3-Methyladenine residues in DNA induce the SOS function sfiA in Escherichia coli.

The induction by methylating agents of the SOS function sfiA was measured by means of a sfiA::lac operon fusion in Escherichia coli mutants defective in alkylation repair. The sfiA operon was turned on at a 10-fold lower concentration of methylmethane sulfonate or dimethyl sulfate in tagA strains, lacking specific 3-methyladenine-DNA glycosylase, than in wild-type strains. In contrast, the induction of sfiA by u.v. light was not affected by a tagA mutation. We confirm that tagA strains specifically accumulate 3-methyladenine in their DNA. We conclude that the persistence of 3-methyladenine in E. coli DNA most likely induces the SOS functions. Results on in vitro DNA synthesis further suggest that this induction is due to an unscheduled arrest of DNA synthesis at this lesion.     

Induction of phr gene expression by irradiation of ultraviolet light in Escherichia coli

Summary To measure the degree of phr gene induction by DNA-damaging agents, the promoter region was fused to the coding region of the lacZ gene in plasmid pMC1403. The new plasmids were introduced into Escherichia coli cells having different repair capabilities. More efficient induction of phr gene expression was detected in a uvrA ^– strain as compared with the wild-type strain. In addition, obvious induction was detected in uvrA ^– cells treated by 4-nitroquinoline 1-oxide and mitomycin C. Nalidixic acid, an inhibitor of DNA gyrase, also induced phr gene expression. In contrast, little induced gene expression was noted in UV-irradiated lexA ^– and recA ^– strains. It is suggested from these results that induction of the phr gene is one of the SOS responses. Possible nucleotide sequences which could be considered to constitute an SOS box were found at the regulator region of the phr gene.Abbreviations phr photoreactivation - UV ultraviolet light - 4NQO 4-nitroquinoline 1-oxide - MMC mitomycin C - PRE photoreactivating enzyme - E. coli Escherichia coli     

Further characterization of sfiA and sfiB mutations in Escherichia coli.

The sfiA and sfiB mutations, originally isolated in thermoresistant ultraviolet-resistant revertants of a tif lon strain, also suppressed filamentation in tsl strains (mutated at the lexA locus). When deoxyribonucleic acid synthesis was arrested, however, sfi-independent filamentation occurred. Other SOS functions were not affected by sfiA and sfiB mutations; in particular, ultraviolet-induced repair and mutagenesis of bacterial deoxyribonucleic acid were normal, as was tsl-tif-induced synthesis of recA protein. Genetic studies (i) established the identity of map location of the sfiA and sulA loci, (ii) showed that the two sfiB mutations are recessive, and (iii) showed that of six independent sfiA mutations, three are recessive and three are dominant. One sfiB strain was shown to have a 6% growth disadvantage relative to a sfi+ or sfiA strain. It is proposed that the sfiA locus may define the structural gene of a hypothetical inducible SOS-associated division inhibitor.     

Cloning of the Escherichia coli gene for the stringent starvation protein

Summary In order to clone the Escherichia coli gene for the stringent starvation protein (SSP), we determined its N-terminal sequence as well as the sequence of two peptide fragments obtained by cyanogen bromide cleavage of the protein. We then chemically synthesized four sets of oligodeoxyribonucleotide mixtures that represented possible codon combinations for parts of these amino acid sequences. The synthetic oligonucleotides were labelled with ³²P at their 5-termini and used as hybridization probes to detect DNA fragments containing the complementary sequences. Genomic Southern hybridization of E. coli chromosomal DNA gave up to ten DNA fragments hybridizing with each probe but only a few hybridized with two or more of the probes. The latter fragments were coloned in pBR322. By determining partial base sequences with a rapid method and examining proteins encoded by the DNA fragments, we were able to show that we had isolated a clone containing the complete SSP structural gene.Abbreviations SSP stringent starvation protein - PTH phenylthiohydantoin     

Bromodeoxyuridine sensitization of the ultraviolet-sensitive Escherichia coli ras- mutant to ultraviolet irradiation

Summary The Escherichia coli ras ^- mutant was sensitized to UV by bromodeoxyuridine. The extent of sensitization indicates that the ras ^- mutation probably increases UV-sensitivity by an effect on excision repair. This effect probably is uncontrolled degradation without concomitant resynthesis in a small proportion of the repair events.     

Use of glucose starvation to limit growth and induce protein production in Escherichia coli

The use of glucose starvation to uncouple the production of recombinant beta-galactosidase from cell growth in Escherichia coli was investigated. A lacZ operon fusion to the carbon starvation-inducible cst-1 locus was used to control beta-galactosidase synthesis. beta-Galactosidase induction was observed only under aerobic starvation conditions, and its expression continued for 6 h following the onset of glucose starvation. The cessation of beta-galactosidase expression closely correlated with the exhaustion of acetate, an overflow metabolite of glucose, from the culture medium. Our results suggest the primary role of acetate in cst-1-controlled protein expression is that of an energy source. Using this information, we metered acetate to a glucose-starved culture and produced a metabolically sluggish state, where growth was limited to a low linear rate and production of recombiant beta-galactosidase occurred continuously throughout the experiment. The cst-1 controlled beta-galactosidase synthesis was also induced at low dilution rates in a glucose-limited chemostat, suggesting possible applications to high-density cell systems such as glucose-limited recycle reactors. This work demonstrates that by using an appropriate promoter system and nutrient limitation, growth can be restrained while recombinant protein production is induced and maintained.     

Amino acid starvation and colicin D treatment induce A-site mRNA cleavage in Escherichia coli

Escherichia coli possesses a unique RNase activity that cleaves stop codons in the ribosomal aminoacyl-tRNA binding site (A-site) during inefficient translation termination. This A-site mRNA cleavage allows recycling of arrested ribosomes by facilitating recruitment of the tmRNA•SmpB ribosome rescue system. To test whether A-site nuclease activity also cleaves sense codons, we induced ribosome pausing at each of the six arginine codons using three strategies; rare codon usage, arginine starvation, and inactivation of arginine tRNAs with colicin D. In each instance, ribosome pausing induced mRNA cleavage within the target arginine codons, and resulted in tmRNA-mediated SsrA-peptide tagging of the nascent polypeptide. A-site mRNA cleavage did not require the stringent factor ppGpp, or bacterial toxins such as RelE, which mediates a similar nuclease activity. However, the efficiency of A-site cleavage was modulated by the identity of the two codons immediately upstream (5′ side) of the A-site codon. Starvation for histidine and tryptophan also induced A-site cleavage at histidine and tryptophan codons, respectively. Thus, A-site mRNA cleavage is a general response to ribosome pausing, capable of cleaving a variety of sense and stop codons. The induction of A-site cleavage during amino acid starvation suggests this nuclease activity may help to regulate protein synthesis during nutritional stress.     

The relationship between survival and mutagenesis in Escherichia coli after fractionated ultraviolet irradiation

The relationship between survival and mutagenesis in Escherichia coli after fractionated ultraviolet (UV) irradiation was studied. The cells were incubated either in buffer or nutrient media. Regardless of incubation conditions, greater survival is observed after fractionated irradiation than after acute irradiation. When the cells are incubated in buffer, UV mutagenesis decreases with an increase in the number of dose fractions. However, when the cells are cultivated in nutrient media, the increased survival (i.e., the enhanced capacity for repair) is coupled with the enhanced capacity for UV mutagenesis. We, therefore, assume that during incubation in nutrient media, fractionated irradiation leads to full and prolonged expression of all UV-inducible (SOS) genes, including those required for mutagenesis.     

Mathematical model of induced mutagenesis in bacteria Escherichia coli under ultraviolet irradiation

A mathematical model is developed for a mutational process in bacteria Escherichia coli induced by ultraviolet radiation. The dynamics of the basic protein complexes of the SOS-response system is investigated. The probability of mutations during translesion synthesis is estimated.     

Degradation of Escherichia coli DNA synthesized after ultraviolet irradiation in the absence of repair

DNA degradation in Escherichia coli uvrA recA bacteria exposed to a low dose (0.07 J/m2) of ultraviolet radiation was studied. A considerable amount of the newly-synthesized DNA, which contains gaps opposite pyrimidine dimers, is broken down. In contrast, parental, dimer-containing DNA is resistant to radiation-induced degradation.