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Target Concepts:
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Query: UMLS:C0038187 (
starvation
)
24,951
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
It has been shown that the decline in mutant frequency (MFD) (argE3(ochre)-->Arg+) which occurs in MMS-treated and then transiently starved AB1157 Escherichia coli K-12 cells concerns revertants which arose by supL suppressor formation in a process which is umuDC dependent. Here we have examined whether MMS-induced Arg+ revertants are susceptible to decline when bacteria are deficient in mismatch repair. We show that there is an absence of MFD in MMS-treated M1 (mutS) and in EC2416 (mutS delta umuDC) cells defective in mismatch repair which is associated with a change in the spectrum of MMS-induced mutations formed. In contrast to AB1157, transformation of M1 (mutS) bacteria with plasmids harbouring various combinations of umuD(D')C genes does not enhance the level of MMS-induced mutations but may influence the proportion of supL mutations. These supL mutations show MFD. Repair processes under MFD conditions were confirmed by analysis of plasmid DNA isolated from MMS-treated bacteria at different stages of their
starvation
and digestion with
Fpg protein
.
...
PMID:Mutation frequency decline in MMS-treated Escherichia coli K-12 mutS strains. 956 83
MMS, an S(N)2 alkylating agent, is a moderate inducer of SOS mutagenesis and adaptive response. Our previous studies have shown that transient
starvation
of Escherichia coli AB1157argE3 strain causes a decrease of MMS-induced argE3-->Arg(+) reversions and this decrease is accompanied by the disappearance of the
Fpg protein
sensitive sites on plasmids isolated from MMS-treated and subsequently starved bacteria. This suggests that in such cells the mutation frequency decline (MFD) repair takes place. Here, we study the relation between MMS-induced mutagenesis as well as mutation frequency decline during
starvation
, and the repair of alkylated bases and AP-sites by base and nucleotide excision repair systems. In the AB1157alkA(-) strain, MMS-induced mutagenesis was over five-fold higher than in the wild type strain and no MFD repair occurred during
starvation
. Surprisingly, the lack of TagA glycosylase diminished MMS mutagenesis and accelerated the MFD effect. However, in double tagA(-)alkA(-) mutant, the frequency of Arg(+) reversions increased over 10-fold during 60 min of aminoacid
starvation
after MMS-treatment. Lack of the uvrA gene function did not affect the MMS-induced mutation rate and MFD in AB1157alkA(+)tagA(+).
Starvation
of MMS treated AB1157tagAalkAuvrA triple mutant caused a decrease of mutation frequency almost to the level of spontaneous mutation rate. Examination of the repair of 3-MeAde, 7-MeGua and AP sites during
starvation
using repair glycosylases and plasmids isolated from MMS-treated and starved bacteria revealed that in E. coli uvr(+) but tagAalkA strain, neither 3-MeAde nor 7-MeGua were repaired during 60 min
starvation
and these persistent lesions could be responsible for the induction of the SOS system and an increase in mutation rate during
starvation
. In the triple tagAalkAuvrA mutant the repair of 3-MeAde, 7-MeGua and AP sites was carried out effectively and this could explain the observed decrease in the mutation rate during
starvation
. These results suggest that only in the absence of the "first choice" repair enzymes TagA, AlkA glycosylases and UvrABC excinuclease, a third error-free repair system of alkylated bases is activated. In the absence of only TagA and AlkA glycosylases, UvrABC excinuclease mediates activation of the SOS response, and this results in an increase of mutagenesis induced by the presence of alkylated bases in DNA.
...
PMID:Contribution of E. coli AlkA, TagA glycosylases and UvrABC-excinuclease in MMS mutagenesis. 1150 1
