Bacterial Extracellular Proteases Research Articles

Cloning of feather-degrading minor extracellular protease from Bacillus cereus DCUW: dissection of the structural domains

Bacterial extracellular proteases play an important role in cell survival and cell-cell communication. A high-molecular-mass minor extracellular protease (Vpr) from a feather-degrading bacterium, Bacillus cereus DCUW, has been reported by our laboratory. In the present study, we cloned and expressed Vpr in Escherichia coli. Complete nucleotide sequencing of this gene predicted that the protease is a member of the serine protease family, and smart domain analysis revealed that the protease consists of an N-terminal signal sequence for secretion, a subtilisin_N sequence that is a signature for N-terminal processing, a catalytic S_8 peptidase domain, and finally a long C-terminal protease-associated (PA) region containing nine intrinsically disordered subdomains. Four truncated constructs of the Vpr protease were cloned and expressed in E. coli. We found that the catalytic domain (amino acid residues 172-583) is sufficient for protease activity. Maturation of the Vpr protease needed both N-terminal and C-terminal processing. We have demonstrated that the oligomerization property is associated with the C-terminal protease-associated domain and also shown that the substrate-binding specificity to raw feather resides in this domain.

Role of an extracellular neutral protease in infection against nematodes by Brevibacillus laterosporus strain G4

Proteases have been proposed as virulence factors in microbial pathogenicity against nematodes. However, what kinds of extracellular proteases from these pathogens and how they contribute to the pathogenesis of infections against nematode in vivo remain largely unknown. A previous analysis using a strain with a deletion in an extracellular alkaline protease BLG4 gene from Brevibacillus laterosporus demonstrated that BLG4 was responsible for the majority of nematicidal activity by destroying host's cuticle. In recent studies, a neutral protease NPE-4, purified from the mutant BLG4-6, was found to be responsible for the majority of the remaining EDTA-inhibited protease activity. However, the purified NPE-4 and recombinant NPE-4 in a related species Bacillus subtilis showed little nematicidal activity in vitro and were unable to degrade the intact cuticle of the host. It is interesting to note that the addition of NPE-4 improved the pathogenicity of crude enzyme extract from wild-type B. laterosporus but had no effect on the BLG4-deficient mutant. This result suggests that NPE-4 functions in the presence of protease BLG4. Moreover, NPE-4 could degrade proteins from the inner layer of purified cuticles from nematode Panagrellus redivivus in vitro. These results indicated that the two different bacterial extracellular proteases might play differential roles at different stages of infection or a synthetic role in penetration of nematode cuticle in B. laterosporus. This is among the first reports to systematically evaluate and define the roles of different bacterial extracellular proteases in infection against nematodes.

Temperature-regulated bleaching and lysis of the coral Pocillopora damicornis by the novel pathogen Vibrio coralliilyticus.

Coral bleaching is the disruption of symbioses between coral animals and their photosynthetic microalgal endosymbionts (zooxanthellae). It has been suggested that large-scale bleaching episodes are linked to global warming. The data presented here demonstrate that Vibrio coralliilyticus is an etiological agent of bleaching of the coral Pocillopora damicornis. This bacterium was present at high levels in bleached P. damicornis but absent from healthy corals. The bacterium was isolated in pure culture, characterized microbiologically, and shown to cause bleaching when it was inoculated onto healthy corals at 25 degrees C. The pathogen was reisolated from the diseased tissues of the infected corals. The zooxanthella concentration in the bacterium-bleached corals was less than 12% of the zooxanthella concentration in healthy corals. When P. damicornis was infected with V. coralliilyticus at higher temperatures (27 and 29 degrees C), the corals lysed within 2 weeks, indicating that the seawater temperature is a critical environmental parameter in determining the outcome of infection. A large increase in the level of the extracellular protease activity of V. coralliilyticus occurred at the same temperature range (24 to 28 degrees C) as the transition from bleaching to lysis of the corals. We suggest that bleaching of P. damicornis results from an attack on the algae, whereas bacterium-induced lysis and death are promoted by bacterial extracellular proteases. The data presented here support the bacterial hypothesis of coral bleaching.

Bacterial extracellular protease activities in field soils under different fertilizer managements.

The major extracellular endopeptidase from Bacillus subtilis PF212 (isolated from paddy field soil) and B. subtilis CF80 (isolated from upland field soil) belongs to the group of serine proteases produced by Bacillus spp. known as subtilisins (optimum pH 7.0, optimum temperature 60 degrees C, and molecular mass 28 kDa). The NH2-terminal amino acid sequence (20 amino acids) of the endopeptidase from (i) strain CF80 was identical with that of subtilisin BPN' and (ii) strain PF212 was identical with that of subtilisin Amylosacchariticus. The properties (i.e., effect of inhibitors) of these endopeptidases were similar to those of the overall soil endopeptidase and soil endopeptidases extracted from paddy field soil. From the numbers of B. subtilis we isolated from paddy fields and found to produce a subtilisin-like serine protease, it seemed possible to consider that subtilisin was one of the soil endopeptidases in paddy field soils. The major extracellular endopeptidase from Serratia marcescens (strains 4-12-132, 4-12-131, and 4-60-110) isolated from upland field soils applied with animal slurry is a serratial metalloprotease (optimum pH 9.5, optimum temperature 40 degrees C, and molecular mass 50 kDa). The NH2-terminal amino acid sequence (20 amino acids) of the endopeptidase from strain 4-12-132 was identical with that of serratial metalloprotease, and partial DNA sequence of the endopeptidase gene of S. marcescens 4-12-132 had high homology with that of the serratial metalloprotease gene. The properties (i.e., effect of inhibitors) of this endopeptidase were similar to those of the overall soil endopeptidase in upland fields applied with animal slurry. Thus, it was possible to consider that serratial metalloprotease was one of the soil endopeptidases in upland fields applied with animal slurry.

Extracellular Proteases of Contaminant Bacteria in Fish Spoilage: A Review

Although the bacteriology of fish spoilage has been the subject of a number of reviews, the role of bacterial protease secretion in relation to fish spoilage has not received enough attention. This article attempts to focus the proteolytic activities of contaminant microorganisms in fish, the role of muscle constituents on protease synthesis, involvement of extracellular proteases in bacterial penetration of the muscle, and action of the enzymes on fish muscle proteins. The limitation of conventional chilling in completely controlling the bacterial spoilage has been stressed since the proteases secreted by psychrotrophic organisms can act on the fish muscle even at low temperatures. The article advocates employment of stringent measures to control secretion and activities of bacterial extracellular proteases to prolong the keeping qualities of refrigerated fish.

Secretion, processing and activation of bacterial extracellular proteases.

Many different bacteria secrete proteases into the culture medium. Extracellular proteases produced by Gram-positive bacteria are secreted by a signal-peptide-dependent pathway and have a propeptide located between the signal peptide and the mature protein. Many extracellular proteases synthesized by Gram-negative bacteria are also produced as precursors with a signal peptide. However, at least two species of Gram-negative bacteria secrete one or more proteases via a novel signal-peptide-independent route. Most proteases secreted by Gram-negative bacteria also have a propeptide whose length and location vary according to the protease. Specific features of protease secretion pathways and the mechanisms of protease activation are discussed with particular reference to some of the best-characterized extracellular proteases produced by Gram-positive and Gram-negative bacteria.

Specific cleavage of human type III and IV collagens by Pseudomonas aeruginosa elastase.

Purified Pseudomonas aeruginosa elastase cleaved human type III and IV collagens with the formation of specific cleavage products. Furthermore, type I collagen appeared to be slowly cleaved by both P. aeruginosa elastase and alkaline protease. These cleavage fragments from type III and IV collagens were separated from the intact collagen chains by SDS polyacrylamide gradient gel electrophoresis run under reducing conditions, and they were detected by their characteristic Coomassie blue staining pattern. The results of these studies suggest that the pathogenesis of tissue invasion and hemorrhagic tissue necrosis observed in P. aeruginosa infections may be related to the degradation of these collagen types by bacterial extracellular proteases.

Production of neutral and alkaline proteases in batch and chemostat cultures by bacillus mesentericus 76

AbstractThe kinetics of the bacterial extracellular protease synthesis (neutral and alkaline protease of Bacillus mesentericusstrain 76, R‐form) in batch and chemostat cultures under conditions of glucose limitation were investigated. When the medium was supplemented with casein the production of the proteases was significantly higher. Optimal dilution rates for obtaining of two proteases are fixed. The synthesis of both alkaline and neutral proteases is controlled by catabolite repression and induction.

Genetic and biochemical analysis of gonococcal IgA1 protease: cloning in Escherichia coli and construction of mutants of gonococci that fail to produce the activity.

The biological significance of bacterial extracellular proteases that specifically cleave human IgA1 is unknown. We have prepared a gene bank of gonococcal chromosomal DNA in Escherichia coli K-12 using a cosmid cloning system. Among these clones, we have identified and characterized an E. coli strain that elaborates an extracellular endopeptidase that is indistinguishable from gonococcal IgA1 protease in its substrate specificity and action on human IgA1. Analysis of recombinant plasmids and examination of plasmid-specific peptides in minicells have shown that the IgA1 protease activity in E. coli is associated with expression of a Mr 140,000 peptide. We have isolated IgA1 protease-deficient mutants of Neisseria gonorrhoeae by reintroduction of physically defined deletions of the cloned gene into the gonococcal chromosome by transformation.

Extracellular protease production of various bacteria and the role of proteases on the pathogenicity of opportunistic pathogens.

We proved that our improved egg york agar medium was useful for the semiquantitative estimation of the protease production as well as for the de-tection of protease-producing strains of various bacteria. The results obtained by this method suggested that bacterial extracellular proteases might play an important role in the pathogenicity of opportunistic pathogens.