David C. Hinkle

The Y-Family of DNA Polymerases

We would like to thank Tomoo Ogi for generating the unrooted phylogenetic tree shown in Figure 1Figure 1 and Junetsu Ito for his comments on our proposal.

Evidence for a second function for Saccharomyces cerevisiae Rev1p.

The function of the Saccharomyces cerevisiae REV1 gene is required for translesion replication and mutagenesis induced by a wide variety of DNA‐damaging agents. We showed previously that Rev1p possesses a deoxycytidyl transferase activity, which incorporates dCMP opposite abasic sites in the DNA template, and that dCMP insertion is the major event during bypass of an abasic site in vivo. However, we now find that Rev1p function is needed for the bypass of a T–T (6–4) UV photoproduct, a process in which dCMP incorporation occurs only very rarely, indicating that Rev1p possesses a second function. In addition, we find that Rev1p function is, as expected, required for bypass of an abasic site. However, replication past this lesion was also much reduced in the G‐193R rev1‐1 mutant, which we find retains substantial levels of deoxycytidyl transferase activity. This mutant is, therefore, presumably deficient principally in the second, at present poorly defined, function. The bypass of an abasic site and T–T (6–4) lesion also depended on REV3 function, but neither it nor REV1 was required for replication past the T–T dimer; bypass of this lesion presumably depends on another enzyme.

The REV3 gene of Saccharomyces cerevisiae is transcriptionally regulated more like a repair gene than one encoding a DNA polymerase

SummaryWe measured the relative steady-state levels of the mRNA transcribed from the Saccharomyces cerevisiae REV3 gene in cells at different stages of the mitotic and meiotic cycles, and after UV irradiation. This gene is thought to encode a DNA polymerase concerned only with a specific recovery function, the replication on mutagen-damaged templates that produces damaged-induced mutations. In keeping with this proposed function, the REV3 gene showed no evidence of the periodic transcription at the G1/S boundary of the mitotic and meiotic cycle that occurs with genes encoding replication enzymes. However, levels of REV3 mRNA were much increased in late meiotic cells, like those of transcripts of some other DNA repair-related genes. Steady-state levels of REV3 transcript were increased only slightly in response to UV irradiation.

Decreased UV mutagenesis in cdc8, a DNA replication mutant of Saccharomyces cerevisiae

SummaryA DNA replication mutant of yeast, cdc8, was found to decrease UV-induced reversion of lys2-1, arg4-17, tyr1 and ura1. This effect was observed with all three alleles of cdc8 tested. Survival curves obtained following UV irradiation in cdc8 rad double mutants show that cdc8 is epistatic to rad6, as well as to rad1; cdc8 rad51 double mutants seem to be more sensitive than the single mutants. Since UV-induced reversion in cdc8 rad1 and cdc8 rad51 double mutants is like that of the cdc8 single mutants, we conclude that CDC8 plays a direct role in error-prone repair. To test whether CDC8 codes for a DNA polymerase, we have purified both DNA polymerase I and DNA polymerase II from cdc8 and CDC+ cells. The purified DNA polymerases from cdc8 were no more heat labile than those from CDC+, suggesting that CDC8 is not a structural gene for either enzyme.

Benzo[a]pyrene diol epoxide–deoxyguanosine adducts are accurately bypassed by yeast DNA polymerase ζ in vitro

The possible role of bypass DNA polymerase zeta in mutagenic translesion synthesis past benzo[a]pyrene (BP) 7,8-diol-9,10-epoxide (DE) N(2)-deoxyguanosine (dG) adducts has been examined. We prepared 59-mer DNA templates containing dG adducts derived from trans opening of enantiomers of BP DE-2, in which the 7-hydroxyl group and epoxide oxygen are trans. The 10S-BP DE-dG and 10R-BP DE-dG adducts derive from the (+)- and (-)-DE-2 enantiomers, respectively. The adducted dG is located at a site identified as a G-->T mutational hotspot in random mutagenesis studies of (+)-BP DE-2 in Chinese hamster V-79 cells. Yeast pol zeta (complex of Gst-Rev3p and Rev7p) formed extension products (total of all lengths) of 71, 74 and 88% of a primer annealed to the 10S-BP DE-dG, 10R-BP DE-dG and non-adducted 59-mer templates, respectively. However, only 18 and 19% of the primer was extended to the full-length product on 10S-BP DE-dG and 10R-BP DE-dG adducted templates compared to 55% of the primer on the non-adducted template. A major 34-mer product corresponding to primer elongation up to and including the base before the adduct indicated that nucleotide incorporation opposite both adducts was strongly blocked. Full-length products were isolated from gels and subjected to PCR amplification and cloning. Sequence analysis of more than 300 clones of these full-length products on each template showed that only the correct dCMP was incorporated opposite both the adducted and non-adducted G-hotspot in the template. This corresponds to a probability of mutation lower than 0.3%, the limit of detection, and demonstrates the remarkable fidelity of yeast pol zeta in translesion synthesis past these BP DB-dG lesions in vitro.

Bacteriophage T7 DNA Packaging: II. Analysis of the DNA sequences required for packaging using a plasmid transduction assay*

Recombinant plasmids carrying a bacteriophage T7 origin of DNA replication and sequences from the T7 concatemer junction are efficiently packaged into transducing particles during phage infection. With some constructs, as many as 50 transducing particles are produced per infected cell. We have used this plasmid packaging system to determine which T7 DNA sequences are required for the processing and packaging of the plasmid concatemers and to investigate the effects of altering the spacing and orientation of the required sequences. An origin of T7 DNA replication is essential for high-efficiency transduction, presumably to form the plasmid concatemers that are the substrates of the packaging reaction. In addition, two short sequences from the concatemer junction are required, one flanking the site where the right end of T7 DNA is formed (pacR) and the other flanking the site for formation of the left end (pacL). The spacing between pacR and pacL is not important, but the sequences must be positioned in the same orientation on the plasmid. With certain deletions of pacL, the specificity of end formation is reduced but the efficiency of packaging is near normal. Plasmids that contain only one of the two pac sites are packaged at about 10% of the efficiency of those with both sites. The residual packaging of these plasmids results from regeneration of the other packaging site by recombination with T7 phage DNA. To function in plasmid packaging, the sequences from the concatemer junction must be positioned on the plasmid in the same orientation relative to the T7 replication origin as is found in T7 DNA. This apparently results from a requirement for transcription through these sequences in the rightward direction from the T7 promoter that is associated with the replication origin. Such transcription from another T7 promoter (phi 10), that is not itself a replication origin, allows packaging when the origin is in the opposite orientation.

Genetic analysis of two bacterial RNA polymerase mutants that inhibit the growth of bacteriophage T7

SummaryThe Escherichia coli mutants 7009 and BR3 are defective in the growth of bacteriophage T7. We have previously shown that both of these mutant hosts produce an altered RNA polymerase which is resistant to inhibition by the T7 gene 2 protein (De Wyngaert and Hinkle 1979). In both strains, the mutation which prevents T7 growth is closely linked to rifA (rpoB). Both mutants are complemented by transformation with a multicopy plasmid carrying rpoB and rpoC but not by a plasmid carrying only rpoB. This indicates that the mutations reside in rpoC, the structural gene for the β′ subunit of RNA polymerase. When a single copy of the wildtype rpoC allele is introduced into the mutant using the transducing phage λdrifd18, the mutant allele is dominant over wildtype. The λdrifd18 transductant also remains unable to support the growth of T7 in the presence of rifampin. This supports our conclusion that the mutation is in rpoC. We have measured the growth of T7 phage, the kinetics of phage DNA synthesis, and the structure of replicative DNA intermediates in several transductants, and compared these results with those obtained in the original mutant strains.