The Escherichia coli heat shock protease HtrA participates in defense against oxidative stress

The serine protease HtrA (DegP), which is indispensable for cell survival at elevated temperatures, is a peripheral membrane protein, localized on the periplasmic side of the inner membrane in Escherichia coli, and the biochemical and genetic evidence indicates that the physiological role of HtrA is to degrade denatured proteins formed in the cellular envelope during heat shock. The aim of this study was to find out if the HtrA protease contributes to protection of the cell against oxidative stress. We compared the influence of various oxidizing agents on htrA mutant cells with their effects on wild-type bacteria, and found that the htrA mutation did not increase sensitivity to hydrogen peroxide or paraquat but made the cell extremely sensitive to ferrous [Fe(II)] ions, which are known to enhance oxidation of proteins. Treatment with ferrous ions caused a larger increase in the level of protein carbonyl groups in the membrane fraction of the cell than in the periplasm and cytoplasm. Iron-induced oxidation of membrane proteins was enhanced in the htrA mutant relative to wild-type cells. Inhibition of the growth of the htrA mutant by iron could be alleviated more efficiently by a nitroxide antioxidant that localizes in the membranes (A-TEMPO) than by a derivative (4OH-TEMPO) that acts mainly in the soluble fraction of the cell. Inhibition of the growth of the htrA mutant was more pronounced following treatment with cumene hydroperoxide, which partitions into membranes, than with t-butyl hydroperoxide, which forms radical mainly in the cytosol. Both ferrous ions and cumene hydroperoxide, but not hydrogen peroxide, paraquat or t-butyl hydroperoxide, induced synthesis of HtrA. Our results show that HtrA plays a role in defense against oxidative shock and support the hypothesis that HtrA participates in the degradation of oxidatively damaged proteins localized in the cell envelope, especially those associated with the membranes.     

The HtrA Protease of Campylobacter jejuni Is Required for Heat and Oxygen Tolerance and for Optimal Interaction with Human Epithelial Cells

Campylobacter jejuni is a predominant cause of food-borne bacterial gastroenteritis in the developed world. We have investigated the importance of a homologue of the periplasmic HtrA protease in C. jejuni stress tolerance. A C. jejuni htrA mutant was constructed and compared to the parental strain, and we found that growth of the mutant was severely impaired both at 44°C and in the presence of the tRNA analogue puromycin. Under both conditions, the level of misfolded protein is known to increase, and we propose that the heat-sensitive phenotype of the htrA mutant is caused by an accumulation of misfolded protein in the periplasm. Interestingly, we observed that the level of the molecular chaperones DnaK and ClpB was increased in the htrA mutant, suggesting that accumulation of nonnative proteins in the periplasm induces the expression of cytoplasmic chaperones. While lack of HtrA reduces the oxygen tolerance of C. jejuni, the htrA mutant was not sensitive to compounds that increase the formation of oxygen radicals, such as paraquat, cumene hydroperoxide, and H₂O₂. Using tissue cultures of human epithelial cells (INT407), we found that the htrA mutant adhered to and invaded human epithelial cells with a decreased frequency compared to the wild-type strain. This defect may be a consequence of the observed altered morphology of the htrA mutant. Thus, our results suggest that in C. jejuni, HtrA is important for growth during stressful conditions and has an impact on virulence.     

Experimental Evidence for the Physiological Role of Bacterial Luciferase in the Protection of Cells Against Oxidative Stress

The origin and function of bioluminescence was considered a problematic question of the Charles Darwin theory. Early evolution of bacterial luminescence and its current physiological importance seem to be especially mysterious. Recently, it was proposed that stimulation of DNA repair may be a physiological role for production of light by bacterial cells. On the other hand, it was also proposed that primary role of luminescent systems could be detoxification of the deleterious oxygen derivatives. Although some previous results might suggest that this hypothesis can be correct, until now experimental evidence for such a mechanism operating in bacterial cells and having physiological importance was generally lacking. Here we demonstrate that in the presence of various oxidants (hydrogen peroxide, cumene hydroperoxide, t-butyl hydroperoxide, and ferrous ions) at certain concentrations in the culture medium, growth of Vibrio harveyi mutants luxA and luxB, but not of the mutant luxD, is severely impaired relative to wild-type bacteria. This deleterious effect of oxidants on the mutants luxA and luxB could be significantly reduced by addition of the antioxidants A-TEMPO or 40H-TEMPO. We conclude that bacterial luciferase may indeed play a physiological role in the protection of cells against oxidative stress.     

Sensitivity of dark mutants of various strains of luminescent bacteria to reactive oxygen species

Recent studies indicated that bioluminescence of the marine bacterium Vibrio harveyi may both stimulate DNA repair and contribute to detoxification of deleterious oxygen derivatives. Therefore, it was also proposed that these reactions can be considered biological roles of bacterial luminescence and might act as evolutionary drives in development of luminous systems. However, experimental evidence for the physiological role of luciferase in protection of cells against oxidative stress has been demonstrated only in one bacterial species, raising the question whether this is a specific or a more general phenomenon. Here we demonstrate that in the presence of various oxidants (hydrogen peroxide, cumene hydroperoxide, t-butyl hydroperoxide and ferrous ions) growth of dark mutants of different strains of Vibrio fischeri and Photobacterium leiognathi is impaired relative to wild-type bacteria, though to various extents. Deleterious effects of oxidants on the mutants could be reduced (with different efficiency) by addition of antioxidants, A-TEMPO or 4OH-TEMPO. These results support the hypotheses that (1) activities of bacterial luciferases may detoxify deleterious oxygen derivatives, and (2) significantly different efficiencies of this reaction are characteristic for various luciferases.     

HtrA Is Essential for Efficient Secretion of Recombinant Proteins by Lactococcus lactis

HtrA is a unique protease on the extracellular surface of Lactococcus lactis. It is known to take part in the proteolysis of many secreted recombinant proteins, and the mutation of htrA can lead to the complete stabilization of recombinant proteins. In this work, we have shown that htrA mutation also leads to significant reduction of the efficiency of recombinant-protein secretion. We also show that the level of HtrA can be lowered by the suppression of the acid tolerance response (ATR) in L. lactis. Instead of using an L. lactis htrA mutant, the reduction of the HtrA level in wild-type recombinant cultures of L. lactis by ATR suppression may serve as a better strategy for the production of secreted recombinant proteins.     

Inverse correlation between cyclic GMP and tyrosine aminotransferase degradation in rat hepatoma tissue culture cells

[1,2-³H]Cholesterol was epoxidized to radioactive cholesterol α- and β-epoxides (5,6α-epoxy-5α- and 5,6β-epoxy-5β-cholestan-3β-ols) in the ratio 1:4 by hepatic microsomal lipid hydroperoxides (MsOOH, 1 mM as active oxygen) in the presence of ferrous ion. MsOOH could be replaced by methyl linoleate hydroperoxides (MOOH) under the same conditions although the latter was less effective than the former. None of cumene hydroperoxide, t-butyl hydroperoxide, and hydrogen peroxide was an effective oxidant even at 10 mM. Neither ADP nor EDTA had an effect on the epoxidation of cholesterol by MsOOH as well as by MOOH. Ferrous ion could not be replaced by ferric ion in the hydroperoxide-mediated epoxidation. Cyanide anion potentially inhibited the reaction.     

Clovamides; l-Dopa Conjugated with trans- and cis-Caffeic Acids in Red Clover (Trifolium pratense)

Selenium-independent glutathione peroxidase was purified from a cell-free extract of Mucor hiemalis by ammonium sulfate fractionation, column chromatographies on DEAE-Sephadex and hydroxylapatite, and gel filtration on Bio-Gel P-100. The purified enzyme was homogeneous on ultracentrifugation. The enzyme had a molecular weight of 45,000 and an isoelectric point of 5.2. The enzyme could reduce cumene hydroperoxide and t-butyl hydroperoxide, but could not reduce hydrogen peroxide. The enzyme was highly specific for glutathione as a hydrogen donor. Mucor glutathione peroxidase was proved to be different from mammalian selenium-dependent glutathione peroxidase I and selenium-independent glutathione peroxidase II in some physicochemical and enzymatic properties.     

Characterisation of worldwide Helicobacter pylori strains reveals genetic conservation and essentiality of serine protease HtrA

HtrA proteases and chaperones exhibit important roles in periplasmic protein quality control and stress responses. The genetic inactivation of htrA has been described for many bacterial pathogens. However, in some cases such as the gastric pathogen Helicobacter pylori, HtrA is secreted where it cleaves the tumour‐suppressor E‐cadherin interfering with gastric disease development, but the generation of htrA mutants is still lacking. Here, we show that the htrA gene locus is highly conserved in worldwide strains. HtrA presence was confirmed in 992 H. pylori isolates in gastric biopsy material from infected patients. Differential RNA‐sequencing (dRNA‐seq) indicated that htrA is encoded in an operon with two subsequent genes, HP1020 and HP1021. Genetic mutagenesis and complementation studies revealed that HP1020 and HP1021, but not htrA, can be mutated. In addition, we demonstrate that suppression of HtrA proteolytic activity with a newly developed inhibitor is sufficient to effectively kill H. pylori, but not other bacteria. We show that Helicobacter htrA is an essential bifunctional gene with crucial intracellular and extracellular functions. Thus, we describe here the first microbe in which htrA is an indispensable gene, a situation unique in the bacterial kingdom. HtrA can therefore be considered a promising new target for anti‐bacterial therapy.     

The relative effectiveness of human plasma glutathione peroxidase as a catalyst for the reduction of hydroperoxides by glutathione

To reveal clues to the function of human plasma glutathione peroxidase (GPx), we investigated its catalytic effectiveness with a variety of hydroperoxides. Comparisons of hydroperoxides as substrates for plasma GPx based on the ratio ofV _max /K _m were blocked by the limited solubility of the organic hydroperoxides, which prevented kinetic saturation of the enzyme at the chosen glutathione concentration. Therefore, we compared the hydroperoxides by the fold increase in the apparent first-order rate constants of their reactions with glutathione owing to catalysis by plasma GPx. The reductions of aromatic and small hydrophobic hydroperoxides (cumene hydroperoxide,t-amyl hydroperoxide,t-butyl hydroperoxide, paramenthane hydroperoxide) were better catalyzed by plasma GPx than were reductions of the more “physiological” substrates (linoleic acid hydroperoxide, hydrogen peroxide, peroxidized plasma lipids, and oxidized cholesterol).     

Killing bacterial spores by organic hydroperoxides

Killing of wild-type spores of Bacillus subtilis by t-butyl hydroperoxide, cumene hydroperoxide and peracetic acid was not through DNA damage, as shown by the absence of mutations in the survivors and the identical sensitivity of spores of strains with or without a recA mutation. In contrast, B. subtilis spores (termed α⁻β⁻) lacking the DNA protective α/β-type small, acid-soluble spore proteins (SASP) were more sensitive to t-butyl hydroperoxide and cumene hydroperoxide, and their killing was in large part through DNA damage, as shown by the high frequency of mutations in the survivors and the greater sensitivity of α⁻β⁻ recA spores. Analysis of t-butyl hydroperoxide-treated spores showed that generation of DNA damage in α⁻β⁻ spores was more rapid than in wild-type spores; α/β-type SASP also protected against DNA strand breakage in vitro caused by t-butyl hydroperoxide. α/β-Type SASP appeared to play no role in protection of spores from killing by peracetic acid; wild-type and α⁻β⁻ spores exhibited identical peracetic acid sensitivity and their killing by this agent appeared to be not through DNA damage. Received 17 December 1996/ Accepted in revised form 13 March 1997     

The HtrA protease of Campylobacter jejuni is required for heat and oxygen tolerance and for optimal interaction with human epithelial cells

Campylobacter jejuni is a predominant cause of food-borne bacterial gastroenteritis in the developed world. We have investigated the importance of a homologue of the periplasmic HtrA protease in C. jejuni stress tolerance. A C. jejuni htrA mutant was constructed and compared to the parental strain, and we found that growth of the mutant was severely impaired both at 44 degrees C and in the presence of the tRNA analogue puromycin. Under both conditions, the level of misfolded protein is known to increase, and we propose that the heat-sensitive phenotype of the htrA mutant is caused by an accumulation of misfolded protein in the periplasm. Interestingly, we observed that the level of the molecular chaperones DnaK and ClpB was increased in the htrA mutant, suggesting that accumulation of non-native proteins in the periplasm induces the expression of cytoplasmic chaperones. While lack of HtrA reduces the oxygen tolerance of C. jejuni, the htrA mutant was not sensitive to compounds that increase the formation of oxygen radicals, such as paraquat, cumene hydroperoxide, and H2O2. Using tissue cultures of human epithelial cells (INT407), we found that the htrA mutant adhered to and invaded human epithelial cells with a decreased frequency compared to the wild-type strain. This defect may be a consequence of the observed altered morphology of the htrA mutant. Thus, our results suggest that in C. jejuni, HtrA is important for growth during stressful conditions and has an impact on virulence.     

Cloning and phenotypic characterization of a gene enhancing resistance against oxidative stress in saccharomyces cerevisiae

A DNA fragment enhancing resistance against oxidative stress caused by several peroxides was cloned from the yeast Saccharomyces cerevisiae, and the corresponding gene was designated OSR; oxidative stress-resistant gene. By amplification of the OSR gene in the yeast cell, the transformant became resistant to tert-butyl hydroperoxide, linoleic acid hydroperoxide and hydrogen peroxide, whereas it became hypersensitive to cumene hydroperoxide. Thus, the dosage of the OSR gene in the yeast cell seemed to affect the behaviour of the transformant against peroxides. The resistance of the transformant was suppressed by the addition of buthionine sulfoximine, a potent inhibitor of glutathione biosynthesis, into a medium containing lipid hydroperoxide; thus a glutathione-dependent resistance mechanism was suggested to be concerned with the phenotype of the transformant.     

Analysis of a flagellar filament cap mutant reveals that HtrA serine protease degrades unfolded flagellin protein in the periplasm of Borrelia burgdorferi

Unlike external flagellated bacteria, spirochetes have periplasmic flagella (PF). Very little is known about how PF are assembled within the periplasm of spirochaetal cells. Herein, we report that FliD (BB0149), a flagellar cap protein (also named hook‐associated protein 2), controls flagellin stability and flagellar filament assembly in the Lyme disease spirochete Borrelia burgdorferi. Deletion of fliD leads to non‐motile mutant cells that are unable to assemble flagellar filaments and pentagon‐shaped caps (10 nm in diameter, 12 nm in length). Interestingly, FlaB, a major flagellin protein of B. burgdorferi, is degraded in the fliD mutant but not in other flagella‐deficient mutants (i.e., in the hook, rod, or MS‐ring). Biochemical and genetic studies reveal that HtrA, a serine protease of B. burgdorferi, controls FlaB turnover. Specifically, HtrA degrades unfolded but not polymerized FlaB, and deletion of htrA increases the level of FlaB in the fliD mutant. Collectively, we propose that the flagellar cap protein FliD promotes flagellin polymerization and filament growth in the periplasm. Deletion of fliD abolishes this process, which leads to leakage of unfolded FlaB proteins into the periplasm where they are degraded by HtrA, a protease that prevents accumulation of toxic products in the periplasm.     

Oxidation of dibenzothiophene catalyzed by immobilized hemoproteins in water-immiscible organic solvents

In various water-immiscible organic solvents, hemoglobin, myoglobin and cytochrome c deposited on Celite catalyzed the oxidation of dibenzothiophene when peroxides having nonpolar substituents, such as t-butyl hydroperoxide and cumene hydroperoxide (, -dimethylbenzyl hydroperoxide), were used as oxidants. In hexadecane, oxidation of dibenzothiophene by immobilized cytochrome c, with a K _m value of 0.15 mM for dibenzothiophene, was inhibited by cumene hydroperoxide above 0.5 mM.     

Extracellular HtrA serine proteases: An emerging new strategy in bacterial pathogenesis

The HtrA family of chaperones and serine proteases is important for regulating stress responses and controlling protein quality in the periplasm of bacteria. HtrA is also associated with infectious diseases since inactivation of htrA genes results in significantly reduced virulence properties by various bacterial pathogens. These virulence features of HtrA can be attributed to reduced fitness of the bacteria, higher susceptibility to environmental stress and/or diminished secretion of virulence factors. In some Gram‐negative and Gram‐positive pathogens, HtrA itself can be exposed to the extracellular environment promoting bacterial colonisation and invasion of host tissues. Most of our knowledge on the function of exported HtrAs stems from research on Helicobacter pylori, Campylobacter jejuni, Borrelia burgdorferi, Bacillus anthracis, and Chlamydia species. Here, we discuss recent progress showing that extracellular HtrAs are able to cleave cell‐to‐cell junction factors including E‐cadherin, occludin, and claudin‐8, as well as extracellular matrix proteins such as fibronectin, aggrecan, and proteoglycans, disrupting the epithelial barrier and producing substantial host cell damage. We propose that the export of HtrAs is a newly discovered strategy, also applied by additional bacterial pathogens. Consequently, exported HtrA proteases represent highly attractive targets for antibacterial treatment by inhibiting their proteolytic activity or application in vaccine development.     

Ferric iron and superoxide ions are required for the killing of cultured hepatocytes by hydrogen peroxide. Evidence for the participation of hydroxyl radicals formed by an iron-catalyzed Haber-Weiss reaction

Cultured hepatocytes pretreated with the ferric iron chelator deferoxamine were resistant to the toxicity of H2O2 generated by either glucose oxidase or by the metabolism of menadione (2-methyl-1,4-naphthoquinone). Ferric, ferrous, or cupric ions restored the sensitivity of the cells to H2O2. Deferoxamine added to hepatocytes previously treated with this chelator prevented the restoration of cell killing by only ferric iron. The free radical scavengers mannitol, thiourea, benzoate, and 4-methylmercapto-2-oxobutyrate protected either native cells exposed to H2O2 or pretreated hepatocytes exposed to H2O2 and given ferric or ferrous iron. Superoxide dismutase prevented the killing of native hepatocytes by either glucose oxidase or menadione. With deferoxamine-pretreated hepatocytes, superoxide dismutase prevented the cell killing dependent upon the addition of ferric but not ferrous iron. Catalase prevented the killing by menadione of deferoxamine-pretreated hepatocytes given either ferric or ferrous iron. Deferoxamine pretreatment did not prevent the toxicity of t-butyl hydroperoxide but did, however, prevent that of cumene hydroperoxide. It is concluded that both ferric iron and superoxide ions are required for the killing of cultured hepatocytes by H2O2. The toxicity of H2O2 is also dependent upon its reaction with ferrous iron to form hydroxyl radicals by the Fenton reaction. The ferrous iron needed for this reaction is formed by the reduction of cellular ferric iron by superoxide ions. Such a sequence corresponds to the so-called iron-catalyzed Haber-Weiss reaction, and the present report documents its participation in the killing of intact hepatocytes by H2O2. Cumene hydroperoxide but not t-butyl hydroperoxide closely models the toxicity of hydrogen peroxide.     

Detection of Picomole Levels in Lipid Hydroperoxides by a Chemiluminescence Assay

A highly sensitive and simple chemiluminescent method for the quantitation of lipid hydroperoxides at the picomole level is described. The method is based on detecting the chemiluminescence generated during the oxidation of luminol by the reaction with hydroperoxide and cytochrome c under mild conditions. A semilogarithmic relationship was observed between the hydroperoxide added and the chemiluminescence produced. For lipid hydroperoxides, cytochrome c was a most favorable catalyst for generating the chemiluminescence, rather than cytochrome c heme peptide and horseradish peroxidase. This method had high sensitivity to methyl linoleate hydroperoxide, arachidonic acid hydroperoxide and cholesterol hydroperoxide, but low to /-butyl hydroperoxide, J-butyl perbenzoate, diacyl peroxides (lauroyl peroxode and benzoyl peroxide) and dialkyl peroxides (di-/-butyl peroxide and dicumyl peroxide).     

The influence of HtrA expression on the growth of Streptococcus mutans during acid stress

When proteins are damaged under stresses conditions, these proteins are either refolded or degraded by quality control system of molecular chaperones and protease. High-temperature requirement A (htrA) is of particular interest because it can perform the roles of both protease and a chaperone. HtrA plays an important role in maintaining the physiological homeostasis of bacteri against environmental stress such as elevated temperature, oxidative and osmotic stress. Inactivation of htrA genes can thus restrict the survival ability of bacteria. These observations suggested that htrA might be responsible for acid tolerance of Streptococcus mutans. In this study, we have generated an htrA mutant and an htrA-complemented strain of S. mutans K7 isolated from a Korean in order to investigate the role of htrA in growth under acidic conditions. In terms of growth under cidic conditions, the htrA mutant exhibited 20% to 23% lower growth than the control group. In ddition, glucosyltransferaseB nd glucosyltransferaseC expression levels significantly decreased. When the htrA expression level was restored by adding the htrA gene to the htrA mutant strain, the normal growth phenotype was restored under acid stress. Further, similar results were obtained for S. mutans UA159. Thus, htrA in S. mutans K7, as well as S. mutans UA159, can be concluded to play an important role during acid stress.     

Studies on hydroperoxide-dependent substrate hydroxylation by purified liver microsomal cytochrome P-450.

Highly purified liver microsomal cytochrome P-450 catalyzes the hydroperoxide-dependent hydroxylation of a variety of substrates in the absence of NADPH, NADPH-cytochrome P-450 reductase, and molecular oxygen. The addition of phosphatidylcholine is necessary for maximal activity. The absence of flavoproteins and cytochrome b₅ from the cytochrome P-450 preparations rules out the involvement of other known microsomal electron carriers. The ferrous form of cytochrome P-450 is not involved in peroxide-dependent hydroxylation reactions, as indicated by the lack of inhibition by carbon monoxide. With cumene hydroperoxide present, a variety of substrates is attacked, including N-methylaniline, N,N-dimethylaniline, cyclohexane, benzphetamine, and aminopyrine. With benzphetamine as the substrate, cumene hydroperoxide may be replaced by other peroxides, including hydrogen peroxide, or by peracids or sodium chlorite. A study of the stoichiometry indicated that equimolar amounts of N-methylaniline, formaldehyde, and cumyl alcohol (α,α-dimethylbenzyl alcohol) are formed in the reaction of N,N-dimethylaniline with cumene hydroperoxide. Since H₂¹⁸O is incorporated only slightly into cyclohexanol in the reaction of cyclohexane with cumene hydroperoxide, it appears that the oxygen atom in cyclohexanol is derived primarily from the peroxide. The data obtained are in accord with a peroxidase-like mechanism for the action of cytochrome P-450.     

Bacillus subtilis paraquat resistance is directed by sigmaM, an extracytoplasmic function sigma factor, and is conferred by YqjL and BcrC

A Bacillus subtilis sigM null mutant, lacking the extracytoplasmic function sigma(M) protein, was sensitive to paraquat (PQ), a superoxide-generating reagent, but not to the redox stress-inducing compounds hydrogen peroxide, cumene hydroperoxide, t-butyl hydroperoxide, or diamide. Surprisingly, a sigM mutant was only sensitive to superoxide-generating compounds with a dipyridyl ring such as PQ, ethyl viologen, benzyl viologen, and diquat but not to menadione, plumbagin, pyrogallol, or nitrofurantoin. Mutational analysis of candidate sigma(M)-regulated genes revealed that both YqjL, a putative hydrolase, and BcrC, a bacitracin resistance protein, were involved in PQ resistance. Expression of yqjL, but not bcrC, from a xylose-inducible promoter restored PQ resistance to the sigM mutant.