Secretion of human serum albumin from Bacillus subtilis.

We have fused the structural gene (hsa) for human serum albumin (HSA) to the expression elements and signal sequence coding region of each of two genes from Bacillus amyloliquefaciens P, an alpha-amylase gene (amyBamP) and a neutral protease gene (nprBamP). Bacillus subtilis strains harboring either of these gene fusions synthesized a protein with the antigenic characteristics and size (68 kilodaltons) of HSA. Results from pulse-labeling studies indicated that the bacterially produced HSA was secreted from cells which had been converted to protoplasts. Results from similar studies with intact cells suggested that the signal sequence was removed from the hybrid protein, providing further evidence that B. subtilis can translocate this foreign protein across the cell membrane. Signal sequence removal was efficient when the level of HSA synthesis was low. However, in strains which synthesized HSA at a high level, signal sequence removal was less efficient.     

Cloning and expression of subtilisin amylosacchariticus gene

The gene encoding subtilisin Amylosacchariticus from Bacillus subtilis var. amylosacchariticus was isolated and the entire nucleotide sequence of the coding sequence was determined. The deduced amino acid sequence revealed an N-terminal signal peptide and pro-peptide of 106 residues followed by the mature protein comprising 275 residues. There were discrepancies in 10 amino acids between the sequence elucidated from the nucleotide sequence and the published protein sequence (Kurihara et al. (1972) J. Biol. Chem. 247, 5619-5631). The nucleotide sequence was highly homologous to that of subtilisin E gene from B. subtilis 168, with discrepancies at 12 nucleotides out of 1,426 nucleotides we sequenced. Ten of them were found in mature subtilisin coding sequence, which resulted in two amino acid changes and another one was in the putative promoter region between two genes. The productivity of subtilisin in culture broth of B. subtilis var. amylosacchariticus was much higher than that of B. subtilis 168. The enzyme gene was inserted in a shuttle vector pHY300PLK, with which B. subtilis ISW1214 was transformed. The proteolytic activity found in the culture broth of the transformed bacterium was 20- and 4-fold higher than those of the host strain and B. subtilis var. amylosacchariticus, respectively. Subtilisin Amylosacchariticus was easily purified to a crystalline form from culture filtrate of cloned B. subtilis, after a single step of chromatography on CM-cellulose.     

Highly efficient gene expression of a fibrinolytic enzyme (subtilisin DFE) in Bacillus subtilis mediated by the promoter of α-amylase gene from Bacillus amyloliquefaciens

Subtilisin DFE is a fibrinolytic enzyme produced by Bacillus amyloliquefaciens DC-4. The promoter and signal peptide-coding sequence of alpha-amylase gene from B. amyloliquefaciens was cloned and fused to the sequence coding for pro-peptide and mature peptide of subtilisin DFE. This hybrid gene was inserted into the Escherichia coli/Bacillus subtilis shuttle plasmid vector, pSUGV4. Recombinant subtilisin DFE gene was successfully expressed in B. subtilis WB600 with a fibrinolytic activity of 200 urokinase units ml(-1).     

Requirement of pro-sequence for the production of active subtilisin E in Escherichia coli

Subtilisin E, an alkaline serine protease of Bacillus subtilis 168, is first produced as a precursor, pre-pro-subtilisin, which consists of a signal peptide for protein secretion (pre-sequence) and a peptide extension of 77 amino acid residues (pro-sequence) between the signal peptide and mature subtilisin. When the entire coding region for pre-pro-subtilisin E was cloned into an Escherichia coli expression vector, active mature subtilisin E was secreted into the periplasmic space. When the pre-sequence was replaced with the E. coli OmpA signal peptide, active subtilisin E was also produced. When the OmpA signal peptide was directly fused to the mature subtilisin sequence, no protease activity was detected, although this product had the identical primary structure as subtilisin E as a result of cleavage of the OmpA signal peptide and was produced at a level of approximately 10% of total cellular protein. When the OmpA signal peptide was fused to the 15th or 44th amino acid residue from the amino terminus of the pro-sequence, active subtilisin was also not produced. These results indicate that the pro-sequence of pre-pro-subtilisin plays an important role in the formation of enzymatically active subtilisin. It is proposed that the pro-sequence is essential for guiding appropriate folding of the enzymatically active conformation of subtilisin E.     

Expression of bovine pancreatic ribonuclease A coded by a synthetic gene in Bacillus subtilis

Two different hybrid genes were constructed which fuse the Bacillus amyloliquefaciens alkaline protease gene (apr[BamP]) promoter and signal peptide coding region to a synthetic bpr gene coding for the mature bovine pancreatic RNase A. The first gene fusion (apr-bpr1) contained the apr[BamP] signal peptide coding region fused to mature bpr through a linker coded 3-amino acid region and retained the signal processing site ala-ala of the alkaline protease. The second fusion (apr-bpr2) joined the end of the apr[BamP] signal peptide coding sequence to the mature bpr resulting in a hybrid signal processing site ala-lys. B. subtilis strains harboring these gene fusions secreted bovine pancreatic RNase A into the growth medium. Cleavage at the hybrid signal processing site ala-lys resulted in the secretion of bovine pancreatic RNase A from B. subtilis which had an N-terminal amino acid sequence that was identical to the native RNase A. Bovine pancreatic RNase A contains four disulfide bonds and the proper formation of these bonds is required for activity. RNase activity could be detected in the culture supernatants of strains carrying the apr-bpr gene fusions, which suggests that the proper disulfide bonds have formed spontaneously.     

Translational coupling in Bacillus subtilis of a heterologous Bacillus subtilis-Escherichia coli gene fusion.

Translational coupling was demonstrated in a gene fusion in which the promoter and the N-terminal region of the Bacillus subtilis subtilisin (aprA) gene were fused to a promoterless Tn9-derived chloramphenicol acetyltransferase (CAT; EC 2.3.1.28) gene. Expression of this gene fusion results in the production of a native-sized CAT product, whereas the Tn9-derived CAT gene is usually not translated from its own ribosome binding site in B. subtilis (D. S. Goldfarb, R. L. Rodriguez, and R. H. Doi, Proc. Natl. Acad. Sci. USA 79:5886-5890, 1982). A 178-base-pair deletion, which removed part of the signal peptide and the propeptide of the aprA gene and created a translational stop codon 230 base pairs upstream of the CAT gene ribosome binding site, reduced expression of the CAT gene. A BamHI 10-mer linker insertion into this deletion site, which restored the reading frame and simultaneously removed the translation stop codon, restored CAT gene expression. The data indicate that expression of the CAT gene was dependent on translation of the truncated aprA gene into the ribosome binding site of the CAT gene.     

Secretion of a heterologous protein from Bacillus subtilis with the aid of protease signal sequences.

Secretion vectors based on the genes from Bacillus amyloliquefaciens P for alkaline protease (aprBamP) and neutral protease (nprBamP) were constructed. With both aprBamP and nprBamP, a unique restriction site was introduced 3' of the predicted signal coding region by using the technique of oligonucleotide-directed mutagenesis. The new sites enabled us to fuse a heterologous gene to the expression and secretion elements. We used the protein A gene (spa) from Staphylococcus aureus as a heterologous gene. Bacillus subtilis cells carrying the resulting apr-spa or npr-spa gene fusions synthesized the fusion protein. B. subtilis cells were also capable of removing the signal peptide from the fusion protein, as indicated by the appearance of processed protein A into the growth medium. In addition, these gene fusions allowed us to identify the signal processing site of both the APR-SPA and NPR-SPA proteins.     

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.     

Synthesis of OmpA protein of Escherichia coli K12 in Bacillus subtilis

We have inserted a C-terminally truncated gene of the major outer membrane protein OmpA of Escherichia coli downstream from the promoter and signal sequence of the secretory alpha-amylase of Bacillus amyloliquefaciens in a secretion vector of Bacillus subtilis. B. subtilis transformed with the hybrid plasmid synthesized a protein that was immunologically identified as OmpA. All the protein was present in the particulate fraction. The size of the protein compared to the peptide synthesized in vitro from the same template indicated that the alpha-amylase derived signal peptide was not removed; this was verified by N-terminal amino acid sequence determination. The lack of cleavage suggests that there was little or no translocation of OmpA protein across the cytoplasmic membrane. This is an unexpected difference compared with periplasmic proteins, which were both secreted and processed when fused to the same signal peptide. A requirement of a specific component for the export of outer membrane proteins is suggested.     

Synthesis of Escherichia coli heat-stable enterotoxin STp as a pre-pro form and role of the pro sequence in secretion.

Escherichia coli heat-stable enterotoxin STp is presumed from its DNA sequence to be synthesized in vivo as a 72-amino-acid residue precursor that is cleaved to generate mature STp consisting of the 18 carboxy-terminal amino acid residues. There are two methionine residues in the inferred STp sequence in addition to the methionine residue at position 1. In order to confirm production of the STp 72-amino-acid residue precursor, we substituted the additional methionine residues by oligonucleotide-directed site-specific mutagenesis. Since these substitutions did not cause a significant change in STp production, it can be concluded that STp is normally synthesized as the 72-amino-acid residue precursor. The length of the STp precursor indicated the existence of a pro sequence between the signal peptide and the mature protein. In order to identify the pro sequence and determine its role in protein secretion, deletion and fusion proteins were made. A deletion mutant in which the gene fragment encoding amino acid residues 22 to 53 of STp was removed was made. STp activity was found in the culture supernatant of cells. Amino acid sequence analysis of the purified STp deletion mutant revealed that the pro sequence encompasses amino acid residues 20 to 54. A hybrid protein consisting of STp amino acids 1 to 53 fused in frame from residue 53 to nuclease A was not secreted into the culture supernatant. These results indicate that the pro sequence does not function to guide periplasmic protein into the extracellular milieu.     

Prochymosin expression in Bacillus subtilis

Prochymosin (PC) sequence was cloned in Bacillus subtilis using two kinds of plasmid constructions. In plasmid pSM316 the cDNA was inserted to obtain the intracellular expression of the enzyme. The enzyme turned out to be expressed in an insoluble form which could be converted to native enzyme under proper denaturing and refolding conditions. The levels of intracellular expression of PC were further enhanced by modifying the 5' region of the gene in a way that a two-cistron expression system was created. For the PC secretion, the cDNA was fused to the subtilisin leader sequence and expressed under the control of the B. subtilis neutral protease promoter. A properly folded PC was secreted by the cells, although to low levels.     

Exchange of precursor-specific elements between Pro-sigma E and Pro-sigma K of Bacillus subtilis.

sigma E and sigma K are sporulation-specific sigma factors of Bacillus subtilis that are synthesized as inactive proproteins. Pro-sigma E and pro-sigma K are activated by the removal of 27 and 20 amino acids, respectively, from their amino termini. To explore the properties of the precursor-specific sequences, we exchanged the coding elements for these domains in the sigma E and sigma K structural genes and determined the properties of the resulting chimeric proteins in B. subtilis. The pro-sigma E-sigma K chimera accumulated and was cleaved into active sigma K, while the pro-sigma K-sigma E fusion protein failed to accumulate and is likely unstable in B. subtilis. A fusion of the sigE "pro" sequence to an unrelated protein (bovine rhodanese) also formed a protein that was cleaved by the pro-sigma E processing apparatus. The data suggest that the sigma E pro sequence contains sufficient information for pro-sigma E processing as well as a unique quality needed for sigma E accumulation.     

Secretion of correctly processed and folded pancreatic secretory trypsin inhibitor by Bacillus subtilis.

We constructed a plasmid, designated pNPP126, containing a DNA sequence encoding a fusion protein composed of Bacillus amyloliquefaciens neutral protease prepeptide (signal peptide) and human pancreatic secretory trypsin inhibitor (hPSTI), where the mature hPSTI is accurately fused to the 3'-terminal of the prepeptide coding region. It was observed that the strain Bacillus subtilis MT600 harboring pNPP126 could secrete a trypsin inhibitory activity into the culture medium. The N-terminal amino acid sequence, the amino acid composition and the stoichiometry of the purified hPSTI produced by B. subtilis were the same as those of natural hPSTI, indicating that the transformant B. subtilis MT600 (pNPP126) could efficiently secrete the correctly processed and folded hPSTI into the culture medium.     

Identification of two novel fibrinolytic enzymes from Bacillus subtilis QK02

Two fibrinolytic enzymes (QK-1 and QK-2) purified from the supernatant of Bacillus subtilis QK02 culture broth had molecular masses of 42,000 Da and 28,000 Da, respectively. The first 20 amino acids of the N-terminal sequence are AQSVPYGISQ IKAPALHSQG. The deduced protein sequence and its restriction enzyme map of the enzyme QK-2 are different from those of other proteases. The enzyme QK-2 digested not only fibrin but also a subtilisin substrate, and PMSF inhibited its fibrinolytic and amidolytic activities completely; while QK-1 hydrolyzed fibrin and a plasmin substrate, and PMSF as well as aprotinin inhibited its fibrinolytic activity. These results indicated QK-1 was a plasmin-like serine protease and QK-2 a subtilisin family serine protease. Therefore, these enzymes were designated subtilisin QK. The sequence of a DNA fragment encoding subtilisin QK contained an open reading frame of 1149 base pairs encoding 106 amino acids for signal peptide and 257 amino acids for subtilisin QK, which is highly similar with that of a fibrinolytic enzyme, subtilisin NAT (identities 96.8%). Asp32, His64 and Ser221 in the amino acid sequence deduced from the QK gene are identical to the active site of nattokinase (NK) produced by B. subtilis natto.     

Genetic system constructed to overproduce and secrete proinsulin in<Emphasis Type="Italic"> Bacillus subtilis</Emphasis>

The first amino acid residue from a proinsulin gene was fused in frame with the last amino acid residue of the aprE signal peptide sequence from Bacillus subtilis, using an overlapping PCR methodology. For expression of the fused DNA the aprE regulatory region (aprERR) was used. A six-protease-deficient strain of B. subtilis with the hpr2 and degU32 mutations was constructed for overproduction of the recombinant protein. The production of proinsulin was carried out in a mineral medium which facilitated the purification of proinsulin. Samples were taken during growth and analyzed by RIA and Western blot. Proinsulin was overproduced (1 mg ml(-1)) and 90% was secreted into the culture medium 1 h after stationary phase began.     

Expression of Bacillus amyloliquefaciens amylase and Vibrio alginolyticus protease A fusion genes.

Previously we reported [Deane, S. M., Maharaj, R., Robb, F. T. & Woods, D. R. (1987) Journal of General Microbiology 133, 2295-2302] that the production of a Vibrio alginolyticus SDS-resistant alkaline serine protease (Pro A) cloned in Escherichia coli was characterized by a 12 h delay between the synthesis of an inactive precursor and secretion of active Pro A. Replacement of the V. alginolyticus promoter region by the alpha-amylase promoter region from Bacillus amyloliquefaciens resulted in the simultaneous synthesis and secretion of Pro A in E. coli. The V. alginolyticus pro A gene cloned on a shuttle vector did not produce active Pro A in Bacillus subtilis. Although Pro A has a typical Gram-positive signal sequence, it was not functional in B. subtilis. Replacement of the Pro A signal sequence with the alpha-amylase signal sequence resulted in the production of active Pro A in B. subtilis.