Role of the COOH-terminal pro-sequence of aqualysin I (a heat-stable serine protease) in its extracellular secretion by Thermus thermophilus

Aqualysin I is a subtilisin-type serine protease secreted into the medium by Thermus aquaticus YT-1. Thermus thermophilus cells harboring a plasmid for the aqualysin I precursor secreted pro-aqualysin I with the C-terminal pro-sequence into the culture medium, and the precursor was then processed to the mature enzyme during the cultivation. However, the extracellular levels of aqualysin I in T. thermophilus cells harboring plasmids for deletion mutants as to the C-terminal pro-sequence were about 10–20% in comparison with the level of wild-type. Only the mature enzyme could be detected in the medium, while pro-aqualysin I with the C-terminal pro-sequence could not. These results suggest that the C-terminal pro-sequence of aqualysin I plays an important role in the extracellular secretion of aqualysin I.     

Production of hydrolytic enzymes by oral isolates of Eikenella corrodens

Abstract Thermus thermophilus cells harboring an expression plasmid for the aqualysin I gene secrete the mature enzyme into the medium. In an Escherichia coli expression system, a precursor of the enzyme with the C-terminal pro-sequence is accumulated in the cells, and upon treatment at 65°C the active enzyme is produced. One- to 10-amino acid residue deletions, as well as complete 105-residue deletion of the C-terminal pro-sequence from the C-terminus, did not affect the production of the enzyme in T. coli cells. T. thermophilus cells harboring plasmids for mutant precursors with one- and three-residue deletions secreted the enzyme extracellularly. However, transformants harboring plasmids for mutant precursors with deletions of five or more amino acid residues could not be obtained. These results suggest that the C-terminal pro-sequence plays an important role in the extracellular secretion of the enzyme in T. thermophilus cells.     

Production and Extracellular Secretion of Aqualysin I (a Thermophilic Subtilisin-Type Protease) in a Host-Vector System for Thermus thermophilus

Aqualysin I is synthesized as a large precursor, processed, and secreted into the culture medium by Thermus aquaticus YT-1. An expression plasmid for the aqualysin I gene in T. thermophilus HB27 was constructed. T. thermophilus cells harboring the recombinant plasmid produced correctly processed aqualysin I, and the mature enzyme was secreted into the culture medium.     

Development of plasmid cloning vectors for Thermus thermophilus HB8: expression of a heterologous, plasmid-borne kanamycin nucleotidyltransferase gene.

While several Thermus genes have been cloned and T. thermophilus has been shown to be transformable, molecular genetic studies of these thermophiles have been hampered by the absence of selectable cloning vectors. We have constructed a selectable plasmid by random insertion of a heterologous gene encoding a thermostable kanamycin nucleotidyltransferase activity into a cryptic, multicopy plasmid from T. thermophilus HB8. This plasmid should serve as a suitable starting point for the development of a gene expression system for T. thermophilus.     

Development of plasmid cloning vectors for Thermus thermophilus HB8: expression of a heterologous, plasmid-borne kanamycin nucleotidyltransferase gene.

While several Thermus genes have been cloned and T. thermophilus has been shown to be transformable, molecular genetic studies of these thermophiles have been hampered by the absence of selectable cloning vectors. We have constructed a selectable plasmid by random insertion of a heterologous gene encoding a thermostable kanamycin nucleotidyltransferase activity into a cryptic, multicopy plasmid from T. thermophilus HB8. This plasmid should serve as a suitable starting point for the development of a gene expression system for T. thermophilus.     

A high-transformation-efficiency cloning vector for Thermus thermophilus.

The cloning vector pMK18 was developed through the fusion of the minimal replicative region from an indigenous plasmid of Thermus sp. ATCC27737, a gene cassette encoding a thermostable resistance to kanamycin, and the replicative origin and multiple cloning site of pUC18. Plasmid pMK18 showed transformation efficiencies from 10(8) to 10(9) per microgram of plasmid in Thermus thermophilus HB8 and HB27, both by natural competence and by electroporation. We also show that T. thermophilus HB27 can take pMK18 modified by the Escherichia coli methylation system with the same efficiency as its own DNA. To demonstrate its usefulness as a cloning vector, a gene encoding the beta-subunit of a thermostable nitrate reductase was directly cloned in T. thermophilus HB27 from a gene library. Its further transfer to E. coli also proved its utility as a shuttle vector.     

Two versatile shuttle vectors for Thermus thermophilus-Escherichia coli containing multiple cloning sites, lacZα gene and kanamycin or hygromycin resistance marker

Two versatile shuttle vectors for Thermus thermophilus and Escherichia coli were developed on the basis of the T. thermophilus cryptic plasmid pTT8 and E. coli vector pUC13. These shuttle vectors, pTRK1T and pTRH1T, carry a gene encoding a protein homologous to replication protein derived from pTT8, a replicon for E. coli, new multiple cloning sites and a lacZα gene from E. coli vector pUC13, and also have a gene encoding a thermostable protein that confers resistance to kanamycin or hygromycin, which can be used as a selection marker in T. thermophilus. These shuttle vectors are useful to develop enzymes and proteins of biotechnological interest. We also constructed a plasmid, pUC13T, which carries the same multiple cloning sites of pTRK1T and pTRH1T. These vectors should facilitate cloning procedures both in E. coli and T. thermophilus.     

Production of recombinant alpha-galactosidases in Thermus thermophilus

A Thermus thermophilus selector strain for production of thermostable and thermoactive alpha-galactosidase was constructed. For this purpose, the native alpha-galactosidase gene (agaT) of T. thermophilus TH125 was inactivated to prevent background activity. In our first attempt, insertional mutagenesis of agaT by using a cassette carrying a kanamycin resistance gene led to bacterial inability to utilize melibiose (alpha-galactoside) and galactose as sole carbohydrate sources due to a polar effect of the insertional inactivation. A Gal(+) phenotype was assumed to be essential for growth on melibiose. In a Gal(-) background, accumulation of galactose or its metabolite derivatives produced from melibiose hydrolysis could interfere with the growth of the host strain harboring recombinant alpha-galactosidase. Moreover, the AgaT(-) strain had to be Km(s) for establishment of the plasmids containing alpha-galactosidase genes and the kanamycin resistance marker. Therefore, a suitable selector strain (AgaT(-) Gal(+) Km(s)) was generated by applying integration mutagenesis in combination with phenotypic selection. To produce heterologous alpha-galactosidase in T. thermophilus, the isogenes agaA and agaB of Bacillus stearothermophilus KVE36 were cloned into an Escherichia coli-Thermus shuttle vector. The region containing the E. coli plasmid sequence (pUC-derived vector) was deleted before transformation of T. thermophilus with the recombinant plasmids. As a result, transformation efficiency and plasmid stability were improved. However, growth on minimal agar medium containing melibiose was achieved only following random selection of the clones carrying a plasmid-based mutation that had promoted a higher copy number and greater stability of the plasmid.     

Nucleotide sequence of the gene for aqualysin I (a thermophilic alkaline serine protease) of Thermus aquaticus YT-1 and characteristics of the deduced primary structure of the enzyme

Aqualysin I is an alkaline serine protease which is secreted into the culture medium by Thermus aquaticus YT-1, an extreme thermophile [Matsuzawa, H., Hamaoki, M. & Ohta, T. (1983) Agric. Biol. Chem. 47, 25-28]. The gene encoding aqualysin I was cloned into Escherichia coli using synthetic oligodeoxyribonucleotides as hybridization probes. The nucleotide sequence of the cloned DNA was determined. The primary structure of aqualysin I, deduced from the nucleotide sequence, agreed with the NH2-terminal sequence previously reported and the determined amino acid sequences, including the COOH-terminal sequence, of the tryptic peptides derived from aqualysin I. Aqualysin I comprised 281 amino acid residues and its molecular mass was determined to be 28,350. On alignment of the whole amino acid sequence, aqualysin I showed high sequence homology with the subtilisin-type serine proteases, and 43% identity with proteinase K, 37-39% with subtilisins and 34% with thermitase. Extremely high sequence identity was observed in the regions containing the active-site residues, corresponding to Asp32, His64 and Ser221 of subtilisin BPN'. The nucleotide sequence of the cloned DNA (1105 nucleotides) revealed that it contains the entire gene encoding aqualysin I and one open reading frame without a translational stop codon. Therefore, aqualysin I was considered to be produced as a large precursor, which contains a NH2-terminal portion, the protease and a COOH-terminal portion. The G + C content of the coding region for aqualysin I was 64.6%, which is lower than those of other Thermus genes (68-74%). The codon usage in the aqualysin I gene was rather random in comparison with that in other Thermus genes.     

Construction of an expression system for aqualysin I in Escherichia coli that gives a markedly improved yield of the enzyme protein

An expression system for aqualysin I from Thermus aquaticus YT-1, a thermophilic serine protease belonging to the proteinase K family, in Escherichia coli is available, but the efficiency of production has been rather low for detailed analysis of the product. We developed a maltose biding protein (MBP)-fused proaqualysin I expression plasmid (pMAQ-c2Delta) in which MBP is attached to the N-terminus of proaqualysin I. MBP appeared effectively to suppress the folding-promoting activity of the N-terminal propeptide when the bacteria were grown at 30 degrees C, leading to a massive accumulation of fusion aqualysin I precursor. The precursor was converted efficiently to mature aqualysin I by heat treatment at 70 degrees C, enabling us to obtain 40 times more aqualysin I than is available using expression systems such as pAQNDeltaC105. By analyzing the product of the pMAQ-c2Delta-derived inactive mutant expression vector, pMAQ-S222A, it was confirmed that aqualysin I was initially expressed as a whole fusion protein and then processed autocatalytically.     

Construction of an Expression System for Aqualysin I in Escherichia coli That Gives a Markedly Improved Yield of the Enzyme Protein

An expression system for aqualysin I from Thermus aquaticus YT-1, a thermophilic serine protease belonging to the proteinase K family, in Escherichia coli is available, but the efficiency of production has been rather low for detailed analysis of the product. We developed a maltose biding protein (MBP)-fused proaqualysin I expression plasmid (pMAQ-c2Δ) in which MBP is attached to the N-terminus of proaqualysin I. MBP appeared effectively to suppress the folding-promoting activity of the N-terminal propeptide when the bacteria were grown at 30 °C, leading to a massive accumulation of fusion aqualysin I precursor. The precursor was converted efficiently to mature aqualysin I by heat treatment at 70 °C, enabling us to obtain 40 times more aqualysin I than is available using expression systems such as pAQNΔC105. By analyzing the product of the pMAQ-c2Δ-derived inactive mutant expression vector, pMAQ-S222A, it was confirmed that aqualysin I was initially expressed as a whole fusion protein and then processed autocatalytically.     

Efficient production of Thermus protease aqualysin I in Escherichia coli: effects of cloned gene structure and two-stage culture

 The DNA sequence encoding Thermus protease aqualysin I was inserted downstream from a bacteriophage T7 promoter in an expression vector. In the T7 expression system, using a strain lacking an F′ episome, aqualysin I was produced in soluble form without chemical induction. The deletions of part (30 amino acid residues) or all (105 residues) of the C-terminal pro-sequence from the C terminus significantly affected both cellular growth and the production of the enzyme. Complete deletion adversely affected both. In contrast, the 30-residue deletion markedly improved productivity by approximately four times compared to non-deletion, and shortened the time needed for the activation of a precursor to active enzyme. The concentration of inducer isopropyl β-D-thiogalactopyrano-side (IPTG) was varied to examine its effects, and it was found that a low concentration of IPTG improved aqualysin I production. To avoid the inhibitory effects of acetic acid accumulation in the culture medium, the use of other carbon sources besides glucose was examined. When cells were cultivated with glycerol, the acetic acid level remained relatively low, and both good cellular growth and a high level of production were attained. The aqualysin I productivity for a fed-batch culture using two carbon sources, glucose and glycerol, reached more than 150 kU/ml enzymatically active aqualysin I. Received: 19 May 1995/Received revision: 28 July 1995/Accepted: 22 August 1995     

Cloning of alpha- and beta-galactosidase genes from an extreme thermophile, Thermus strain T2, and their expression in Thermus thermophilus HB27.

The genes encoding thermostable alpha- and beta-galactosidases from an extremely thermophilic bacterium, Thermus strain T2, were cloned in Escherichia coli. The alpha-galactosidase gene was located just downstream from the beta-galactosidase gene. The genes were introduced into Thermus thermophilus HB27 with the aid of Thermus cryptic plasmid pTT8, and beta-galactosidases were expressed constitutively.     

Isolation of a low-molecular-weight, multicopy plasmid, pNHK101, from Thermus sp. TK10 and its use as an expression vector for T. thermophilus HB27

We isolated a small multicopy cryptic plasmid, pNHK101, from Thermus sp. TK10 for use as a replicon of a Thermus expression vector. The nucleotide sequence of pNHK101 revealed that this plasmid was 1564bp long, with a total G+C content of 66.8%, which was in agreement with that of Thermus genomic DNA. The sequence did not show any significant similarities to any other plasmids; also, the amino acid sequences of four putative open reading frames, found in the plasmid, did not show strong similarities to those in the databases, except the ORF1, which had very slight similarities to several replication proteins of plasmids from other bacteria. pNHK101 was able to replicate in Thermus thermophilus HB27 with copy number about 80, and was stably maintained at 60 degrees C, but became unstable at 70 degrees C. Based on pNHK101, we constructed a plasmid vector, pKMH052, containing the highly thermostable kanamycin resistance gene as a selective marker. The copy number of pKMH052 decreased to about one-fourth of that of pNHK101, but stability at 60 degrees C did not alter under non-selective conditions. pKMH052 was compatible with pTT8, and interestingly, the presence of pTT8 in the same cells improved the stability of pKMH052 at 70 degrees C. Cloning of the crtB gene of T. thermophilus HB27 encoding phytoene synthase into pKMH052, and introduction into T. thermophilus cells resulted in a 2.8-fold production of carotenoids, indicating the potential use of this plasmid for overexpression of genes from thermophiles and hyperthermophiles.     

Unique precursor structure of an extracellular protease, aqualysin I, with NH2- and COOH-terminal pro-sequences and its processing in Escherichia coli

Aqualysin I is a subtilisin-type serine protease which is secreted into the culture medium by Thermus aquaticus YT-1, an extremely thermophilic Gram-negative bacterium. The nucleotide sequence of the entire gene for aqualysin I was determined, and the deduced amino acid sequence suggests that aqualysin I is produced as a large precursor, consisting of at least three portions, an NH2-terminal pre-pro-sequence (127 amino acid residues), the protease (281 residues), and a COOH-terminal pro-sequence (105 residues). When the cloned gene was expressed in Escherichia coli cells, aqualysin I was not secreted. However, a precursor of aqualysin I lacking the NH2-terminal pre-pro-sequence (38-kDa protein) accumulated in the membrane fraction. On treatment of the membrane fraction at 65 degrees C, enzymatically active aqualysin I (28-kDa protein) was produced in the soluble fraction. When the active site Ser residue was replaced with Ala, cells expressing the mutant gene accumulated a 48-kDa protein in the outer membrane fraction. The 48-kDa protein lacked the NH2-terminal 14 amino acid residues of the precursor, and heat treatment did not cause any subsequent processing of this precursor. These results indicate that the NH2-terminal signal sequence is cleaved off by a signal peptidase of E. coli, and that the NH2- and COOH-terminal pro-sequences are removed through the proteolytic activity of aqualysin I itself, in that order. These findings indicate a unique four-domain structure for the aqualysin I precursor; the signal sequence, the NH2-terminal pro-sequence, mature aqualysin I, and the COOH-terminal pro-sequence, from the NH2 to the COOH terminus.     

Cloning, sequencing, and expression of ruvB and characterization of RuvB proteins from two distantly related thermophilic eubacteria.

The ruvB genes of the highly divergent thermophilic eubacteria Thermus thermophilus and Thermotoga maritima were cloned, sequenced, and expressed in Escherichia coli. Both thermostable RuvB proteins were purified to homogeneity. Like E. coli RuvB protein, both purified thermostable RuvB proteins showed strong double-stranded DNA-dependent ATPase activity at their temperature optima (> or = 70 degrees C). In the absence of ATP, T. thermophilus RuvB protein bound to linear double-stranded DNA with a preference for the ends. Addition of ATP or gamma-S-ATP destabilized the T. thermophilus RuvB-DNA complexes. Both thermostable RuvB proteins displayed helicase activity on supercoiled DNA. Expression of thermostable T. thermophilus RuvB protein in the E. coli ruvB recG mutant strain N3395 partially complemented the UV-sensitive phenotype, suggesting that T. thermophilus RuvB protein has a function similar to that of E. coli RuvB in vivo.     

Role of proline residues in conferring thermostability on aqualysin I

To understand the molecular basis of the thermostability of a thermophilic serine protease aqualysin I from Thermus aquaticus YT-1, we introduced mutations at Pro5, Pro7, Pro240 and Pro268, which are located on the surface loops of aqualysin I, by changing these amino acid residues into those found at the corresponding locations in VPR, a psychrophilic serine protease from Vibrio sp. PA-44. All mutants were expressed stably and exhibited essentially the same specific activity as wild-type aqualysin I at 40 degrees C. The P240N mutant protein had similar thermostability to wild-type aqualysin I, but P5N and P268T showed lower thermostability, with a half-life at 90 degrees C of 15 and 30 min, respectively, as compared to 45 min for the wild-type enzyme. The thermostability of P7I was decreased even more markedly, and the mutant protein was rapidly inactivated at 80 degrees C and even at 70 degrees C, with half-lives of 10 and 60 min, respectively. Differential scanning calorimetry analysis showed that the transition temperatures of wild-type enzyme, P5N, P7I, P240N and P268T were 93.99 degrees C, 83.45 degrees C, 75.66 degrees C, 91.78 degrees C and 86.49 degrees C, respectively. These results underscore the importance of the proline residues in the N- and C-terminal regions of aqualysin I in maintaining the integrity of the overall protein structure at elevated temperatures.     

Role of disulphide bonds in a thermophilic serine protease aqualysin I from Thermus aquaticus YT-1

A thermophilic serine protease, Aqualysin I, from Thermus aquaticus YT-1 has two disulphide bonds, which are also found in a psychrophilic serine protease from Vibrio sp. PA-44 and a proteinase K-like enzyme from Serratia sp. at corresponding positions. To understand the significance of these disulphide bonds in aqualysin I, we prepared mutants C99S, C194S and C99S/C194S (WSS), in which Cys69-Cys99, Cys163-Cys194 and both of these disulphide bonds, respectively, were disrupted by replacing Cys residues with Ser residues. All mutants were expressed stably in Escherichia coli. The C99S mutant was 68% as active as the wild-type enzyme at 40 degrees C in terms of k(cat) value, while C194S and WSS were only 6 and 3%, respectively, as active, indicating that disulphide bond Cys163-Cys194 is critically important for maintaining proper catalytic site conformation. Mutants C194S and WSS were less thermostable than wild-type enzyme, with a half-life at 90 degrees C of 10 min as compared to 45 min of the latter and with transition temperatures on differential scanning calorimetry of 86.7 degrees C and 86.9 degrees C, respectively. Mutant C99S was almost as stable as the wild-type aqualysin I. These results indicate that the disulphide bond Cys163-Cys194 is more important for catalytic activity and conformational stability of aqualysin I than Cys67-Cys99.     

Thermostable DNA polymerase from Thermus thermophilus B35: cloning, sequence analysis, and gene expression

The nucleotide sequences of three thermostable DNA polymerase (Taq, Tth, and Tfl) genes were analyzed and high conserved regions typical for this polymerase family were identified. Using primers for one of the conserved regions, the genomic DNA fragment of T. thermophilus B35 strain was amplified. The resulting fragment was cloned into a plasmid and used as a hybridization probe with digests of T. thermophilus B35 DNA cleaved by different restriction endonucleases. A restriction DNA fragment carrying the full-length Tte polymerase gene was found, cloned, and sequenced. The primary structures of the Tte and Tth DNA polymerase genes were analyzed. The Tte-pol gene was recloned into an expression vector and recombinant protein was purified to homogeneity. The properties of Tte-pol in the polymerase chain reaction were investigated.