The fluorescence intensity of the lipophilic probe N-phenyl-1-naphthylamine responds to the oxidation-reduction state of purified Escherichia coli cytochrome o incorporated into phospholipid vesicles

N-Phenyl-1-naphthylamine (NPN), a reagent which has been used previously to probe the fluidity or microviscosity of the membrane lipids of intact cells of Escherichia coli, was found to respond to the redox state of purified cytochrome o incorporated into lipid vesicles formed from purified or E. coli phospholipids. NPN was bound to the proteoliposomes to produce a steady-state level of fluorescence intensity. Addition of the substrate ascorbate, in the presence of phenazine methosulfate as an electron donor, did not alter the fluorescence. However, following complete removal of oxygen from the medium by oxidation of the substrate by molecular oxygen catalyzed by cytochrome o, there was an increase in the fluorescence of NPN. This coincided with the reduction of cytochrome o. Reoxidation of the cytochrome by addition of oxygen decreased the fluorescence to steady-state levels until the oxidant had been completely reduced. The fluorescence changes were dependent on the incorporation of cytochrome o into phospholipid vesicles but were insensitive to the state of energization of the vesicle membrane.     

Evolutionary rates for tuf genes in endosymbionts of aphids

The gene encoding elongation factor Tu (tuf) in aphid endosymbionts (genus Buchnera) evolves at rates of 1.3 x 10(-10) to 2.5 x 10(-10) nonsynonymous substitutions and 3.9 x 10(-9) to 8.0 x 10(-9) synonymous substitutions per position per year. These rates, which are at present among the most reliable substitution rates for protein-coding genes of bacteria, have been obtained by calibrating the nodes in the phylogenetic tree produced from the Buchnera EF-Tu sequences using divergence times for the corresponding ancestral aphid hosts. We also present data suggesting that the rates of nonsynonymous substitutions are significantly higher in the endosymbiont lineages than in the closely related free-living bacteria Escherichia coli and Salmonella typhimurium. Synonymous substitution rates for Buchnera approximate estimated mutation rates for E. coli and S. typhimurium, as expected if synonymous changes act as neutral mutations in Buchnera. We relate the observed differences in substitution frequencies to the absence of selective codon preferences in Buchnera and to the influence of Muller's ratchet on small asexual populations.      

Long-term effects of physical training programme on risk factors for coronary heart disease in otherwise sedentary men.

Three hundred and seventy sedentary men aged 20-65 years enrolled in a physical training programme after a medical and fitness examination that included measurements of "classical" risk factors for coronary heart disease. Five years later re-examination showed (a) that on average the subjects had not changed significantly in weight, blood pressure, serum lipid concentrations, smoking habits, and physical working capacity; (b) that men who had remained active and therefore had a higher degree of fitness did not differ in risk factors from men who had returned to sedentary habits; and (c) that men who had improved substantially in fitness did not differ in risk factors from men whose fitness had not changed or had declined. Five years after the initial programme one-third of the men were continuing with regular vigorous exercise. These results do not support the view that classical risk factors for coronary heart disease improve with increased physical activity and fitness.     

Lysogenic induction of lambdoid phages in lexA mutants of Escherichia coli

Summary UV irradiation of lexA3 mutants of E. coli caused lysogenic induction of prophage , _i21, _i434 and 80. Maximal induction in lexA3 lysogens needed less UV than in lexA ⁺ bacteria and gave 25–100% of the normal levels of infective centres induced. Assays of gene expression arising from derepression of a defective prophage showed at least 40% of the normal levels of induction by mitomycin C in lexA3 bacteria. The need for post-irradiation protein synthesis for lysogenic induction in lexA3 lysogens was reduced by increasing the basal level of recA protein with a recA ⁺ plasmid. It is concluded that in lexA E. coli some recA protein synthesis, too small to be detected by physical means, is needed for UV induced lysogenic induction.     

Different mechanisms for SOS induced alleviation of DNA restriction in Escherichia coli.

The alleviation of DNA restriction during the SOS response in Escherichia coli has been further investigated. With the EcoK DNA restriction system UV irradiated wild-type cells show a 10(4)-fold increase in ability to plate non-modified lambda phage and a 3-4 fold increase in transformation by non-modified plasmid DNA. A role for the umuDC genes of E coli in the process of SOS-induced restriction alleviation was identified by showing that a umuC122::Tn5 mutant could alleviate EcoK restriction to only 5% that of wild-type levels. Although umuDC are better characterized for their pivotal role in SOS induced mutagenesis, it is demonstrated here that umu-dependent alleviation of EcoK restriction is a transient process in which umu-dependent mutagenesis plays little part. A second form of SOS induced alleviation of DNA restriction is described in this paper involving the McrA restriction system. The mcrA gene is shown to be encoded within a defective prophage called e14 situated at the 25 min region on the Escherichia coli genetic map. e14 is known to abortively excise from the chromosome after SOS induction and it is demonstrated in this report that mcrA is lost from the genome after SOS induction as part of e14. This results in co-ordinate decrease in the level of McrA restriction within a population of cells.     

Alleviation of EcoK DNA restriction in Escherichia coli and involvement of umuDC activity.

Summary The activity of the EcoK DNA restriction system of Escherichia coli reduces both the plating efficiency of unmodified phage and the transforming ability of unmodified pBR322 plasmid DNA. However, restriction can be alleviated in wild-type cells, by UV irradiation and expression of the SOS response, so that 10³-to 10⁴-fold increases in phage growth and fourfold increases in plasmid transformation occurred with unmodified DNA. Restriction alleviation was found to be a transient effect because induced cells, which initially failed to restrict unmodified plasmid DNA, later restricted unmodified phage . Although the SOS response was needed for restriction alleviation, constitutive SOS induction, elicited genetically with a recA730 mutation, did not alleviate restriction and UV irradiation was still needed. A hitherto unsuspected involvement of the umuDC operon in this alleviation of restriction is characterized and, by differential complementation, was separated from the better known role of umuDC in mutagenic DNA repair. The need for cleavage of UmuD for restriction alleviation was shown with plasmids encoding cleavable, cleaved, and non-cleavable forms of UmuD. However, UV irradiation was still needed even when cleaved UmuD was provided. The possibility that restriction alleviation occurs by a general inhibition of the EcoK restriction/modification complex was tested and discounted because modification of was not reduced by UV irradiation. An alternative idea, that restriction activity was competitively reduced by an increase in EcoK modification, was also discounted by the lack of any increase in the modification of Ral^–, a naturally undermodified phage. Other possible mechanisms for restriction alleviation are discussed.     

The effect of new potent selective inhibitors of protein kinase C on the neutrophil respiratory burst

New potent inhibitors of protein kinase C were found to inhibit protein kinase C isolated from rat brain and human neutrophils, with a large degree of selectivity over cAMP-dependent kinase and Ca2+/calmodulin-dependent kinase. These novel compounds were potent inhibitors of the fluoride, diC8- and formyl-methionyl-leucyl-phenylalanine-mediated respiratory bursts in intact neutrophils. The opsonized zymosan-stimulated burst was only marginally affected by the compounds. These results differ from those obtained in studies with H7 and CI, (which are less potent and less specific protein kinase C inhibitors) and are consistent with the hypothesis that protein kinase C has a role in the transduction mechanism for the neutrophil oxidative burst stimulated with fluoride, formyl-methionyl-leucyl-phenylalanine and diC8.     

Molecular cloning of a gene which regulates the adaptive response to alkylating agents in Escherichia coli

Summary The ada ⁺ gene of E. coli is a regulatory gene of the adaptive response to simple alkylating agents. ada mutants are sensitive to both the mutagenicity and toxicity of alkylating agents, and are unable to induce O⁶-methylguanine DNA methyltransferase and 3-methyladenine DNA glycosylase II. The ada ⁺ gene was cloned from wild type E. coli B by ligating bacterial DNA partially digested with Sau3A into the cosmid vector pJB8. The hybrid cosmid, pCS33, conveyed N-methyl-N-nitro-N-nitrosoguanidine resistance to ada mutants of E. coli B and E. coli K12, and resulted in the constitutive synthesis of the two DNA repair enzymes at high levels. An alk mutation, which results in a deficiency of only the DNA glycosylase, was not complemented by this cosmid. It was concluded that the product of the ada ⁺ gene is a positive regulator of the adaptive response. The cosmid insert DNA was subcloned into the plasmid vector pAT153, and the ada ⁺ plasmids pCS42 and pCS58 selected. The ada ⁺ gene located in PCS58 by transposon mutagenesis and subcloning. Two polypeptides of Mr 37,000 and 27,000, were identified in maxicells as products of the ada ⁺ gene(s). It is as yet unclear whether they represent different forms of the same gene product, or are encoded by separate ada ⁺ genes within the same operon.