Multiple forms of Bacillus subtilis subtilisin and effects of mutations on the distribution of its molecular forms]

Using polyacrylamide-gel electrophoresis, isoelectric focusing and gel-filtration it was demonstrated that the auxotrophic mutant strains of Bac. subtilis A-50 and their prototrophic revertant strains produce multiple molecular forms of subtilisin. Three of them are the same as the corresponding molecular forms of subtilisin from the wild strain A-50. In different mutant strains the relative amounts of the main three forms varies considerably resulting in the absence of certain forms in several strains. There is the additional minor form of subtilisin possessing high electrophoretic mobility in four prototrophic revertant strains and one Arg--auxotrophic strain of Bac. subtilis A-50. It would be reasonable to suppose that different molecular forms of subtilisin derive from the product of its single structural gene as a result of post-translational modifications (limited proteolysis). This enzyme and probably most, if not all secretory proteins may be synthesised as larger precursors and then specifically modified in the bacterial cell membranes. Thus, certain mutations, without affecting the structural gene of this secretory protein -- subtilisin -- have pronounced effects on this structural gene expression, varying the degree of its product modification and the amount of resulting secretory molecular forms of subtilisin.     

Immunochemical study of subtilisins obtained from Bacillus subtilis A-50 and some of its mutants]

Physico-chemical parameters of subtilisins from the original Bacillus subtilis A-50 strain (proteolytic activity, electrophoretic mobility, molecular weight, reactions with specific inhibitors) were similar to those mentioned in the literature for the enzymes of other strains. Immunological experiment has shown, that Bacillus subtilis A-50 subtilisins with various electrophoretic mobility do not differ in their antigenic properties. Enzymes with high electrophoretic mobility from mutant strains were similar to I--III subtilisin fractions from Bac. subtilis A-50 in the antigenic characteristics. However, the antigenic heterogeneity was observed in I, II and III enzyme fractions of some mutant strains. Subtilisins studied appear to form the isoenzyme system.     

Effect of Bacillus subtilis A-50 "streptomycin" mutations on the formation of molecular forms of subtilisin, an extracellular alkaline proteinase]

The patterns of subtilisin molecular forms of streptomycin-resistant (Strr) and streptomycin-dependent (Strd) mutants of Bacillus subtilis A-50, as well as the revertants of Strd to streptomycin-independence (Str1) were studied. Strr mutants had different quantitative pattern of the same subtilisin molecular forms as compared with the initial strain A-50 (the forms with Rf 0.08, 0.16 and 0.3). In comparison with the initial strain A-50, Strd mutants and Str1 revertants revealed three additional forms of the active enzyme with Rf 0.02, 0.5 and 0.7 and the molecular weights less than 35,000, 28,000 and 20,000 respectively. It was suggested that the rate and character of the enzyme secretion of the degree of its post-translational modifications might result in the different pattern of subtilisin molecular forms produced by these streptomycin mutants.     

Intracellular serine protease of Bacillus subtilis: sequence homology with extracellular subtilisins.

Intracellular serine protease was isolated from stationary-grown Bacillus subtilis A-50 cells and purified to homogeneity. The molecular weight of the enzyme is 31,000 +/- 1,000, with an isoelectric point of 4.3. Its amino acid composition is characteristically enriched in glutamic acid content, differing from that of extra-cellular subtilisins. The enzyme is completely inhibited with phenylmethylsulfonyl fluoride and ethylenediaminetetraacetic acid. Intracellular protease possesses negligible activity towards bovine serum albumin and hemoglobin, but has 5- to 20-fold higher specific activity against p-nitroanilides of benzyloxycarbonyl tripeptides than subtilisin BPN'. Esterolytic activity of the enzyme is also higher than that of subtilisin BPN'. The enzyme is sequence homologous with secretory subtilisins throughout 50 determined NH2-terminal residues, indicating the presence of duplicated structural genes for serine proteases in the B. subtilis genome. The occurrence of two homologous genes in the cell might accelerate the evolution of serine protease not only by the loosening of selective constrainst, but also by creation of sequence variants by means of intragenic recombination. Three molecular forms of intracellular protease were found, two of them with NH2-terminal glutamic acid and one minor form, three residues longer, with asparagine as NH2 terminus. These data indicate the possible presence of an enzyme precursor proteolytically modified during cell growth.     

Nature of the mutations that determine the ability of Bacillus subtilis A-50 to sporulate at high glucose concentrations in the medium]

The ability of Bacillus subtilis A-50 to sporulate in the medium containing high glucose concentrations is caused by at least two mutation types: pts mutations and cat (or tgl) mutations, both of them affecting differently the level of alkaline proteinase synthesis. The decrease of the level of enzyme activity in the case of pts mutation (gluR3 mutant) occurs at the expense of glucose transport disturbance. The mutation cat (tgl) (mutant gluR5) causes the increase in enzyme synthesis at the expense of catabolic resistance to glucose of genes controlling alkaline proteinase synthesis and the spore formation in Bac. subtilis A-50. cat5(gluR5) and pts3(gluR3) mutations are located on the chromosome of Bac. subtilis in the region metD and argC respectively. The over-synthesis of alkaline proteinase characteristic of Bac. subtilis A-50 is controlled by the polygenic system, as the level of alkaline proteinase synthesis in argA+ transformants makes up 25% of the level of activity of the original strain. The productivity of Bac. subtilis A-50 can be enhanced by introducing an additional cat mutation.     

Protease-deficient Bacillus subtilis host strains for production of Staphylococcal protein A

We constructed strains of Bacillus subtilis which produced very low levels of extracellular proteases. These strains carried insertion or deletion mutations in the subtilisin structural gene (apr) which were constructed in vitro by using the cloned gene. The methods used to construct the mutations involved the use of a plasmid vector which allowed the selection of chromosomal integrates and their subsequent excision by homologous recombination to effect replacement of the chromosomal apr gene by a derivative carrying an inactivating insert with a selectable marker (a cat gene conferring chloramphenicol resistance). The strains produced no subtilisin, no detectable extracellular metalloprotease activity, and residual extracellular serine protease levels as low as 0.5% of that of the standard strain from which they were derived. The strains proved to be superior host strains for the production of staphylococcal protein A, accumulating higher levels of intact protein than do previously available B. subtilis strains.     

Protease-deficient Bacillus subtilis host strains for production of Staphylococcal protein A.

We constructed strains of Bacillus subtilis which produced very low levels of extracellular proteases. These strains carried insertion or deletion mutations in the subtilisin structural gene (apr) which were constructed in vitro by using the cloned gene. The methods used to construct the mutations involved the use of a plasmid vector which allowed the selection of chromosomal integrates and their subsequent excision by homologous recombination to effect replacement of the chromosomal apr gene by a derivative carrying an inactivating insert with a selectable marker (a cat gene conferring chloramphenicol resistance). The strains produced no subtilisin, no detectable extracellular metalloprotease activity, and residual extracellular serine protease levels as low as 0.5% of that of the standard strain from which they were derived. The strains proved to be superior host strains for the production of staphylococcal protein A, accumulating higher levels of intact protein than do previously available B. subtilis strains.     

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.     

Replacement of the Bacillus subtilis subtilisin structural gene with an In vitro-derived deletion mutation.

The entire subtilisin structural gene from Bacillus subtilis I168 has been cloned, and its nucleotide sequence has been determined. When expressed on a high-copy-number shuttle vector, a fivefold increase in serine protease activity was observed. The DNA sequence of the gene is 80% homologous to the Bacillus amyloliquefaciens subtilisin structural gene, and the translated mature coding sequence is 85% homologous to the published protein sequence of subtilisin BPN'. The chloramphenicol resistance determinant of a plasmid integrated at the subtilisin locus was mapped by PBS1 transduction and was found to be linked to glyB (83%) and argC (60%), but not with metC or purB . The chromosomal locus containing the wild-type subtilisin allele was replaced with an in vitro-derived allele of the gene (delta apr-684) that contained a 684-base-pair deletion. The technique used for introducing the deletion is a variation of the gene replacement methods used in Saccharomyces cerevisiae and Escherichia coli. When used in B. subtilis, deletion mutants could be directly screened among the transformants. Physiological characterization of the delta apr-684 mutation revealed no discernable effect on the formation of heat-resistant endospores, but strains carrying the mutation produced only 10% of wild-type serine protease activity. A model is presented that outlines the pathway for plasmid integration and deletion formation in B. subtilis.     

Subtilisins of Bacillus spp. hydrolyze keratin and allow growth on feathers

Keratinase is a serine protease produced by Bacillus licheniformis PWD-1 that effectively degrades keratin and confers the ability to grow on feathers to a protease-deficient B. subtilis strain. Studies presented herein demonstrate that B. licheniformis Carlsberg strain NCIMB 6816, which produces the well-characterized serine protease subtilisin Carlsberg, also degrades and grows on feathers. The PWD-1 and Carlsberg strains showed a similar time-course of enzyme production, and the purified serine proteases have similar enzymatic properties on insoluble azokeratin and soluble FITC-casein. Kinetic analysis of both enzymes demonstrated that they have high specificity for aromatic and hydrophobic amino acids in the P1 substrate position, although keratinase discriminates more than subtilisin Carlsberg against charged residues at this site. Nucleotide sequence analysis of the serine protease genes from B. licheniformis strains PWD-1, Carlsberg NCIMB 6816, ATCC 12759, and NCIMB 10689 showed that the kerA-encoded protease of PWD-1 differs from the others only by having V222, rather than A222, near the active site serine S220. Further, high-level expression of subE-encoded subtilisin from B. subtilis (78% similar to subtilisin Carlsberg) also confers growth on feathers on a protease-deficient B. subtilis strain. While strain PWD-1 and the kerA protease efficiently degrade keratin, keratin hydrolysis and growth on feathers is a property that can be conferred by appropriate expression of the major subtilisins, including the industrially produced enzymes.     

Characterization of Bacillus subtilis strains in Thua nao, a traditional fermented soybean food in northern Thailand

AIMS: To clarify the diversity of Bacillus subtilis strains in Thua nao that produce high concentrations of products useful in food manufacturing and in health-promoting compounds. METHOD AND RESULTS: Production of amylase, protease, subtilisin NAT (nattokinase), and gamma-polyglutamic acid (PGA) by the Bacillus subtilis strains in Thua nao was measured. Productivity of protease NAT by these strains tended to be higher than by Japanese commercial natto-producing strains. Molecular diversity of isolated strains was analysed via randomly amplified polymorphic DNA-PCR fingerprinting. The strains were divided into 19 types, including a type with the same pattern as a Japanese natto-producing strain. CONCLUSION: B. subtilis strains that could be a resource for effective production of protease, amylase, subtilisin NAT, or PGA were evident in Thua nao produced in various regions in northern Thailand. SIGNIFICANCE AND IMPACT OF THE STUDY: This study clearly demonstrated the value of Thua nao as a potential resource of food-processing enzymes and health-promoting compounds.     

Molecular cloning of a subtilisin J gene from Bacillus stearothermophilus and its expression in Bacillus subtilis.

The structural gene for a subtilisin J from Bacillus stearothermophilus NCIMB10278 was cloned in Bacillus subtilis using pZ124 as a vector, and its nucleotide sequence was determined. The nucleotide sequence revealed only one large open reading frame, composed of 1,143 base pairs and 381 amino acid residues. A Shine-Dalgarno sequence was found 8 bp upstream from the translation start site (GTG). The deduced amino acid sequence revealed an N-terminal signal peptide and pro-peptide of 106 residues followed by the mature protein comprised of 275 residues. The productivity of subtilisin in the culture broth of the Bacillus subtilis was about 46-fold higher than that of the Bacillus stearothermophilus. The amino acid sequence of the extracellular alkaline protease subtilisin J is highly homologous to that of subtilisin E and it shows 69% identity with subtilisin Carlsberg, 89% with subtilisin BPN' and 70% with subtilisin DY. Some properties of the subtilisin J that had been purified from the Bacillus subtilis were examined. The subtilisin J has alkaline pH characteristics and a molecular weight of 27,500. It retains about 50% of its activity even after treatment at 60 degrees C for 30 min in the presence of 2 mM calcium chloride.     

Cloning and expression in Bacillus subtilis of the gene for neutral protease of Bacillus brevis

Plasmids pCB20 and pCB22 were used for cloning and expression of the Bac brevis 7882 neutral protease gene in Bac. subtilis cells. The protease-containing fragments of 13 and 14 kb were cloned in pCB20 plasmid based on replication region of Streptococci plasmid pSM19035. Expression of the gene was shown to take place in Bac. subtilis. Application of vegetative promoters of the previously identified expression unit EU19035 greatly increases the expression of the protease in Bac. subtilis. Bac. subtilis cells, expressing the gene of Bac. brevis neutral protease, do not sporulate, are considerably larger than the cells which do not contain the gene and form multicellular structures.     

Analysis of the structure of Bacillus brevis neutral proteinase and its biosynthesis in Bacillus subtilis cells

Amino acid sequence of neutral metalloprotease from Bac. brevis has been compared with that of Bac. amyloloquefaciens, Bac. cereus, Bac. subtilis, Bac. stearothermophilis, Bac. thermoproteolyticus (thermolysine). A sequence region from N-40 to N-1 with a significant degree of homology allowed to predict the processing site of the propart of Bac. brevis enzyme. The sequence comparison allows to put Bac. brevis enzyme within the evolutionary branch of enzymes, which includes thermolysin and proteases of Bac. cereus and Bac. stearothermophilus. Using automated Edman degradation the N-terminal sequence of Bac. brevis protease has been determined. It does not differ from the sequence predicted from the nucleotide sequence of the gene. It was shown that, when Bac. brevis gene coding for thermostable protease is expressed on a plasmid vector in Bac. subtilis cells at 37 degrees C, enzyme forms possessing low activity are secreted. The enzyme may be significantly activated without an additional cleavage or processing and the activation includes numerous conformation transition states of the protein molecule.     

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.     

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.     

Eglin C与2709碱性蛋白酶相互作用分析及亲和纯化方法

Eglin C是来自水蛭中的一种小型热稳定蛋白质,属于马铃薯胰凝乳蛋白酶抑制剂家族,可以抑制弹性蛋白酶、枯草杆菌蛋白酶、组织蛋白酶、α-lytic蛋白酶以及胰凝乳蛋白酶等.然而,利用eglin C纯化蛋白酶,尚未见研究报道.本文将化学合成的编码eglin C及其突变体的基因序列,克隆到原核表达载体pQE30,在大肠杆菌...     

Molecular cloning of a thermostable neutral protease gene from Bacillus stearothermophilus in a vector plasmid and its expression in Bacillus stearothermophilus and Bacillus subtilis.

The structural gene for a thermostable protease from Bacillus stearothermophilus was cloned in plasmid pTB90. It is expressed in both B. stearothermophilus and Bacillus subtilis. B. stearothermophilus carrying the recombinant plasmid produced about 15-fold more protease (310 U/mg of cell dry weight) than did the wild-type strain of B. stearothermophilus. Some properties of the proteases that have been purified from the transformants of B. stearothermophilus and B. subtilis were examined. No significant difference was observed among the enzyme properties studied here despite the difference in host cells. We found that the protease, neutral in pH characteristics and with a molecular weight of 36,000, retained about 80% of its activity even after treatment of 65 degrees C for 30 min.