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.     

Role of the C-terminal pro-domain of aqualysin I in the maturation and translocation of the precursor across the cytoplasmic membrane in Escherichia coli

Aqualysin I, which is a subtilisin-type, extracellular protease secreted by Thermus aquaticus YT-1, is synthesized as a unique precursor bearing pro-domains at both N- and C-terminus of the mature protease domain as well as an N-terminal signal peptide. To investigate the function of the C-terminal pro-domain in maturation and export pathway of the precursor in E. coli cells, aqualysin I variants were constructed in which deletion mutants of the C-terminal pro-domain lacking its own signal peptide were inserted into pIN-III-ompA3. When E. coli harboring wild type and mutant plasmids were induced by 0.2 mM IPTG, active aqualysin I was produced by heat treatment at 65 °C. Aqualysin I precursors with deletions of more than 5 amino acid residues at the C-terminal end of pro-domain were much more rapidly processed than that of wild type, indicating that the C-terminal pro-domain functions as a inhibitor for processing of aqualysin I precursor. With the wild type, most of aqualysin I was present in membrane fraction (probably the outer membrane), whereas for the truncated mutants, it remained in the cytoplasm, indicating that for deletion mutants, their precursors expressed in cells were not translocated across the cytoplasmic membrane, despite the existence of an N-terminal signal peptide.     

Substrate Specificity of Aqualysin I Altered by an Organic Solvent,DMSO

Aqualysin I is the alkaline serine protease isolated from an extreme thermophile, Thermus aquaticus YT-1. We have analyzed the kinetic properties of aqualysin I, using thirty-one kinds of chromogenic succinyl-tripeptide p-nitroanilides as substrates in the presence of 10% dimethylsulfoxide (DMSO). Aqualysin I hydrolyzed many peptides in a DMSO-containing mixture, however the substrate specificity was different from that in the absence of DMSO. The K_m for each peptide was raised by the addition of 10% DMSO. Also, the P3- as well as P2-specificity of aqualysin I was altered. These results suggested that the side chains of the P2 and P3 residues are exposed to the solvent, and the hydrophobic interactions between the side chain of the substrate and the solvent may take a part in the substrate recognition of the enzyme.     

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.     

A 38 kDa precursor protein of aqualysin I (a thermophilic subtilisin-type protease) with a C-terminal extended sequence: its purification and in vitro processing

The precursor of aqualysin I, an extracellular subtilisin-type protease produced by Thermus aquaticus, consists of four domains: an N-terminal signal peptide, an N-terminal pro-sequence, a protease domain, and a C-terminal extended sequence. In an Escherichia coli expression system for the aqualysin I gene, a 38 kDa precursor protein consisting of the protease domain and the C-terminal extended sequence is accumulated in the membrane fraction and processed to a 28 kDa mature enzyme upon heat treatment at 65°C. The 38 kDa precursor protein is separated as a soluble form from denatured E. coli proteins after heat treatment. Accordingly, purification of the 38 kDa proaqualysin I was performed using chromatography. The purified precursor protein gave a single band on SDS-polyacrylamide gels. The precursor protein exhibited proteolytic activity comparable to that of the mature enzyme. The purified precursor protein was processed to the mature enzyme upon heat treatment. The processing was inhibited by diisopropyl fluorophosphate. The processing rate increased upon either the addition of mature aqualysin I or upon an increase in the concentration of the precursor, suggesting that the cleavage of the C-terminal extended sequence occurs through an intermolecular self-processing mechanism.     

Optimization of Protease Extraction from Horse Mango (Mangifera foetida Lour) Kernels by a Response Surface Methodology

The thermophilic protease aqualysin I (AQI) gene (aqul), derived from Thermus aquaticus YT-I, was inserted under the control of the bacteriophage T7 promoter in an expression plasmid. The plasmid was introduced into two strains of E. coli JMI09 (DE3), one carrying and one lacking an F’ episome, which carries the lacI_q gene. Upon cultivation the strain carrying an F’ episome produced AQI as an insoluble fusion protein (74 kDa) with the T7 gene 10 protein. This insoluble protein could not be processed into mature AQI by heat treatment and thus it had no proteolytic activity. On the other hand, when the strain lacking an F’ episome was used as a host cell for aqul expression, non-induced, or leaky, expression occurred, and AQI was produced in a soluble form. This soluble protein could be processed into active AQI by heat treatment. Moreover, when a low concentration of IPTG (0.0125 mM) was added, the amount of active AQI was 2.7 times greater than that produced in a batch culture without induction.     

Properties of a subtilisin-like proteinase from a psychrotrophic Vibrio species comparison with proteinase K and aqualysin I.

An extracellular serine proteinase purified from cultures of a psychrotrophic Vibrio species (strain PA-44) belongs to the proteinase K family of the superfamily of subtilisin-like proteinases. The enzyme is secreted as a 47-kDa protein, but under mild heat treatment (30 min at 40 degrees C) undergoes autoproteolytic cleavage on the carboxyl-side of the molecule to give a proteinase with a molecular mass of about 36 kDa that apparently shares most of the enzymatic characteristics and the stability of the 47-kDa protein. In this study, selected enzymatic properties of the Vibrio proteinase were compared with those of the related proteinases, proteinase K and aqualysin I, as representative mesophilic and thermophilic enzymes, respectively. The catalytic efficiency (kcat/Km) for the amidase activity of the cold-adapted enzyme against succinyl-AAPF-p-nitroanilide was significantly higher than that of its mesophilic and thermophilic counterparts, especially when compared with aqualysin I. The stability of the Vibrio proteinase, both towards heat and denaturants, was found to be significantly lower than of either proteinase K or aqualysin I. One or more disulfide bonds in the psychrotrophic proteinase are important for the integrity of the active enzyme structure, as disulfide cleavage, either by reduction with dithiothreitol or by sulfitolysis, led to a loss in its activity. Under the same conditions, aqualysin I was also partially inactivated by dithiothreitol, but the activity of proteinase K was unaffected. The disulfides of either proteinase K or aqualysin I were not reactive towards sulfitolysis, except under denaturing conditions, while all disulfides of the Vibrio proteinase reacted in absence of a denaturant. The reactivity of the disulfides of the proteins as a function of denaturant concentration followed the order: Vibrio proteinase > proteinase K > aqualysin I. The same order of reactivity was also observed for the inactivation of the enzymes by H2O2-oxidation, as a function of temperature. The order of reactivity observed in these reactions most likely reflects the accessibility of the reactive cystine or methionine side chains present in the three related proteinases, and hence a difference in the compactness of their protein structures.     

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.     

A non-covalent NH2-terminal pro-region aids the production of active aqualysin I (a thermophilic protease) without the COOH-terminal pro-sequence in Escherichia coli

The precursor of aqualysin I, an extracellular protease produced by Thermus aquaticus, consists of four domains: an N-terminal signal peptide, an N-terminal pro-sequence, the protease domain and a C-terminal pro-sequence. In an Escherichia coli expression system, mature and active aqualysin I is formed by treatment at 65 degrees C and the N-pro-sequence is required for its production. Complete deletion of the C-pro-sequence did not affect the production of active aqualysin I, indicating that the C-pro-sequence is not essential. A non-covalent N-pro-region was separately synthesized from the protease domain with or without the C-pro-sequence. In this system, mature and active aqualysin I was detected only when the C-pro-sequence was deleted.     

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     

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.     

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.     

Purification and characterization of aqualysin I (a thermophilic alkaline serine protease) produced by Thermus aquaticus YT-1

Aqualysin I is an alkaline serine protease which is secreted into the culture medium by Thermus aquaticus YT-1. Aqualysin I was purified, and its apparent relative molecular mass was determined to be 28 500. The enzyme contained four Cys residues (probably as two cystines), and its amino acids composition was similar to those of cysteine-containing serine proteases (proteinase K, etc.) as well as those of subtilisins. The NH2-terminal sequence of aqualysin I showed homology with those of the microbial serine proteases. The optimum pH for the proteolytic activity of aqualysin I was around 10.0. Ca2+ stabilized the enzyme to heat treatment, and the maximum proteolytic activity was observed at 80 degrees C. Aqualysin I was stable to denaturing reagents (7 M urea, 6 M guanidine.HCl and 1% SDS) at 23 degrees C for 24 h. The enzyme hydrolyzed the ester bond of an alanine ester and succinyl-Ala-Ala-Ala p-nitroanilide, a synthetic substrate for mammalian elastase. The cleavage sites for aqualysin I in oxidized insulin B chain were not specific when it was digested completely.     

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.     

Effects of detergent on the excited state structure and relaxation dynamics of the photosystem II reaction center: A high resolution hole burning study

Low temperature (4.2 K) absorption and hole burned spectra are reported for a stabilized preparation (no excess detergent) of the photosystem II reaction center complex. The complex was studied in glasses to which detergent had and had not been added. Triton X-100 (but not dodecyl maltoside) detergent was found to significantly affect the absorption and persistent hole spectra and to disrupt energy transfer from the accessory chlorophyll a to the active pheophytin a. However, Triton X-100 does not significantly affect the transient hole spectrum and lifetime (1.9 ps at 4.2 K) of the primary donor state, P680^*. Data are presented which indicate that the disruptive effects of Triton X-100 are not due to extraction of pigments from the reaction center, leaving structural perturbations as the most plausible explanation. In the absence of detergent the high resolution persistent hole spectra yield an energy transfer decay time for the accessory Chl a Q_Y-state at 1.6 K of 12 ps, which is about three orders of magnitude longer than the corresponding time for the bacterial RC. In the presence of Triton X-100 the Chl a Q_Y-state decay time is increased by at least a factor of 50.Abbreviations PS I photosystem I - PS II photosystem II - RC reaction center - P680, P870, P960 the primary electron donor absorption bands of photosystem II, Rhodobacter sphaeroides, Rhodopseudomonas viridis - NPHB nonphotochemical hole burning - TX Triton X-100 - DM Dodecyl Maltoside - Chl chlorophyll - Pheo pheophytin - ZPH ero phonon hole     

Single-site substitutions improve cold activity and increase thermostability of the dehairing alkaline protease (DHAP)

To engineer dehairing alkaline protease (DHAP) variants to improve cold activity and increase thermostability so these variants are suitable for the leather processing industry. Based on previous studies with bacterial alkaline proteases, double-site mutations (W106K/V149I and W106K/M124L) were introduced into the DHAP from Bacillus pumilus. Compared with the wild-type DHAP hydrolytic activity, the double-site variant W106K/V149I showed an increase in specific hydrolytic activity at 15 °C by 2.3-fold toward casein in terms of hydrolytic rate and 2.7-fold toward the synthetic peptide AAPF-pN by means of k_cat/K_m value. The thermostability of the variant (W106K/V149I) was improved with the half-life at 60 and 70 °C increased by 2.7- and 5.0-fold, respectively, when compared with the thermostability of the wild-type DHAP. Conclusively, an increase in the cold activity and thermostability of a bacterial alkaline protease was achieved by protein engineering.     

Identification and designing of the S3 site of aqualysin I, a thermophilic subtilisin-related serine protease.

Aqualysin I is a bacterial subtilisin-related alkaline serine protease, originating in Thermus aquaticus YT-1. Based on computational analysis, we predicted that two residues, Ser102 and Gly131, form the S3 site of aqualysin I, and we proved that this prediction by site-directed mutagenesis. To alter the P3-specificity of the enzyme, we built a "wall" on the S3 site edge by introducing a bulky side chain at target sites. Six mutant proteins were prepared: S102H, S102K, S102E, G131H, G131K, and G131D. The mutant enzymes were examined with two kinetically typical peptides for aqualysin I, suc-X-Ala-Ala-pNA, where X is Ala or Phe. All mutations reduced the efficiency for the Phe-containing peptide, while they raised the k(cat) values for the Ala-containing peptide. Especially, the S102K mutant protein hydrolyzed the polyalanine peptide efficiently. The strategies we have adopted in this paper are applicable to all subtilisin-related enzymes.     

Determining the disinfection of textiles in compressed carbon dioxide using various indicator microbes

Aims: This paper presents a research on the disinfection efficiency of inoculated textile swatches by compressed carbon dioxide, an environmental friendly way to disinfect textiles as opposed to the conventional laundering procedures using water. The disinfection efficiency was determined by using the following microbes inoculated on cotton test fabrics: Enterococcus faecium, Enterobacter aerogenes and Candida albicans. Methods and Results: The experiments were performed using the high pressure extraction device with a maximum pressure of 50 MPa and a small extraction vessel of 500 ml. Pure CO₂ and CO₂ with added disinfection agent or commercial detergent were used. The chosen disinfecting agent was hydrogen peroxide, a widespread disinfecting chemical. It was found that treatment with CO₂ for 25 min at 5 MPa and 40°C (313K) and the addition of 4 ml of specific detergent per litre of CO₂ assures at least a five log step reduction of Enterobacter aerogenes and C. albicans, whilst treatment at 50°C (323K) with CO₂ for 25 min at 5 MPa is sufficient for at least a five log step reduction for Enterococcus faecium. It was also found that a 15‐min CO₂ treatment at 7 MPa and 20°C (293K) was sufficient for the inactivation of the yeast C. albicans, whilst these conditions were not rigorous enough for the challenge bacteria. On the other hand, the labscale treatment with CO₂ for 25 min at pressure 4 and 6 MPa with the addition of detergent or hydrogen peroxide only yields a log step reduction of up to 4 log steps, thus proving the slightly disinfective properties of the CO₂ treatment with added agents, but not reaching efficient results as a 5 log step reduction was not reached. Conclusions: Addition of heat to the compressed CO₂ treatment of textiles inoculated with microorganisms proved more effective than the addition of detergent or disinfectant with compressed CO₂ treatment at temperature of 20°C. Significance and Impact of the Study: CO₂ treatment of textiles is a promising ecological alternative dry‐cleaning method for the disinfection of medical textiles.