Hydrogen peroxide-inducible proteins in Salmonella typhimurium overlap with heat shock and other stress proteins

Biochemical and antigenic characterization of the Mycobacterium tuberculosis 71kD antigen, a member of the 70kD heat-shock protein family

A 71 kiloDalton antigen from Mycobacterium tuberculosis is recognized by antibodies and by T lymphocytes during infection (Britton et al., 1986a). Partial sequence analysis indicates a relationship between this antigen and the highly conserved family of 70-kiloDalton heat shock proteins (hsp70) (Young et al., 1988). Biochemical and serological characterization of the protein confirms its membership of the hsp70 gene family, and metabolic labelling demonstrates that it is a major component of the mycobacterial response to heat stress. The role of stress proteins as antigens during infection is discussed.

Mutagenic lipid peroxides from edible oils

Weak mutagenic activity was detected in several commercially available edible palm and corn oils using liquid incubation bioassays with Salmonella typhimurium TA1537. Chromatographic fractionation of unrefined palm oil established that mutagenic activity was present in three fractions that also contained fatty acyl hydroperoxides. Similar weak mutagenic activity was also demonstrated for linoleic and linolenic acid hydroperoxides. In all cases, the mutagenicity was abolished by exogenous catalase, implying that the observed activity was moderated by hydrogen peroxide.

Hydrogen peroxide mutagenicity towards Salmonella typhimurium

In bioassays conducted under controlled, comparable conditions, weak direct mutagenicity responses were observed for hydrogen peroxide in the standard (Ames test) agar plate incorporation bioassay with Salmonella typhimurium strains TA97, TA98, TA102, and TA1537, in a 20 min preincubation test with strains TA97, TA98, TA100, TA102, TA1537, and TA1538, and in a liquid incubation modification using strain TA1537. These results conclusively demonstrate that hydrogen peroxide is a weak mutagen, especially in strains that are sensitive to oxidative damage under suitable bioassay conditions.

Bacterial genes involved in response to near-ultraviolet radiation

A model of the possible pathways of activities following NUV treatment was presented in Section I and in Fig. 1. Some of the components are firmly established, some are speculative, and many are difficult to evaluate because of insufficient experimental information. Perhaps the most relevant experiments, especially concerning ozone depletion, would be to determine the mutational specificity of NUV. By selecting lacI mutants after exposing cells to NUV, and sequencing the bases of this gene, this is now feasible. There are some problems, however. The mutation frequency is normally so low that it might be difficult to distinguish NUV mutants from spontaneous mutants. However, by irradiating cells having a uvrA or uvrB mutation, the frequency of mutation above background can be increased considerably. There remains the problem as to what fraction of the observed mutations results from oxidative damage. Some of this could be clarified by comparing mutation spectra of cells treated with NUV and cells subjected to excess oxidative damage and determining what fraction results from other avenues of lesion formation in DNA. Different species of reactive oxygen could cause different kinds of DNA lesions, and, fortunately, use of appropriate mutants should allow us to sort out any differences in specificity of lesions. Also, by appropriate manipulation of quantities of endogenous photosensitizers, it might be possible to sort out the specific mutations that are caused by photodynamic action. Another avenue of research is to explore the pathways by which NUV lesions are repaired, and whether such repair is error prone or error free. Again, the use of mutants such as xthA, uvr, and polA should assist in our understanding of the specificity of the mutational events. There are now a number of examples of global control mechanisms whereby cells abruptly shift their protein synthesis pattern under environmental stress. It is important to understand whether NUV stress results in induction of one or more of the known regulatory genes, or whether another regulon might be involved. One particular aspect of regulation that remains unsolved is the role of the katF gene, which is known to regulate the xthA and katE, but it may also regulate other genes as well. A number of striking physiological events occur even at very low fluences of NUV irradiation of cells. In part, this may be related to regulon induction. However, some of these events are in need of special exploration, such as changes at the membrane level.(ABSTRACT TRUNCATED AT 400 WORDS)

lac fusion analysis of the bet genes of Escherichia coli: regulation by osmolarity, temperature, oxygen, choline, and glycine betaine

The synthesis of glycine betaine, a powerful osmoprotectant, from its precursor, choline, is a function of the bet genes. The bet genes code for the high-affinity transport of choline and the enzymes for its conversion to glycine betaine. These genes map at 7.5 min on the E. coli chromosome and are contained on the conjugative plasmid F'2. To study the transcriptional regulation of the bet genes in response to various environmental conditions, a collection of 30 lac operon fusions was isolated by utilizing the bet genes contained on F'2. Four osmoregulated bet loci (betA, betB, betC, and betT) were identified based on biochemical, regulatory, and merodiploid analysis of these fusions. All of the bet fusions demonstrated a 7- to 10-fold increase in transcription in response to increases in the osmotic strength of the growth medium. Choline further induced expression of lac fusions at the betA, betB, and betT loci when the cells were grown under conditions of osmotic stress. The end product of the pathway, glycine betaine, was a corepressor of choline induction for fusions at the betA and betT loci. Expression of the betA, betB, and betT loci was reduced 7- to 10-fold under anaerobic conditions. In addition, expression of the betB and betT loci was reduced when the cells were grown in high osmolarity at 16 degrees C. These studies demonstrate that the expression of the bet genes is under the control of several environmental stimuli.

Nucleotide sequence of katG, encoding catalase HPI of Escherichia coli

The gene katG, encoding catalase HPI of Escherichia coli, was sequenced, predicting a 726-amino-acid protein. The sequence was confirmed by identification of potential regulatory elements and amino acid sequencing of peptides. HPI shows no homology to other catalases. The distances between katG, metF, and ppc were defined.

Starvation-induced cross protection against heat or H2O2 challenge in Escherichia coli

Glucose- or nitrogen-starved cultures of Escherichia coli exhibited enhanced resistance to heat (57 degrees C) or H2O2 (15 mM) challenge, compared with their exponentially growing counterparts. The degree of resistance increased with the time for which the cells were starved prior to the challenge, with 4 h of starvation providing the maximal protection. Protein synthesis during starvation was essential for these cross protections, since chloramphenicol addition at the onset of starvation prevented the development of thermal or oxidative resistance. Starved cultures also demonstrated stronger thermal and oxidative resistance than did growing cultures adapted to heat, H2O2, or ethanol prior to the heat or H2O2 challenge. Two-dimensional gel electrophoresis of 35S-pulse-labeled proteins showed that subsets of the 30 glucose starvation proteins were also synthesized during heat or H2O2 adaptation; three proteins were common to all three stresses. Most of the common proteins were among the previously identified Pex proteins (J.E. Schultz, G. I. Latter, and A. Matin, J. Bacteriol. 170:3903-3909, 1988), which are independent of cyclic AMP positive control for their induction during starvation. Induction of starvation proteins dependent on cyclic AMP was not important in these cross protections, since a delta cya strain of E. coli K-12 exhibited the same degree of resistance to heat or H2O2 as the wild-type parent did during both growth and starvation.

Transcriptional regulation of katE in Escherichia coli K-12

Escherichia coli produces two distinct species of catalase, hydroperoxidases I and II, which differ in kinetic properties and regulation. To further examine catalase regulation, a lacZ fusion was placed into one of the genes that is involved in catalase synthesis. Transductional mapping revealed the fusion to be either allelic with or very close to katE, a locus which together with katF controls the synthesis of the aerobically inducible hydroperoxidase (hydroperoxidase II). katE was expressed under anaerobic conditions at levels that were approximately one-fourth of those found in aerobically grown cells and was found to be induced to higher levels in early-stationary-phase cells relative to levels of exponentially growing cells under both anaerobic and aerobic conditions. katE was fully expressed in air and was not further induced when the growth medium was sparged with 100% oxygen. Expression of katE was unaffected by the addition of hydrogen peroxide or by the presence of additional lesions in oxyR or sodA, indicating that it is not part of the oxyR regulon. When katF::Tn10 was introduced into a katE::lacZ strain, beta-galactosidase synthesis was largely eliminated and was no longer inducible, suggesting that katF is a positive regulator of katE expression.

Sequence of the Saccharomyces cerevisiae CTA1 gene and amino acid sequence of catalase A derived from it

The nucleotide sequence of a 2785-base-pair stretch of DNA containing the Saccharomyces cerevisiae catalase A (CTA1) gene has been determined. This gene contains an uninterrupted open reading frame encoding a protein of 515 amino acids (relative molecular mass 58,490). Catalase A, the peroxisomal catalase of S. cerevisiae was compared to the peroxisomal catalases from bovine liver and from Candida tropicalis and to the non-peroxisomal, presumably cytoplasmic, catalase T of S. cerevisiae. Whereas the peroxisomal catalases are almost colinear, three major insertions have to be introduced in the catalase T sequence to obtain an optimal fit with the other proteins. Catalase A is most closely related to the C. tropicalis enzyme. It is also more similar to the bovine liver catalase than to the second S. cerevisiae catalase. The differences between the two S. cerevisiae enzymes are most striking within four blocks of amino acids consisting of a total of 37 residues with high homology between the three peroxisomal, but low conservation between the S. cerevisiae catalases. The results obtained indicate that the peroxisomal catalases compared have very similar three-dimensional structures and might have similar targeting signals.

Isolation of gene fusions (soi::lacZ) inducible by oxidative stress in Escherichia coli

Mu dX phage was used to isolate three gene fusions to the lacZ gene (soi::lacZ; soi for superoxide radical inducible) that were induced by treatment with superoxide radical anion generators such as paraquat and plumbagin. The induction of beta-galactosidase in these fusion strains with the superoxide radical generating agents required aerobic metabolism. Hyperoxygenation (i.e., bubbling of cultures with oxygen gas) also induced the fusions. On the other hand, hydrogen peroxide did not induce the fusions at concentrations that are known to invoke an adaptive response. Introduction of oxyR, htpR, or recA mutations did not affect the induction. Two of the fusion strains exhibited increased sensitivity to paraquat but not to hydrogen peroxide. The third fusion strain showed no increased sensitivity to either agent. All three fusions were located in the 45- to 61-min region of the Escherichia coli chromosome.

Transcriptional and posttranscriptional regulation of manganese superoxide dismutase biosynthesis in Escherichia coli, studied with operon and protein fusions

Protein and operon fusions between the manganese superoxide dismutase (MnSOD) gene, sodA, and genes of the lactose operon were constructed in an attempt to explore the effects of various factors on MnSOD expression and the level at which they operate. In sodA-lacZ protein fusions, induction of beta-galactosidase perfectly mimicked MnSOD induction (i.e., beta-galactosidase was not expressed in anaerobiosis and was induced by oxygen, redox-cycling compounds in aerobiosis, and iron chelators in anaerobiosis). In tac-sodA operon fusions, MnSOD induction was monitored only by the lactose operon inducer isopropyl-beta-D-thiogalactopyranoside. Various plasmids carrying part or all of the sodA regulatory and structural region inhibited aerobic beta-galactosidase induction in sodA-lacZ fusions. This included plasmids carrying only the transcription start and upstream region and also plasmids which did not contain this region and in which MnSOD was under foreign transcriptional control. The role of metal ions was also investigated. Addition of Mn(II) enhanced MnSOD activity but did not affect induction. The anaerobic expression of MnSOD from the oxygen-insensitive tac promoter was enhanced threefold by iron-chelating agents, implying a posttranscriptional or most likely a posttranslational modulation of enzyme activity via metal ions. To accommodate all these data, multiregulation of MnSOD is proposed.

Stress proteins are immune targets in leprosy and tuberculosis

To understand the immune response to infection by tuberculosis and leprosy bacilli and to develop improved vaccines, the nature of antigens that are involved in humoral and cell-mediated immunity was investigated. We have determined that five immunodominant protein antigens under study are homologues of stress proteins. This finding and observations with other pathogens suggest that infectious agents may respond to the host environment by producing stress proteins and that these proteins can be important immune targets. We postulate that abundant and highly conserved stress proteins may have "immunoprophylactic" potential for a broad spectrum of human pathogens.

Near-UV stress in Salmonella typhimurium: 4-thiouridine in tRNA, ppGpp, and ApppGpp as components of an adaptive response

We have examined the role of 4-thiouridine in the responses of Salmonella typhimurium to near-UV irradiation. Mutants lacking 4-thiouridine (nuv) and mutants defective in the synthesis of ppGpp (guanosine 5'-diphosphate-3'-diphosphate) (relA) were found to be sensitive to killing by near-UV. Near-UV induced the synthesis of a set of proteins that were not induced in the nuv mutant. Some of these proteins were identified as oxidative defense proteins, and others were identified as ppGpp-inducible proteins. Over 100-fold increases in ApppGpp (adenosine 5', 5"'-triphosphoguanosine-3"'-diphosphate, the adenylylated form of ppGpp) were observed in wild-type cells after near-UV irradiation but not in the 4-thiouridine-deficient mutant. These data support a model in which ppGpp and ApppGpp, a dinucleotide proposed to be synthesized by tRNA-aminoacyl synthetases as a response to the cross-linking of 4-thiouridine in tRNA by near-UV, induce the synthesis of proteins necessary for resistance to near-UV irradiation.

Hydrogen peroxide (H2O2) induces actin and some heat-shock proteins in Drosophila cells

Drosophila cells of a clone derived from line Kc were treated with various concentrations of hydrogen peroxide (H2O2). The concentration of 10 mM was lethal, whereas concentrations of 1-100 microM did not affect cell viability, rate of multiplication or protein synthesis. The intermediate concentration of 1 mM H2O2 was used to study the response of the cells to an oxidative stress. We observed a transitory decrease of the global protein synthesis, which was accompanied by changes in the polypeptide pattern. There was a 2.5-fold increase of the synthesis of the heat-shock proteins 70-68 and 23. The most prominent response was a 6.5-fold increase of actin synthesis 3 h after a 1 mM H2O2 treatment. When aminotriazole (an inhibitor of catalase) was added in association with H2O2, the increase of actin synthesis became 8.5-fold. Experiments in which catalase was added at various times after H2O2 showed that a 10-min treatment with H2O2 was sufficient to induce actin and heat-shock protein synthesis 3 h later. H2O2 was shown to induce the transcriptional activation of an actin gene and of the heat-shock protein genes 70 and 23 within minutes. These results are coherent with the hypothesis that the byproducts of O2 reduction (the superoxide ion and hydrogen peroxide) could be inducers of the heat-shock response. Whether the increase of actin synthesis is a stress-related response, and the mode of action of H2O2 are discussed.

Stress proteins and the immune response to mycobacteria--antigens as virulence factors?

The immune response to mycobacterial infection includes pathogenic as well as protective activities. It is possible that different types of immune responses are associated with recognition of different antigenic determinants. Amongst the antigens which are prominent in antibody and T cell recognition of mycobacteria, we have identified members of highly conserved stress protein families. Mapping of antigenic determinants on stress proteins shows that both species-specific and conserved regions of these proteins can take part in immune recognition. Induction of an immune response to conserved, "self-like", determinants on stress proteins could play a role in the immunopathology associated with chronic mycobacterial infections.

Two-dimensional gel electrophoretic analysis of Escherichia coli proteins: influence of various anaerobic growth conditions and the fnr gene product on cellular protein composition

Two-dimensional gel electrophoresis was used to examine the response of the cellular proteins of Escherichia coli to various anaerobic growth conditions and to the presence or absence of a functional Fnr protein. The steady-state levels of 125 polypeptides were found to vary in either a positive or negative manner, with many polypeptides being affected under a number of conditions. A large number (21) of the anaerobically inducible polypeptides were shown to be totally independent of the presence of Fnr while 22 were shown to be reduced in a fnr mutant under all anaerobic growth conditions tested. A total of 8 proteins were shown to be reduced in a fnr mutant only in aerobically grown cells indicating that the Fnr protein has a function in the presence of oxygen. This was further confirmed by the observation that 15 anaerobically inducible polypeptides were also found to show an increase in aerobically grown cells, however, only in a fnr strain. This latter finding implies that Fnr may also exhibit repressor function. This effect of Fnr-dependent repression was also observed with several polypeptides in anaerobically grown cells.

Oxidative stress and growth temperature in Bacillus subtilis

Pretreatment of Bacillus subtilis with low concentrations of hydrogen peroxide protected the cells against the lethal effects of higher levels of oxidative stress. During the period of adaptation, eight proteins were induced, as detected by one-dimensional gel electrophoresis. Four of these proteins were the same size as four of the proteins induced by the temperature upshift. The range of proteins synthesized in response to an elevation in temperature depended both on the starting (lower) temperature and on the temperature to which the cells were shifted. Both catalase and superoxide dismutase were present at high levels in B. subtilis, but neither was induced by oxidative stress or temperature upshift. In fact, catalase activity was reduced after the temperature upshift.

Spontaneous mutagenesis and oxidative damage to DNA in Salmonella typhimurium

Salmonella typhimurium strains containing deletions of oxyR, a positive regulator of defenses against oxidative stress, show 10- to 55-fold higher frequencies of spontaneous mutagenesis compared to otherwise isogenic oxyR+ control strains. The high spontaneous-mutation frequency in oxyR deletion strains is decreased by a factor of 3 when the strains are grown anaerobically. oxyR deletion strains show an increase in small deletion mutations and at least three of the six possible base-substitution mutations (T.A to A.T, C.G to T.A, and C.G to A.T). However, the largest increase in mutation frequency is observed for T.A to A.T transversions (40- to 146-fold), the base-substitution mutation most frequently caused by chemical oxidants. The introduction into oxyR deletion strains of multicopy plasmids carrying the oxyR-regulated genes for catalase (katG) or alkyl hydroperoxide reductase (ahp) results in overexpression of the respective enzyme activities and decreases the number of spontaneous mutants to wild-type levels. The introduction into oxyR deletions of a plasmid carrying the gene for superoxide dismutase (sodA) decreases the mutation frequency by a factor of 5 in some strain backgrounds. Strains that contain a dominant oxyR mutation and overexpress proteins regulated by oxyR show lower spontaneous-mutation frequencies by a factor of 2. These results indicate that oxyR and oxyR-regulated genes play a significant role in defense against spontaneous oxidative DNA damage. The role of oxidative damage to DNA in "spontaneous" mutagenesis is discussed.

The 1987 Walter Hubert lecture. Regulation and deficiencies in DNA repair

A number of rare human inherited syndromes are associated with apparent defects in DNA repair and a greatly increased frequency of cancer. Cell lines derived from such individuals phenotypically resemble certain bacterial mutant strains that have increased sensitivity to radiation or chemical agents and well characterised repair defects. This analogy provides leads for unravelling the molecular alterations in such cancer-prone human cells. The inducibility of DNA repair enzymes is also reviewed. Exposure of bacteria to alkylating agents, or oxygen radicals, causes the overproduction of several novel and interesting repair activities, and the induced bacteria provide an abundant source of these proteins for purification and biological characterisation. Enzymes with the same defined specificities are often present in human cells, presumably serving the same functions as in microorganisms, but these activities are only constitutively expressed at low levels.

Mutagenesis and stress responses induced in Escherichia coli by hydrogen peroxide

Killing of Escherichia coli by hydrogen peroxide proceeds by two modes. Mode one killing appears to be due to DNA damage, has a maximum near 1 to 3 mM H2O2, and requires active metabolism during exposure. Mode two killing is due to uncharacterized damage, occurs in the absence of metabolism, and exhibits a classical multiple-order dose-response curve up to at least 50 mM H2O2 (J. A. Imlay and S. Linn, J. Bacteriol. 166:519-527, 1986). H2O2 induces the SOS response in proportion to the degree of killing by the mode one pathway, i.e., induction is maximal after exposure to 1 to 3 mM H2O2. Mutant strains that cannot induce the SOS regulon are hypersensitive to peroxide. Analysis of the sensitivities of mutants that are deficient in individual SOS-regulated functions suggested that the SOS-mediated protection is due to the enhanced synthesis of recA protein, which is rate limiting for recombinational DNA repair. Specifically, strains wholly blocked in both SOS induction and DNA recombination were no more sensitive than mutants that are blocked in only one of these two functions, and strains carrying mutations in uvrA, -B, -C, or -D, sfiA, umuC or -D, ssb, or dinA, -B, -D, -F, -G, -H, -I, or -J were not abnormally sensitive to killing by H2O2. After exposure to H2O2, mutagenesis and filamentation also occurred with the dose response characteristic of SOS induction and mode one killing, but these responses were not dependent on the lexA-regulated umuC mutagenesis or sfiA filamentation functions, respectively. Exposure of E. coli to H2O2 also resulted in the induction of functions under control of the oxyR regulon that enhance the scavenging of active oxygen species, thereby reducing the sensitivity to H2O2. Catalase levels increased 10-fold during this induction, and katE katG mutants, which totally lack catalase, while not abnormally sensitive to killing by H2O2 in the naive state, did not exhibit the induced protective response. Protection equal to that observed during oxyR induction could be achieved by the addition of catalase to cultures of naive cells in an amount equivalent to that induced by the oxyR response. Thus, the induction of catalase is necessary and sufficient for the observed oxyR-directed resistance to killing by H2O2. Although superoxide dismutase appeared to be uninvolved in this enhanced protective response, sodA sodB mutants, which totally lack superoxide dismutase, were especially sensitive to mode one killing by H2O2 in the naive state. gshB mutants, which lack glutathione, were not abnormally sensitive to killing by H2O2.

Hydrogen peroxide or heat shock induces resistance to hydrogen peroxide in Chinese hamster fibroblasts

Survival after H2O2 exposure or heat shock of asynchronous Chinese hamster ovary cells (HA-1) was assayed following pretreatment with mildly toxic doses of either H2O2 or hyperthermia. H2O2 cytotoxicity at 37 degrees C, expressed as a function of mM H2O2 was found to be dependent on cell density at the time of treatment. The density dependence reflected the ability of cells to reduce the effectiveness of H2O2 as a cytotoxic agent. When the survival data were plotted as a function of mumoles H2O2/cell at the beginning of the treatment, survival was independent of cell density. Cells pretreated with 0.1 mM (3-5 mumoles/cell X 10(-7)) H2O2 for 1 hr at 37 degrees C (30-50% survival) became resistant to a subsequent H2O2 treatment 16-36 hr after pretreatment [dose modifying factor (DMF) at 1% isosurvival = 4-6]. Their resistance to 43 degrees C heating, however, was only slightly increased over controls 16-36 hr following pretreatment (DMF at 1% isosurvival = 1.2). During this same interval, the synthesis of protein migrating in the 70 kD region of a one-dimensional SDS-polyacrylamide gel was enhanced twofold in the H2O2-pretreated cells. When the cells were heated for 15 min at 45 degrees C (40-60% survival), the survivors became extremely resistant to 43 degrees C heating and somewhat resistant to H2O2 (DMF at 1% isosurvival = 2). The heat-induced resistance to heat developed much more rapidly (reached a maximum between 6 and 13 hr) following pretreatment than the heat-induced resistance to H2O2 (16-36 hr). The enhanced synthesis of 70 kD protein after heat shock was greater in magnitude and occurred more rapidly following preheating than following H2O2 pretreatment. The cells that became resistant to H2O2 by either pretreatment (H2O2 or heat shock) also increased their ability to reduce the H2O2 cytotoxicity from the treatment medium beyond that of the untreated HA-1 cells. This may be one of the mechanisms involved in the increased resistance and a common adaptive mechanism induced by both stresses. These data indicate that mammalian cells develop resistance to H2O2 following mild pretreatment with H2O2 or heat shock. The cross-resistance induced by H2O2 and heat shock reinforce the hypothesis that some overlap in mechanisms exist between the cellular responses to these two stresses. However, the failure of H2O2 pretreatment to induce much resistance to heat indicates that there are also differences in the actions of the two agents.

Induction of superoxide dismutase in Escherichia coli by heat shock

Exposure of midlogarithmic-phase cultures of Escherichia coli B to 48 degrees C for 1 hr elicited an induction of the manganese-containing superoxide dismutase (MnSOD), which became more pronounced during 1 hr of recovery at 37 degrees C. This induction required protein biosynthesis, since it was suppressed by chloramphenicol. Induction of MnSOD appeared to be a response to a heat-mediated increase in O2- production because it was dioxygen-dependent and because heating to 48 degrees C doubled the cyanide-resistant fraction of the total respiration.

Endonuclease IV of Escherichia coli is induced by paraquat

The addition of paraquat (methyl viologen) to a growing culture of Escherichia coli K-12 led within 1 hr to a 10- to 20-fold increase in the level of endonuclease IV, a DNase for apurinic/apyrimidinic sites. The induction was blocked by chloramphenicol. Increases of 3-fold or more were also seen with plumbagin, menadione, and phenazine methosulfate. H2O2 produced no more than a 2-fold increase in endonuclease IV activity. The following agents had no significant effect: streptonigrin, nitrofurantoin, tert-butyl hydroperoxide, gamma rays, 260-nm UV radiation, methyl methanesulfonate, mitomycin C, and ascorbate. Paraquat, plumbagin, menadione, and phenazine methosulfate are known to generate superoxide radical anions via redox cycling in vivo. A mutant lacking superoxide dismutase was unusually sensitive to induction by paraquat. In addition, endonuclease IV could be induced by merely growing the mutant in pure O2. The levels of endonuclease IV in uninduced or paraquat-treated cells were unaffected by mutations of oxyR, a H2O2-inducible gene that governs an oxidative-stress regulon. The results indicate that endonuclease IV is an inducible DNA-repair enzyme and that its induction can be mediated via the production of superoxide radicals.

Oxidative mechanisms of toxicity of low-intensity near-UV light in Salmonella typhimurium

The exposure of Salmonella typhimurium to environmentally relevant near-UV light stress has been studied by the use of a low-intensity, broad-band light source. The exposure of cells to such a light source rapidly induced a growth delay; after continuous exposure for 3 to 4 h, cells began to die at a rapid rate. The oxidative defense regulon controlled by the oxyR gene was involved in protecting cells from being killed by near-UV light. This killing may be potentiated by the overexpression of near-UV-absorbing proteins. These results are consistent with near-UV toxicity involving the absorption of light by endogenous photosensitizers, leading to the production of active oxygen species. We have shown, however, that one such species, H2O2, is not a major photoproduct involved in killing by near-UV light. Strains lacking alkyl hydroperoxide reductase were more sensitive to near-UV light, indicating that such hydroperoxides may be photoproducts. Near-UV exposure induced sensitivity to high salt levels, indicating that membranes may be a target of near-UV toxicity and a possible source of alkyl hydroperoxides. The demonstration of the inactivation of the heme-containing protein catalase indicates that direct destruction of UV-absorbing macromolecules could be another factor in near-UV toxicity. Cells which have been exposed to near-UV light for long, but sublethal, periods of time (up to 4 h) can recover and resume growth if the UV exposure is stopped but become progressively more sensitive to further stresses, such as H2O2. This result indicates that cells gradually accumulated damage during near-UV exposure until toxic levels were reached.

Mutagenic and lethal effects of near-ultraviolet radiation (290-400 nm) on bacteria and phage

Despite decades of study of the effect of near-ultraviolet radiation (NUV) on bacterial cells, insights into mechanisms of deleterious alterations and subsequent recovery are just now emerging. These insights are based on observations that 1) damage by NUV may be caused by a reactive oxygen molecule, since H2O2 may be a photoproduct of NUV; 2) some, but not all, of the effects of NUV and H2O2 are interchangeable; 3) there is an inducible regulon (oxyR) that responds to oxidative stress and is involved in protection against NUV; 4) a number of NUV-sensitive mutants are defective either in the capacity to detoxify reactive oxygen molecules or to repair DNA damage caused by NUV; and 5) recovery from NUV damage may not directly involve induction of the SOS response. Since several distinctly different photoreceptors and targets are involved, it is unknown whether NUV lethality and mutagenesis result from an accumulation of damages or whether there is a particularly critical photoeffect. To fully understand the mechanisms involved, it is important to identify the chromophore(s) of NUV, the mechanism of toxic oxygen species generation, the role of the oxidative defense regulon (oxyR), the specific lesions in the DNA, and the enzymatic events of subsequent repair.