Cloning, nucleotide sequence, and expression of Achromobacter protease I gene

Achromobacter protease I (API) is a lysine-specific serine protease which hydrolyzes specifically the lysyl peptide bond. A gene coding for API was cloned from Achromobacter lyticus M497-1. Nucleotide sequence of the cloned DNA fragment revealed that the gene coded for a single polypeptide chain of 653 amino acids. The N-terminal 205 amino acids, including signal peptide and the threonine/serine-rich C-terminal 180 amino acids are flanking the 268 amino acid-mature protein which was identified by protein sequencing. Escherichia coli carrying a plasmid containing the cloned API gene overproduced and secreted a protein of Mr 50,000 (API') into the periplasm. This protein exhibited a distinct endopeptidase activity specific for lysyl bonds as well. The N-terminal amino acid sequence of API' was the same as mature API, suggesting that the enzyme retained the C-terminal extended peptide chain. The present experiments indicate that API, an extracellular protease produced by gram-negative bacteria, is synthesized in vivo as a precursor protein bearing long extended peptide chains at both N and C termini.     

Nucleotide sequence of the Vibrio alginolyticus calcium-dependent, detergent-resistant alkaline serine exoprotease A

The nucleotide sequence of the Vibrio alginolyticus alkaline serine exoprotease A (ProA) gene cloned in Escherichia coli was determined. The exoprotease A gene (proA) consisted of 1602 bp which encoded a protein of 534 amino acids (aa) with an Mr of 55,900. The region upstream from the gene was characterized by a putative promoter consensus region (-10 -35), a ribosome-binding site and ATG start codon. The proA gene encodes a typical 21-aa N-terminal signal sequence which, when fused to alkaline phosphatase by means of transposon TnphoA, was able to mediate transport of the alkaline phosphatase to the periplasm in E. coli. Deletions of up to 106 aa from the C terminus of ProA did not result in the loss of extracellular protease activity. Additional V. alginolyticus genes were not involved in the secretion into the medium of the cloned ProA in E. coli. The amino acid sequence of ProA showed low overall homology to a Serratia marcescens serine exoprotease but significant homology was detected with other subtilisin family exoproteases. The fungal proteinase K, another sodium dodecyl sulfate-resistant protease, had 44% aa homology with ProA.     

Cloning and sequencing of Serratia protease gene.

The gene encoding an extracellular metalloproteinase from Serratia sp. E-15 has been cloned, and its complete nucleotide sequence determined. The amino acid sequence deduced from the nucleotide sequence reveals that the mature protein of the Serratia protease consists of 470 amino acids with a molecular weight of 50,632. The G+C content of the coding region for the mature protein is 58%; this high G+C content is due to a marked preference for G+C bases at the third position of the codons. The gene codes for a short pro-peptide preceding the mature protein. The Serratia protease gene was expressed in Escherichia coli and Serratia marcescens; the former produced the Serratia protease in the cells and the latter in the culture medium. Three zinc ligands and an active site of the Serratia protease were predicted by comparing the structure of the enzyme with those of thermolysin and Bacillus subtilis neutral protease.     

Detection of large COOH-terminal domains processed from the precursor of Serratia marcescens serine protease in the outer membrane of Escherichia coli.

The Serratia marcescens serine protease gene encoding a 1,045-amino-acid precursor protein of 112 kDa directs excretion of the mature protease of ca. 58 kDa through the outer membrane of Escherichia coli. A typical signal peptide of 27 amino acids and a large COOH-terminal domain of the precursor are both functionally essential for the excretion of the mature protease into the medium. Sequence analysis of the fragment peptides of the mature protease as well as site-directed mutagenesis indicated that the COOH-terminus of the mature enzyme was Asp645. By using the polyclonal antibody against the 112-kDa precursor protein, not only the intact precursor but also two proteins, C-1 (40 kDa) and C-2 (38 kDa), corresponding to the processed COOH-terminal domains were detected in the insoluble fraction of E. coli cells. Further fractionation by sucrose density gradient centrifugation showed that C-1 and C-2 were localized in the outer membrane. The NH2-terminal residues of C-1 and C-2 were determined to be Ala702 and Phe717, respectively. All these data suggest that the precursor is cleaved at three positions, between Asp645-Ser646, Glu701-Ala702, and Gly716-Phe717, probably by the self-processing activity in the normal excretion pathway through the outer membrane.     

Characterization of the precursor of Serratia marcescens serine protease and COOH-terminal processing of the precursor during its excretion through the outer membrane of Escherichia coli.

The Serratia marcescens serine protease, which is directed by the gene encoding a precursor composed of a typical NH2-terminal signal sequence, a mature enzyme domain, and a large COOH-terminal domain, was excreted through the outer membrane of Escherichia coli. The precursor, with the expected molecular size (110 kilodaltons), was detected in an insoluble form in the periplasmic space of E. coli cells after induction with isopropyl-beta-D-thiogalactopyranoside of the expression of the gene under the control of the tac promoter. Upon membrane fractionation of the disrupted cells by sucrose density gradient centrifugation, the precursor was recovered from a fraction slightly heavier than the outer membrane fraction but not from the inner membrane fraction. Conversion of the precursor into the mature form, which was accompanied by its excretion into the medium, was observed even in the absence of de novo protein synthesis caused by the addition of chloramphenicol. The mutated gene product lacking all of the COOH-terminal domain was localized in the periplasmic space only and was not excreted into the medium. Additional mutant genes were generated by site-directed mutagenesis to test the role of some amino acids in the excretion of this protease in E. coli. The mutant protein with no protease activity because of the change of the catalytic residue Ser-341 to Thr was still excreted into the medium but with abnormal processing. Both self-processing and host-dependent processing of the precursor seem to be involved in the excretion of the mature enzyme. Replacement of the four Cys residues, two in the mature enzyme and two in the COOH-terminal domain, with Ser in different combinations caused a distinct or complete loss of excretion, suggesting that a certain conformation possibly formed via disulfide bonding was important for the excretion of the S. marcescens protease.     

Protease II from Escherichia coli: sequencing and expression of the enzyme gene and characterization of the expressed enzyme.

Protease II gene of Escherichia coli HB101 was cloned and expressed in E. coli JM83. The transformant harboring a hybrid plasmid, pPROII-12, with a 2.4 kbp fragment showed 90-fold higher enzyme activity than the host. The whole nucleotide sequence of the inserted fragment of plasmid pPROII-12 was clarified by the dideoxy chain-terminating method. The sequence that encoded the mature enzyme protein was found to start at an ATG codon, as judged by comparison with amino terminal protein sequencing. The molecular weight of the enzyme was estimated to be 81,858 from the nucleotide sequence. The reactive serine residue of protease II was identified as Ser-532 with tritium DFP. The sequence around the serine residue is coincident with the common sequence of Gly-X-Ser-X-Gly, which has been found in the active site of serine proteases. Except for this region, protease II showed no significant sequence homology with E. coli serine proteases, protease IV and protease La (lon gene), or other known families of serine proteases. However, 25.3% homology was observed between protease II and prolyl endopeptidase from porcine brain. Although the substrate specificities of these two enzymes are quite different, it seems possible to classify protease II as a member of the prolyl endopeptidase family from the structural point of view.     

Characterization of a protein inhibitor of extracellular proteases produced by Erwinia chrysanthemi

Erwinia chrysanthemi, a phytopathogenic bacterium, produces a protease inhibitor which is a low-molecular-weight, heat-stable protein. In addition to its action on the three E. chrysanthemi extracellular proteases A, B and C, it also strongly inhibits the 50 kD extracellular protease of Serratia marcescens. Its structural gene (inh) was subcloned and expressed in Escherichia coli, in which it encodes an active inhibitor which was purified. The nucleotide sequence of the inh gene shows an open reading frame of 114 condons. The N-terminal amino acid sequence of the purified inhibitor was also determined. It indicated the existence of an amino-terminal signal peptide absent from the mature protein. The inhibitor is entirely periplasmic in E. chrysanthemi and partially periplasmic in E. coli.     

Genes on the 90-kilobase plasmid of Salmonella typhimurium confer low-affinity cobalamin transport: relationship to fimbria biosynthesis genes.

A cloned fragment of Salmonella typhimurium DNA complemented the defect in cobalamin uptake of Escherichia coli or S. typhimurium btuB mutants, which lack the outer membrane high-affinity transport protein. This DNA fragment did not carry btuB and was derived from the 90-kb plasmid resident in S. typhimurium strains. The cobalamin transport activity engendered by this plasmid had substantially lower affinity and activity than that conferred by btuB. Complementation behavior and maxicell analyses of transposon insertions showed that the cloned fragment encoded five polypeptides, at least two of which were required for complementation activity. The nucleotide sequence of the coding region for one of these polypeptides, an outer membrane protein of about 84,000 Da, was determined. The deduced polypeptide had properties typical of outer membrane proteins, with an N-terminal signal sequence and a predicted preponderance of beta structure. This outer membrane protein had extensive amino acid sequence homology with PapC and FaeD, two E. coli outer membrane proteins involved in the export and assembly of pilus and fimbria subunits on the cell surface. This homology raises the likelihood that the observed cobalamin transport did not result from the production of an authentic transport system but that overexpression of one or more outer membrane proteins allowed leakage of cobalamins through the perturbed outer membrane. These results also suggest that the 90-kb plasmid carries genes encoding an adherence mechanism.     

Purification, characterization, and primary structure of Escherichia coli protease VII with specificity for paired basic residues: identity of protease VII and OmpT.

Escherichia coli cells were found to contain a novel outer membrane-associated protease, designated protease VII (K. Sugimura and N. Higashi, J. Bacteriol. 170:3650-3654, 1988). This enzyme was purified to homogeneity and exhibited an apparent molecular weight of 36,000 on sodium dodecyl sulfate gels and 180,000 on a TSK G-3000SW column in the presence of Triton X-100. It was capable of cleaving several peptides at the center of paired basic residues but not at single basic residues, implying that it is distinct from trypsinlike proteases. Protease VII was most active at pH 6.0 and was sensitive to a serine protease inhibitor, diisopropylfluorophosphate, and to the bivalent cations Zn2+, Cu2+, and Fe2+. The nucleotide sequence of a protease VII gene-carrying DNA fragment, which had been cloned by complementation analysis (K. Sugimura, Biochem. Biophys. Res. Commun. 153:753-759, 1988) was determined. It carried two putative promoter regions and a putative Shine-Dalgarno sequence in addition to the complete structural gene, which encoded pre-protease VII of 317 amino acid residues, with the N-terminal 20 residues being a signal peptide. By comparing their amino acid sequences, protease VII and OmpT, which specifically cleaves ferric enterobactin receptor protein, were found to be identical.     

An endochitinase A from Vibrio carchariae: cloning, expression, mass and sequence analyses, and chitin hydrolysis

We provide evidence that chitinase A from Vibrio carchariae acts as an endochitinase. The chitinase A gene isolated from V. carchariae genome encodes 850 amino acids expressing a 95-kDa precursor. Peptide masses of the native enzyme identified from MALDI-TOF or nanoESIMS were identical with the putative amino acid sequence translated from the corresponding nucleotide sequence. The enzyme has a highly conserved catalytic TIM-barrel region as previously described for Serratia marcescens ChiA. The Mr of the native chitinase A was determined to be 62,698, suggesting that the C-terminal proteolytic cleavage site was located between R597 and K598. The DNA fragment that encodes the processed enzyme was subsequently cloned and expressed in Escherichia coli. The expressed protein exhibited chitinase activity on gel activity assay. Analysis of chitin hydrolysis using HPLC/ESI-MS confirmed the endo characteristics of the enzyme.     

Cloning and expression in Escherichia coli of the gene for extracellular phospholipase A1 from Serratia liquefaciens.

From a genomic library of Serratia liquefaciens, a cloned DNA fragment comprising a two-gene operon was isolated and expressed in Escherichia coli. One of the gene products was identified as a phospholipase A1, and the enzyme was found to be excreted to the outer environment from S. liquefaciens as well as from E. coli. Both genes were sequenced, and the relationship between open reading frames in the DNA sequence and in vitro-expressed polypeptides was established. The length of the phospholipase polypeptide was found to be 319 amino acids. In the amino-terminal end of the coding sequence was a stretch of about 20 hydrophobic amino acids, but, in contrast to consensus signal peptides, no basic residues were present. The length of the second polypeptide was 227 amino acids. It was found that expression of the phospholipase gene in both E. coli and S. liquefaciens was growth phase regulated (late expression).     

Primary structure of the oligo-1,6-glucosidase of Bacillus cereus ATCC7064 deduced from the nucleotide sequence of the cloned gene

The gene coding for Bacillus cereus ATCC7064 (mesophile) oligo-1,6-glucosidase was cloned within a 2.8-kb SalI-EcoRI fragment of DNA, using the plasmid pUC19 as a vector and Escherichia coli C600 as a host. E. coli C600 bearing the hybrid plasmid pBCE4 accumulated oligo-1,6-glucosidase in the cytoplasm. The cloned enzyme coincided absolutely with B. cereus oligo-1,6-glucosidase in its Mr (65,000), in its electrophoretic behavior on a polyacrylamide gel with or without sodium dodecyl sulfate, in its isoelectric point (4.5), in the temperature dependence of its stability and activity, and in its antigenic determinants. The nucleotide sequence of B. cereus oligo-1,6-glucosidase gene and its flanking regions was determined with both complementary strands of DNA (each 2838 nucleotides). The gene consisted of an open reading frame of 1674 bp commencing with a ATG start codon and followed by a TAA stop codon. The amino acid sequence deduced from the nucleotide sequence predicted a protein of 558 amino acid residues with a Mr of 66,010. The amino acid composition and Mr were comparable with those of B. cereus oligo-1,6-glucosidase. The predicted N-terminal sequence of 10 amino acid residues agreed completely with that of the cloned ligo-1,6-glucosidase. The deduced amino acid sequence of B. cereus oligo-1,6-glucosidase was 72% and 42% similar to those from Bacillus thermoglucosidasius KP1006 (DSM2542, obligate thermophile) oligo-1,6-glucosidase and from Saccharomyces carlsbergensis CB11 alpha-glucosidase, respectively. Predictions of protein secondary structures along with amino acid sequence alignments demonstrated that B. cereus oligo-1,6-glucosidase may take the similar (alpha/beta)8-barrel super-secondary structure, a barrel of eight parallel beta-strands surrounded by eight alpha-helices, in its N-terminal active site domain as S. carlsbergensis alpha-glucosidase and Aspergillus oryzae alpha-amylase.     

Molecular analysis of the gene encoding α-lytic protease: evidence for a preproenzyme

A 1.7-kb EcoRI fragment containing the structural gene for α-lytic protease has been cloned from Lysobacter enzymogenes 495 chromosomal DNA: the first example of a gene cloned from this organism. The protein sequence deduced from the nucleotide sequence encoding this serine protease matches the published amino acid sequence [Olson et al., Nature 228 (1970) 438–442] precisely. Sequence analysis and S 1 mapping indicate that, like subtilisin [e.g. Wells et al., Nucleic Acids Res. 11 (1983) 7911–7925] α-lytic protease is synthesized as a pre-pro protein (41 kDa) that is subsequently processed to its mature extracellular form (20 kDa). This first finding of a large N-terminal protease precursor in a Gram-negative bacterial protease strengthens the hypothesis that large precursors may be a general property of extracellular bacterial proteases, and suggests that the N- or C-terminal location of the precursor segment may be significant.     

Identification of two components of the Serratia marcescens metalloprotease transporter: protease SM secretion in Escherichia coli is TolC dependent.

The Serratia marcescens metalloprotease (protease SM) belongs to a family of proteins secreted from gram-negative bacteria by a signal peptide-independent pathway which requires a specific transporter consisting of three proteins: two in the inner membrane and one in the outer membrane. The prtDSM and prtESM genes encoding the two S. marcescens inner membrane components were cloned and expressed in Escherichia coli. Their nucleotide sequence revealed high overall homology with the two analogous inner membrane components of the Erwinia chrysanthemi protease secretion apparatus and lower, but still significant, homology with the two analogous inner membrane components of the E. coli hemolysin transporter. When expressed in E. coli, these two proteins, PrtDSM and PrtESM, allowed the secretion of protease SM only in the presence of TolC protein, the outer membrane component of the hemolysin transporter.     

Isolation of a yeast gene, SRH1, that encodes a homologue of the 54K subunit of mammalian signal recognition particle

A 1.7 kilobase HindIII fragment of Saccharomyces cerevisiae DNA was cloned by cross-hybridization with the Escherichia coli secY gene. The complete nucleotide sequence of the 2.6 kb fragment of the yeast genomic DNA containing the cross-hybridizing HindIII fragment was determined. The sequence showed no apparent similarity with that of the E. coli secY gene with the exception of a completely matched sequence of 21 bp, but it contained a 1,623 nucleotide open reading frame coding for a protein of 541 amino acids with a calculated Mr of 59,600. The N-terminal portion of 303 residues of the predicted sequence was homologous to the cytosolic domain of the alpha-subunit of the signal recognition particle receptor (SR alpha), including consensus sequence elements for a GTP binding site, whereas the C-terminal portion of 238 residues had an unusual methionine-rich domain containing several repetitive sequences. An mRNA of 2.0 kb was detected on Northern blotting analysis. The predicted sequence was 48% identical with the reported sequences of the 54K subunit of the mammalian signal recognition particle (SRP54) (Romisch K. et al. (1989) Nature 340, 478-483; Bernstein, H.D. et al. (1989) Nature 340, 482-486). We designated this gene as SRH1 (SRP54 homologue). Gene disruption experiments showed that the SRH1 gene product is essential for cell growth.     

Isolation, molecular characterization and expression of the ushB gene of Salmonella typhimurium which encodes a membrane-bound UDP-sugar hydrolase

The UDP-sugar hydrolase of Salmonella typhimurium has previously been reported to be located in both the inner and the outer membrane. We have cloned the gene, designated ushB, encoding this enzyme and determined its nucleotide sequence. No significant sequence homology with the periplasmic UDP-sugar hydrolase of Escherichia coli was found at either the DNA or protein level. However, a sequence is detectable, in the E. coli genome, which weakly hybridizes with a specific ushB probe. Polypeptide analysis has allowed the identification of the Salmonella hydrolase which has an Mr of 28,349 as compared to an Mr of 60,767 for the E. coli hydrolase. Most of the protein (approximately 90%) is located in the inner membrane. Two independent membrane fractionation procedures indicate that the remainder may be associated with the outer membrane. The deduced primary structure indicates the presence of an N-terminal signal peptide, although certain features of the region surrounding the putative processing site indicate that processing may be inefficient, or may not occur. Experiments with several inhibitors of signal peptidase function fail to demonstrate the appearance of a precursor form.     

The three genes lipB, lipC, and lipD involved in the extracellular secretion of the Serratia marcescens lipase which lacks an N-terminal signal peptide.

The extracellular lipase of Serratia marcescens Sr41, lacking a typical N-terminal signal sequence, is secreted via a signal peptide-independent pathway. The 20-kb SacI DNA fragment which allowed the extracellular lipase secretion was cloned from S. marcescens by selection of a phenotype conferring the extracellular lipase activity on the Escherichia coli cells. The subcloned 6.5-kb EcoRV fragment was revealed to contain three open reading frames which are composed of 588, 443, and 437 amino acid residues constituting an operon (lipBCD). Comparisons of the deduced amino acid sequences of the lipB, lipC, and lipD genes with those of the Erwinia chrysanthemi prtDEC, prtEEC, and prtFEC genes encoding the secretion apparatus of the E. chrysanthemi protease showed 55, 46, and 42% identity, respectively. The products of the lipB and lipC genes were 54 and 45% identical to the S. marcescens hasD and hasE gene products, respectively, which were secretory components for the S. marcescens heme-binding protein and metalloprotease. In the E. coli DH5 cells, all three lipBCD genes were essential for the extracellular secretion of both S. marcescens lipase and metalloprotease proteins, both of which lack an N-terminal signal sequence and are secreted via a signal-independent pathway. Although the function of the lipD gene seemed to be analogous to those of the prtFEC and tolC genes encoding third secretory components of ABC transporters, the E. coli TolC protein, which was functional for the S. marcescens Has system, could not replace LipD in the LipB-LipC-LipD transporter reconstituted in E. coli. These results indicated that these three proteins are components of the device which allows extracellular secretion of the extracellular proteins of S. marcescens and that their style is similar to that of the PrtDEF(EC) system.     

The lipA gene of Serratia marcescens which encodes an extracellular lipase having no N-terminal signal peptide.

The lipA gene encoding an extracellular lipase was cloned from the wild-type strain of Serratia marcescens Sr41. Nucleotide sequencing showed a major open reading frame encoding a 64.9-kDa protein of 613 amino acid residues; the deduced amino acid sequence contains a lipase consensus sequence, GXSXG. The lipase had 66 and 56% homologies with the lipases of Pseudomonas fluorescens B52 and P. fluorescens SIK W1, respectively, but did not show any overall homology with lipases from other origins. The Escherichia coli cells carrying the S. marcescens lipA gene did not secrete the lipase into the medium. The S. marcescens lipase had no conventional N-terminal signal sequence but was also not subjected to any processing at both the N-terminal and C-terminal regions. A specific short region similar to the regions of secretory proteins having no N-terminal signal peptide was observed in the amino acid sequence. Expression of the lipA gene in S. marcescens was affected by the carbon source and the addition of Tween 80.     

Molecular cloning and nucleotide sequence of the 90k serine protease gene,hspK, from Bacillus subtilis (natto) No. 16

We previously reported purification and characterization of a 90k serine protease with pI 3.9 from Bacillus subtilis (natto) No. 16 [Kato et al. 1992 Biosci Biotechnol Biochem 56:1166]. The enzyme showed different and unique substrate specificity towards the oxidized B-chain of insulin from those of well-known bacterial serine proteases from Bacillus subtilisins. The structural gene, hspK, for the 90k serine protease was cloned and sequenced. The cloned DNA fragment contained a single open reading frame of 4302 bp coding a protein of 1433 amino acid residues. The deduced amino acid sequence of the 90k-protease indicated the presence of a typical signal sequence of the first 30 amino acids region and that there was a pro-sequence of 164 amino acid residues after the signal sequence. The mature region of the 90k-protease started from position 195 of amino acid residue, and the following peptide consisted of 1239 amino acid residues with a molecular weight of 133k. It might be a precursor protein of the 90k-protease, and the C-terminal region of 43k might be degraded to a mature protein from the precursor protein. The catalytic triad was thought to consist of Asp33, His81, and Ser259 from comparison of the amino acid sequence of the 90k-protease with those of the other bacterial serine proteases. The high-molecular-weight serine protease, the 90k-protease, may be an ancient form of bacterial serine proteases.