RESUMEN
The aim of this work was to search if the rat DNA polymerase beta can substitute the capability of DNA polymerase I to repair damage caused by the UV light in Escherichia coli. The oriC origin of replication from p beta 5 was replaced by the rep origin from pSC101 and named p beta 6. The presence of pol beta in the new construct was verified by PCR. E. coli polA-1 (WP6) was transformed with p beta 6. A protein with size similar to DNA Pol beta (40 kDa) was shown in the cell free extracts carrying pbeta5. In WP6/p beta 6 cell free extracts a slightly smaller protein was observed instead of the 40 kDa. DNA Pol beta was revealed by western analysis, with polyclonal antibodies, in strains with p beta 5. Yet, it was not detected in the western from WP6/p beta 6. A moderate change in UV resistance was observed in strains carrying p beta 5. However, in polAl carrying p beta 6 (WP6/p beta 6), irradiated with 60-90 J/m2 of UV light, the viability was increased by more than four orders of magnitude, when compared with the polA1 (WP6) strain, reaching approximately the same UV resistance as the strains with DNA polymerase I. The results suggests that probably Pol beta is rapidly degraded in the cell free extracts from WP6/p beta 6 and, it repairs the lethal effect of the UV light in E. coli.
Asunto(s)
Daño del ADN/genética , ADN Polimerasa I/fisiología , ADN Polimerasa beta/fisiología , Reparación del ADN , Rayos Ultravioleta/efectos adversos , Animales , RatasRESUMEN
The mutagenic role of 1-N6-Ethenodeoxydenosine (epsilon A) was assessed by a genetic assay of mutations in the 5' coding region of the lacl gene of Escherichia coli. 1-N6-Etheno-2-deoxydadenosine 5'-triphosphate (epsilon dATP) was substituted for dATP during in vitro DNA synthesis on M13 recombinant uracil single stranded DNA bearing the lacl gene, catalyzed by the large fragment of E. coli DNA polymerase I. DNA products were transfected into a strain of E. coli lacking a chromosomal copy of the lacl gene, and i- phenotypic mutants were seen as blue plaques in the absence of inducer. Mutant progeny were characterized by dideoxy sequencing in the N-terminal region of the lacl gene where epsilon A had originally replaced A, and were found to have T-->C transitions. The frequency of base substitution mutation was different in each of three target sites tested. Taking into account the sequence changes and the coding properties at target sites, we conclude that in general, epsilon A increases the mutation frequency when compared with the control (transfection with unsubstituted DNA). This increase was similar to that produced by in vitro primer elongation in absence of dATP. The combined results of the electrophoretic assay of primer elongation, measurements of mutation frequency, and sequence analysis of mutant phage progeny support the proposal that epsilon A in template DNA can be mutagenic through epsilon AC mispairing during in vivo replication.