Advances in Genomics of Entomopathogenic Fungi.

Fungi are the commonest pathogens of insects and crucial regulators of insect populations. The rapid advance of genome technologies has revolutionized our understanding of entomopathogenic fungi with multiple Metarhizium spp. sequenced, as well as Beauveria bassiana, Cordyceps militaris, and Ophiocordyceps sinensis among others. Phylogenomic analysis suggests that the ancestors of many of these fungi were plant endophytes or pathogens, with entomopathogenicity being an acquired characteristic. These fungi now occupy a wide range of habitats and hosts, and their genomes have provided a wealth of information on the evolution of virulence-related characteristics, as well as the protein families and genomic structure associated with ecological and econutritional heterogeneity, genome evolution, and host range diversification. In particular, their evolutionary transition from plant pathogens or endophytes to insect pathogens provides a novel perspective on how new functional mechanisms important for host switching and virulence are acquired. Importantly, genomic resources have helped make entomopathogenic fungi ideal model systems for answering basic questions in parasitology, entomology, and speciation. At the same time, identifying the selective forces that act upon entomopathogen fitness traits could underpin both the development of new mycoinsecticides and further our understanding of the natural roles of these fungi in nature. These roles frequently include mutualistic relationships with plants. Genomics has also facilitated the rapid identification of genes encoding biologically useful molecules, with implications for the development of pharmaceuticals and the use of these fungi as bioreactors.

Insect Immunity to Entomopathogenic Fungi.

The study of infection and immunity in insects has achieved considerable prominence with the appreciation that their host defense mechanisms share many fundamental characteristics with the innate immune system of vertebrates. Studies on the highly tractable model organism Drosophila in particular have led to a detailed understanding of conserved innate immunity networks, such as Toll. However, most of these studies have used opportunistic human pathogens and may not have revealed specialized immune strategies that have arisen through evolutionary arms races with natural insect pathogens. Fungi are the commonest natural insect pathogens, and in this review, we focus on studies using Metarhizium and Beauveria spp. that have addressed immune system function and pathogen virulence via behavioral avoidance, the use of physical barriers, and the activation of local and systemic immune responses. In particular, we highlight studies on the evolutionary genetics of insect immunity and discuss insect-pathogen coevolution.

Not all GMOs are crop plants: non-plant GMO applications in agriculture.

Since tools of modern biotechnology have become available, the most commonly applied and often discussed genetically modified organisms are genetically modified crop plants, although genetic engineering is also being used successfully in organisms other than plants, including bacteria, fungi, insects, and viruses. Many of these organisms, as with crop plants, are being engineered for applications in agriculture, to control plant insect pests or diseases. This paper reviews the genetically modified non-plant organisms that have been the subject of permit approvals for environmental release by the United States Department of Agriculture/Animal and Plant Health Inspection Service since the US began regulating genetically modified organisms. This is an indication of the breadth and progress of research in the area of non-plant genetically modified organisms. This review includes three examples of promising research on non-plant genetically modified organisms for application in agriculture: (1) insects for insect pest control using improved vector systems; (2) fungal pathogens of insects to control insect pests; and (3) virus for use as transient-expression vectors for disease control in plants.

Transformants of Metarhizium anisopliae sf. anisopliae overexpressing chitinase from Metarhizium anisopliae sf. acridum show early induction of native chitinase but are not altered in pathogenicity to Manduca sexta.

Extracellular chitinase activity has been implicated in the pathogenesis of several fungal infections. Following induction with chitin, the insect pathogens Metarhizium anisopliae sf. acridum ARSEF strain 324 and Metarhizium anisopliae sf. anisopliae ARSEF strain 2575 secrete 44-kDa basic and acidic isoforms of endochitinase, respectively. The gene from strain 324 (Chit1) was cloned and inserted into the genome of strain 2575 under the control of Aspergillus regulatory elements such that transgenic 2575 (2575-Chit(+)) expressed CHIT1 in a noninducing medium (i.e., not containing chitin). Isoelectric focusing followed by a zymogram technique revealed that neither wild-type 2575 nor 2575-Chit(+) produced significant amounts of the native 2575 acidic chitinase in a noninducing medium. However, in a chitin-containing medium, 2575-Chit(+) produced the native chitinase earlier than strain 2575, soon after secretion of CHIT1. We hypothesize that this is due to the production of soluble inducers following chitin hydrolysis by CHIT1 and that M. anisopliae uses enzymes expressed at low levels to sense the nature of the polymeric nutrient present in the immediate environment. However, the chitinase overproducers did not show altered virulence to caterpillars (Manduca sexta) compared to the wild-type fungus, suggesting that wild-type levels of chitinase are not limiting for cuticle penetration.

Cloning, expression, and substrate specificity of a fungal chymotrypsin. Evidence for lateral gene transfer from an actinomycete bacterium.

Unlike trypsins, chymotrypsins have not until now been found in fungi. Expressed sequence tag analysis of the deuteromycete Metarhizium anisopliae identified two trypsins (family S1) and a novel chymotrypsin (CHY1). CHY1 resembles actinomycete (bacterial) chymotrypsins (family S2) rather than other eukaryote enzymes (family S1) in being synthesized as a precursor species (374 amino acids, pI/MW: 5.07/38,279) containing a large N-terminal fragment (186 amino acids). Chy1 was expressed in Pichia pastoris yielding an enzyme with a chymotrypsin specificity for branched aliphatic and aromatic C-terminal amino acids. This is predictable as key catalytic residues determining the specificity of Streptomyces griseus chymotrypsins are conserved with CHY1. Mature (secreted) CHY1 (pI/MW: 8.29/18,499) shows closest overall amino acid identity to S. griseus protease C (55%) and clustered with other secreted bacterial S2 chymotrypsins that diverged widely from animal and endocellular bacterial enzymes in phylogenetic trees of the chymotrypsin superfamily. Conversely, actinomycete chymotrypsins are much more closely related to fungal proteases than to other eubacterial sequences. Complete genomes of yeast, gram eubacteria, archaebacteria, and mitochondria do not contain paralogous genes. Expressed sequence tag data bases from other fungi also lack chymotrypsin homologs. In light of this patchy distribution, we conclude that chy1 probably arose by lateral gene transfer from an actinomycete bacterium.

Lack of host specialization in Aspergillus flavus.

Aspergillus spp. cause disease in a broad range of organisms, but it is unknown if strains are specialized for particular hosts. We evaluated isolates of Aspergillus flavus, Aspergillus fumigatus, and Aspergillus nidulans for their ability to infect bean leaves, corn kernels, and insects (Galleria mellonella). Strains of A. flavus did not affect nonwounded bean leaves, corn kernels, or insects at 22 degrees C, but they killed insects following hemocoelic challenge and caused symptoms ranging from moderate to severe in corn kernels and bean leaves injured during inoculation. The pectinase P2c, implicated in aggressive colonization of cotton balls, is produced by most A. flavus isolates, but its absence did not prevent colonization of bean leaves. Proteases have been implicated in colonization of animal hosts. All A. flavus strains produced very similar patterns of protease isozymes when cultured on horse lung polymers. Quantitative differences in protease levels did not correlate with the ability to colonize insects. In contrast to A. flavus, strains of A. nidulans and A. fumigatus could not invade living insect or plant tissues or resist digestion by insect hemocytes. Our results indicate that A. flavus has parasitic attributes that are lacking in A. fumigatus and A. nidulans but that individual strains of A. flavus are not specialized to particular hosts.

The entomopathogenic fungus Metarhizium anisopliae alters ambient pH, allowing extracellular protease production and activity.

Ambient pH regulates the expression of virulence genes of Metarhizium anisopliae, but it was unknown if M. anisopliae can regulate ambient pH. Mutants of M. anisopliae altered in production of oxalic acid were evaluated for the interrelationship of ambient pH, buffering capacity added to media, growth, and generation of extracellular proteases and ammonia. Wild-type and acid-overproducing mutants [Acid(+)] grew almost as well at pH 8 as at pH 6, but acid-non-producing [Acid(-)] mutants showed limited growth at pH 8, indicating that acid production is linked to the ability to grow at higher pH. Production of ammonia by M. anisopliae was strongly stimulated by low levels of amino acids in the medium when cells were derepressed for nitrogen and carbon. Likewise, although Aspergillus fumigatus and Neurospora crassa produced some ammonia in minimal media, addition of low levels of amino acids enhanced production. Ammonia production by A. fumigatus, N. crassa and M. anisopliae increased the pH of the medium and allowed production of subtilisin proteases, whose activities are observed only at basic pH. In contrast, protease production by the Acid(+) mutants of M. anisopliae was greatly reduced because of the acidification of the medium. This suggests that alkalinization by ammonia production is adaptive by facilitating the utilization of proteinaceous nutrients. Collectively, the data imply that ammonia may have functions related to regulation of the microenvironment and that it represents a previously unconsidered virulence factor in diverse fungi with the potential to harm tissues and disturb the host's immune system.

Cloning, expression, and substrate specificity of MeCPA, a zinc carboxypeptidase that is secreted into infected tissues by the fungal entomopathogen Metarhizium anisopliae.

To date zinc carboxypeptidases have only been found in animals and actinomycete bacteria. A cDNA clone (MeCPA) for a novel fungal (Metarhizium anisopliae) carboxypeptidase (MeCPA) was obtained by using reverse transcription differential display polymerase chain reaction to identify pathogenicity genes. MeCPA resembles pancreatic carboxypeptidases in being synthesized as a precursor species (418 amino acids) containing a large amino-terminal fragment (99 amino acids). The mature (secreted) form of MeCPA shows closest amino acid identity to human carboxypeptidases A1 (35%) and A2 (37%). MeCPA was expressed in an insect cell line yielding an enzyme with dual A1 + A2 specificity for branched aliphatic and aromatic COOH-terminal amino acids. However, in contrast to the very broad spectrum A + B-type bacterial enzymes, MeCPA lacks B-type activity against charged amino acids. This is predictable as key catalytic residues determining the specificity of MeCPA are conserved with those of mammalian A-type carboxypeptidases. Thus, in evolutionary terms the fungal enzyme is an intermediate between the divergence of A and B forms and the differentiation of the A form into A1 and A2 isoforms. Ultrastructural immunocytochemistry of infected host (Manduca sexta) cuticle demonstrated that MeCPA participates with the concurrently produced endoproteases in procuring nutrients; an equivalent function to digestive pancreatic enzymes.

Ambient pH is a major determinant in the expression of cuticle-degrading enzymes and hydrophobin by Metarhizium anisopliae.

Secretion of proteolytic and chitinolytic enzymes is a hallmark of infection processes of Metralhizium anisopliae in response to host (insect) cuticular signals. The regulation of these enzymes (subtilisin-like proteases [Pr1a and Pr1b], trypsin-like proteases [Pr2], metalloproteases, aspartyl proteases, aminopeptidase, and chitinases) and a hydrophobin was investigated by Northern analysis and/or enzyme assay. The production of each enzyme showed a differential expression pattern in response to ambient pH; enzymes were synthesized only at pHs at which they function effectively, irrespective of whether the medium contained an inductive cuticle substrate. Three aspartyl proteases (pH optimum, 3), and chitinase (pH optimum, 5) showed maximal accumulation at acidic pHs. The highest level of aminopeptidase (pH optimum, 7) was detected at pH 7. The highest levels of five metalloproteases (pH optima, ca. 7) were detected over the pH range 6 to 8. Two trypsins and several subtilisin-like Pr1 isoforms with pH optima of ca. 8 were produced only under alkaline conditions. Northern analysis of RNA species corresponding to seven cDNA sequences encoding proteases and chitinase confirmed that the ambient pH played a major role in gene expression of secreted proteins. Hydrophobin was expressed almost equally at pHs 5 and 8 but was not expressed at pH 3. During fungal penetration, the pH of infected cuticle rises from about 6.3 to 7.7. Consistent with pH regulation of enzyme production, serine and metalloproteases were produced in situ during infection, but no production of aspartyl proteases was found. We propose that the alkalinity of infected cuticle represents a physiological signal that triggers the production of virulence factors.

Isolation of a cDNA encoding a novel subtilisin-like protease (Pr1B) from the entomopathogenic fungus, Metarhizium anisopliae using differential display-RT-PCR.

Reverse transcription differential display PCR (RT-DD-PCR) was used to identify genes that are specifically expressed by Metarhizium anisopliae when it contacts the host insect cuticle. Using a homology-based subtilisin-like protease primer we identified a hitherto unsuspected differentially expressed subtilisin-like protease (Pr1B) encoding gene. The deduced amino acid sequence shows 54% similarity to the well characterized Pr1A subtilisin of M. anisopliae and karyotype analysis revealed that Pr1A and Pr1B are located on separate chromosomes. Like Pr1A, Pr1B is synthesized as a large precursor (1158 nucleotides; deduced molecular mass = 40031 Da) containing a signal peptide, a propeptide and the mature protease (283 aa; deduced molecular mass = 28714 Da). However, Pr1B possesses several substitutions in the highly conserved sequences comprising the active sites of subtilisins. In particular, the substitution of Thr220 by serine is unique to Pr1B. Substitution of Asn155 by glycine is also very unusual, and we discuss the likely effects these changes will have on the catalytic efficiency of Pr1B.

Construction of an improved mycoinsecticide overexpressing a toxic protease.

Mycoinsecticides are being used for the control of many insect pests as an environmentally acceptable alternative to chemical insecticides. A key aim of much recent work has been to increase the speed of kill and so improve commercial efficacy of these biocontrol agents. This might he achieved by adding insecticidal genes to the fungus, an approach considered to have enormous potential for the improvement of biological pesticides. We report here the development of a genetically improved entomopathogenic fungus. Additional copies of the gene encoding a regulated cuticle-degrading protease (Pr1) from Metarhizium anisopliae were inserted into the genome of M. anisopliae such that Pr1 was constitutively overproduced in the hemolymph of Manduca sexta, activating the prophenoloxidase system. The combined toxic effects of Pr1 and the reaction products of phenoloxidase caused larvae challenged with the engineered fungus to exhibit a 25% reduction in time of death and reduced food consumption by 40% compared to infections by the wild-type fungus. In addition, infected insects were rapidly melanized, and the resulting cadavers were poor substrates for fungal sporulation. Thus, environmental persistence of the genetically engineered fungus is reduced, thereby providing biological containment.

Biochemical characterization and ultrastructural localization of two extracellular trypsins produced by Metarhizium anisopliae in infected insect cuticles.

Proteinase 2 (Pr2) is a fungal (Metarhizium anisopliae) serine proteinase which has a tryptic specificity for basic residues and which may be involved in entomopathogenicity. Analytical and preparative isoelectric focusing methods were used to separate two trypsin components, produced during growth on cockroach cuticle, with isoelectric points of 4.4 (molecular mass, 30 kDa) and 4.9 (27 kDa). The catalytic properties of the proteases were analyzed by their kinetic constants and by a combination of two-dimensional gelatin-sodium dodecyl sulfate-polyacrylamide gel electrophoresis and enzyme overlay membranes. Both Pr2 isoforms preferentially cleave at the carboxyl sides of positively charged amino acids, preferring arginine; the pI 4.4 Pr2 isoform also possessed significant activity against lysine. Compared with the pathogen's subtilisin-like enzyme (Pr1), the pI 4.4 Pr2 isoform shows low activity against insoluble proteins in a host (Manduca sexta) cuticle. However, it degrades most cuticle proteins when they are solubilized, with high-molecular-weight basic proteins being preferentially hydrolyzed. Polyclonal antibodies raised against each Pr2 isoform were isotype specific. This allowed us to use ultrastructural immunocytochemistry to independently visualize each isoform during penetration of the host (M. sexta) cuticle. Both isoforms were secreted by infection structures (appressoria) on the cuticle surface and by the penetrant hyphae within the cuticle. The extracellular sheath, which is commonly observed around fungal cells, often contained Pr2 molecules. Intracellular labelling was sparse.

Fate of biological control introductions: monitoring an Australian fungal pathogen of grasshoppers in North America.

In North America there are two generally recognized pathotypes (pathotypes 1 and 2) of the fungus Entomophaga grylli which show host-preferential infection of grasshopper subfamilies. Pathotype 3, discovered in Australia, has a broader grasshopper host range and was considered to be a good biocontrol agent. Between 1989 and 1991 pathotype 3 was introduced at two field sites in North Dakota. Since resting spores are morphologically indistinguishable among pathotypes, we used pathotype-specific DNA probes to confirm pathotype identification in E. grylli-infected grasshoppers collected at the release sites in 1992, 1993, and 1994. In 1992, up to 23% of E. grylli-infected grasshoppers of the subfamilies Melanoplinae, Oedipodinae, and Gomphocerinae were infected by pathotype 3, with no infections > 1 km from the release sites. In 1993, pathotype 3 infections declined to 1.7%. In 1994 grasshopper populations were low and no pathotype 3 infections were found. The frequency of pathotype 3 infection has declined to levels where its long-term survival in North America is questionable. Analyses of biocontrol releases are critical to evaluating the environmental risks associated with these ecological manipulations, and molecular probes are powerful tools for monitoring biocontrol releases.

Cloning of a cuticle-degrading protease from the entomopathogenic fungus, Beauveria bassiana.

A Beauveria bassiana extracellular subtilisin-like serine endoprotease is a potential virulence factor by virtue of its activity against insect cuticles. A cDNA clone of the protease was isolated from mycelia of B. bassiana grown on cuticle/chitin cultures. The amino acid sequence of this gene was compared to that of Metarhizium anisopliae Pr1, the only pathogenicity determinant so far described from an entomopathogenic fungus, and proteinase K, isolated from Tritirachium album, a saprophytic fungus. The cDNA sequence revealed that B. bassiana Pr1 is synthesized as a large precursor (M(r) 37,460) containing a signal peptide, a propeptide and the mature protein predicted to have an M(r) of 26,832.

Characterization of a novel carboxypeptidase produced by the entomopathogenic fungus Metarhizium anisopliae.

Preparative isoelectric focusing and gel filtration chromatography were used to purify a carboxypeptidase produced by the entomopathogenic fungus Metarhizium anisopliae during growth on cockroach cuticle. The enzyme was inhibited by diisopropyl fluorophosphate, implying involvement of a serine residue in catalysis. However, the M. anisopliae enzyme differed from most serine carboxypeptidases in also being inhibited by the metal chelator 1,10-phenanthroline and in being a small (30 kDa), basic (pI 9.97) protein with a neutral pH optima (pH 6.8). These properties resemble those exhibited by some metalloproteases but the enzyme is not inhibited by Cd2+; nor do Zn2+ or Co2+ restore activity in enzyme inhibited with phenanthroline. The amino-terminal sequence (22 residues) showed no similarity to other protein sequences. Unlike previously reported fungal carboxypeptidases, the M. anisopliae enzyme is powerfully inhibited by potato carboxypeptidase inhibitor. The carboxypeptidase shows a broad primary specificity toward amino acids with hydrophobic side groups in a series of N-blocked dipeptides, with substrates with phenylalanine being the most rapidly hydrolyzed. The S1 subsite also accommodated Glu, confirming its low selectivity. Proline at P1 or P1 resulted in a very poor substrate. The specificity of the carboxypeptidase complements that of the subtilisin-like protease (Pr1) of M. anisopliae. Both Pr1 and the carboxypeptidase are produced during carbon and nitrogen deprivation, which indicates that the exopeptidase functions with Pr1 to degrade peptides to supply amino acids during starvation and pathogenicity.

Isoforms of the cuticle-degrading Pr1 proteinase and production of a metalloproteinase by Metarhizium anisopliae.

The entomopathogenic fungus, Metarhizium anisopliae, produces three distinct types of proteinases during growth on cockroach cuticle. These were separated by analytical isoelectric focusing and characterized according to their substrate specificity and inhibition patterns as Pr1 subtilisin-like proteinases (four isoforms pI range approximately 9.3-10.2), a thermolysin-like metalloproteinase (pI approximately 7.3), and trypsin-like serine Pr2 proteinases (two major isoforms, pI approximately 4.4 and 4.9 and two minor isoforms, pI approximately 5.2). Preparative isoelectric focusing was used to separate the four Pr1(2) components produced during growth on cockroach cuticle with isoelectric points of 10.2 (m = 30.2 kDa), 9.8 (m = 28.5 kDa), 9.3 (m = 29.5 kDa), and 9.0 (m = 31.5 kDa). Two of the isoforms were also produced, at diminished levels, during growth on elastin or cellulose presumably as a result of carbon and nitrogen derepression. The pI 10.2 Pr1 differed from the other isoforms in preferring alanine over bulky hydrophobic groups at P2 and P3, in discriminating against proline at P2 and in its lack of sensitivity to tetra-butyl-oxycarbonyl-Gly-Leu-Phe-chloromethyl ketone. Differences in the N-terminal amino acid sequences confirmed that the four isoforms are related products of at least two distinct genes. The isoforms showed similar primary specificities, with the aromatic P1 phenylalanine being 10- to 16-fold more reactive than a P1 leucine residue reflected principally in Kcat. However, methionine (containing a long unsubstituted side chain) was also a good substrate for each isoform confirming the low selectivity of their S1 subsites. The isoforms all degraded a variety of solubilized cuticle proteins, with high-molecular-weight acidic proteins being preferentially hydrolyzed. The metalloproteinase is active against the Pr1 substrate succinyl-(Ala)2-Pro-Phe-7-amino-4-coumarin trifluoromethyl, but differs from the Pr1 isoforms in being inhibited by 1,10-phenanthroline and phosphoramidon. The potential role of the metalloproteinase in pathogenicity is discussed.

Differentiation of species and strains of entomopathogenic fungi by random amplification of polymorphic DNA (RAPD).

Polymerase chain reaction (PCR)-based technology, involving random amplification of polymorphic DNA (RAPD), was used to assess the genomic variability between 24 isolates of deuteromycetous fungi (Metarhizium anisopliae, Metarhizium flavoviride, unidentified strains of Metarhizium and Beauveria bassiana) which were found to infect grasshoppers or locusts. M. flavoviride showed little intraspecific variability in PCR-amplified fragments when compared to M. anisopliae. The high level of variability in PCR-amplified fragments contained within M. anisopliae was similar to the total variability between B. bassiana, M. anisopliae and M. flavoviride, and suggests that M. anisopliae may include a number of cryptic species. Four polymorphic RAPD fragments were used to probe the genomic DNA of the various species and strains. On the basis of these probes the fungi can be grouped into M. flavoviride, M. anisopliae, or B. bassiana. According to PCR-amplified fragments, previously-unidentified Metarhizium strains were characterized as M. flavoviride. There was little evidence that these fungi, all isolated from, or virulent towards, grasshoppers or locusts, showed host-selection in PCR-amplified fragments. Nor was geographical origin a criterion for commonality based on PCR-amplified fragments. PCR-fragment-pattern polymorphisms and the construction of probes from one or more of these fragments may provide a useful and rapid tool for identifying species and strains of entomopathogenic fungi.

Analysis of aminopeptidase and dipeptidylpeptidase IV from the entomopathogenic fungus Metarhizium anisopliae.

Analytical and preparative isoelectric focusing were used to separate extracellular isoenzymes of aminopeptidase (pI 4.51, M(r) 45,000, pH optimum 7.0) and prolyl-dipeptidylpeptidase (pI 4.01, M(r) 74,000, pH optimum 8.0) produced by the entomopathogenic fungus Metarhizium anisopliae during growth on locust cuticle. Production of both activities is repressed by readily utilized nitrogen sources, but unlike the aminopeptidase, the dipeptidylpeptidase was also excreted at high levels during growth on casein. Casein-grown cultures contained additional isoenzymes with activity against lysyl-alanyl-4-methoxy-2-naphthylamine indicating M. anisopliae possesses multiple peptidases as an adaptation to different nutrient conditions. The aminopeptidase hydrolysed alanyl-leucyl-alanine and showed a broad specificity versus monoaminoacyl beta-naphthylamine (beta NA) substrates with alanine beta NA being the most rapidly hydrolysed. Inhibition by both bestatin and amastatin indicated similarities to the class of alanyl aminopeptidases (aminopeptidase M). Metal complexing agents also inhibited the aminopeptidase indicating a metal ion requirement. A specific inhibitor for serine proteases [diisopropyl fluorophosphate (DFP)] was without effect. The dipeptidylpeptidase showed a strong preference for substrates having a penultimate proline residue including alanyl-prolyl-glycine and aa-prolyl-beta NA substrates. The enzyme showed a broad specificity at the N-terminal amino acid. Inhibition by diprotin A indicates similarities with mammalian prolyl-dipeptidylpeptidases. The enzyme was also inhibited by DFP, implying involvement of a serine residue in catalysis. The results are discussed in the context of cuticle degradation and the participation of exopeptidases as mediators in releasing amino acids necessary for pathogen growth.

Cloning and regulatory analysis of starvation-stress gene, ssgA, encoding a hydrophobin-like protein from the entomopathogenic fungus, Metarhizium anisopliae.

The nucleotide (nt) sequence of a starvation-stress gene (ssgA) of the entomopathogenic fungus, Metarhizium anisopliae, and its deduced amino acid (aa) sequence were determined. The primary structure of the SSGA (96 aa; deduced M(r) = 9925; pI = 4.1) protein shares extensive similarities with fungal wall proteins of the 'hydrophobin' class, and the eight Cys residues and putative signal sequences are conserved. Secondary structure predictions suggest an additional resemblance to low-M(r) toxins and agglutinins. Northern (RNA) blot analysis and nuclear run-on assays demonstrated transcriptional control of expression of ssgA during nutrient deprivation and during formation of infection structures. Hybridizations of M. anisopliae genomic DNA indicate that there is only one form of ssgA in the genome.

Molecular cloning and regulatory analysis of the cuticle-degrading-protease structural gene from the entomopathogenic fungus Metarhizium anisopliae.

The proteinaceous insect cuticle is an effective barrier against most microbes, but entomopathogenic fungi can breach it using extracellular proteases. We report here the isolation and characterization of a cDNA clone of the cuticle-degrading protease (Pr1) of Metarhizium anisopliae. The cDNA sequence revealed that Pr1 is synthesized as a large precursor (40.3 kDa) containing a signal peptide, a propeptide and the mature protein predicted to have a molecular mass of 28.6 kDa. The primary structure of Pr1 has extensive similarity with enzymes of the subtilisin subclass of serine endopeptidases and the serine, histidine and aspartate components of the active site in subtilisins are preserved. Proteinase K demonstrated the closest sequence similarity to Pr1 (61%) but Pr1 was twofold more effective than proteinase K at degrading isolated cuticles of Manduca sexta and 33-fold more effective at degrading structural proteins bound to the cuticle by covalent bonds. We postulate that the additional positively charged residues on the surface of the Pr1 molecule, as determined using proteinase K, may facilitate electrostatic binding to cuticle proteins which is a prerequisite for activity. Northern-blot analysis of RNA and nuclear run-on assays demonstrated transcriptional control of the expression of Pr1 during nutrient deprivation and during the formation of infection structures. Southern-blot analysis demonstrated that genes with significant homologies to Metarhizium Pr1 were present in the entomopathogens Aspergillus flavus and Verticillium lecanii but not Zoophthora (= Erynia) radicans.