Warren E. Masker

The effect of mutations in the uvrD cistron of Escherichia coli on repair resynthesis.

The resynthesis step of the excision repair pathway has been examined in Escherichia coli K12 strains isogenic except for mutations in the uvrD cistron. Strains mutant at the uvrD3, uvrD101, uvrE156, and recL152 loci exhibited slight but distinct differences in their response to ultraviolet radiation. The repair capacity of the uvrD101 mutant was given special attention. Repair resynthesis in this mutant was saturated at fluences greater than about 20 J/m2. Isopycnic analysis of repaired deoxyribonucleic acid from this strain revealed a two-fold increase over its wild-type counterpart in the amount of repair replication performed after a dose of 15 J/m2. Sedimentation velocity analysis of DNA after selective photolysis of bromouracil-containing repaired regions showed that the uvrD101 mutation exerted its primary effect on the long-patch component of excision repair. The uvrD101 mutant performed long-patch repair at a larger number of sites than the number repaired by this mode in the wild-type strain; these patches were more extensive in length than the long-patch component in wild-type.

Survival and mutagenesis of bacteriophage T7 damaged by methyl methanesulfonate and ethyl methanesulfonate

We have examined survival and mutagenesis of bacteriophage T7 after exposure to the alkylating agents methyl methanesulfonate (MMS) and ethyl methanesulfonate (EMS). It was found that although both alkylating agents caused increased reversion of specific T7 mutations, EMS caused a higher frequency of reversion than did MMS. Exposure of the host cells to ultraviolet light so as to induce the SOS system resulted in increased survival (Weigle reactivation) of T7 phage damaged with either EMS or MMS. However, after SOS induction of the host we did not detect an accompanying increase in mutation frequency measured as either reversion of specific T7 mutants or by generation of mutations in the T7 gene that codes for phage ligase. Neither mutation frequency nor survival of alkylated phage was affected by the umuD,C mutation in the Escherichia coli host nor by the presence of plasmid pKM101. This may mean that the mode of Weigle reactivation that is detected in T7 is not mutagenic in nature.

Repair of benzo[a]pyrene diol epoxide damaged bacteriophage T7 DNA determined by survival of phage made by in vitro packaging

DNA from bacteriophage T7 was treated with benzo[a]pyrene diol epoxide (BPDE) and the number of covalently bound adducts per T7 genome was determined. BPDE treated T7 DNA was then incubated in an in vitro DNA packaging system so as to form infective T7 phage. The observed reduced survival of these phage measured with Escherichia coli uvrA- indicator bacteria showed that the BPDE treated DNA was in fact utilized by the in vitro packaging system and that the resulting phage contained DNA damage caused by in vitro exposure to BPDE. T7 DNA damage by BPDE was also incubated in an in vitro DNA repair system that used partially purified uvrABC proteins from E. coli. Alkaline sucrose gradient analysis demonstrated that nicks were introduced into the damaged DNA and that these incisions were repaired to yield nearly intact DNA molecules of about the size of a T7 genome. Encapsulation of the repaired DNA with the packaging system yielded phage that showed higher survival than the unrepaired control when plated on uvrA- indicator bacteria.

In vitro replication of bacteriophage T7 DNA damaged by ultraviolet radiation

The effect of ultraviolet radiation on DNA replication has been examined with an in vitro system capable of replicating intact chromosomes of T7 DNA from an exogenous template. Exposure of the template DNA to ultraviolet radiation resulted in a sharp drop in the amount of in vitro DNA synthesis. The residual replication detected when irradiated templates were used was found to proceed semiconservatively and to result in the production of pieces of duplex DNA approximately the same size as the average distance between pyrimidine dimers. It was also found that prior irradiation of the template inhibits formation of fast-sedimenting concatemer-like DNA structures normally synthesized in vitro. Hybridization studies demonstrated that the product synthesized in vitro from ultraviolet-irradiated templates includes DNA from both the left and right halves of the T7 chromosome. This may mean that after ultraviolet irradiation more than one origin of replication exists.

Repair resynthesis in Escherichia coli mutants deficients in single-stranded DNA-binding protein

A series of Escherichia coli strains deficient in single-stranded DNA-binding protein (SSB) and DNA polymerase I was constructed in order to analyze the effects of these mutations on DNA repair resynthesis after UV-irradiation. Since SSB has been suggested to play a role in protecting single-stranded regions which may transiently exist during excision repair and since long single-stranded regions are believed to occur frequently as repair intermediates in strains deficient in DNA polymerase I, studies of repair resynthesis and strand rejoining were performed on strains containing both the ssb-1 and polA1 mutations. Repair resynthesis appears to be slightly decreased in the ssb-1 strain at 42 degrees C relative to the wild-type; however, this effect is not enhanced in a polA1 derivative of this strain. After UV-irradiation, the single-strand molecular weight of the DNA of an ssb-1 strain decreases and fails to recover to normal size. These results are discussed in the context of long patch repair as an inducible component of repair resynthesis and of the protection of intermediates in the excision repair process by SSB. A direct role for SSB in repair resynthesis involving modulation of the proteins involved in this mode of DNA synthesis (particularly stimulation of DNA polymerase II) is not supported by our findings.

In vitro packaging of damaged bacteriophage T7 DNA

Experiments using in vitro packaging to monitor the biological activity of DNA recovered after in vitro repair, replication, and recombination reactions are described. These results suggest that the in vitro systems mimic the in vivo situation sufficiently well to allow generation (or restoration) of DNA molecules which can be encapsulated to form fully viable T7 phage particles. The in vitro packaging system has proved to be a convenient and relatively sensitive means for determining the amount of biological damage present in T7 DNA and for examining the response of various DNA metabolic systems to that damage.