Fungal catalases: Function, phylogenetic origin and structure

Most fungi have several monofunctional heme-catalases. Filamentous ascomycetes (Pezizomycotina) have two types of large-size subunit catalases (L1 and L2). L2-type are usually induced by different stressors and are extracellular enzymes; those from the L1-type are not inducible and accumulate in asexual spores. L2 catalases are important for growth and the start of cell differentiation, while L1 are required for spore germination. In addition, pezizomycetes have one to four small-size subunit catalases. Yeasts (Saccharomycotina) do not have large-subunit catalases and generally have one peroxisomal and one cytosolic small-subunit catalase. Small-subunit catalases are inhibited by substrate while large-subunit catalases are activated by H(2)O(2). Some small-subunit catalases bind NADPH preventing inhibition by substrate. We present a phylogenetic analysis revealing one or two events of horizontal gene transfers from Actinobacteria to a fungal ancestor before fungal diversification, as the origin of large-size subunit catalases. Other possible horizontal transfers of small- and large-subunit catalases genes were detected and one from bacteria to the fungus Malassezia globosa was analyzed in detail. All L2-type catalases analyzed presented a secretion signal peptide. Mucorales preserved only L2-type catalases, with one containing a secretion signal if two or more are present. Basidiomycetes have only L1-type catalases, all lacking signal peptide. Fungal small-size catalases are related to animal catalases and probably evolved from a common ancestor. However, there are several groups of small-size catalases. In particular, a conserved group of fungal sequences resemble plant catalases, whose phylogenetic origin was traced to a group of bacteria. This group probably has the heme orientation of plant catalases and could in principle bind NADPH. From almost a hundred small-subunit catalases only one fourth has a peroxisomal localization signal and in fact many fungi lack a peroxisomal catalase. Catalases have a deep buried active site and H(2)O(2) has to go through a long passage to reach it. In all known structures of catalases, the major channel has common features, particularly in the straight and narrow final section that is positioned perpendicular to the heme. Besides, other conserved channels are present in catalases whose function remains to be elucidated. One of these channels intercommunicates the major channels from the two R-related subunits. In three of the four known large-subunits catalase structures, the heme b is partially transformed into heme d. In Neurospora crassa, this occurs in vivo and is related to oxidative stress conditions in which singlet oxygen is produced. A pure source of singlet oxygen oxidizes catalases purified from different sources and singlet oxygen quenchers prevent oxidation. A second modification is observed in N. crassa catalase-1, in which the tyrosine that forms the fifth coordination bound to the heme iron makes a covalent bond with a vicinal cysteine, similarly to the tyrosine-histidine bonding found in Escherichia coli hydroperoxidase II. Molecular dynamics has been used to determine how H(2)O(2) reaches the enzyme active site and how products exit the protein. We found that the bottleneck of the major channel seems to disappear in water and is wide open in the presence of substrate. Amino acid residues exhibiting an increased residence time for H(2)O(2) are abundant at the protein surface and at the entrances to the major channel. The net effect of this is an increased H(2)O(2)/H(2)O ratio in the major channel. Once in the final section of this channel, H(2)O(2) is retained and tends to occupy specific sites while water molecules have a higher turnover rate and occupy different sites. Despite the intense study of catalases our knowledge of this enzyme is still limited and in need of new studies and different approaches.     

Multiple catalase genes are differentially regulated in Aspergillus nidulans

Detoxification of hydrogen peroxide is a fundamental aspect of the cellular antioxidant responses in which catalases play a major role. Two differentially regulated catalase genes, catA and catB, have been studied in Aspergillus nidulans. Here we have characterized a third catalase gene, designated catC, which predicts a 475-amino-acid polypeptide containing a peroxisome-targeting signal. With a molecular mass of 54 kDa, CatC shows high similarity to other small-subunit monofunctional catalases and is most closely related to catalases from other fungi, Archaea, and animals. In contrast, the CatA (approximately 84 kDa) and CatB (approximately 79 kDa) enzymes belong to a family of large-subunit catalases, constituting a unique fungal and bacterial group. The catC gene displayed a relatively constant pattern of expression, not being induced by oxidative or other types of stress. Targeted disruption of catC eliminated a constitutive catalase activity not detected previously in zymogram gels. However, a catalase activity detected in catA catB mutant strains during late stationary phase was still present in catC and catABC null mutants, thus demonstrating the presence of a fourth catalase, here named catalase D (CatD). Neither catC nor catABC triple mutants showed any developmental defect, and both mutants grew as well as wild-type strains in H(2)O(2)-generating substrates, such as fatty acids, and/or purines as the sole carbon and nitrogen sources, respectively. CatD activity was induced during late stationary phase by glucose starvation, high temperature, and, to a lesser extent, H(2)O(2) treatment. The existence of at least four differentially regulated catalases indicates a large and regulated capability for H(2)O(2) detoxification in filamentous fungi.     

Molecular evolution of maize catalases and their relationship to other eukaryotic and prokaryotic catalases

We have compared the nucleotide and protein sequences of the three maize catalase genes with other plant catalases to reconstruct the evolutionary relationship among these catalases. These sequences were also compared with other eukaryotic and prokaryotic catalases. Phylogenies based on distances and parsimony analysis show that all plant catalases derive from a common ancestral catalase gene and can be divided into three distinct groups. The first, and major, group includes maizeCatl, barleyCat1, riceCatB and most of the dicot catalases. The second group is an apparent dicot-specific catalase group encompassing the tobaccoCat2 and tomatoCat. The third is a monocot-specific catalase class including the maize Cat3, barley Cat2, and riceCatA. The maize Cat2 gene is loosely related to the first group. The distinctive features of monocot-specific catalases are their extreme high codon bias at the third position and low degree of sequence similarity to other plant catalases. Similarities in the intron positions for several plant catalase genes support the conclusion of derivation from a common ancestral gene. The similar intron position between bean catalases and human catalase implies that the animal and plant catalases might have derived from a common progenitor gene sequence. Correspondence to: J.G. Scandalios     

Molecular evolutionary analysis based on the amino acid sequence of catalase

Heme-containing catalase sequences from 20 different organisms representing prokaryotes, fungi, animals, and plants have been compiled for phylogenetic reconstruction. Phylogenies based on distance and parsimony analysis show that fungal and animal catalases can be derived from one ancestor, whereas bacterial catalases fail to form a monophyletic group. Plant catalases appear to form a second class of catalases that arose independently from a possible prokaryotic ancestor.Correspondence to: P.C. Loewen     

Identification of two highly divergent catalase genes in the fungal tomato pathogen, Cladosporium fulvum.

Catalases of pathogenic micro-organisms have attracted attention as potential virulence factors. Homology-based screens were performed to identify catalase genes in the fungal tomato pathogen Cladosporium fulvum. Two highly divergent genes, Cat1 and Cat2, were isolated and characterized. Cat1 codes for a putative 566-amino-acid catalase subunit and belongs to the gene family that also encodes the mainly peroxisome-localized catalases of animal and yeast species. Cat2 codes for a putative catalase subunit of 745 amino acids and belongs to a different gene family coding for the large-subunit catalases similar to ones found in bacteria and filamentous fungi. Neither catalase had an obvious secretory signal sequence. A search for an extracellular catalase was unproductive. The Cat1 and Cat2 genes showed differential expression, with the Cat1 mRNA preferentially accumulating in spores and the Cat2 mRNA preferentially accumulating in response to external H(2)O(2). With Cat2-deleted strains, activity of the Cat2 gene product (CAT2) was identified among four proteins with catalase activity separated on non-denaturing gels. The CAT2 activity represented a minor fraction of the catalase activity in spores and H(2)O(2)-stressed mycelium, and no phenotype was observed for Cat2-deleted strains, which showed a normal response to H(2)O(2) treatment. These results indicate the existence of a complex catalase system in C. fulvum, with regard to both the structure and regulation of the genes involved. In addition, efficient C. fulvum gene-replacement technology has been established.     

Diversity of properties among catalases

Catalases from 16 different organisms including representatives from all three phylogenetic clades were purified and characterized to provide a comparative picture of their respective properties. Collectively the enzymes presented a diverse range of activities and properties. Specific activities ranged from 20,700 to 273,800 units per milligram of protein and maximal turnover rates ranged from 54,000 to 833,000 per second. The effective concentrations of common catalase inhibitors, cyanide, azide, hydroxylamine, aminotriazole, and mercaptoethanol, varied over a 100- to 1000-fold concentration range, and a broad range of sensitivities to heat inactivation was observed. Michaelis-Menten kinetics were approximately followed only at the low substrate concentrations. At high H(2)O(2) concentrations, inactivation of small-subunit enzymes resulted in lower velocities than what were predicted, whereas large-subunit enzymes had velocities higher than predicted. Kinetic constants such as K(m) and V(max) for catalases must be labeled as "apparent."     

Sequence determination and analysis of S-adenosyl-L-homocysteine hydrolase from yellow lupine (Lupinus luteus).

The coding sequences of two S-adenosyl-L-homocysteine hydrolases (SAHases) were identified in yellow lupine by screenig of a cDNA library. One of them, corresponding to the complete protein, was sequenced and compared with 52 other SAHase sequences. Phylogenetic analysis of these proteins identified three groups of the enzymes. Group A comprises only bacterial sequences. Group B is subdivided into two subgroups, one of which (B1) is formed by animal sequences. Subgroup B2 consist of two distinct clusters, B2a and B2b. Cluster B2b comprises all known plant sequences, including the yellow lupine enzyme, which are distinguished by a 50-residue insert. Group C is heterogeneous and contains SAHases from Archaea as well as a new class of animal enzymes, distinctly different from those in group B1.     

Comparison of partial 16S rRNA gene sequences obtained from activated sludge bacteria

The cultivated and uncultivated bacterial communities of an activated sludge plant were studied. Two samples were taken and a total of 516 bacterial isolates were classified into groups using their whole-cell protein patterns. The distribution of bacteria into protein-pattern groups differed significantly between the two samples, suggesting variation in culturable bacterial flora. Partial 16S rRNA gene sequences were determined for representatives of the commonest protein-pattern groups. Most of the sequences obtained were previously unknown, but relatively closely related to known sequences of organisms belonging to the α, β or γ subclasses of the proteobacteria, the first two subclasses being predominant. This classification of bacteria isolated on a diluted nutrient-rich medium differed from recent culture-dependent studies using nutrient-rich media. The uncultivated bacterial community was studied by analyzing ten partial 16S rRNA gene sequences cloned directly from activated sludge. None of the cloned sequences was identical to those determined for culturable organisms; or to those in the GenBank database. They were, however, related to the α or β subclasses of the proteobacteria, or to the gram-positive bacteria with a high G+C DNA content. Received: 4 November 1996 / Received revision: 24 February 1997 / Accepted: 28 February 1997     

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.     

A novel group of type I polyketide synthases (PKS) in animals and the complex phylogenomics of PKSs

Type I polyketide synthases (PKSs), and related fatty acid synthases (FASs), represent a large group of proteins encoded by a diverse gene family that occurs in eubacteria and eukaryotes (mainly in fungi). Collectively, enzymes encoded by this gene family produce a wide array of polyketide compounds that encompass a broad spectrum of biological activity including antibiotic, antitumor, antifungal, immunosuppressive, and predator defense functional roles. We employed a phylogenomics approach to estimate relationships among members of this gene family from eubacterial and eukaryotic genomes. Our results suggest that some animal genomes (sea urchins, birds, and fish) possess a previously unidentified group of pks genes, in addition to possessing fas genes used in fatty acid metabolism. These pks genes in the chicken, fish, and sea urchin genomes do not appear to be closely related to any other animal or fungal genes, and instead are closely related to pks genes from the slime mold Dictyostelium and eubacteria. Continued accumulation of genome sequence data from diverse animal lineages is required to clarify whether the presence of these (non-fas) pks genes in animal genomes owes their origins to horizontal gene transfer (from eubacterial or Dictostelium genomes) or to more conventional patterns of vertical inheritance coupled with massive gene loss in several animal lineages. Additionally, results of our broad-scale phylogenetic analyses bolster the support for previous hypotheses of horizontal gene transfer of pks genes from bacterial to fungal and protozoan lineages.     

Neurospora crassa catalases,singlet oxygen and cell differentiation

The morphogenetic transitions of the N. crassa asexual life cycle are responses to a hyperoxidant state in which probably singlet oxygen is generated. Induction of catalase activity and catalase oxidation by singlet oxygen are consequences of this recurrent hyperoxidant state. Here the biochemical properties and regulation of two large monofunctional catalases are reviewed, and a new catalase-peroxidase gene and activity is described. Catalase-3 is associated to growing and Catalase-1 to non-growing cells. Under stressful conditions one of these catalases is synthesized, depending on whether growth can be continued or a resistant cell has to be made. The catalase-peroxidase Catalase-2 was possibly derived from a bacterial enzyme. In contrast to the other catalases, Catalase-2 had catalase and peroxidase activity. Catalase-2 was expressed under conditions in which vacuolization of hyphae is observed. All three enzymes have a chlorin in its active site instead of ferroprotoheme IX and are resistant to molar concentrations of hydrogen peroxide. These and all other catalases tested so far are oxidized by singlet oxygen, probably at the heme moiety. The catalase activity is virtually unaffected by oxidation, but the enzymes are probably degraded more rapidly than the unmodified ones.     

Pectin degrading glycoside hydrolases of family 28: sequence-structural features, specificities and evolution.

Family 28 belongs to the largest families of glycoside hydrolases. It covers several enzyme specificities of bacterial, fungal, plant and insect origins. This study deals with all available amino acid sequences of family 28 members. First, it focuses on the detailed analysis of 115 sequences of polygalacturonases yielding their evolutionary tree. The large data set allowed modification of some of the existing family 28 sequence characteristics and to draw the sequence features specific for bacterial and fungal exopolygalacturonases discriminating them from the endopolygalacturonases. The evolutionary tree reflects both the taxonomy and specificity so that bacterial, fungal and plant enzymes form their own clusters, the endo- and exo-mode of action being respected, too. The only insect (animal) representative is most related to fungal endopolygalacturonases. The present study brings further: (i) the analysis of available rhamnogalacturonase sequences; (ii) the elucidation of relatedness between the recently added member, the endo-xylogalacturonan hydrolase and the rest of the family; and (iii) revealing the sequence features characteristic of the individual enzyme specificities and the evolutionary relationships within the entire family 28. The disulfides common for the individual enzyme groups were also proposed. With regard to functionally important residues of polygalacturonases, xylogalacturonan hydrolase possesses all of them, while the rhamnogalacturonases, known to lack the histidine residue (His223; Aspergillus niger polygalacturonase II numbering), have a further tyrosine (Tyr291) replaced by a conserved tryptophan. Evolutionarily, the xylogalacturonan hydrolase is most related to fungal exopolygalacturonases and the rhamnogalacturonases form their own cluster on the adjacent branch.     

The C-terminal domain of plant catalases. Implications for a glyoxysomal targeting sequence.

A castor bean (Ricinus communis cv. Hale) cDNA encoding catalase was cloned and sequenced. The cDNA encoding the carboxy-terminal domain of catalase was compared to the corresponding sequences of six other plant catalases. The deduced amino acid sequences were compared according to the chemical attributes of each amino acid within each carboxy-terminal domain. A tripeptide sequence having the chemical attributes of the peroxisomal targeting sequence [Gould, S.J., Keller, G.-A., Hosken, N., Wilkinson, J. & Subramani, S. (1989) J. Cell Biol. 108, 1657-1664] was common to all the glyoxysomal/peroxisomal plant catalases. This sequence motif was located six amino acids from the carboxy terminus of each of the plant catalases. An identical motif was also found within the carboxy-terminal domain of three mammalian catalases previously sequenced. We hypothesize that these motifs are at least part of the targeting mechanism for catalase entry into plant glyoxysomes/peroxisomes.     

Thirty years of heme catalases structural biology

About thirty years ago the crystal structures of the heme catalases from Penicillium vitale (PVC) and, a few months later, from bovine liver (BLC) were published. Both enzymes were compact tetrameric molecules with subunits that, despite their size differences and the large phylogenetic separation between the two organisms, presented a striking structural similarity for about 460 residues. The high conservation, confirmed in all the subsequent structures determined, suggested a strong pressure to preserve a functional catalase fold, which is almost exclusively found in these mono-functional heme catalases. However, even in the absence of the catalase fold an efficient catalase activity is also found in the heme containing catalase-peroxidase proteins. The structure of these broad substrate range enzymes, reported for the first time less than ten years ago from the halophilic archaebacterium Haloarcula marismortui (HmCPx) and from the bacterium Burkholderia pseudomallei (BpKatG), showed a heme pocket closely related to that of plant peroxidases, though with a number of unique modifications that enable the catalase reaction. Despite the wealth of structural information already available, for both monofunctional catalases and catalase-peroxidases, a number of unanswered major questions require continuing structural research with truly innovative approaches.     

Molecular diversity of bacterial endosymbionts associated with dagger nematodes of the genus Xiphinema (Nematoda: Longidoridae) reveals a high degree of phylogenetic congruence with their host

Bacterial endosymbionts have been detected in some groups of plant‐parasitic nematodes, but few cases have been reported compared to other groups in the phylum Nematoda, such as animal‐parasitic or free‐living nematodes. This study was performed on a wide variety of plant‐parasitic nematode families and species from different host plants and nematode populations. A total of 124 nematode populations (previously identified morphologically and molecularly) were screened for the presence of potential bacterial endosymbionts using the partial 16S rRNA gene and fluorescence in situ hybridization (FISH) and confocal microscopy. Potential bacterial endosymbionts were only detected in nematode species belonging to the genus Xiphinema and specifically in the X. americanum group. Fifty‐seven partial 16S rRNA sequences were obtained from bacterial endosymbionts in this study. One group of sequences was closely related to the genus ‘Candidatus Xiphinematobacter’ (19 bacterial endosymbiont sequences were associated with seven nematode host species, including two that have already been described and three unknown bacterial endosymbionts). The second bacterial endosymbiont group (38 bacterial endosymbiont sequences associated with six nematode species) was related to the family Burkholderiaceae, which includes fungal and soil–plant bacterial endosymbionts. These endosymbionts were reported for the first time in the phylum Nematoda. Our findings suggest that there is a highly specific symbiotic relationship between nematode host and bacterial endosymbionts. Overall, these results were corroborated by a phylogeny of nematode host and bacterial endosymbionts that suggested that there was a high degree of phylogenetic congruence and long‐term evolutionary persistence between hosts and endosymbionts.     

Ectopic gene conversions in bacterial genomes.

We characterized the gene conversions found between the duplicated genes of 75 bacterial genomes from five species groups (archaea, nonpathogenic and pathogenic firmicutes, and nonpathogenic and pathogenic proteobacteria). The number of gene conversions is positively correlated with the size of multigene families and the size of multigene families is not significantly different between pathogenic and nonpathogenic taxa. However, gene conversions occur twice as frequently in pathogenic species as in nonpathogenic species. Comparisons between closely related species also indicate a trend towards increased gene conversion in pathogenic species. Whereas the length of the conversions is positively correlated with flanking sequence similarity in all five groups, these correlations are smaller for pathogenic firmicutes and proteobacteria than for nonpathogenic firmicutes and proteobacteria. These results are consistent with our previous work on E. coli genomes and suggest that pathogenic bacteria allow recombination between more divergent gene sequences. This higher permissiveness is likely adaptive because it allows them to generate more genetic variability.     

Evolutionary implications of bacterial polyketide synthases

Polyketide synthases (PKS) perform a stepwise biosynthesis of diverse carbon skeletons from simple activated carboxylic acid units. The products of the complex pathways possess a wide range of pharmaceutical properties, including antibiotic, antitumor, antifungal, and immunosuppressive activities. We have performed a comprehensive phylogenetic analysis of multimodular and iterative PKS of bacteria and fungi and of the distinct types of fatty acid synthases (FAS) from different groups of organisms based on the highly conserved ketoacyl synthase (KS) domains. Apart from enzymes that meet the classification standards we have included enzymes involved in the biosynthesis of mycolic acids, polyunsaturated fatty acids (PUFA), and glycolipids in bacteria. This study has revealed that PKS and FAS have passed through a long joint evolution process, in which modular PKS have a central position. They appear to have derived from bacterial FAS and primary iterative PKS and, in addition, share a common ancestor with animal FAS and secondary iterative PKS. Furthermore, we have carried out a phylogenomic analysis of all modular PKS that are encoded by the complete eubacterial genomes currently available in the database. The phylogenetic distribution of acyltransferase and KS domain sequences revealed that multiple gene duplications, gene losses, as well as horizontal gene transfer (HGT) have contributed to the evolution of PKS I in bacteria. The impact of these factors seems to vary considerably between the bacterial groups. Whereas in actinobacteria and cyanobacteria the majority of PKS I genes may have evolved from a common ancestor, several lines of evidence indicate that HGT has strongly contributed to the evolution of PKS I in proteobacteria. Discovery of new evolutionary links between PKS and FAS and between the different PKS pathways in bacteria may help us in understanding the selective advantage that has led to the evolution of multiple secondary metabolite biosyntheses within individual bacteria.     

New Aspects on Lanosterol 14α-Demethylase and Cytochrome P450 Evolution: Lanosterol/Cycloartenol Diversification and Lateral Transfer

Sterol 14-demethylase (CYP51) is a member of the cytochrome P450 superfamily, widely found in animals, fungi, and plants but present in few prokaryotic groups. CYP51 is currently believed to be the ancestral cytochrome P450 that has been transferred from prokaryotes to eukaryotic kingdoms. We propose an alternate view of CYP51 evolution that has an impact on understanding the evolution of the entire CYP superfamily. Two hundred forty-nine bacterial and four archaeal CYP sequences have been aligned and a bacterial CYP tree designed, showing a separation of two branches. Prokaryotic CYP51s cluster to the minor branch, together with other eukaryote-like CYPs. Mycobacterial and methylococcal CYP51s cluster together (100% bootstrap probability), while Streptomyces CYP51 remains on a distant branch. A CYP51 phylogenetic tree has been constructed from 44 sequences resulting in a ((plant, bacteria),(animal, fungi)) topology (100% bootstrap probability). This is in accordance with the lanosterol/cycloartenol diversification of sterol biosynthesis. The lanosterol branch (nonphotosynthetic lineage) follows the previously proposed topology of animal and fungal orthologues (100% bootstrap probability), while plant and D. discoideum CYP51s belong to the cycloartenol branch (photosynthetic lineage), all in accordance with biochemical data. Bacterial CYP51s cluster within the cycloartenol branch (69% bootstrap probability), which is indicative of a lateral gene transfer of a plant CYP51 to the methylococcal/mycobacterial progenitor, suggesting further that bacterial CYP51s are not the oldest CYP genes. Lateral gene transfer is likely far more important than hitherto thought in the development of the diversified CYP superfamily. Consequently, bacterial CYPs may represent a mixture of genes with prokaryotic and eukaryotic origin.     

Bacterial catalase in the microsporidian Nosema locustae: implications for microsporidian metabolism and genome evolution

Microsporidia constitute a group of extremely specialized intracellular parasites that infect virtually all animals. They are highly derived, reduced fungi that lack several features typical of other eukaryotes, including canonical mitochondria, flagella, and peroxisomes. Consistent with the absence of peroxisomes in microsporidia, the recently completed genome of the microsporidian Encephalitozoon cuniculi lacks a gene for catalase, the major enzymatic marker for the organelle. We show, however, that the genome of the microsporidian Nosema locustae, in contrast to that of E. cuniculi, encodes a group II large-subunit catalase. Surprisingly, phylogenetic analyses indicate that the N. locustae catalase is not specifically related to fungal homologs, as one would expect, but is instead closely related to proteobacterial sequences. This finding indicates that the N. locustae catalase is derived by lateral gene transfer from a bacterium. The catalase gene is adjacent to a large region of the genome that appears to be far less compact than is typical of microsporidian genomes, a characteristic which may make this region more amenable to the insertion of foreign genes. The N. locustae catalase gene is expressed in spores, and the protein is detectable by Western blotting. This type of catalase is a particularly robust enzyme that has been shown to function in dormant cells, indicating that the N. locustae catalase may play some functional role in the spore. There is no evidence that the N. locustae catalase functions in a cryptic peroxisome.     

Erwinia amylovora catalases KatA and KatG are virulence factors and delay the starvation‐induced viable but non‐culturable (VBNC) response

The life cycle of the plant pathogen Erwinia amylovora comprises periods inside and outside the host in which it faces oxidative stress caused by hydrogen peroxide (H₂O₂) and other compounds. The sources of this stress are plant defences, other microorganisms and/or exposure to starvation or other environmental challenges. However, the functional roles of H₂O₂‐neutralizing enzymes, such as catalases, during plant–pathogen interactions and/or under starvation conditions in phytopathogens of the family Erwiniaceae or closely related families have not yet been investigated. In this work, the contribution of E. amylovora catalases KatA and KatG to virulence and survival in non‐host environments was determined using catalase gene mutants and expression, as well as catalase activity analyses. The participation of E. amylovora exopolysaccharides (EPSs) in oxidative stress protection was also investigated. Our study revealed the following: (i) a different growth phase regulation of each catalase, with an induction by H₂O₂ and host tissues; (ii) the significant role of E. amylovora catalases as virulence and survival factors during plant–pathogen interactions; (iii) the induction of EPSs by H₂O₂ despite the fact that apparently they do not contribute to protection against this compound; and (iv) the participation of both catalases in the detoxification of the starvation‐induced intracellular oxidative stress, favouring the maintenance of culturability, and hence delaying the development of the viable but non‐culturable (VBNC) response.