Ultraviolet mutagenesis and inducible DNA repair in Caulobacter crescentus

The ability to reactivate ultraviolet (UV) damaged phage ΦCbK (W-reactivation) is induced by UV irradiation of Caulobacter crescentus cells. Induction of W-reactivation potential is specific for phage ΦCbK, requires protein synthesis, and is greatly reduced in the presence of the rec-526 mutation. The induction signal generated by UV irradiation is transient, lasting about 1 1/2–2 h at 30°C; if chloramphenicol is present during early times after UV irradiation, induction of W-reactivation does not occur. Induction is maximal when cells are exposed to 5–10 J/m 2 of UV, a dose that also results in considerable mutagenesis of the cells. Taken together, these observations demonstrate the existence of a UV inducible, protein synthesis requiring, transiently signalled, rec -requiring DNA repair system analogous to W-reactivation in Escherichia coli . In addition, C. crescentus also has an efficient photoreactivation system that reverses UV damage in the presence of strong visible light.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/47557/1/438_2004_Article_BF00329935.pd

New mutations in and around the L2 disordered loop of the RecA protein modulate recombination and/or coprotease activity.

The RecA protein plays a key role in Escherichia coli recombination and DNA repair. We have created new recA mutants with mutations in the vicinity of the recA430 mutation (Gly-204----Ser) which is known to affect RecA coprotease activity. Mutants carrying recA659 or recA611, located 3 and 7 amino acids downstream of residue 204, respectively, lose all RecA activities, while the mutant carrying recA616, which is located at 12 amino acids from this residue, keeps the coprotease activity but is unable to promote recombination. Complementation experiments show that both mutations recA611 and recA659 are dominant over the wild-type or recA430 allele while recA616 seems to be recessive to recA+ and dominant over recA430. It is suggested that these mutations are located in RecA domains which direct conformational modifications

Characterization of dinY, a new Escherichia coli DNA repair gene whose products are damage inducible even in a lexA(Def) background.

Bacteriophage Mu dX(Ap lac) was used to isolate a mutation in an Escherichia coli lexA(Def) strain representing a previously undescribed gene (dinY) which does not seem to be under the direct control of LexA. The insertion created a dinY::lacZ fusion in which beta-galactosidase expression required a DNA-damaging treatment (UV irradiation or mitomycin) and activable RecA protein. This strain showed a decreased Weigle reactivation of bacteriophage lambda. However, it was fully inducible for UV mutagenesis. Two-dimensional gel electrophoresis analysis identified two spots absent in the mutant which were both UV inducible only in the presence of activated RecA protein (RecA*). This finding suggests that the dinY::lacZ fusion lies in a gene either that is under the direct control of activated RecA or whose product undergoes RecA*-dependent posttranscriptional/posttranslational modification(s). The dinY gene may also control the expression of some other gene(s) and/or lie in an operon. The fusion was mapped at a position between 41 and 41.5 min on the E. coli chromosome, in the vicinity of the ruv operon