 gene and single and multiple mutants of the RAD6, RAD5, RAD18, REV3, and MMS2 genes from the RAD6 repair group. Our results show that the RAD6 repair pathway is also active in starving cells and its contribution to starvation-associated mutagenesis is similar to that of spontaneous mutagenesis. Epistatic analysis based on both spontaneous and starvation-associated mutagenesis and UV sensitivity showed that the RAD6 repair group consists of distinct repair pathways of different relative importance requiring, besides the presence of Rad6, also either Rad18 or Rad5 or both. We postulate the existence of four pathways: (1) nonmutagenic Rad5/Rad6/Rad18, (2) mutagenic Rad5/Rad6 /Rev3, (3) mutagenic Rad6/Rad18/Rev3, and (4) Rad6/Rad18/Rad30. Furthermore, we show that the high mutation rate observed in rad6 mutants is caused by a mutator different from Rev3. From our data and data previously published, we suggest a role for Rad6 in DNA repair and mutagenesis and propose a model for the RAD6 postreplicative repair group.

Domains required for dimerization of yeast Rad6 ubiquitin-conjugating enzyme and Rad18 DNA binding protein.

The RAD6 gene of Saccharomyces cerevisiae encodes a ubiquitin-conjugating enzyme required for postreplicational repair of UV-damaged DNA and for damage-induced mutagenesis. In addition, Rad6 functions in the N end rule pathway of protein degradation. Rad6 mediates its DNA repair role via its association with Rad18, whose DNA binding activity may target the Rad6-Rad18 complex to damaged sites in DNA. In its role in N end-dependent protein degradation, Rad6 interacts with the UBR1-encoded ubiquitin protein ligase (E3) enzyme. Previous studies have indicated the involvement of N-terminal and C-terminal regions of Rad6 in interactions with Ubr1. Here, we identify the regions of Rad6 and Rad18 that are involved in the dimerization of these two proteins. We show that a region of 40 amino acids towards the C terminus of Rad18 (residues 371 to 410) is sufficient for interaction with Rad6. This region of Rad18 contains a number of nonpolar residues that have been conserved in helix-loop-helix motifs of other proteins. Our studies indicate the requirement for residues 141 to 149 at the C terminus, and suggest the involvement of residues 10 to 22 at the N terminus of Rad6, in the interaction with Rad18. Each of these regions of Rad6 is indicated to form an amphipathic helix.

A ubiquitin mutant with specific defects in DNA repair and multiubiquitination.

The degradation of many proteins involves the sequential ligation of ubiquitin molecules to the substrate to form a multiubiquitin chain linked through Lys-48 of ubiquitin. To test for the existence of alternate forms of multiubiquitin chains, we examined the effects of individually substituting each of six other Lys residues in ubiquitin with Arg. Substitution of Lys-63 resulted in the disappearance of a family of abundant multiubiquitin-protein conjugates. The UbK63R mutants were not generally impaired in ubiquitination, because they grew at a wild-type rate, were fully proficient in the turnover of a variety of short-lived proteins, and exhibited normal levels of many ubiquitin-protein conjugates. The UbK63R mutation also conferred sensitivity to the DNA-damaging agents methyl methanesulfonate and UV as well as a deficiency in DNA damage-induced mutagenesis. Induced mutagenesis is mediated by a repair pathway that requires Rad6 (Ubc2), a ubiquitin-conjugating enzyme. Thus, the UbK63R mutant appears to be deficient in the Rad6 pathway of DNA repair. However, the UbK63R mutation behaves as a partial suppressor of a rad6 deletion mutation, indicating that an effect of UbK63R on repair can be manifest in the absence of the Rad6 gene product. The UbK63R mutation may therefore define a new role of ubiquitin in DNA repair. The results of this study suggest that Lys-63 is used as a linkage site in the formation of novel multiubiquitin chain structures that play an important role in DNA repair.

Elimination of the yeast RAD6 ubiquitin conjugase enhances base-pair transitions and G.C----T.A transversions as well as transposition of the Ty element: implications for the control of spontaneous mutation.

The RAD6 gene of the yeast Saccharomyces cerevisiae encodes an enzyme that conjugates ubiquitin to other proteins. Defects in RAD6 confer a mutator phenotype due, in part, to an increased rate of transposition of the yeast Ty element. To further delineate the role of protein ubiquitination in the control of spontaneous mutagenesis in yeast, we have characterized 202 mutations that arose spontaneously in the SUP4-o gene carried on a centromere vector in a RAD6 deletion strain. The resulting mutational spectrum was compared to that for 354 spontaneous SUP4-o mutations isolated in the isogenic wild-type parent. This comparison revealed that the rad6 mutator enhanced the rate of single base-pair substitution, as well as Ty insertion, but did not affect the rates of the other mutational classes detected. Relative to the wild-type parent, Ty inserted at considerably more SUP4-o positions in the rad6 strain with a significantly smaller fraction detected at a transposition hotspot. These findings suggest that, in addition to the rate of transposition, protein ubiquitination might influence the target site specificity of Ty insertion. The increase in the substitution rate accounted for approximately 90% of the rad6 mutator effect but only the two transitions and the G. C----T.A transversion were enhanced. Analysis of the distribution of these events within SUP4-o suggested that the site specificity of the substitutions was influenced by DNA sequence context. Transformation of heteroduplex plasmid DNAs into the two strains demonstrated that the rad6 mutator did not reduce the efficiency of correcting mismatches that could give rise to the transitions or transversion nor did it bias restoration of the mismatches to the incorrect base-pairs. These results are discussed in relation to possible mechanisms that might link ubiquitination of proteins to spontaneous mutation rates.