Construction of a Bacillus subtilis double mutant deficient in extracellular alkaline and neutral proteases

A mutant strain of Bacillus subtilis carrying lesions in the structural genes for extracellular neutral (nprE) and serine (aprA) proteases was constructed by the gene conversion technique. This mutant had less than 4% of the extracellular protease activity of the wild type and sporulated normally, indicating that neither of these sporulation-associated proteases is essential for development.     

Genetic manipulation of Bacillus amyloliquefaciens.

Application of modern gene technology to strain improvement of the industrially important bacterium Bacillus amyloliquefaciens is reported. Several different plasmid constructions carrying the alpha-amylase gene (amyE) from B. amyloliquefaciens were amplified in this species either extrachromosomally or intrachromosomally. The amyE gene cloned on a pUB110-derived high copy plasmid pKTH10 directed the highest yields both in rich laboratory medium and in crude industrial medium. The alpha-amylase activity, when compared with the parental strain, was enhanced up to 20-fold in the pKTH 10 transformant. This strain showed decreased activities for other exoenzymes, such as proteases and beta-glucanase suggesting common limiting resources in the processing of these enzymes. Deletions were made in vitro in genes encoding neutral (nprE), alkaline (aprE) protease and beta-glucanase (bglA). The engineered genes were cloned into the thermosensitive plasmid pE194, and the resulting plasmids were used to replace the corresponding wild type chromosomal genes in B. amyloliquefaciens by integration-excision at non-permissive temperature. The double mutant deficient in the major proteases (delta nprE delta aprE) showed about a 2-fold further enhancement in alpha-amylase production in the industrial medium compared with the relevant wild type backgroud, both when plasmid-free and when transformed with pKTH10; this strain also produced elevated levels of the chromosomally-encoded beta-glucanase; pKTH10 was stably maintained both in the wild type strain and in the delta nprE delta aprE mutant. We suggest that the higher yields in alpha-amylase and beta-glucanase in the delta nprE delta aprE strain are primarily due to improved access to limiting resources, and that decreased proteolytic degradation may have had a secondary role in retaining the high activity obtained.     

Expression in Escherichia coli of the Bacillus subtilis neutral protease gene (NPRE) lacking its ribosome binding site

Bacillus subtilis neutral protease (NprE) is first produced as a precursor, pre-pro-NprE, which consists of a signal peptide or prepeptide for secretion (27 amino acid residues) and a pro-peptide (194 amino acid residues) between the signal peptide and the mature protease. While the wildtype nprE gene could not be maintained in Escherichia coli, we have been able to show that expression and secretion of the neutral protease can be achieved from the nprE gene when its ribosome binding site (RBS) is removed. The results suggest that the failure to observe expression of the wildtype nprE gene is due to the lytic effect of the nprE gene product on E. coli host cells and that translation initiation in E. coli can be achieved even in the absence of a classical ribosome binding site.     

n-Terminal Amino Acid Sequences of Neutral Proteases from Bacillus amyloliquefaciens and Bacillus subtilis: Identification of a Neutral Protease Gene Cloned in Bacillus subtilis

Bacillus subtilis 1A20 transformed with a hybrid plasmid, pNP150, to which a DNA fragment from Bacillus amyloliquefaciens F was attached, produced a large amount of a neutral protease. To identify the origin of the gene specifying this neutral protease, neutral proteases from B. amyloliquefaciens F, B. subtilis NP58 (a derivative of Marburg 6160), and B. subtilis 1A20 transformed with pNP150 were purified. We investigated their immunological properties and primary structures.

The proteases from these two species were indistinguishable by chromatography, but they were distinguishable from each other by SDS-polyacrylamide gel electrophoresis and double immunodiffusion. Amino acid sequencing of these two proteases by Edman degradation showed that there were four substitutions in the 20-residue amino acid sequence from the N-termini.

Neutral protease from the transformant had the same immunological characteristics and N-terminal amino acid sequence as that from B. amyloliquefaciens. These results meant that the gene in question was derived from a gene specifying the neutral protease in this bacterium.     

CDP-glycerol:poly(glycerophosphate) glycerophosphotransferase, which is involved in the synthesis of the major wall teichoic acid in Bacillus subtilis 168, is encoded by tagF (rodC).

Assays of CDP-glycerol:poly(glycerophosphate) glycerophosphotransferase (CGPTase) (EC 2.7.8.12) in membranes isolated from Bacillus subtilis 168 wild type and 11 strains bearing conditional lethal thermosensitive mutations in tagB, tagD, or tagF revealed that CGPTase deficiency was associated only with mutant tagF alleles. In vitro, thermosensitivity of CGPTase strongly suggests that the structural gene for this enzyme is tagF. We discuss apparent discrepancies between biochemical evidence favoring a membrane location for TagF and a previous report that suggested a cytoplasmic location based on sequence analysis.     

The transition state regulator Hpr of Bacillus subtilis is a DNA-binding protein

The synthesis of a variety of proteins, including the well characterized degradative enzymes, which occurs during the transition state between vegetative growth and the onset of sporulation in Bacillus subtilis is controlled by a class of molecules known as transition state regulators. One of these regulators is the product of the hpr gene, first identified by mutations affecting the synthesis of extracellular proteases. We have purified the Hpr protein and found that it binds specifically to DNA fragments carrying the promoters and the upstream regions of the alkaline (aprE) and neutral (nprE) protease genes of B. subtilis. DNase I protection experiments revealed that the Hpr protein is able to bind at four and two regions of the aprE and nprE promoters, respectively. We have also located two Hpr binding sites in the promoter region of a gene of unknown function which is nevertheless known to be developmentally regulated during the transition state and which occurs in the same operon as the gene encoding another transition state regulator, Sin. The location of one of the Hpr binding sites on the aprE gene occurs adjacent to a region to which the Sin protein binds. However, in mixing competition experiments we have shown that Hpr and Sin binding occurred independently, and no visible alterations of protected regions were detected.     

Ribonuclease U2: cloning, production in Pichia pastoris and affinity chromatography purification of the active recombinant protein

A recombinant lipase, CWB-LipB, localized on the Bacillus subtilis cell surface and retaining lipase activity was unstable and not accumulated in a high yield. To improve the accumulation, we examined cell wall binding protease (wprA)- and/or sigma D (sigD)-deficient mutants, and also a NprE and AprA protease-deficient mutant as host strains. The nprE aprA mutation did not lead to a significant increase in the CWB-LipB accumulation. The wprA mutant accumulated a greater amount than the wild-type only in the stationary phase, but the sigD mutant accumulated a greater amount in both the exponential and stationary phases. The double mutant exhibited great accumulation of CWB-LipB, the amount being 36% of the total proteins extracted from the cell surface.     

Mutants affecting tRNA(Phe) from Escherichia coli. Studies of the suppression of thermosensitive phenylalanyl-tRNA synthetase

Four mutants of pheV, a gene coding for tRNA(Phe) in Escherichia coli, share the characteristic that when carried in the plasmid pBR322, they lose the capacity of wild-type pheV to complement the thermosensitive defect in a mutant of phenylalanyl-tRNA synthetase. One of these mutants, leading to the change C2----U2 in tRNA(Phe), is expressed about 10-fold lower in transformed cells than wild-type pheV. This mutant, unlike the remaining three (G15----A15, G44----A44, m7G46----A46), can recover the capacity to complement thermosensitivity when carried in a plasmid of higher copy number. The other three mutants, even when expressed at a similar level, remain unable to complement thermosensitivity. A study of charging kinetics suggests that the loss of complementation associated with these mutants is due to an altered interaction with phenylalanyl-tRNA synthetase. The mutant gene pheV (U2), when carried in pBR322, can also recover the capacity to complement thermosensitivity through a second-site mutation outside the tRNA structural gene, in the discriminator region. This mutation, C(-6)----T(-6), restores expression of the mutant U2 to about the level of wild-type tRNA(Phe).     

Heterologous gene expression in Lactococcus lactis subsp. lactis: synthesis, secretion, and processing of the Bacillus subtilis neutral protease

The Bacillus subtilis nprE gene lacking its own promoter sequence was inserted in the lactococcal expression vector pMG36e. Upon introduction of the recombinant plasmid into Lactococcus lactis subsp. lactis strain MG1363, neutral protease activity could be visualized by the appearance of large clearing zones around colonies grown on milk agar plates. By measuring the activities of the neutral protease and the intracellular enzyme lactate dehydrogenase in culture supernatants and cell fractions, it was demonstrated that the neutral protease was actively secreted into the growth medium. This was corroborated by using the Western blot (immunoblot) technique, which showed the presence of the mature form of the neutral protease in the culture supernatant. On the basis of these results, it is concluded that the B. subtilis neutral protease gene was expressed in L. lactis and that the gene product was secreted into the growth medium and was apparently correctly processed to produced a biologically active protein. The secretion of this particular enzyme may be helpful in achieving accelerated cheese ripening.     

Heterologous gene expression in Lactococcus lactis subsp. lactis: synthesis, secretion, and processing of the Bacillus subtilis neutral protease.

The Bacillus subtilis nprE gene lacking its own promoter sequence was inserted in the lactococcal expression vector pMG36e. Upon introduction of the recombinant plasmid into Lactococcus lactis subsp. lactis strain MG1363, neutral protease activity could be visualized by the appearance of large clearing zones around colonies grown on milk agar plates. By measuring the activities of the neutral protease and the intracellular enzyme lactate dehydrogenase in culture supernatants and cell fractions, it was demonstrated that the neutral protease was actively secreted into the growth medium. This was corroborated by using the Western blot (immunoblot) technique, which showed the presence of the mature form of the neutral protease in the culture supernatant. On the basis of these results, it is concluded that the B. subtilis neutral protease gene was expressed in L. lactis and that the gene product was secreted into the growth medium and was apparently correctly processed to produced a biologically active protein. The secretion of this particular enzyme may be helpful in achieving accelerated cheese ripening.     

Interaction of the Escherichia coli lipoprotein NlpI with periplasmic Prc (Tsp) protease

Escherichia coli spr (suppressor of prc) mutants and nlpI mutants show thermosensitive growth. The thermosensitivity of the spr mutants was suppressed by the nlpI mutations. Expression of the fusion genes encoding hexa-histidine-tagged NlpI (NlpI-His) and purification of the tagged NlpI showed that NlpI-His bound with Prc protease and IbpB chaperone. NlpI-His with the amino acid substitution of G103D did not bind with either of these proteins, while NlpI-His variants (NlpI-284-His, NlpI-Q283-His, and NlpI-G282-His) lacking 10 to 12 residues from the carboxy terminus bound with both proteins. The tagged NlpI lacking 11 amino acid residues from the carboxy terminus was processed by Prc, but that lacking 12 residues was not. The thermosensitivity of the nlpI mutant was corrected by the production of the former NlpI variant, but not by production of the latter. Expression of the truncated NlpI that lacked 10 or 11 residues from the carboxy terminus corrected the thermosensitivity of the prc nlpI double mutant, while expression of the full-length NlpI did not. Thus, it was suggested that NlpI was activated by Prc protease processing.     

Effects of Mutational Loss of Specific Intracellular Proteases on the Sporulation of Bacillus subtilis

Two protease-deficient mutants of Bacillus subtilis 168 (Trp(-)) were isolated and compared with the parental strain with respect to production of intracellular proteases and sporulation. A mutant lacking the metal-requiring "neutral" protease intracellularly sporulated as well as the parental strain. A second mutant, deficient in an as yet uncharacterized intracellular protease, failed to sporulate normally. It is proposed that this new protease is also involved in intracellular protein turnover.     

Extracellular proteases modify cell wall turnover in Bacillus subtilis.

The rate of turnover of peptidoglycan in exponentially growing cultures of Bacillus subtilis was observed to be sensitive to extracellular protease. In protease-deficient mutants the rates of cell wall turnover were greater than that of wild-type strain 168, whereas hyperprotease-producing strains exhibited decreased rates of peptidoglycan turnover. The rate of peptidogylcan turnover in a protease-deficient strain was decreased when the mutant was grown in the presence of a hyperprotease-producing strain. The addition of phenylmethylsulfonyl fluoride, a serine protease inhibitor, to cultures of hyperprotease-producing strains increased their rates of cell wall turnover. Isolated cell walls of all protease mutants contained autolysin levels equal to or greater than that of wild-type strain 168. The presence of filaments, or cells with incomplete septa, was observed in hyperprotease-producing strains or when a protease-deficient strain was grown in the presence of subtilisin. The results suggest that the turnover of cell walls in B. subtilis may be regulated by extracellular proteases.     

Regulation of Neutral Protease Productivity in Bacillus subtilis: Transformation of High Protease Productivity

A transformable strain of Bacillus subtilis 6160, a derivative of B. subtilis 168, produces three kinds of casein hydrolytic enzymes (alkaline protease, neutral protease, and esterase) in a culture medium. B. natto IAM 1212 produces 15 to 20 times as much total proteolytic activity as does B. subtilis. Extracellular proteases produced by the two strains were separated into each enzyme fraction by diethylaminoethyl-Sephadex A-50 column chromatography. The difference in the total protease activities of extracellular proteases between the two strains was due to the amount of neutral protease. The ratios of neutral protease activity to alkaline protease activity (N/A) were 1.1 in B. subtilis 6160 and 13.0 in B. natto IAM 1212. Enzymological and immunological properties of alkaline protease and neutral protease obtained from the two strains were quite similar or identical, respectively. Specific activities measured by an immunological analysis of the two neutral proteases against casein were also equal. A genetic character of high protease productivity in B. natto IAM 1212 was transferred to B. subtilis 6160 by the deoxyribonucleic acid-mediated transformation. Among 73 transformants that acquired high protease productivity, 69 produced a higher amount of neutral protease and the ratios of N/A were changed to 15 to 60. Three other strains were transformed in the productivity of neutral protease and alpha-amylase simultaneously, and one showed considerable change in the production of alkaline protease and neutral protease. The specific activities (casein hydrolytic activities/enzyme molecules) of neutral proteases from the representative four transformants were equal to those of the two parental strains. These results suggested the presence of a specific gene(s) that participated in the productivity of neutral protease in B. subtilis.     

Mutation of Bacillus subtilis causing hyperproduction of alpha-amylase and protease, and its synergistic effect.

Mutants that had a genetic lesion increasing the production of alpha-amylase and protease simultaneously were isolated from a transformable strain of Bacillus subtilis Marburg by N-methyl-N'-nitro-N-nitrosoguanidine treatment. These mutants produced two to three times more alpha-amylase and five to 16 times more protease than their parent and were tentatively referred to as AP mutants. As this mutation seems to have occurred at a single gene of the bacterial chromosome and was not located near the alpha-amylase structural gene, the gene was designated as "pap." When pap- and amyR2 (an alpha amylase regulator gene) or pap- and ProH coexisted in the same cell, synergistic effects of the two genetic characters were observed on the alpha-amylase and protease production, respectively. Upon introduction of the pap mutation, the following phenotypic changes were observed in addition to changes in alpha-amylase and protease productivity. (i) Mutants lost the character of competence for the transformation. (ii) When cells were cultured at 30 C for 30 h, mutant cells became filament owing to the formation of chains of cells. (iii) Autolysis of cells was decreased in the mutants. When pap- was transferred to the wild strain by deoxyribonucleic acid-mediated transformation, the transformants showed all these phenotypic alterations simultaneously.     

Proteases from Bacillus: a new insight into the mechanism of action for rhizobacterial suppression of nematode populations

AIMS: The aim of this study was to investigate the role of proteases in Bacillus spp. of rhizobacteria in suppressing nematode populations and to understand their mechanism of action. METHODS AND RESULTS: Rhizobacteria with nematicidal activity were isolated from soil samples of five root knot nematode-infested farms. Among these strains, nematotoxicities of Bacillus strains were intensively analysed. Further assays of nematicidal toxins from Bacillus sp. strain RH219 indicated an extracellular cuticle-degrading protease Apr219 was an important pathogenic factor. The Apr219 shared high similarity with previously reported cuticle-degrading proteases from Brevibacillus laterosporus strain G4 and Bacillus sp. B16 (Bacillus nematocida). The cuticle-degrading protease genes were also amplified from four other nematicidal Bacillus strains isolated from the rhizosphere. In addition to Apr219, a neutral protease Npr219 from Bacillus sp. RH219 was also investigated for activity against nematodes. CONCLUSIONS: The wide distribution of cuticle-degrading proteases in Bacillus strains with nematicidal activity suggested that these enzymes likely play an important role in bacteria-nematode-plant-environment interactions and that they may serve as important nematicidal factors in balancing nematode populations in the soil. SIGNIFICANCE AND IMPACT OF THE STUDY: Increased understanding of the mechanism of action of Bacillus spp. against nematodes could potentially enhance the value of these species as effective nematicidal agents and develop new biological control strategies.     

Properties of Thermosensitive Extracellular α-Amylases of Bacillus subtilis

Enzymological properties of four thermosensitive alpha-amylases (M3, M9, M18, and M20) brought by different mutation sites in alpha-amylase structural gene of Bacillus subtilis were compared with those of the parental alpha-amylase NA64. Two thermosensitive alpha-amylases (M9 and M20) were altered not only in their thermosensitivity but also in their immunological properties, catalytic properties, molecular weights determined by the gel filtration on a Bio-Gel P-100 column, and others. The other two thermosensitive alpha-amylases (M3 and M18) were altered only in their thermosensitivity.     

Thermosensitive mutants of the MPTP and hPTP1B protein tyrosine phosphatases: isolation and structural analysis.

A PCR-based random mutagenesis procedure was employed to identify several thermosensitive mutants of the MPTP enzyme, the murine homologue of the human T-cell PTPase and rat PTP-S enzymes. Four mutants with varying degrees of thermosensitivity were characterized for their thermostability and refolding properties following incubation at the nonpermissive temperature. Structure analysis of these mutations based on the hPTP1B co-ordinate structure demonstrates a clear relationship between the position of each mutated amino acid relative to the catalytic cysteine residue and their thermostability. Introduction of two of these mutations in the related enzyme hPTP1B suggests that the structural defects and the resulting thermosensitivity of these mutations may represent an intrinsic property of all PTPase catalytic domains.