The Mechanism of Reca Pola Lethality: Suppression by Reca-Independent Recombination Repair Activated by the Lexa(def) Mutation in Escherichia Coli

The mechanism of recA polA lethality in Escherichia coli has been studied. Complementation tests have indicated that both the 5' -> 3' exonuclease and the polymerization activities of DNA polymerase I are essential for viability in the absence of RecA protein, whereas the viability and DNA replication of DNA polymerase I-defective cells depend on the recombinase activity of RecA. An alkaline sucrose gradient sedimentation analysis has indicated that RecA has only a minor role in Okazaki fragment processing. Double-strand break repair is proposed for the major role of RecA in the absence of DNA polymerase I. The lexA(Def)::Tn5 mutation has previously been shown to suppress the temperature-sensitive growth of recA200(Ts) polA25::spc mutants. The lexA(Def) mutation can alleviate impaired DNA synthesis in the recA200(Ts) polA25::spc mutant cells at the restrictive temperature. recF(+) is essential for this suppression pathway. recJ and recQ mutations have minor but significant adverse effects on the suppression. The recA200(Ts) allele in the recA200(Ts) polA25::spc lexA(Def) mutant can be replaced by δrecA, indicating that the lexA(Def)-induced suppression is RecA independent. lexA(Def) reduces the sensitivity of δrecA polA25::spc cells to UV damage by ~10(4)-fold. lexA(Def) also restores P1 transduction proficiency to the δrecA polA25::spc mutant to a level that is 7.3% of the recA(+) wild type. These results suggest that lexA(Def) activates a RecA-independent, RecF-dependent recombination repair pathway that suppresses the defect in DNA replication in recA polA double mutants.     

Excision and Transposition of Tn5 as an Sos Activity in Escherichia Coli

Excision and transposition of the Tn5 element in Escherichia coli ordinarily appear to occur by recA-independent mechanisms. However, recA(Prtc) genes, which encode RecA proteins that are constitutively activated to the protease state, greatly enhanced excision and transposition; both events appeared to occur concomitantly and without destruction of the donor DNA. The recombinase function of the RecA protein was not required. Transposition was accompanied by partial, and occasionally full, restoration of the functional integrity of the gene vacated by the excised Tn5. The stimulation of transposition was inhibited by an uncleavable LexA protein and was strongly enhanced by an additional role of the RecA(Prtc) protein besides its mediation of LexA cleavage. To account for the enhanced transposition, we suggest that (i) there may be a LexA binding site within the promoter for the IS50 transposase, (ii) activated RecA may cleave the IS50 transposition inhibitor, and (iii) the transposase may be formed by RecA cleavage of a precursor molecule.     

Enhanced Deletion Formation by Aberrant DNA Replication in Escherichia Coli

Repeated genes and sequences are prone to genetic rearrangements including deletions. We have investigated deletion formation in Escherichia coli strains mutant for various replication functions. Deletion was selected between 787 base pair tandem repeats carried either on a ColE1-derived plasmid or on the E. coli chromosome. Only mutations in functions associated with DNA Polymerase III elevated deletion rates in our assays. Especially large increases were observed in strains mutant in dnaQ, the ε editing subunit of Pol III, and dnaB, the replication fork helicase. Mutations in several other functions also altered deletion formation: the α polymerase (dnaE), the γ clamp loader complex (holC, dnaX), and the β clamp (dnaN) subunits of Pol III and the primosomal proteins, dnaC and priA. Aberrant replication stimulated deletions through several pathways. Whereas the elevation in dnaB strains was mostly recA- and lexA-dependent, that in dnaQ strains was mostly recA- and lexA-independent. Deletion product analysis suggested that slipped mispairing, producing monomeric replicon products, may be preferentially increased in a dnaQ mutant and sister-strand exchange, producing dimeric replicon products, may be elevated in dnaE mutants. We conclude that aberrant Polymerase III replication can stimulate deletion events through several mechanisms of deletion and via both recA-dependent and independent pathways.     

Adaptive Reversion of a Frameshift Mutation in Escherichia Coli

Mutation rates are generally thought not to be influenced by selective forces. This doctrine rests on the results of certain classical studies of the mutations that make bacteria resistant to phages and antibiotics. We have studied a strain of Escherichia coli which constitutively expresses a lacI-lacZ fusion containing a frameshift mutation that renders it Lac-. Reversion to Lac+ is a rare event during exponential growth but occurs in stationary cultures when lactose is the only source of energy. No revertants accumulate in the absence of lactose, or in the presence of lactose if there is another, unfulfilled requirement for growth. The mechanism for such mutation in stationary phase is not known, but it requires some function of RecA which is apparently not required for mutation during exponential growth.     

Structure-guided Mutation of the Conserved G3-box Glycine in Rheb Generates a Constitutively Activated Regulator of Mammalian Target of Rapamycin (mTOR)

Constitutively activated variants of small GTPases, which provide valuable functional probes of their role in cellular signaling pathways, can often be generated by mutating the canonical catalytic residue (e.g. Ras Q61L) to impair GTP hydrolysis. However, this general approach is ineffective for a substantial fraction of the small GTPase family in which this residue is not conserved (e.g. Rap) or not catalytic (e.g. Rheb). Using a novel engineering approach, we have manipulated nucleotide binding through structure-guided substitutions of an ultraconserved glycine residue in the G3-box motif (DXXG). Substitution of Rheb Gly-63 with alanine impaired both intrinsic and TSC2 GTPase-activating protein (GAP)-mediated GTP hydrolysis by displacing the hydrolytic water molecule, whereas introduction of a bulkier valine side chain selectively blocked GTP binding by steric occlusion of the γ-phosphate. Rheb G63A stimulated phosphorylation of the mTORC1 substrate p70S6 kinase more strongly than wild-type, thus offering a new tool for mammalian target of rapamycin (mTOR) signaling.     

Microbial Evolution in a Simple Unstructured Environment: Genetic Differentiation in Escherichia Coli

Populations of Escherichia coli initiated with a single clone and maintained for long periods in glucose-limited continuous culture, become polymorphic. In one population, three clones were isolated and by means of reconstruction experiments were shown to be maintained in stable polymorphism, although they exhibited substantial differences in maximum specific growth rates and in glucose uptake kinetics. Analysis of these three clones revealed that their stable coexistence could be explained by differential patterns of the secretion and uptake of two alternative metabolites acetate and glycerol. Regulatory (constitutive and null) mutations in acetyl-coenzyme A synthetase accounted for different patterns of acetate secretion and uptake seen. Altered patterns in glycerol uptake are most likely explained by mutations which result in quantitative differences in the induction of the glycerol regulon and/or structural changes in glycerol kinase that reduce allosteric inhibition by effector molecules associated with glycolysis. The evolution of resource partitioning, and consequent polymorphisms which arise may illustrate incipient processes of speciation in asexual organisms.     

Maize Glutamine Synthetase Cdnas: Isolation by Direct Genetic Selection in Escherichia Coli

Maize glutamine synthetase cDNA clones were isolated by genetic selection for functional rescue of an Escherichia coli delta glnA mutant growing on medium lacking glutamine. The Black Mexican Sweet cDNA library used in this study was constructed in pUC13 such that cDNA sense strands were transcribed under the control of the lac promoter. E. coli delta glnA cells were transformed with cDNA library plasmid DNA, grown briefly in rich medium to allow phenotypic expression of the cDNAs and the pUC13 ampr gene, and challenged to grow on agar medium lacking glutamine. Large numbers of glutamine synthetase cDNA clones have been identified in individual 150-mm Petri dishes; all characterized cDNA clones carry complete coding sequences. Two cDNAs identical except for different 5' and 3' termini have been sequenced. The major open reading frame predicts a protein with an amino acid sequence that exhibits striking similarity to the amino acid sequences of the predicted products of previously sequenced eukaryotic glutamine synthetase cDNAs and genes. In addition, the maize glutamine synthetase cDNAs were shown to contain a 5' mini-ORF of 29 codons separated by 37 nucleotide pairs from the major ORF. This mini-ORF was shown not to be essential for the functional rescue of the E. coli delta glnA mutant. Expression of the cDNAs in E. coli is presumed to be due to the function of a polycistronic hybrid lac messenger RNA or translational fusions encoded by the pUC plasmids. Proteins of the expected sizes encoded by two different pUC clones were shown to react with antibodies to tobacco glutamine synthetase.     

Conjugational Recombination in Escherichia Coli: Genetic Analysis of Recombinant Formation in Hfr X F(-) Crosses

The formation of recombinants during conjugation between Hfr and F(-) strains of Escherichia coli was investigated using unselected markers to monitor integration of Hfr DNA into the circular recipient chromosome. In crosses selecting a marker located ~500 kb from the Hfr origin, 60-70% of the recombinants appeared to inherit the Hfr DNA in a single segment, with the proximal exchange located >300 kb from the selected marker. The proportion of recombinants showing multiple exchanges increased in matings selecting more distal markers located 700-2200 kb from the origin, but they were always in the minority. This effect was associated with decreased linkage of unselected proximal markers. Mutation of recB, or recD plus recJ, in the recipient reduced the efficiency of recombination and shifted the location of the proximal exchange (s) closer to the selected marker. Mutation of recF, recO or recQ produced recombinants in which this exchange tended to be closer to the origin, though the effect observed was rather small. Up to 25% of recombinant colonies in rec(+) crosses showed segregation of both donor and recipient alleles at a proximal unselected locus. Their frequency varied with the distance between the selected and unselected markers and was also related directly to the efficiency of recombination. Mutation of recD increased their number by twofold in certain crosses to a value of 19%, a feature associated with an increase in the survival of linear DNA in the absence of RecBCD exonuclease. Mutation of recN reduced sectored recombinants in these crosses to ~1% in all the strains examined, including recD. A model for conjugational recombination is proposed in which recombinant chromosomes are formed initially by two exchanges that integrate a single piece of duplex Hfr DNA into the recipient chromosome. Additional pairs of exchanges involving the excised recipient DNA, RecBCD enzyme and RecN protein, can subsequently modify the initial product to generate the spectrum of recombinants normally observed.     

Abnormal 30S Ribosomal Subunits Determined by an Ochre Suppressor Mutation in Escherichia coli

The results demonstrate that an ochre suppressor mutant of Escherichia coli K-12 produces abnormal 30S ribosomes. The production of these abnormal 30S ribosomes is probably a secondary consequence of the suppressor mutation.     

Double-Stranded Gap Repair of DNA by Gene Conversion in Escherichia Coli

We demonstrated repair of a double-stranded DNA gap through gene conversion by a homologous DNA sequence in Escherichia coli. We made a double-stranded gap in one of the two regions of homology in an inverted orientation on a plasmid DNA molecule and introduced it into an E. coli strain which has the RecE system of recombination (genotype; sbcA23 recB21 recC22). We detected repair products by genetic selection. The repair products were those expected by the double-strand-gap repair model. Gene conversion was frequently accompanied by crossing over of the flanking sequences as in eukaryotes. This double-strand gap repair mechanism can explain plasmid recombination in the absence of an artificial double-stranded break reported in a companion study by Yamamoto et al.     

Mutation as an error in base pairing

Summary The model of mutation by transitional change (Freese 1959) predicts that a heritable change in genotype is established when two replications of DNA succeed the initial incorporation of an analogue. The model was tested in populations ofSalmonella typhimurium strainstryD-10 andtryD-79 whose division had been synchronized by fractional filtration. Mutation from auxotrophy to prototrophy (try ^–try ⁺) induced by 5-bromodeoxyuridine (BUDR) and 2-aminopurine (AP) occurred in accordance with DNA replication. Two subsequent DNA replications were necessary to obtain BUDR-induced prototrophs inD-79, one subsequent DNA replication was required for AP-induced prototrophs inD-79, while no subsequent DNA replication was necessary for AP-induced prototrophs inD-10. This was observed whether the mutagens were present continuously or during only the first replication and also when the cells were allowed to replicate their DNA without cell division in the presence of inhibitory concentrations of the base analogue or when protein synthesis was blocked in the presence of chloramphenicol. A statistical analysis of the patterns of mutant increase observed for six mutant strains was used to distinguish between errors in replication and errors in incorporation induced by the base analogues and thereby the base pair at the mutant site was identified.With 10 Figures in the TextSupported in part by grants from the American Cancer Society the U.S. Public Health Service and the National Science Foundation administered by ProfessorF. J. Ryan.