Evidence for three differentially regulated catalase genes in Neurospora crassa: effects of oxidative stress, heat shock, and development

Understanding the structure and function of catalases: clues from molecular evolution and in vitro mutagenesis

This review gives an overview about the structural organisation of different evolutionary lines of all enzymes capable of efficient dismutation of hydrogen peroxide. Major potential applications in biotechnology and clinical medicine justify further investigations. According to structural and functional similarities catalases can be divided in three subgroups. Typical catalases are homotetrameric haem proteins. The three-dimensional structure of six representatives has been resolved to atomic resolution. The central core of each subunit reveals a characteristic "catalase fold", extremely well conserved among this group. In the native tetramer structure pairs of subunits tightly interact via exchange of their N-terminal arms. This pseudo-knot structures implies a highly ordered assembly pathway. A minor subgroup ("large catalases") possesses an extra flavodoxin-like C-terminal domain. A > or = 25 A long channel leads from the enzyme surface to the deeply buried active site. It enables rapid and selective diffusion of the substrates to the active center. In several catalases NADPH is tightly bound close to the surface. This cofactor may prevent and reverse the formation of compound II, an inactive reaction intermediate. Bifunctional catalase-peroxidase are haem proteins which probably arose via gene duplication of an ancestral peroxidase gene. No detailed structural information is currently available. Even less is know about manganese catalases. Their di-manganese reaction centers may be evolutionary.

Mutational activation of a Galphai causes uncontrolled proliferation of aerial hyphae and increased sensitivity to heat and oxidative stress in Neurospora crassa

Heterotrimeric G proteins, consisting of alpha, beta, and gamma subunits, transduce environmental signals through coupling to plasma membrane-localized receptors. We previously reported that the filamentous fungus Neurospora crassa possesses a Galpha protein, GNA-1, that is a member of the Galphai superfamily. Deletion of gna-1 leads to defects in apical extension, differentiation of asexual spores, sensitivity to hyperosmotic media, and female fertility. In addition, Deltagna-1 strains have lower intracellular cAMP levels under conditions that promote morphological abnormalities. To further define the function of GNA-1 in signal transduction in N. crassa, we examined properties of strains with mutationally activated gna-1 alleles (R178C or Q204L) as the only source of GNA-1 protein. These mutations are predicted to inhibit the GTPase activity of GNA-1 and lead to constitutive signaling. In the sexual cycle, gna-1(R178C) and gna-1(Q204L) strains are female-fertile, but produce fewer and larger perithecia than wild type. During asexual development, gna-1(R178C) and gna-1(Q204L) strains elaborate abundant, long aerial hyphae, produce less conidia, and possess lower levels of carotenoid pigments in comparison to wild-type controls. Furthermore, gna-1(R178C) and gna-1(Q204L) strains are more sensitive to heat shock and exposure to hydrogen peroxide than wild-type strains, while Deltagna-1 mutants are more resistant. In contrast to Deltagna-1 mutants, gna-1(R178C) and gna-1(Q204L) strains have higher steady-state levels of cAMP than wild type. The results suggest that GNA-1 possesses several Gbetagamma-independent functions in N. crassa. We propose that GNA-1 mediates signal transduction pathway(s) that regulate aerial hyphae development and sensitivity to heat and oxidative stresses, possibly through modulation of cAMP levels.

Secretion of a Fungal Extracellular Catalase by Claviceps purpurea During Infection of Rye: Putative Role in Pathogenicity and Suppression of Host Defense

ABSTRACT Hydrogen peroxide of the host origin accumulates in plant apoplasts in response to pathogen attack and probably functions directly in defense reactions or in signaling, according to a previous study. Since Claviceps purpurea produces compatible interactions with hundreds of host species, we hypothesized that the fungus might interfere with H(2)O(2)-mediated defense by means of secreted catalases. In axenic culture of C. purpurea, catalase activity accumulated in the medium and was inhibited by the catalase inhibitor aminotriazole. Polyacrylamide gel electrophoresis followed by diaminobenzidine (DAB)-mediated activity staining showed that one specific catalase found in culture filtrate was also present in rye ovaries infected with C. purpurea and in honeydew. This catalase form is probably induced during infection. In situ activity staining, using DAB-mediated enzyme-cytochemistry in electron microscopy, located catalase activity in hyphal walls during both axenic culture and infection of rye. Activity staining accumulated in periplasmic spaces and was especially strong at hyphal surfaces; control staining after aminotriazole inhibition was negative. Intracellular activity staining in organelles of the fungal secretory pathway substantiated that catalase was secreted by C. purpurea. With molecular cytology, anticatalase epitopes were localized with different heterologous catalase antibodies at sites corresponding to the activity staining pattern. In all infection phases, immunogold labeling indicated that the putative catalase was secreted via multivesicular bodies into the fungal wall and diffused into the host apoplast exclusively at the hostpathogen interface. The secretion of fungal catalase is a novel finding in phytopathology, and we discuss its role in the ubiquitous ergot disease.

Virulence of catalase-deficient aspergillus nidulans in p47(phox)-/- mice. Implications for fungal pathogenicity and host defense in chronic granulomatous disease

Chronic granulomatous disease (CGD) is a rare genetic disorder in which phagocytes fail to produce superoxide because of defects in one of several components of the NADPH oxidase complex. As a result, patients develop recurrent life-threatening bacterial and fungal infections. The organisms to which CGD patients are most susceptible produce catalase, regarded as an important factor for microbial pathogenicity in CGD. To test the role of pathogen-derived catalase in CGD directly, we have generated isogenic strains of Aspergillus nidulans in which one or both of the catalase genes (catA and catB), have been deleted. We hypothesized that catalase negative mutants would be less virulent than the wild-type strain in experimental animal models. CGD mice were produced by disruption of the p47(phox) gene which encodes the 47-kD subunit of the NADPH oxidase. Wild-type A. nidulans inoculated intranasally caused fatal infection in CGD mice, but did not cause disease in wild-type littermates. Surprisingly, wild-type A. nidulans and the catA, catB, and catA/catB mutants were equally virulent in CGD mice. Histopathological studies of fatally infected CGD mice showed widely distributed lesions in the lungs regardless of the presence or absence of the catA and catB genes. Similar to the CGD model, catalase-deficient A. nidulans was highly virulent in cortisone-treated BALB/c mice. Taken together, these results indicate that catalases do not play a significant role in pathogenicity of A. nidulans in p47(phox)-/- mice, and therefore raise doubt about the central role of catalases as a fungal virulence factor in CGD.

Oxidation of catalase by singlet oxygen

Different bands of catalase activity in zymograms (Cat-1a-Cat-1e) appear during Neurospora crassa development and under stress conditions. Here we demonstrate that singlet oxygen modifies Cat-1a, giving rise to a sequential shift in electrophoretic mobility, similar to the one observed in vivo. Purified Cat-1a was modified with singlet oxygen generated from a photosensitization reaction; even when the reaction was separated from the enzyme by an air barrier, a condition in which only singlet oxygen can reach the enzyme by diffusion. Modification of Cat-1a was hindered when reducing agents or singlet oxygen scavengers were present in the photosensitization reaction. The sequential modification of the four monomers gave rise to five active catalase conformers with more acidic isoelectric points. The pI of purified Cat-1a-Cat-1e decreased progressively, and a similar shift in pI was observed as Cat-1a was modified by singlet oxygen. No further change was detected once Cat-1e was reached. Catalase modification was traced to a three-step reaction of the heme. The heme of Cat-1a gave rise to three additional heme peaks in a high performance liquid chromatography when modified to Cat-1c. Full oxidation to Cat-1e shifted all peaks into a single one. Absorbance spectra were consistent with an increase in asymmetry as heme was modified. Bacterial, fungal, plant, and animal catalases were all susceptible to modification by singlet oxygen, indicating that this is a general feature of the enzyme that could explain in part the variety of catalases seen in several organisms and the modifications observed in some catalases. Modification of catalases during development and under stress could indicate in vivo generation of singlet oxygen.

Photosensitization of the yeast Phaffia rhodozyma at a low temperature for screening carotenoid hyperproducing mutants

Phaffia rhodozyma strain Ant-1 produces more carotenoids, known as antioxidants, but it was more sensitive to light plus toluidine blue O (TBO), a superoxide producer, than wild strain 67-385 at 20 degrees C. Carotenoid hyperproducing mutants (CHMs), Ant-1 and 2A2N, exhibited decreased activity of superoxide dismutase (SOD) compared to 67-385, and this is in part responsible for hypersensitivity of the mutants to photosensitization. Light plus TBO at 2 degrees C allowed carotenoid hyperproducing mutants to produce higher colony-forming units than the wild-type. Photosensitization with limited cell metabolism by a low temperature, provides an idea of selective conditions for carotenoid hyperproducers of P. rhodozyma.

Two divergent catalase genes are differentially regulated during Aspergillus nidulans development and oxidative stress

Catalases are ubiquitous hydrogen peroxide-detoxifying enzymes that are central to the cellular antioxidant response. Of two catalase activities detected in the fungus Aspergillus nidulans, the catA gene encodes the spore-specific catalase A (CatA). Here we characterize a second catalase gene, identified after probing a genomic library with catA, and demonstrate that it encodes catalase B. This gene, designated catB, predicts a 721-amino-acid polypeptide (CatB) showing 78% identity to an Aspergillus fumigatus catalase and 61% identity to Aspergillus niger CatR. Notably, similar levels of identity are found when comparing CatB to Escherichia coli catalase HPII (43%), A. nidulans CatA (40%), and the predicted peptide of a presumed catA homolog from A. fumigatus (38%). In contrast, the last two peptides share a 79% identity. The catalase B activity was barely detectable in asexual spores (conidia), disappeared after germination, and started to accumulate 10 h after spore inoculation, throughout growth and conidiation. The catB mRNA was absent from conidia, and its accumulation correlated with catalase activity, suggesting that catB expression is regulated at the transcription level. In contrast, the high CatA activity found in spores was lost gradually during germination and growth. In addition to its developmental regulation, CatB was induced by H2O2, heat shock, paraquat, or uric acid catabolism but not by osmotic stress. This pattern of regulation and the protective role against H2O2 offered by CatA and CatB, at different stages of the A. nidulans life cycle, suggest that catalase gene redundancy performs the function of satisfying catalase demand at the two different stages of metabolic and genetic regulation represented by growing hyphae versus spores. Alternative H2O2 detoxification pathways in A. nidulans were indicated by the fact that catA/catB double mutants were able to grow in substrates whose catabolism generates H2O2.

Purification and characterization of an intracellular catalase-peroxidase from Penicillium simplicissimum

The first dimeric catalase-peroxidase of eucaryotic origin, an intracellular hydroperoxidase from Penicillium simplicissimum which exhibited both catalase and peroxidase activities, has been isolated. The enzyme has an apparent molecular mass of about 170 kDa and is composed of two identical subunits. The purified protein has a pH optimum for catalase activity at 6.4 and for peroxidase at 5.4. Both activities are inhibited by cyanide and azide whereas 3-amino-1,2,4-triazole has no effect. 3,3'-Diaminobenzidine, 3,3'-dimethoxybenzidine, guaiacol, 2,6-dimethoxyphenol and 2,2'-azinobis(3-ethylbenzothiazoline-6-sulfonic acid) all serve as substrates. The optical spectrum of the purified enzyme shows a Soret band at 407 nm. Reduction by dithionite results in the disappearance of the Soret band and formation of three absorption maxima at 440, 562 and 595 nm. The prosthetic group was identified as a protoheme IX and EPR spectroscopy revealed the presence of a histidine residue as proximal ligand. In addition to the catalase-peroxidase, an atypical catalase which is active over a broad pH range was also partially purified from P. simplicissimum. This catalase is located in the periplasm and contains a chlorin-type heme as prosthetic group.

A catalase from Streptomyces coelicolor A3(2)

Catalase was purified from the Gram-positive bacterium Streptomyces coelicolor A3(2) in a three-step purification procedure comprising (NH4)2SO4 fractionation, Phenyl-Sepharose chromatography and Mono Q chromatography. The purification of catalase, as judged by the final specific activity of 110,000 U mg-1, was 250-fold with a 35% yield. The native protein was a homotetramer with a subunit M(r) 55,000. N-terminal and internal peptide sequence analyses showed that there was a high degree of sequence similarity between the S. coelicolor catalase and other microbial and mammalian catalases. Southern blot analysis indicated that there was a single catalase gene in S. coelicolor. The specific activity of catalase throughout the growth of batch cultures was investigated and elevated catalase activity was found in stationary-phase cells.

Role of catalase in myocardial protection against ischemia in heat shocked rats

It was recently reported that in rats exposure to heat shock leads to appearance of a myocardial heat shock protein (HSP 70) and to an increase in myocardial catalase activity. This correlated with an improvement in post-ischemic function either in Langendorff-perfused hearts after low-flow ischemia or in working hearts after short-term, no-flow ischemia. We investigated the effect of the same hyperthermic treatment on functional recovery from no-flow ischemia of various durations in isolated working rat hearts performing at high or low external workloads. Rats were heated to core temperature of 42 degrees C for 15 min. No significant protein oxidation (% oxidized methionine) was observed 2.5 hr after treatment. A protein with migration characteristics similar to HSP 70 was observed in hearts of heat shocked rats 24 hr after this treatment while their myocardial catalase activity was not increased. Hearts of similarly treated rats were excised 24 hr after hyperthermia and perfused in a working mode with Krebs-Henseleit buffer (1.25 mM Ca2+, 11 mM glucose). At 15 cm H2O preload and 100 cm H2O afterload after 30 min no-flow ischemia, control hearts recovered to 36.9%, 2%, 47.6%, and 21.5% of the preischemic values of heart rate-peak systolic pressure product (RPP), aortic output, coronary flow, and cardiac output, respectively. After only 25 min of ischemia the respective recovered values were 61.6%, 11.5%, 58.7%, and 33.5%. Throughout the recovery period these hemodynamic values were consistently higher in hearts of heat shocked animals than in those of control hearts but the differences were not statistically significant.(ABSTRACT TRUNCATED AT 250 WORDS)

The catR gene encoding a catalase from Aspergillus niger: primary structure and elevated expression through increased gene copy number and use of a strong promoter

Synthetic oligonucleotide probes based on amino acid sequence data were used to identify and clone cDNA sequences encoding a catalase (catalase-R) of Aspergillus niger. One cDNA clone was subsequently used to isolate the corresponding genomic DNA sequences (designated catR). Nucleotide sequence analysis of both genomic and cDNA clones suggested that the catR coding region consists of five exons interrupted by four small introns. The deduced amino acid sequence of catalase-R spans 730 residues which show significant homology to both prokaryotic and eukaryotic catalases, particularly in regions involved in catalytic activity and binding of the haem prosthetic group. Increased expression of the catR gene was obtained by transformation of an A. niger host strain with an integrative vector carrying the cloned genomic DNA segment. Several of these transformants produced three- to fivefold higher levels of catalase than the untransformed parent strain. Hybridization analyses indicated that these strains contained multiple copies of catR integrated into the genome. A second expression vector was constructed in which the catR coding region was functionally joined to the promoter and terminator elements of the A. niger glucoamylase (glaA) gene. A. niger transformants containing this vector produced from three- to 10-fold higher levels of catalase-R than the untransformed parent strain.

Selection and analysis of superoxide dismutase mutants of Neurospora

A survey of 12 genetically distinct, heat-sensitive mutants of Neurospora revealed three (un-1, un-3, and un-17) that are specifically deficient in the superoxide dismutase (SOD) isozymes SOD-2 (mitochondrial), SOD-3 (mitochondrial), SOD-4 (exocellular), respectively. Genetic analysis of the three mutants indicates that the enzyme deficiencies are probably the cause of the heat-sensitive phenotype. The phenotypes of the mutants are (1) no growth at the normally optimal temperature 35 degrees C and comparatively inferior growth at 15-30 degrees C; (2) inferior resistance to the oxidants paraquat or oxygen; (3) female sterility; and (4) inferior conidial viability and longevity. Paraquat or O2 inhibition is alleviated respectively by desferrioxamine-Mn (a SOD mimic) and tocopherol. Diverse antioxidants, including tocopherol, are therapeutic for the heat-sensitive and female-sterile phenotypes, and for inferior growth of wild type at stressfully high temperatures. The results support previous theories that heat stress is a form of oxyradical/oxidant stress and that antioxidant enzymes such as SOD are essential for normal growth, development, and longevity. Since the three genes may encode the three enzymes and are not closely linked to either one another or the family of antioxidant-enzyme regulatory genes Age-1, the latter apparently trans-regulate their expression.

Purification and characterization of a catalase-peroxidase from the fungus Septoria tritici

Three classes of heme proteins, commonly designated hydroperoxidases, are involved in the metabolism of hydrogen peroxide: catalases, peroxidases, and catalase-peroxidases. While catalases and peroxidases are widely spread in animals, plants, and microorganisms, catalase-peroxidases were characterized only in prokaryotes. We report here, for the first time, on a catalase-peroxidase in a eukaryotic organism. The enzyme was purified from the fungal wheat pathogen Septoria tritici, and is one of three different hydroperoxidases synthesized by this organism. The S. tritici catalase-peroxidase, designated StCP, is similar to the enzymes previously isolated from the bacteria Rhodobacter capsulatus, Escherichia coli, and Klebsiella pneumoniae, although it is significantly more sensitive to denaturing conditions. In addition to its catalatic activity StCP catalyzes peroxidatic activity with o-dianisidine, diaminobenzidine, pyrogallol, NADH, and NADPH as electron donors. The enzyme is a tetramer with identical subunits of 61,000 Da molecular weight. StCP shows a typical high-spin ferric heme spectrum with a Soret band at 405 nm and a peak at 632 nm, and binding of cyanide causes a shift of the Soret band to 421 nm, the appearance of a peak at 537 nm, and abolition of the peak at 632 nm. Reduction with dithionite results in a decrease in the intensity of the Soret band and its shift to 436 nm, and in the appearance of a peak at 552 nm. The pH optimum is 6-6.5 and 5.4 for the catalatic and peroxidatic activities, respectively. Fifty percent of the apparent maximal activity is reached at 3.4 mM and 0.26 mM for the catalatic and peroxidatic activities, respectively. The enzyme is inactivated by ethanol/chloroform, and is inhibited by KCN and NaN3, but not by the typical catalase inhibitor 3-amino-1,2,4-triazole.

Increase in superoxide production by heat-shocked cells of Neurospora crassa, demonstrated by a fluorometric assay

1. Increase in superoxide production by heat-shocked cells of Neurospora crassa was demonstrated by a fluorometric assay. 2. A sensitive fluorometric assay for the estimation of superoxide anion radical--based on the liberation of 4-methylumbelliferone from 4-methyl-beta-D-umbelliferyl glucopyranoside--is described. 3. Using this system the level of superoxide in the medium of heat-shocked Neurospora crassa cells was found to be consistently higher, in comparison with that of non-shocked cells, cultured at the normal growth temperature of 28 degrees C. 4. Addition of superoxide dismutase to the culture media suppressed the production of 4-methylumbelliferone.

Localization of Glucose Oxidase and Catalase Activities in Aspergillus niger

The subcellular localization of glucose oxidase (EC 1.1.3.4) in Aspergillus niger N400 (CBS 120.49) was investigated by (immuno)cytochemical methods. By these methods, the bulk of the enzyme was found to be localized in the cell wall. In addition, four different catalases (EC 1.11.1.6) were demonstrated by nondenaturing polyacrylamide gel electrophoresis of crude extracts of induced and noninduced cells. Comparison of both protoplast and mycelial extracts indicated that, of two constitutive catalases, one is located outside the cell membrane whereas the other is intracellular. Parallel with the induction of glucose oxidase, two other catalases are also induced, one located intracellularly and one located extracellularly. Furthermore, lactonase (EC 3.1.1.17) activity, catalyzing the hydrolysis of glucono-δ-lactone to gluconic acid, was found to be exclusively located outside the cell membrane, indicating that gluconate formation in A. niger occurs extracellularly.

Changes in superoxide dismutase and catalase in aging heat-shocked Drosophila

We have examined the age-dependent expression of CuZn superoxide dismutase (SOD) and catalase (CAT) in Drosophila melanogaster following heat shock. Quantitative northern blot analysis was performed after heat shock on 2-, 23- and 49-day-old flies, using a 0.48 kb Sal1 EcoR1 fragment of the Drosophila SOD cDNA and a 1.4 kb fragment of the human catalase cDNA. Heat shock induction was monitored with a 5.4 kb DNA fragment of the Drosophila hsp70 gene. After exposure to 37 degrees C for 30 min and 60 min, the level of SOD RNA in young flies was elevated above that of nonstressed conditions. Changes in the transcription of SOD gene with age paralleled the expression of hsp70 RNA. The SOD RNA was elevated in heat-shocked middle aged (23-25 days old) flies compared to young Drosophila (2 days old), then it decreased in 49-50-day-old flies. The relative expression of CAT RNA did not change with age or after heat shock. Enzymatic activities of these two antioxidant enzymes were evaluated in nondenaturing polyacrylamide electrophoresis gels. SOD migrates on this gel as three different electromorphs. These were designated as fast, intermediate and slow migrating bands. The most intense activity was associated with the fast band in these flies. In the absence of heat shock, there was an age-dependent decrease in the intermediate, but not in the slow or fast bands. Heat shock does not affect the intensity of the fast band in young or old flies, however; in middle aged flies, there is a shift in this band toward the slow position. No change was detected in the activity of catalase with age or heat shock, although flies of all ages exhibited a shift toward a faster-migrating electromorph with increasing time of heat shock. This effect was also observed in flies fed H2O2 and is more pronounced in insects fed higher concentrations. These results are discussed in relation to the role of these antioxidant enzymes in protecting against age-induced oxidative stresses.

Two genes encode the two subunits of cottonseed catalase

The isolation and sequence of a cDNA encoding a developmentally distinct subunit of cottonseed catalase are presented. A 1.8-kb cDNA was selected from a cDNA library constructed with poly(A)+ RNA isolated from 3-day-old dark-grown cotyledons in which a second subunit (designated SU 2 in an earlier publication) of catalase was predominantly synthesized. The cDNA encodes a 492-amino acid peptide with a calculated Mr of 56,900. The nucleotide sequence is 76% identical to a cDNA encoding another subunit (SU 1) which was predominantly synthesized in 1-day-old-cotyledons. Most of the divergence occurs in the 5' and 3' non-coding regions, and at the third positions of the codons. The deduced amino acid sequence is 92% identical to that of SU 1. Denaturing isoelectric focusing and SDS-PAGE of products transcribed and translated in vitro from these cDNAs revealed that the cDNA selected from the "1-day" library encoded SU 1 and the cDNA selected from the "3-day" library (this paper) encoded SU 2 of catalase. These data and results from Southern blot analyses of genomic DNA indicate that there are two genes encoding catalase subunits in cotton cotyledons, with only one copy of SU 1 and at least two copies of SU 2 in the genome. A peroxisomal targeting signal, e.g., Ser-Lys-Leu, is not located at the C-terminus of either subunit, or within 25 residues of the C-terminus of SU 1, although it occurs at six residues upstream from the C-terminus of SU 2. A possible location of a targeting sequence for catalase and other peroxisomal proteins lacking the C-terminal tripeptide motif is proposed.

Microbial stress proteins

There is general agreement that a function, perhaps the major function, of stress proteins under normal physiological conditions is to help assembly and disassembly of protein complexes and to catalyse protein-translocation processes. It remains unclear, however, as to what role these processes play in stressed cells. It could be that cells under stress produce abnormal, misfolded or otherwise damaged proteins and that increased synthesis of stress proteins is required to counter protein modifications. A role for stress proteins in recovery of cells from stress, as opposed to a role in helping cells to withstand a lethal stress, is thus suggested. The intracellular location of stress proteins, in the unstressed and stressed cell, is worthy of further studies. Members of the hsp70 family are associated with the cytosol, mitochondria and endoplasmic reticulum. There is evidence, particularly from studies on mammalian cells (Tanguay, 1985; Welch and Mizzen, 1988; Arrigo et al., 1988), that following stress hsps migrate to various cellular compartments and subsequently delocalize after stress. However, there is little comparable data from microbial systems for this phenomenon (e.g. Rossi and Lindquist, 1989). The question as to the role of stress proteins in the transient acquisition of thermotolerance remains to be answered. It is insufficient to equate the kinetics of stress-protein synthesis with acquisition of thermotolerance. Quantitative data on the amount of stress protein present at various times, including the recovery period, is required. The demonstration that microbial stress proteins are important antigenic determinants of micro-organisms causing major debilitating diseases in the world is an exciting observation. Studies on the interplay of pathogen and host, both carrying similar antigenic hsp determinants, will be a challenging area for future research. It is likely that E. coli and Sacch. cerevisiae, with their well-established biochemical and genetic properties, will continue to be the experimental systems of choice for studies on stress proteins. On the other hand, it is encouraging that studies on other micro-organisms have expanded in the past few years and have made substantial contributions towards our understanding of the stress response. The ubiquitous nature of the stress response and the remarkable evolutionary conservation of the stress proteins continue to be attractive areas for research.