Developmental regulator Le.CDC5 of the mushroom Lentinula edodes: analyses of its amount in each of the stages of fruiting-body formation and its distribution in parts of the fruiting bodies

Immunoblot analysis of Le.CDC5 (842 amino acid residues), the expressed product of the cDNA of Le.cdc5 gene that has been previously reported to be most actively transcribed in primordia and small immature fruiting bodies of the basidiomycete Lentinula edodes, showed that the primordia, immature fruiting bodies and mature fruiting bodies contain similar amounts of Le.CDC5 protein. This indicates that the Le.CDC5 protein molecules synthesized in the beginning and early stage of fruiting-body formation remains in mycelial tissues even after small immature fruiting bodies developed and matured. Immunohistochemical analysis showed that Le.CDC5 is present everywhere in the mycelial tissues of immature fruiting body, but prehymenophore, the border between pileus and stipe, and the bottom of stipe seem likely to contain larger amounts of Le.CDC5. Within the hymenophore of mature fruiting body, the hymenium (in/on which a large number of basidia and basidiospores are formed) contains the Le.CDC5 most exclusively.     

The role of Bacteroides fragilis RecQ DNA helicases in cell survival after metronidazole exposure

The inactivation of Bacteroides fragilis genes encoding putative RecQ helicases recQ1, recQ2 and recQ3 (ORFs BF638R_3282, BF638R_3781, BF638R_3932) was used to determine whether these proteins are involved in cell survival following metronidazole exposure. The effects of the mutations on growth, cellular morphology and DNA integrity were also evaluated. Mutations in the RecQ DNA helicases caused increased sensitivity to metronidazole, with recQ1, recQ2 and recQ3 mutants being 1.32-fold, 41.88-fold and 23.18-fold more sensitive than the wild type, respectively. There was no difference in cell growth between the recQ1 and recQ3 mutants and the wild type. However, the recQ2 mutant exhibited reduced cell growth, aberrant cell division and increased pleiomorphism, with an increase in filamentous forms and chains of cells being observed using light, fluorescence and electron microscopy. There was no spontaneous accumulation of DNA single- or double-strand breaks in the recQ mutants, as compared with the wild type, during normal cell growth in the absence of metronidazole. Bacteroides fragilis RecQ DNA helicases, therefore, enhance cell survival following metronidazole damage. The abnormal cellular phenotype and growth characteristics of recQ2 mutant cells suggest that this gene, or the downstream gene of the operon in which it occurs, may be involved in cell division.     

Genetic control of recombination exchange frequency in Escherichia coli K-12.

The frequency of recombination exchanges per unit length of DNA (Freuld) can be estimated by measuring the scale of the genetic map that is the mean statistical distance between two neighboring crossovers. The scales appear to be equal for the alternative pathways of recombination, RecBCD (wild-type cells) or RecF (recBC- sbcB- sbcC- genotypes). The absolute value of the scale depends on specific experimental conditions. recR, recQ, ruv, recJ and recN genes of the RecF pathway of recombination (recBC- sbcBC- cell genotypes) do not appear to be silent in wild-type cells where the RecBCD pathway predominates. On the contrary, these genes are responsible for the Freuld. The list recF504::Kmr greater than recQ61::Tn3 greater than ruv-54 greater than recJ284::Tn10 shows decreasing efficiency in inhibiting recombination exchanges by these mutations. The recN264 mutation gives a small, but opposite effect of increasing the frequency of recombination exchanges. The effect of the recF and recQ mutations appears to be additive, but that is not the case in combinations of ruv-54 with recF504::Kmr or recQ61::Tn3.     

DNA helicases in recombination and repair: construction of a delta uvrD delta helD delta recQ mutant deficient in recombination and repair.

DNA helicases play pivotal roles in homologous recombination and recombinational DNA repair. They are involved in both the generation of recombinogenic single-stranded DNA ends and branch migration of synapsed Holliday junctions. Escherichia coli helicases II (uvrD), IV (helD), and RecQ (recQ) have all been implicated in the presynaptic stage of recombination in the RecF pathway. To probe for functional redundancy among these helicases, mutant strains containing single, double, and triple deletions in the helD, uvrD, and recQ genes were constructed and examined for conjugational recombination efficiency and DNA repair proficiency. We were unable to construct a strain harboring a delta recQ delta uvrD double deletion in a recBC sbcB(C) background (RecF pathway), suggesting that a delta recQ deletion mutation was lethal to the cell in a recBC sbcB(C) delta D background. However, we were able to construct a triple delta recQ delta uvrD Delta helD mutant in the recBC sbcB(C) background. This may be due to the increased mutator frequency in delta uvrD mutants which may have resulted in the fortuitous accumulation of a suppressor mutation(s). The triple helicase mutant recBC sbcB(C) delta uvrD delta recQ delta helD severely deficient in Hfr-mediated conjugational recombination and in the repair of methylmethane sulfonate-induced DNA damage. This suggests that the presence of at least one helicase--helicase II, RecQ helicase, or helicase IV--is essential for homologous recombination and recombinational DNA repair in a recBC sbcB(C) background. The triple helicase mutant was recombination and repair proficient in a rec+ background. Genetic analysis of the various double mutants unmasked additional functional redundancies with regard to conjugational recombination and DNA repair, suggesting that mechanisms of recombination depend both on the DNA substrates and on the genotype of the cell.     

Mutation of recF, recJ, recO, recQ, or recR improves Hfr recombination in resolvase-deficient ruv recG strains of Escherichia coli.

The formation of recombinants in Hfr crosses was studied in Escherichia coli strains carrying combinations of genes known to affect recombination and DNA repair. Mutations in ruv and recG eliminate activities that have been shown to process Holliday junction intermediates by nuclease cleavage and/or branch migration. Strains carrying null mutations in both ruv and recG produce few recombinants in Hfr crosses and are extremely sensitive to UV light. The introduction of additional mutations in recF, recJ, recO, recQ, or recR is shown to increase the yield of recombinants by 6- to 20-fold via a mechanism that depends on recBC. The products of these genes have been linked with the initiation of recombination. We propose that mutation of recF, recJ, recO, recQ, or recR redirects recombination to events initiated by the RecBCD enzyme. The strains constructed were also tested for sensitivity to UV light. Addition of recF, recJ, recN, recO, recQ, or recR mutations had no effect on the survival of ruv recG strains. The implications of these findings are discussed in relation to molecular models for recombination and DNA repair that invoke different roles for the branch migration activities of the RuvAB and RecG proteins.     

Effect of rec mutations on viability and processing of DNA damaged by methylmethane sulfonate in xth nth nfo cells of Escherichia coli

The role of recombination genes in the processing of DNA damaged by methlymethane sulfonate (MMS) was examined in an xth nth nfo strain of Escherichia coli K-12. Introduction of a recQ mutation did not increase the cell's sensitivity to MMS treatment. The presence of recF, recJ or recN mutation slightly increased the cell's sensitivity to MMS treatment. The introduction of recA or recB mutation into the cells led to inviability. Taken together, we suggest that replication of DNA containing apurinic/apyrimidinic (AP) sites in vivo will lead to the formation of secondary lesions. The repair of these secondary lesions requires the function of recA and recB genes, but does not appear to require recF, recJ, recQ or recN genes.