Activity Of Thermolysin Research Articles

Temperature influence on the stability of the precursor cluster of the thermolysin crystal

We used the molecular dynamics method to assess the stability of the precursor-cluster (hexamer) of thermolysin crystal over a wide range of temperatures (10–90°C). The simulation results showed that as the temperature increases, the stability of the hexamer, in general, decreases, however, the hexamer does not dissociate at any of the considered temperatures. At a temperature of 60°C, an increase in the stability of the hexamer was observed. This value is close to the temperature of maximum enzymatic activity of thermolysin (70°C). Based on the analysis of the results, it was assumed that the crystallization of thermolysin could be carried out at 60°C.

Production and characterisation of photorin, a new protein protease inhibitor from the entomopathogenic bacteria <i>photorhabdus laumondii</i>

Entomopathogenic bacteria of the genus Photorhabdus secrete protease S (PrtS), which is considered as a virulence factor. We found that in Photorhabdus genomes, immediately after the prtS genes, there are genes that encode small hypothetical proteins homologous to emfourin, a recently discovered protein inhibitor of metalloproteases. Emfourin-like inhibitor gene from Photorhabdus laumondii subsp. laumondii TT01 was cloned and expressed in Escherichia coli cells. The recombinant protein, named photorin (Phin), was purified by metal chelate affinity and gel permeation chromatography and characterized. It has been established that Phin is a monomer and inhibits the activity of protealysin and thermolysin, which, like PrtS, belong to the M4 peptidase family. The inhibition constants were 1.0 ± 0.3 and 10 ± 2 µM, respectively. It was also demonstrated that Phin is able to suppress the proteolytic activity of P. laumondii culture broth (half-maximal inhibition concentration 3.9 ± 0.3 nM). Polyclonal antibodies to Phin were obtained, and it was shown by immunoblotting that P. laumondii cells produce Phin. Thus, the prtS genes in entomopathogenic bacteria of the genus Photorhabdus are colocalized with the genes of emphorin-like inhibitors, which probably regulate the activity of the enzyme during infection. Strict regulation of the activity of proteolytic enzymes is essential for the functioning of all living systems. At the same time, the principles of regulation of protease activity by protein inhibitors remain poorly understood. Bacterial protease-inhibitor pairs, such as the PrtS and Phin pair, are a promising model for in vivo studies of these principles. Bacteria of the genus Photorhabdus have a complex life cycle with multiple hosts, being both nematode symbionts and powerful insect pathogens. This provides a unique opportunity to use the PrtS and Phin pair as a model for studying the principles of regulation of protease activity by proteinaceous inhibitors in the context of bacterial interactions with different types of hosts.

Production and Characterization of Photorin, a Novel Proteinaceous Protease Inhibitor from the Entomopathogenic Bacteria Photorhabdus laumondii.

Entomopathogenic bacteria of the genus Photorhabdus secrete protease S (PrtS), which is considered a virulence factor. We found that in the Photorhabdus genomes, immediately after the prtS genes, there are genes that encode small hypothetical proteins homologous to emfourin, a recently discovered protein inhibitor of metalloproteases. The gene of emfourin-like inhibitor from Photorhabdus laumondii subsp. laumondii TT01 was cloned and expressed in Escherichia coli cells. The recombinant protein, named photorin (Phin), was purified by metal-chelate affinity and gel permeation chromatography and characterized. It has been established that Phin is a monomer and inhibits activity of protealysin and thermolysin, which, similar to PrtS, belong to the M4 peptidase family. Inhibition constants were 1.0 ± 0.3 and 10 ± 2 µM, respectively. It was also demonstrated that Phin is able to suppress proteolytic activity of P. laumondii culture fluid (half-maximal inhibition concentration 3.9 ± 0.3 nM). Polyclonal antibodies to Phin were obtained, and it was shown by immunoblotting that P. laumondii cells produce Phin. Thus, the prtS genes in entomopathogenic bacteria of the genus Photorhabdus are colocalized with the genes of emfourin-like inhibitors, which probably regulate activity of the enzyme during infection. Strict regulation of the activity of proteolytic enzymes is essential for functioning of all living systems. At the same time, the principles of regulation of protease activity by protein inhibitors remain poorly understood. Bacterial protease-inhibitor pairs, such as the PrtS and Phin pair, are promising models for in vivo studies of these principles. Bacteria of the genus Photorhabdus have a complex life cycle with multiple hosts, being both nematode symbionts and powerful insect pathogens. This provides a unique opportunity to use the PrtS and Phin pair as a model for studying the principles of protease activity regulation by proteinaceous inhibitors in the context of bacterial interactions with different types of hosts.

Radiofrequency remote control of thermolysin activity

The majority of biological processes are regulated by enzymes, precise control over specific enzymes could create the potential for controlling cellular processes remotely. We show that the thermophilic enzyme thermolysin can be remotely activated in 17.76 MHz radiofrequency (RF) fields when covalently attached to 6.1 nm gold coated magnetite nanoparticles. Without raising the bulk solution temperature, we observe enzyme activity as if the solution was 16 ± 2 °C warmer in RF fields—an increase in enzymatic rate of 129 ± 8%. Kinetics studies show that the activity increase of the enzyme is consistent with the induced fit of a hot enzyme with cold substrate.

Immobilization of thermolysin enzyme on dendronized silica supports. Evaluation of its feasibility on multiple protein hydrolysis cycles

This work evaluates different dendrimer-silica supports for the immobilization of enzymes by multipoint covalent binding. Thermolysin was immobilized on two dendrimers (PAMAM and carbosilane) with two different generations (zero (G0) and first (G1)). Results were compared with a control, a silica support functionalized with a monofunctional molecule. Dendrimers increased the number of available sites to bind the enzyme. Despite the enzyme was immobilized on all supports, G0 dendrimers immobilized a 30% more enzyme than G1. Thermolysin immobilized on G0 dendrimer supports showed the highest activity and could be employed in three consecutive hydrolysis cycles. Optimal immobilization time was 1 h while optimal protein loading was 25 mg enzyme/100 mg support. Enzyme activity was promoted when using 5 mg of immobilized enzyme at 750 rpm, 60 °C, and 2 h of hydrolysis. Under these conditions, the activity of thermolysin increased up to the 78% of the free enzyme activity. Kinetics of the hydrolysis reaction using the immobilized thermolysin was also studied and compared with the obtained using the free thermolysin. The addition of ZnCl2 and NaCl during the immobilization procedure increased thermolysin activity in the second (22% more) and in the third (14% more) hydrolysis clycles.

Leptospira interrogans thermolysin refolded at high pressure and alkaline pH displays proteolytic activity against complement C3

Enzymes from the thermolysin family are crucial factors in the pathogenesis of several diseases caused by bacteria and are potential targets for therapeutic interventions. Thermolysin encoded by the gene LIC13322 of the causative agent of leptospirosis, Leptospira interrogans, was shown to cleave proteins from the Complement System. However, the production of this recombinant protein using traditional refolding processes with high levels of denaturing reagents for thermolysin inclusion bodies (TL-IBs) solubilization results in poor recovery and low proteolytic activity probably due to improper refolding of the protein. Based on the assumption that leptospiral proteases play a crucial role during infection, the aim of this work was to obtain a functional recombinant thermolysin for future studies on the role of these metalloproteases on leptospiral infection. The association of high hydrostatic pressure (HHP) and alkaline pH was utilized for thermolysin refolding. Incubation of a suspension of TL-IBs at HHP and a pH of 11.0 is non-denaturing but effective for thermolysin solubilization. Soluble protein does not reaggregate by dialysis to pH 8.0. A volumetric yield of 46 mg thermolysin/L of bacterial culture and a yield of near 100% in relation to the total thermolysin present in TL-IBs were obtained. SEC-purified thermolysin suffers fragmentation, likely due to autoproteolysis and presents proteolytic activity against complement C3 α-chain, possibly by a generation of a C3b-like molecule. The proteolytic activity of thermolysin against C3 was time and dose-dependent. The experience gained in this study shall help to establish efficient HHP-based processes for refolding of bioactive proteins from IBs.

Pathogenic Leptospira Secreted Proteases Target the Membrane Attack Complex: A Potential Role for Thermolysin in Complement Inhibition.

Leptospirosis is a zoonosis caused by spirochetes from the genus Leptospira. This disease is common in tropical and subtropical areas, constituting a serious public health problem. Pathogenic Leptospira have the ability to escape the human Complement System, being able to survive when in contact with normal human serum. In a previous study, our group demonstrated that supernatants of pathogenic Leptospira (SPL) inhibit the three activation pathways of the Complement System. This inhibition can be directly correlated with the activity of secreted proteases, which cleave the Complement molecules C3, Factor B (Alternative Pathway), C4 and C2 (Classical and Lectin Pathways). In this work, we analyze the activity of the leptospiral proteases on the components of Terminal Pathway of Complement, called the membrane attack complex (MAC). We observed that proteases present in SPL from different Leptospira strains were able to cleave the purified proteins C5, C6, C7, C8, and C9, while culture supernatant from non-pathogenic Leptospira strains (SNPL) had no significant proteolytic activity on these substrates. The cleavages occurred in a time-dependent and specificity manner. No cleavage was observed when we used whole serum as a source of C5–C9 proteins, probably because of the abundant presence of plasma protease inhibitors such as α2-macroglobulin. Complement protein cleavage by SPL was inhibited by 1,10-phenanthroline, indicating the involvement of metalloproteases. Furthermore, 1,10-phenanthroline- treated normal human serum diminished pathogenic leptospira survival. We also analyzed the proteolytic activity of thermolysin (LIC13322) a metalloprotease expressed exclusively by pathogenic Leptospira strains. Recombinant thermolysin was capable of cleaving the component C6, either purified or as part of the SC5b-9 complex. Furthermore, we found that the MAC proteins C6–C9 interact with thermolysin, indicating that this metalloprotease may have an additional inhibitory effect on these molecules by direct interactions. Finally, a functional assay demonstrated that thermolysin was able to inhibit MAC-dependent erythrocytes lysis. We conclude that proteases secreted exclusively by pathogenic Leptospira strains are capable of degrading several Complement effector molecules, representing potential targets for the development of new therapies and prophylactic approaches in leptospirosis.

Effects of salts on the interaction of 8-anilinonaphthalene 1-sulphonate and thermolysin.

Neutral salts activate and stabilize thermolysin. In this study, to explore the mechanism, we analyzed the interaction of 8-anilinonaphthalene 1-sulphonate (ANS) and thermolysin by ANS fluorescence. At pH 7.5, the fluorescence of ANS increased and blue-shifted with increasing concentrations (0-2.0 μM) of thermolysin, indicating that the anilinonaphthalene group of ANS binds with thermolysin through hydrophobic interaction. ANS did not alter thermolysin activity. The dissociation constants (Kd) of the complex between ANS and thermolysin was 33 ± 2 μM at 0 M NaCl at pH 7.5, decreased with increasing NaCl concentrations, and reached 9 ± 3 μM at 4 M NaCl. The Kd values were not varied (31-34 μM) in a pH range of 5.5-8.5. This suggests that at high NaCl concentrations, Na(+) and/or Cl(-) ions bind with thermolysin and affect the binding of ANS with thermolysin. Our results also suggest that the activation and stabilization of thermolysin by NaCl are partially brought about by the binding of Na(+) and/or Cl(-) ions with thermolysin.

A standardised ‘off the shelf’ substrate for enhanced tissue engineering

AbstractPurpose Amniotic membrane (AM) is a popular ophthalmic tissue engineering adjunct. We previously developed a highly effective thermolysin‐based denuding technique that preserves basement membrane integrity This technique has been validated clinically using fresh frozen AM (FAM). We now propose a standardised dry‐prepared ‘off the shelf’ AM tissue engineering substrate.Methods Dry preserved thermolysin denuded AM (DAM), and FAM denuded with ethylenediaminetetraacetic acid (EDTA), and dispase ‐based methodologies were prepared. Denuding efficiencies were compared using electron microscopy. The effect of denuding on AM molecular composition was investigated and characterised using proteomics. The propensity of DAM to support stem cells was explored using fluorescent immunohistochemistry for defined markers.Results Electron microscopy demonstrated thermolysin denuding efficiency was comparable in FAM and DAM. Proteomic analyses showed effective removal of epithelial cell proteins in DAM, but not EDTA–based denuding techniques. Whilst similar enzymatic activity to thermolysin, mechanical scraping reduces the efficacy of dispase denuding. Collagens IV, VI, periostin, βig‐h3 and VLA‐6 are targets of thermolysin activity. DAM maintains stem cell characteristics and is most effective in preventing differentiation.Conclusion Conventional EDTA and dispase procedures for preparing AM for tissue engineering are ineffective at removing cells whilst preserving the basement membrane. Combining our novel thermolysin denuding and dry preservation techniques improves the overall quality of AM for tissue‐engineered constructs. Therefore, we propose a fist of its kind, stable and dry‐stored ‘off the shelf’ construct for enhanced ocular surface tissue engineering.

Dityrosine-based substrates for the selective and sensitive assay of thermolysin

Thermolysin family proteases are related to various diseases such as bacterial infections, cholera, gastritis and peptic ulcers, and gastric carcinoma. Hence, assay materials capable of the sensitive and specific assessment of thermolysin activity need to be developed for the detection of those diseases. In this study, simple peptides containing an unusual fluorescent amino acid, dityrosine, were tested for the assay of thermolysin. Various types of DBDY-(amino acid-INH)2 were synthesized from the conjugation of N,N′-diBoc-dityrosine (DBDY) with two molecules of amino acid and isoniazid (INH). Among these, DBDY-(Phe-INH)2 and DBDY-(Ile-INH)2 were found to be the most promising substrates for thermolysin assays. The hydrolysis reaction occurring between DBDY and Phe (or Ile) resulted in the release of Phe-INH and Ile-INH, and the fluorescence of DBDY was recovered. The reaction was found to follow Michaelis-Menten kinetics, and the KM and kcat/KM values were in the ranges of 1.91–3.95μM and 2.43×104–6.03×104M−1s−1, respectively, which were comparable to other protease assay materials. Considering the simple preparations of DBDY-(Phe-INH)2 and DBDY-(Ile-INH)2, they are believed to be useful for the selective and sensitive assay of thermolysin.

Involvement of Val 315 located in the C-terminal region of thermolysin in its expression in Escherichia coli and its thermal stability

Thermolysin is a thermophilic and halophilic zinc metalloproteinase that consists of β-rich N-terminal (residues 1–157) and α-rich C-terminal (residues 158–316) domains. Expression of thermolysin variants truncated from the C-terminus was examined in E. coli culture. The C-terminal Lys316 residue was not significant in the expression, but Val315 was critical. Variants in which Val315 was substituted with fourteen amino acids were prepared. The variants substituted with hydrophobic amino acids such as Leu and Ile were almost the same as wild-type thermolysin (WT) in the expression amount, α-helix content, and stability. Variants with charged (Asp, Glu, Lys, and Arg), bulky (Trp), or small (Gly) amino acids were lower in these characteristics than WT. All variants exhibited considerably high activities (50–100% of WT) in hydrolyzing protein and peptide substrates. The expression amount, helix content, and stability of variants showed good correlation with hydropathy indexes of the amino acids substituted for Val315. Crystallographic study of thermolysin has indicated that V315 is a member of the C-terminal hydrophobic cluster. The results obtained in the present study indicate that stabilization of the cluster increases thermolysin stability and that the variants with higher stability are expressed more in the culture. Although thermolysin activity was not severely affected by the variation at position 315, the stability and specificity were modified significantly, suggesting the long-range interaction between the C-terminal region and active site.

Effects of Conversion of the Zinc-Binding Motif Sequence of Thermolysin, HEXXH, to That of Dipeptidyl Peptidase III, HEXXXH, on the Activity and Stability of Thermolysin

Most zinc metalloproteinases have the consensus zinc-binding motif sequence HEXXH, in which two histidine residues chelate a catalytic zinc ion. The zinc-binding motif sequence of thermolysin, H(142)ELTH(146), belongs to this motif sequence, while that of dipeptidyl peptidase III (DPP III), H(450)ELLGH(455), belongs to the motif sequence HEXXXH. In this study, we examined effects of conversion of HEXXH to HEXXXH in thermolysin on its activity and stability. Thermolysin variants bearing H(142)ELLGH(146) or H(142)ELTGH(146) (designated T145LG and T145TG respectively) were constructed by site-directed mutagenesis and were produced in Escherichia coli cells by co-expressing the mature and pro domains separately. They did not exhibit hydrolyzing activity for casein or N-[3-(2-furyl)acryloyl]-glycyl-L-leucine amide, but exhibited binding ability to a substrate analog glycyl-D-phenylalanine (Gly-D-Phe). The apparent denaturing temperatures based on the ellipticity at 222 nm of T145LG and T145TG were 85 ± 1 °C and 86 ± 1 °C respectively, almost the same as that of wild-type thermolysin (85 ± 1 °C). These results indicate that conversion of HEXXH to HEXXXH abolishes thermolysin activity, but does not affect its binding ability to Gly-D-Phe or its stability. Our results are in contrast to ones reported previously, that DPP III variants bearing H(450)ELGH(455) exhibit activity.

Effects of Mutations of Thermolysin, Asn116 to Asp and Asp150 to Glu, on Salt-Induced Activation and Stabilization

Neutral salts activate and stabilize thermolysin. We previously found that two single mutations, Asn116→Asp and Asp150→Glu, increase the activity of thermolysin. In the present study, we examined their effects on NaCl-induced activation and stabilization. In the hydrolysis of N-[3-(2-furyl)acryloyl]-glycyl-L-leucine amide, the relative activities (the ratios of the specificity constant, kcat/Km, at x M NaCl to that at 0 M NaCl) at 0.5-4.0 M NaCl of D150E and N116D/D150E were lower than those of wild-type thermolysin (WT) and N116D, respectively. In thermal inactivation at 70 °C, the relative stabilities (the ratios of the first-order rate constant, kobs, at 0 M NaCl to that at x M NaCl) at 0.5-4.0 M NaCl of D150E and N116D/D150E were lower than those of WT and N116D, respectively. These results indicate that unlike Asn116→Asp, Asp150→Glu reduced NaCl-induced activation and stabilization, suggesting that the binding of ions with certain residues of thermolysin is involved in the activation and stabilization.

Effects of site-directed mutagenesis in the N-terminal domain of thermolysin on its stabilization

The thermolysin variant G8C/N60C/S65P in which the triple mutation in the N-terminal domain, Gly8→Cys/Asn60→Cys/Ser65→Pro, is undertaken increases stability [Yasukawa, K. and Inouye, K. (2007) Improving the activity and stability of thermolysin by site-directed mutagenesis. Biochim. Biophys. Acta 1774, 1281-1288] and its mechanism is examined in this study. The apparent denaturing temperatures based on ellipticity at 222 nm of the wild-type thermolysin (WT), G8C/N60C, S65P and G8C/N60C/S65P were 85, >95, 88 and >95°C, respectively. The first-order rate constants, k(obs), of the thermal inactivation of WT and variants at 10 mM CaCl₂ increased with increasing thermal treatment temperatures (70-95°C), and those at 80°C decreased with increasing CaCl₂ concentrations (1-100 mM). The k(obs) values were in the order of WT > S65P > G8C/N60C≒G8C/N60C/S65P at all temperatures and CaCl₂ concentrations. These results indicate that the mutational combination, Gly8→Cys/Asn60→Cys and Ser65→Pro, increases stability only as high as Gly8→Cys/Asn60→Cys does. Assuming that irreversible inactivation of thermolysin occurs only in the absence of calcium ions, the dissociation constants, K(d), to the calcium ions of WT, G8C/N60C, S65P and G8C/N60C/S65P were 47, 8.9, 17 and 7.2 mM, respectively, suggesting that Gly8→Cys/Asn60→Cys and Ser65→Pro stabilize thermolysin by improving its affinity to calcium ions, most probably the one at the Ca²⁺-binding site III in the N-terminal domain.

Effects of site-directed mutagenesis of Asn116 in the -hairpin of the N-terminal domain of thermolysin on its activity and stability

In the N-terminal domain of thermolysin, two anti-parallel β-strands, Asn112-Ala113-Phe114-Trp115 and Ser118-Gln119-Met120-Val121-Tyr122 are connected by an Asn116-Gly117 turn to form a β-hairpin structure. In this study, we examined the role of Asn116 in the activity and stability of thermolysin by site-directed mutagenesis. Of the 19 Asn116 variants, four (N116A, N116D, N116T and N116Q) were produced in Escherichia coli, by co-expressing the mature and pro domains separately, while the other 15 were not. In the hydrolysis of N-[3-(2-furyl)acryloyl]-glycyl-L-leucine amide (FAGLA) at 25°C, the intrinsic k(cat)/K(m) value of N116D was 320% of that of the wild-type thermolysin (WT), and in the hydrolysis of N-carbobenzoxy-L-aspartyl-L-phenylalanine methyl ester (ZDFM) at pH 7.5 at 25°C, the k(cat)/K(m) value of N116D was 140% of that of WT, indicating that N116D exhibited higher activity than WT. N116Q exhibited similar activity as WT, and N116A and N116T exhibited reduced activities. The first-order rate constants, k(obs), of the thermal inactivation at 80°C were in the order N116A, N116D, N116T > N116Q > WT at all CaCl(2) concentrations examined (1-100 mM), indicating that all variants exhibited reduced stabilities. These results suggest that Asn116 plays an important role in the activity and stability of thermolysin presumably by stabilizing this β-hairpin structure.

Effects of Site-Directed Mutagenesis of the Loop Residue of the N-Terminal Domain Gly117 of Thermolysin on Its Catalytic Activity

In the N-terminal domain of thermolysin, two polypeptide strands, Asn112-Ala113-Phe114-Trp115 and Ser118-Gln119-Met120-Val121-Tyr122, are connected by a short loop, Asn116-Gly117, to form an anti-parallel β-sheet. The Asn112-Trp115 strand is located in the active site, while the Ser118-Tyr122 strand and the Asn116-Gly117 loop are located outside the active site. In this study, we explored the catalytic role of Gly117 by site-directed mutagenesis. Five variants, G117A (Gly117 is replaced by Ala), G117D, G117E, G117K, and G117R, were produced by co-expressing in Escherichia coli the mature and pro domains as independent polypeptides. The production levels were in the order G117E > wild type > G117K, G117R > G117D. G117A was hardly produced. This result is in contrast to our previous one that all 72 active-site thermolysin variants were produced at the similar levels whether they retained activity or not (M. Kusano et al. J. Biochem., 145, 103-113 (2009)). G117E exhibited lower activity in the hydrolysis of N-[3-(2-furyl)acryloyl]-glycyl-L-leucine amide and higher activity in the hydrolysis of N-carbobenzoxy-L-aspartyl-L-phenylalanine methyl ester than the wild-type thermolysin. G117K and G117R exhibited considerably reduced activities. This suggests that Gly117 plays an important role in the activity and stability of thermolysin, presumably by affecting the geometries of the Asn112-Trp115 and Ser118-Tyr122 strands.

Serine protease inhibitors suppress pancreatic endogenous proteases and modulate bacterial neutral proteases

Pefabloc, Trasylol and Urinary Trypsin Inhibitor (UTI) have been reported to be effective serine protease inhibitors that impair pancreatic endogenous proteases resulting in improved islet yield. Here we evaluated the effect of these inhibitors on endogenous proteases (trypsin, chymotrypsin and elastase), bacterial neutral proteases (thermolysin and neutral protease) and islet isolation digestion samples. Protease activity was measured using a fluorimetric assay and islet function was assessed by dynamic perifusion. Trypsin, chymotrypsin and elastase were significantly inhibited by Pefabloc and UTI. Trasylol showed strong inhibitory effects on trypsin and chymotrypsin but also decreased thermolysin activity. UTI was found to inhibit the activity of endogenous proteases and increase the activity of bacterial neutral proteases. Human islets exposed to Pefabloc had reduced insulin response, unlike Trasylol or UTI, which had no detrimental effect on insulin secretion. Although Trasylol was an effective inhibitor of endogenous proteases, FDA regulatory issues preclude its use in clinical application and thus in the isolation process. UTI has the greatest potential because it impairs endogenous pancreatic proteases and enhances digestion enzymes.

Effects of the mutational combinations on the activity and stability of thermolysin

We have previously indicated that three single mutations (Leu144 → Ser, Asp150 → Glu, and Ile168 → Ala) in the site-directed mutagenesis of thermolysin increase the activity and two single (Ser53 → Asp and Leu155 → Ala) and one triple (Gly8 → Cys/Asn60 → Cys/Ser65 → Pro) mutations increase the stability. In the present study, aiming to generate highly active and stable thermolysin variants, we combined these mutations and analyzed the effect of combinations on the activity and stability of thermolysin. The combination of the mutations of Leu144 → Ser and Asp150 → Glu yielded the most significant increase in the hydrolytic activities for N-[3-(2-furyl)acryloyl]-Gly- l-Leu amide (FAGLA) and N-carbobenzoxy- l-Asp- l-Phe methyl ester (ZDFM), while that of Leu144 → Ser and Ile168 → Ala abolished the activity. The combination of Ser53 → Asp and Leu155 → Ala yielded the greatest increase in the thermal stability, while that of Ser53 → Asp and Gly8 → Cys/Asn60 → Cys/Ser65 → Pro increased the stability as high as the individual mutations do. The combination of three mutations of Leu144 → Ser, Asp150 → Glu, and Ser53 → Asp yielded a variant L144S/D150E/S53D with improved activity and stability. Its k cat/ K m values in the hydrolysis of FAGLA and ZDFM were 8.6 and 10.2 times higher than those of wild-type thermolysin (WT), respectively, and its rate constant for thermal inactivation at 80 °C was 60% of that of WT.

Mammalian Tissue-Free Liberase: A New GMP-Graded Enzyme Blend for Human Islet Isolation

Islet transplantation has found its niche in diabetes treatment. It has contributed to a better quality of life and better glycemic control of patients with diabetes suffering from severe hypoglycemia that are not eligible for vascularized pancreas transplantation. Islet isolation is a technically challenging procedure. The different studies within this doctoral thesis aim to improve and standardize different steps in the isolation procedure. They are in particular looking to improve human pancreas preservation during cold storage, to optimize islet release from the exocrine tissue and to assess whether the isolated islet yield can be predicted from a biopsy. We found that pancreas preservation with pre-oxygenated perfluorodecalin (two-layer method) did not improve the ischemic tolerance of the human pancreas as compared to cold storage with the University of Wisconsin (UW) solution. Furthermore, in pancreas with long cold ischemia time (CIT) (>10 hours), Histidine-Tryptophan-Ketoglutarate (HTK) had a limited preservation capacity as compared with the UW solution with respect to isolation outcome. We also found that during enzymatic pancreas digestion, Vitacyte HA was able to provide a similar islet yield and quality as Serva NB1 with less collagenase activity and shorter digestion time. We further describe the first experience with a new GMP manufactured enzyme called Liberase MTF-S for successful human islet isolation. Finally, we found that the isolated islet yield could not be predicted from a biopsy taken from the head of the pancreas concerning solely morphological parameters of the islets tissue. The improvement of pancreas preservation will allow for marginal organs with prolonged cold ischemia time to expand the donor pool. Better knowledge of how the pancreatic extracellular matrix is digested by collagenase will lead to a fast and predictable islet release from the exocrine tissue. By standardizing the isolation procedure and improving organ selection we will increase the success rate in human islet isolation, thereby making islet transplantation available for more patients.

Insights into the Catalytic Roles of the Polypeptide Regions in the Active Site of Thermolysin and Generation of the Thermolysin Variants with High Activity and Stability

The active site of thermolysin is composed of one zinc ion and five polypeptide regions [N-terminal sheet (Asn112-Trp115), alpha-helix 1 (Val139-Thr149), C-terminal loop 1 (Asp150-Gly162), alpha-helix 2 (Ala163-Val176) and C-terminal loop 2 (Gln225-Ser234)]. To explore their catalytic roles, we introduced single amino-acid substitutions into these regions by site-directed mutagenesis and examined their effects on the activity and stability. Seventy variants, in which one of the twelve residues (Ala113, Phe114, Trp115, Asp150, Tyr157, Gly162, Ile168, Ser169, Asp170, Asn227, Val230 and Ser234) was replaced, were produced in Escherichia coli. The hydrolytic activities of thermolysin for N-[3-(2-furyl)acryloyl]-Gly-l-Leu amide (FAGLA) and casein revealed that the N-terminal sheet and alpha-helix 2 were critical in catalysis and the C-terminal loops 1 and 2 were in substrate recognition. Twelve variants were active for both substrates. In the hydrolysis of FAGLA and N-carbobenzoxy-L-Asp-L-Phe methyl ester, the k(cat)/K(m) values of the D150E (in which Asp150 is replaced with Glu) and I168A variants were 2-3 times higher than those of the wild-type (WT) enzyme. Thermal inactivation of thermolysin at 80 degrees C was greatly suppressed with the D150H, D150W, I168A, I168H, N227A, N227H and S234A. The evidence might provide the insights into the activation and stabilization of thermolysin.