Applications of thermolysin in protein structural analysis

Specificity-directed design of a FRET-quenched heptapeptide for assaying thermolysin-like proteases

Thermolysin (TL) is an industrially important zinc endopeptidase, and the prototype of the M4 family of metallopeptidases. The catalytic function of TL and its relatives is typically assessed using chromogenic or more sensitive fluorescent peptides, with the latter substrates relying on Förster resonance energy transfer (FRET). Here, we demonstrate that a FRET-quenched heptapeptide designed on the basis of the enzyme's substrate specificity (Dabcyl-FKFLGKE-EDANS) is efficiently cleaved by TL and dispase (a TL-like protease) in between the Phe3 and Leu4 residues. The specificity constants (determined at pH 7.4 and 25 °C) for TL and dispase (3.6 × 10⁶ M^-1 s^-1 and 4.6 × 10⁶ M^-1 s^-1, respectively) were found to be amongst the highest documented for any TL substrate. Maximal peptide cleavage rates were achieved at pH 6.5 and a temperature of 65 °C. In view of the sensitivity of the assay, concentrations as low as 10 pM TL could be detected. Furthermore, the rate of hydrolysis of Dabcyl-FKFLGKE-EDANS was slow or immeasurable with some other unrelated metallo-, serine- and cysteine proteases, suggesting that the peptide has the potential to serve as a selective substrate for TL and TL-like proteases.

Enzymatic release of dipeptidyl peptidase-4 inhibitors (gliptins) from pigeon pea (Cajanus cajan) nutrient reservoir proteins: In silico and in vitro assessments

In silico and in vitro parameters were used to assess the potential of pigeon pea (Cajanus cajan) nutrient reservoir proteins as sources of dipeptidyl peptidase (DPP)-4 inhibitors. In silico, 40 pigeon pea proteins evaluated had 46% of amino acids associated with DPP-4 inhibition. After virtual hydrolysis, pepsin had the highest frequency of release and bioactivity of released DPP-4 inhibiting peptides, compared to papain and thermolysin. In vitro, thermolysin released the most active DPP-4 inhibitors. The protein hydrolysates contained similar amino acids but different particle sizes. Thus, the bioactivity patterns are attributable to the different nature and behavior of proteins/peptides under actual and virtual conditions. Using eight physicochemical variables, a random forest model with moderate prediction accuracy was developed for predicting DPP-4 inhibitory activity of papain hydrolysates. The findings demonstrate that proteins from pigeon pea are precursors of DPP-4 inhibitors, with potential use in formulating functional food for managing type 2 diabetes. PRACTICAL APPLICATIONS: The emerging use of in silico simulations to predict bioactivity of peptides can provide a framework to direct further wet lab assessments. This pattern can enhance focusing on factors relevant to the bioactive properties of interest. However, there is still limited evidence to confirm the reliability and accuracy of this tool. This study therefore provides insight into the practical use of in silico simulations to predict bioactivity of food peptides by assessing the factors relevant to the enzymatic release of dipeptidyl peptidase-4 inhibitors from pigeon pea seed storage proteins and validating the findings with wet lab assessment. This work also provides important information that can enhance the utilization of pigeon pea, which is an orphan crop, in developing functional food products for managing type 2 diabetes mellitus in developing countries.

Cloning a neutral protease of Clostridium histolyticum, determining its substrate specificity, and designing a specific substrate

Islet transplantation is a prospective treatment for restoring normoglycemia in patients with type 1 diabetes. Islet isolation from pancreases by decomposition with proteolytic enzymes is necessary for transplantation. Two collagenases, collagenase class I (ColG) and collagenase class II (ColH), from Clostridium histolyticum have been used for islet isolation. Neutral proteases have been added to the collagenases for human islet isolation. A neutral protease from C. histolyticum (NP) and thermolysin from Bacillus thermoproteolyicus has been used for the purpose. Thermolysin is an extensively studied enzyme, but NP is not well known. We therefore cloned the gene encoding NP and constructed a Bacillus subtilis overexpression strain. The expressed enzyme was purified, and its substrate specificity was examined. We observed that the substrate specificity of NP was higher than that of thermolysin, and that the protein digestion activities of NP, as determined by colorimetric methods, were lower than those of thermolysin. It seems that decomposition using NP does not negatively affect islets during islet preparation from pancreases. Furthermore, we designed a novel substrate that allows the measurement of NP activity specifically in the enzyme mixture for islet preparation and the culture broth of C. histolyticum. The activity of NP can also be monitored during islet isolation. We hope the purified enzyme and this specific substrate contribute to the optimization of islet isolation from pancreases and that it leads to the success of islet transplantation and the improvement of the quality of life (QOL) for diabetic patients.

Stabilization of the third fibronectin type III domain of human tenascin-C through minimal mutation and rational design

Non-antibody scaffolds are increasingly used to generate novel binding proteins for both research and therapeutic applications. Our group has developed the tenth fibronectin type III domain of human tenascin-C (TNfn3) as one such scaffold. As a scaffold, TNfn3 must tolerate extensive mutation to introduce novel binding sites. However, TNfn3's marginal stability (T(m) ∼ 59°C, ΔG(unfolding) = 5.7 kcal/mol) stands as a potential obstacle to this process. To address this issue, we sought to engineer highly stable TNfn3 variants. We used two parallel strategies. Using insights gained from structural analysis of other FN3 family members, we (1) rationally designed stabilizing point mutations or (2) introduced novel stabilizing disulfide bonds. Both strategies yielded highly stable TNfn3 variants with T(m) values as high as 83°C and ΔG(unfolding) values as high as 9.4 kcal/mol. Notably, only three or four mutations were required to achieve this level of stability with either approach. These results validate our rational design strategies and illustrate that substantial stability increases can be achieved with minimal mutation. One TNfn3 variant reported here has now been successfully used as a scaffold to develop two promising therapeutic molecules. We anticipate that other variants described will exhibit similar utility.

Elongation of the C-terminal domain of an anti-amyloid β single-chain variable fragment increases its thermodynamic stability and decreases its aggregation tendency

Amyloid β (Aβ) immunotherapy is considered a promising approach to Alzheimer disease treatment. In contrast to the use of complete antibodies, administration of single-chain variable fragments (scFv) has not been associated with either meningoencephalitis or cerebral hemorrhage. ScFv-h3D6 is known to preclude cytotoxicity of the Aβ 1-42 peptide by removing its oligomers from the amyloid pathway. As is the case for other scFv molecules, the recombinant production of scFv-h3D6 is limited by its folding and stability properties. Here, we show that its urea-induced unfolding pathway is characterized by the presence of an intermediate state composed of the unfolded VL domain and the folded VH domain, which suggests the VL domain as a target for thermodynamic stability redesign. The modeling of the 3D structure revealed that the VL domain, located at the C-terminal of the molecule, was ending before its latest β-strand was completed. Three elongation mutants, beyond VL-K107, showed increased thermodynamic stability and lower aggregation tendency, as determined from urea denaturation experiments and Fourier-transform infrared spectroscopy, respectively. Because the mutants maintained the capability of removing Aβ-oligomers from the amyloid pathway, we expect these traits to increase the half-life of scFv-h3D6 in vivo and, consequently, to decrease the effective doses. Our results led to the improvement of a potential Alzheimer disease treatment and may be extrapolated to other class-I scFv molecules of therapeutic interest.

An anti-Aβ (amyloid β) single-chain variable fragment prevents amyloid fibril formation and cytotoxicity by withdrawing Aβ oligomers from the amyloid pathway

Aβ (amyloid β) immunotherapy has been revealed as a possible tool in Alzheimer's disease treatment. In contrast with complete antibodies, the administration of scFvs (single-chain variable fragments) produces neither meningoencephalitis nor cerebral haemorrhage. In the present study, the recombinant expression of scFv-h3D6, a derivative of an antibody specific for Aβ oligomers, is presented, as well as the subsequent proof of its capability to recover the toxicity induced by the Aβ1–42 peptide in the SH-SY5Y neuroblastoma cell line. To gain insight into the conformational changes underlying the prevention of Aβ toxicity by this antibody fragment, the conformational landscape of scFv-h3D6 upon temperature perturbation is also described. Heating the native state does not lead to any extent of unfolding, but rather directly to a β-rich intermediate state which initiates an aggregation pathway. This aggregation pathway is not an amyloid fibril pathway, as is that followed by the Aβ peptide, but rather a worm-like fibril pathway which, noticeably, turns out to be non-toxic. On the other hand, this pathway is thermodynamically and kinetically favoured when the scFv-h3D6 and Aβ1–42 oligomers form a complex in native conditions, explaining how the scFv-h3D6 withdraws Aβ1–42 oligomers from the amyloid pathway. To our knowledge, this is the first description of a conformational mechanism by which a scFv prevents Aβ-oligomer cytotoxicity.

Coactosin-like protein functions as a stabilizing chaperone for 5-lipoxygenase: role of tryptophan 102

The activity of 5-LO (5-lipoxygenase), which catalyses two initial steps in the biosynthesis of pro-inflammatory LTs (leukotrienes), is strictly regulated. One recently discovered factor, CLP (coactosin-like protein), binds 5-LO and promotes LT formation. In the present paper we report that CLP also stabilizes 5-LO and prevents non-turnover inactivation of the enzyme in vitro. Mutagenesis of tryptophan residues in the 5-LO β-sandwich showed that 5-LO-Trp102 is essential for binding to CLP, and for CLP to support 5-LO activity. In addition, the stabilizing effect also depended on binding between CLP and 5-LO. After mutations which prevent interaction (5-LO-W102A or CLP-K131A), the protective effect of CLP was absent. A calculated 5-LO–CLP docking model indicates that CLP may bind to additional residues in both domains of 5-LO, thus possibly stabilizing the 5-LO structure. To obtain further support for binding between CLP and 5-LO in a living cell, subcellular localization of CLP and 5-LO in the monocytic cell line Mono Mac 6 was determined. In these cells, 5-LO associates with a nuclear fraction only when differentiated cells are primed with phorbol ester and stimulated with ionophore. The same pattern of redistribution was found for CLP, indicating that the two proteins associate with the nucleus in a co-ordinated fashion. The results of the present study support a role for CLP as a chaperoning scaffold factor, influencing both the stability and the activity of 5-LO.

Enzymatic synthesis of peptides on a solid support

We have previously shown that dipeptides can be synthesised in high yields from amino acids using protease catalysis in aqueous media, if the amino component is immobilised on porous PEGA resin (a copolymer of polyethylene glycol and polyacrylamide). Here we explore the scope of this methodology for using protected and glycosylated amino acids as well as the synthesis of longer peptides on resin and show that such a method can also be applied on non-porous surfaces, in particular on gold.

Characterization of the glutamyl endopeptidase from Staphylococcus aureus expressed in Escherichia coli

V8 protease, a member of the glutamyl endopeptidase I family, of Staphylococcus aureus V8 strain (GluV8) is widely used for proteome analysis because of its unique substrate specificity and resistance to detergents. In this study, an Escherichia coli expression system for GluV8, as well as its homologue from Staphylococcus epidermidis (GluSE), was developed, and the roles of the prosegments and two specific amino acid residues, Val69 and Ser237, were investigated. C-terminal His(6)-tagged proGluSE was successfully expressed from the full-length sequence as a soluble form. By contrast, GluV8 was poorly expressed by the system as a result of autodegradation; however, it was efficiently obtained by swapping its preprosegment with that of GluSE, or by the substitution of four residues in the GluV8 prosequence with those of GluSE. The purified proGluV8 was converted to the mature form in vitro by thermolysin treatment. The prosegment was essential for the suppression of proteolytic activity, as well as for the correct folding of GluV8, indicating its role as an intramolecular chaperone. Furthermore, the four amino acid residues at the C-terminus of the prosegment were sufficient for both of these roles. In vitro mutagenesis revealed that Ser237 was essential for proteolytic activity, and that Val69 was indispensable for the precise cleavage by thermolysin and was involved in the proteolytic reaction itself. This is the first study to express quantitatively GluV8 in E. coli, and to demonstrate explicitly the intramolecular chaperone activity of the prosegment of glutamyl endopeptidase I.

Thermolysin in human cultured keratinocyte isolation

BACKGROUND: When treating extensively burned patients using cultured epidermal sheets, the main problem is the time required for its production. Conventional keratinocyte isolation is usually done using Trypsin. We used a modification of the conventional isolation method in order to improve this process and increase the number of colonies from the isolated epidermal cell population. PURPOSE: To compare the action of trypsin and thermolysin in the keratinocyte isolation using newborn foreskin. METHODS: This method used thermolysin as it selectively digests the dermo-epidermal junction. After dermis separation, the epidermis was digested by trypsin in order to obtain a cell suspension. RESULTS: Compared to the conventional procedure, these experiments demonstrated that in the thermolysin group, the epidermis was easily detached from the dermis, there was no fibroblast contamination and there were a larger number of keratinocyte colonies which had a significant statistical difference. CONCLUSION: The number of colonies in the thermolysin group was significantly greater than in the trypsin group.

Controlling protein retention on enzyme-responsive surfaces

The ability to change the properties of solid surfaces on demand is a key component of a multitude of established and emerging technologies. Stimuli that have previously been used to trigger changes in surface properties include changes in solvent, light, pH, ionic strength, temperature and magnetic or electric fields. We are interested in developing surfaces that can be triggered by the catalytic action of enzymes. We demonstrate the selective protease (alpha-chymotrypsin and thermolysin) catalysed peptide hydrolysis of surface-tethered fluorenylmethoxycarbonyl-dipeptides. We highlight some of the challenges evident from surface analysis in overcoming enzyme retention to the surface addressed by physical adsorption of soluble PEG(200) to the surface prior to enzyme exposure. Analysis by ToF-SIMS and XPS shows that alpha-chymotrypsin is deposited and retained on the surfaces and that thermolysin, a much more stable enzyme, selectively cleaves the tethered peptides as intended, and is removed from the surface by washing.

The Protein-protein Interactions Between SMPI and Thermolysin Studied by Molecular Dynamics and MM/PBSA Calculations

Thermolysin is a zinc-metalloendopeptidase secreted by the gram-positive thermophilic bacterium Bacillus thermoproteolyticus. Thermolysin belongs to the gluzinicin family of enzymes, which is selectively inhibited by Steptomyces metalloproteinase inhibitor (SMPI). Very little is known about the interaction between SMPI and thermolysin. Knowledge about the protein-protein interactions is very important for designing new thermolysin inhibitors with possible industrial or pharmaceutical applications. In the present study, two binding modes between SMPI and thermolysin were studied by 2300 picoseconds (ps) of comparative molecular dynamics (MD) simulations and calculation of the free energy of binding using the molecular mechanics-Poisson-Boltmann surface area (MM/PBSA) method. One of the positions, the 'horizontal arrow head docking' (HAHD) was similar to the previously proposed binding mode by Tate et al. (Tate, S., Ohno, A., Seeram, S. S., Hiraga, K., Oda, K., and Kainosho, M. J. Mol. Biol. 282, 435-446 (1998)). The other position, the 'vertical arrow head docking' (VAHD) was obtained by a manual docking guided by the shape and charge distribution of SMPI and the binding pocket of thermolysin. The calculations showed that SMPI had stronger interactions with thermolysin in the VAHD than in the HAHD complex, and the VAHD complex was considered more realistic than the HAHD complex. SMPI interacted with thermolysin not only at the active site but had auxiliary binding sites contributing to proper interactions. The VAHD complex can be used for designing small molecule inhibitors mimicking the SMPI-thermolysin binding interfaces.

Pulse proteolysis: a simple method for quantitative determination of protein stability and ligand binding

Thermodynamic stability is fundamental to the biology of proteins. Information on protein stability is essential for studying protein structure and folding and can also be used indirectly to monitor protein-ligand or protein-protein interactions. While clearly valuable, the experimental determination of a protein's stability typically requires biophysical instrumentation and substantial quantities of purified protein, which has limited the use of this technique as a general laboratory method. We report here a simple new method for determining protein stability by using pulse proteolysis with varying concentrations of denaturant. Pulse proteolysis is designed to digest only the unfolded proteins in an equilibrium mixture of folded and unfolded proteins that relaxes on a time scale longer than the proteolytic pulse. We used this method to study the stabilities of Escherichia coli ribonuclease H and its variants, both in purified form and directly from cell lysates. The DeltaG(unf) degrees values obtained by this technique were in agreement with those determined by traditional methods. We also successfully used this method to monitor the binding of maltose-binding protein to maltose, as well as to rapidly screen cognate ligands for this protein. The simplicity of pulse proteolysis suggests that it is an excellent strategy for the high-throughput determination of protein stability in protein engineering and drug discovery applications.

Probing the high energy states in proteins by proteolysis

Unless the native conformation has an unstructured region, proteases cannot effectively digest a protein under native conditions. Digestion must occur from a higher energy form, when at least some part of the protein is exposed to solvent and becomes accessible by proteases. Monitoring the kinetics and denaturant dependence of proteolysis under native conditions yields insight into the mechanism of proteolysis as well as these high-energy conformations. We propose here a generalized approach to exploit proteolysis as a tool to probe high-energy states in proteins. This "native state proteolysis" experiment was carried out on Escherichia coli ribonuclease HI. Mass spectrometry and N-terminal sequencing showed that thermolysin cleaves the peptide bond between Thr92 and Ala93 in an extended loop region of the protein. By comparing the proteolysis rate of the folded protein and a peptidic substrate mimicking the sequence at the cleavage site, the energy required to reach the susceptible state (Delta G(proteolysis)) was determined. From the denaturant dependence of Delta G(proteolysis), we determined that thermolysin digests this protein through a local fluctuation, i.e. localized unfolding with minimal change in solvent assessable surface area. Proteolytic susceptibilities of proteins are discussed based on the finding of this local fluctuation mechanism for proteolysis under native conditions.

Purification and pH stability characterization of a chymotrypsin inhibitor from Schizolobium parahyba seeds

Schizolobium parahyba chymotrypsin inhibitor (SPCI) was completely purified as a single polypeptide chain with two disulfide bonds, by TCA precipitation and ion exchange chromatography. This purification method is faster and more efficient than that previously reported: SPCI is stable from pH 2 to 12 at 25 degrees C, and is highly specific for chymotrypsin at pH 7-12. It weakly inhibits elastase and has no significant inhibitory effect against trypsin and alpha-amylase. SPCI is a thermostable protein and resists thermolysin digestion up to 70 degrees C.

The C-terminal segment of the 1,3-beta-glucanase Ole e 9 from olive (Olea europaea) pollen is an independent domain with allergenic activity: expression in Pichia pastoris and characterization

Several allergenic proteins, such as the 1,3-beta-glucanases, have been associated with plant defence responses. Ole e 9 (46 kDa) is a 1,3-beta-glucanase and major allergen from olive pollen, which is a principal cause of allergy in Mediterranean countries. Its C-terminal segment (101 amino acid residues) has been produced as a recombinant polypeptide in the yeast Pichia pastoris. The cDNA encoding the polypeptide was inserted into the plasmid vector pPICZalpha-A and overexpressed in KM71 yeast cells. The recombinant product was purified by size-exclusion chromatography followed by reversed-phase HPLC. Edman degradation, MS and CD were used to determine molecular properties of the recombinant polypeptide, which exhibited 16% alpha-helix and 30% beta-sheet as regular elements of secondary structure. Disulphide bridges of the molecule were determined at positions Cys-14-Cys-76, Cys-33-Cys-94 and Cys-39-Cys-48. The high IgE-binding capability of the recombinant C-terminal segment of Ole e 9 against sera from Ole e 9-sensitive individuals, which was determined by immunoblotting and ELISA inhibition, supported the proper folding of the polypeptide and the maintenance of antigenic properties that it exhibits as a part of the whole allergen. These data indicated that this portion of Ole e 9 constitutes an independent domain, which could be used to study its three-dimensional structure and function, as well as for clinical purposes such as diagnosis and specific immunotherapy. Since it shows sequence similarity with portions of 1,3-beta-glucanases from plant tissues and the Gas/Phr/Epd protein families involved in yeast morphogenesis, we suggest that this domain could play an equivalent functional role within these enzymes.

Functional characterization of arginine 30, lysine 40, and arginine 62 in Tn5 transposase

Three N-terminal basic residues of Tn5 transposase, which are associated with proteolytic cleavages by Escherichia coli proteinases, were mutated to glutamine residues with the goal of producing more stable transposase molecules. Mutation of either arginine 30 or arginine 62 to glutamine produced transposase molecules that were more stable toward E. coli proteinases than the parent hyperactive Tn5 transposase, however, they were inactive in vivo. In vitro analysis revealed these mutants were inactive, because both Arg(30) and Arg(62) are required for formation of the paired ends complexes when the transposon is attached to the donor backbone. These results suggest Arg(30) and Arg(62) play critical roles in DNA binding and/or synaptic complex formation. Mutation of lysine 40 to glutamine did not increase the overall stability of the transposase to E. coli proteinases. This mutant transposase was only about 1% as active as the parent hyperactive transposase in vivo; however, it retained nearly full activity in vitro. These results suggest that lysine 40 is important for a step in the transposition mechanism that is bypassed in the in vitro assay system, such as the removal of the transposase molecule from DNA following strand transfer.

Surprisingly high stability of barley lipid transfer protein, LTP1, towards denaturant, heat and proteases

Barley LTP1 belongs to a large family of plant proteins termed non-specific lipid transfer proteins. The in vivo function of these proteins is unknown, but it has been suggested that they are involved in responses towards stresses such as pathogens, drought, heat, cold and salt. Also, the proteins have been suggested as transporters of monomers for cutin synthesis. We have analysed the stability of LTP1 towards denaturant, heat and proteases and found it to be a highly stable protein, which apparently does not denature at temperatures up to 100 degrees C. This high stability may be important for the biological function of LTP1.

Assignment of the disulfide bonds of Ole e 1, a major allergen of olive tree pollen involved in fertilization

The most prevalent allergen from olive tree pollen, Ole e 1, consists of a single polymorphic polypeptide chain of 145 amino acids which includes six cysteine residues at positions 19, 22, 43, 78, 90 and 131. By using an homogeneous form of the allergen expressed in Pichia pastoris, the array of the disulfide bridges has been elucidated. Specific proteolysis with thermolysin and reverse-phase HPLC separation of the peptides allowed the determination of the disulfide bond between Cys43 and Cys78. Another thermolytic product, which contained three peptides linked by the remaining four cysteines, was digested with Glu-specific staphylococcal V8 protease and the products isolated by reverse-phase HPLC. Amino acid compositions and Edman degradation of the peptide products indicated the presence of the disulfide bonds at Cys19-Cys90 and Cys22-Cys131. These data can help in the analysis of the three-dimensional structure of the protein as well as in studies of its allergenic determinants.

Early steps in the unfolding of thermolysin-like proteases

Several series of site-directed mutations in thermolysin-like proteases are presented that show remarkable nonadditivity in their effect on thermal stability. A simple model is proposed that relates this nonadditivity to the occurrence of independent partial unfolding processes that occur in parallel at elevated temperatures. To prove this model, a thermolysin-like protease was designed in which two mutations located approximately 35 A apart in the structure individually exert small stabilizing effects of 2.3 and 4. 1 degreesC, respectively, but when combined stabilize the protease by 14.6 degreesC. This overadditivity, which follows directly from the model, confirms that unfolding of this engineered protease starts in parallel at two different regions of the protein.

Structural characterization of a soluble and partially folded class I major histocompatibility heavy chain/beta 2m heterodimer

Class I major histocompatibility (MHC) heavy chain (HC) must fold and assemble with beta 2 microglobulin (beta 2m) prior to binding peptides in the endoplasmic reticulum (ER). Each of these events is mediated by association with chaperones and other proteins and is an essential requirement for the maturation and normal cell surface expression of stable class I MHC-peptide complexes. Here we describe the biochemical and structural characterization of a soluble HC (B*0702)/beta 2m heterodimer, apparently free of peptide. Results suggest that the peptide binding domains (alpha 1 and alpha 2) of this folding intermediate are unstable and possess many of the properties ascribed to the molten globule state. The partially folded state of the HC/beta 2m heterodimer is consistent with the suggestion that it is stabilized by chaperones and other proteins in the ER. This soluble intermediate may be useful for studying protein-assisted folding and peptide binding of class I MHC molecules.

Chemical synthesis and structural characterization of the RGD-protein decorsin: a potent inhibitor of platelet aggregation

Decorsin is a 39-residue RGD-protein crosslinked by three disulfide bridges isolated from the leech Macrobdella decora belonging to the family of GPIIb-IIIa antagonists and acting as a potent inhibitor of platelet aggregation. Here we report the solid-phase synthesis of decorsin using the Fmoc strategy. The crude polypeptide was purified by reverse-phase HPLC in its reduced form and allowed to refold in the presence of glutathione. The homogeneity of the synthetic oxidized decorsin was established by reverse-phase HPLC and capillary zone electrophoresis. The results of amino acid analysis after acid hydrolysis of the synthetic protein, NH2-terminal sequencing and mass determination (4,377 Da) by electrospray mass spectrometry were in full agreement with this theory. The correct pairing of the three disulfide bridges in synthetic decorsin was determined by a combined approach of both peptide mapping using proteolytic enzymes and analysis of the disulfide chirality by CD spectroscopy in the near-UV region. Synthetic decorsin inhibited human platelet aggregation with an IC50 of approximately 0.1 microM, a figure quite similar to that determined utilizing decorsin from natural source. In particular, the synthetic protein was 2,000-fold more potent than a model RGD-peptide (e.g., Arg-Gly-Asp-Ser) in inhibiting platelet aggregation. Thermal denaturation experiments of synthetic decorsin, monitored by CD spectroscopy, revealed its high thermal stability (Tm approximately 74 degrees C). The features of the oxidative refolding process of reduced decorsin, as well as the thermal stability of the oxidized species, were compared with those previously determined for the NH2-terminal core domain fragment 1-41 or 1-43 from hirudin. This fragment shows similarity in size, pairing of the three disulfides and three-dimensional structure with those of decorsin, even if very low sequence similarity. It is suggested that the less efficient oxidative folding and the enhanced thermal stability of decorsin in respect to those of hirudin core domain likely can be ascribed to the presence of the six Pro residues in the decorsin chain, whereas none is present in the hirudin domain. The results of this study indicate that decorsin can be obtained by solid-phase methodology in purity and quantities suitable for structural and functional studies and thus open the way to prepare by chemical methods novel decorsin derivatives containing unusual amino acids or even non-peptidic moieties.

Mutational analysis of a surface area that is critical for the thermal stability of thermolysin-like proteases

Site-directed mutagenesis was used to assess the contribution of individual residues and a bound calcium in the 55-69 region of the thermolysin-like protease of Bacillus stearothermophilus (TLP-ste) to thermal stability. The importance of the 55-69 region was reflected by finding that almost all mutations had drastic effects on stability. These effects (both stabilizing and destabilizing) were obtained by mutations affecting main chain flexibility, as well as by mutations affecting the interaction between the 55-69 region and the rest of the protease molecule. The calcium-dependency of stability could be largely abolished by mutating one of its ligands (Asp57 or Asp59). In the case of the Asp57-->Ser mutation, the accompanying loss in stability was modest compared with the effects of other destabilizing mutations or the effects of (combinations of) stabilizing mutations. The detailed knowledge of the stability-determining region of TLP-ste permits effective rational design of stabilizing mutations, which, presumably, are also useful for related TLP such as thermolysin. This is demonstrated by the successful design of a stabilizing salt bridge involving residues 65 and 11.

Extreme stabilization of a thermolysin-like protease by an engineered disulfide bond

The thermal inactivation of broad specificity proteases such as thermolysin and subtilisin is initiated by partial unfolding processes that render the enzyme susceptible to autolysis. Previous studies have revealed that a surface-located region in the N-terminal domain of the thermolysin-like protease produced by Bacillus stearothermophilus is crucial for thermal stability. In this region a disulfide bridge between residues 8 and 60 was designed by molecular modelling, and the corresponding single and double cysteine mutants were constructed. The disulfide bridge was spontaneously formed in vivo and resulted in a drastic stabilization of the enzyme. This stabilization presents one of the very few examples of successful stabilization of a broad specificity protease by a designed disulfide bond. We propose that the success of the present stabilization strategy is the result of the localization and mutation of an area of the molecule involved in the partial unfolding processes that determine thermal stability.

Limited proteolysis of ribonuclease A with thermolysin in trifluoroethanol

We have examined the proteolysis of bovine pancreatic ribonuclease A (RNase) by thermolysin when dissolved in aqueous buffer, pH 7.0, in the presence of 50% (v/v) trifluoroethanol (TFE). Under these solvent conditions, RNase acquires a conformational state characterized by an enhanced content of secondary structure (helix) and reduced tertiary structure, as given by CD measurements. It was found that the TFE-resistant thermolysin, despite its broad substrate specificity, selectively cleaves the 124-residue chain of RNase in its TFE state (20-42 degrees C, 6-24 h) at peptide bond Asn 34-Leu 35, followed by a slower cleavage at peptide bond Thr 45-Phe 46. In the absence of TFE, native RNase is resistant to proteolysis by thermolysin. Two nicked RNase species, resulting from cleavages at one or two peptide bonds and thus constituted by two (1-34 and 35-124) (RNase Th1) or three (1-34, 35-45 and 46-124) (RNase Th2) fragments linked covalently by the four disulfide bonds of the protein, were isolated to homogeneity by chromatography and characterized. CD measurements provided evidence that RNase Th1 maintains the overall conformational features of the native protein, but shows a reduced thermal stability with respect to that of the intact species (-delta Tm 16 degrees C); RNase Th2 instead is fully unfolded at room temperature. That the structure of RNase Th1 is closely similar to that of the intact protein was confirmed unambiguously by two-dimensional NMR measurements. Structural differences between the two protein species are located only at the level of the chain segment 30-41, i.e., at residues nearby the cleaved Asn 34-Leu 35 peptide bond. RNase Th1 retained about 20% of the catalytic activity of the native enzyme, whereas RNase Th2 was inactive. The 31-39 segment of the polypeptide chain in native RNase forms an exposed and highly flexible loop, whereas the 41-48 region forms a beta-strand secondary structure containing active site residues. Thus, the conformational, stability, and functional properties of nicked RNase Th1 and Th2 are in line with the concept that proteins appear to tolerate extensive structural variations only at their flexible or loose parts exposed to solvent. We discuss the conformational features of RNase in its TFE-state that likely dictate the selective proteolysis phenomenon by thermolysin.

Probing the partly folded states of proteins by limited proteolysis

The folding of a polypeptide chain of a relatively large globular protein into its unique three-dimensional and functionally active structure occurs via folding intermediates. These partly folded states of proteins are difficult to characterize, because they are usually short lived or exist as a distribution of possible conformers. A variety of experimental techniques and approaches have been utilized in recent years in numerous laboratories for characterizing folding intermediates that occur at equilibrium, including spectroscopic techniques, solution X-ray scattering, calorimetry and gel filtration chromatography, as well as genetic methods and theoretical calculations. In this review, we focus on the use of proteolytic enzymes as probes of the structure and dynamics of folding intermediates and we show that this simple biochemical technique can provide useful information, complementing that obtained by other commonly used techniques and approaches. The key result of the proteolysis experiments is that partly folded states (molten globules) of proteins can be sufficiently rigid to prevent extensive proteolysis and appear to maintain significant native-like structure.

Structural determinants of the stability of thermolysin-like proteinases

Thermolysin is a member of a family of homologous proteinases which differ in their resistance to thermally induced unfolding and subsequent autolytic degradation. Site-directed mutagenesis studies of the thermolysin-like proteinase (TLP) from Bacillus stearothermophilus (TLP-ste) show that its reduced resistance to thermally induced autolysis, as compared to thermolysin, is due to only some of the 44 naturally occurring amino-acid differences between them. In fact TLP-ste becomes more resistant than thermolysin by mutation of just a few of these amino-acids. The crucial differences are all localized to a solvent-exposed region in the N-terminal domain of TLP-ste.

Structural studies on the zinc-endopeptidase light chain of tetanus neurotoxin

Tetanus neurotoxin (TeNT) blocks neuroexocytosis via a zinc-endopeptidase activity highly specific for vescicle-associated membrane protein(VAMP)/synaptobrevin. TeNT is the prototype of clostridial neurotoxins, a new family of metalloproteinases. They consist of three domains and the proteolytic activity is displayed by the 50-kDa light chain (L chain). The L chain was isolated here in the native state from bacterial filtrates of Clostridium tetani and its structure was studied via circular dichroism (CD) and fluorescence spectroscopy. The secondary structure content (27% alpha-helix and 43% beta-sheet), estimated by far-ultraviolet CD measurements, was in reasonable agreement with that obtained by standard predictive methods (25% alpha-helix and 49% beta-sheet). Moreover, the hypothetical zinc-binding motif, encompassing residues His-Glu-Leu-Ile-His, was correctly predicted to be in alpha-helical conformation, as also expected on the basis of the geometrical requirements for a correct coordination of the zinc ion. Both near-ultraviolet CD and fluorescence data strongly suggest that the single Trp43 residue is buried and constrained in a hydrophobic environment, likely distant from the zinc ion located in the active-site cleft. The contribution of the bound zinc ion to the overall conformation of TeNT L chain was investigated by different and complementary techniques, including spectroscopic (far- and near-ultraviolet CD, fluorescence, second derivative absorption spectroscopy) as well as proteolytic probes. The results indicate that the zinc ion plays little, if any, role in determining the structural properties of the L chain molecule. Similarly, the metal-free apo-enzyme and the holo-protein share common stability features evaluated in respect to different physico-chemical parameters (pH, temperature and urea concentration). These results parallel those obtained on thermolysin, a zinc-dependent neutral endoprotease from Bacillus thermoproteolyticus, where both conformational and stability properties are unchanged upon zinc removal.

Probing the structure of hirudin from Hirudinaria manillensis by limited proteolysis. Isolation, characterization and thrombin-inhibitory properties of N-terminal fragments

Hirudin is the most potent and specific inhibitor of the blood-clotting enzyme thrombin so far known. Several hirudin variants were isolated mostly from Hirudo medicinalis and shown to be polypeptide chains of approximately 7 kDa with three internal disulfide bridges. In this study, limited proteolysis has been used to probe aspects of the structure and dynamics of a hirudin variant HM2 isolated from Hirudinaria manillensis. Proteolysis of the polypeptide chain of 64-amino-acid residues of hirudin HM2 by protease from Staphylococcus aureus V8, trypsin, thermolysin and subtilisin occurs at region 41-49 of the chain. The N-terminal fragments 1-41 and 1-47 were isolated to homogeneity and shown to maintain inhibitory action on thrombin, though much lower than the intact protein. The results were interpreted on the basis of a proposed three-dimensional structure of hirudin HM2 deduced by protein modelling the known structure of hirudin variant HV1 from Hirudo medicinalis (75% sequence similarity between HM2 and HV1). Both proteolysis experiments and protein modelling provide evidence for the existence in hirudin HM2 of a N-terminal well-structured domain (core) and a C-terminal flexible polypeptide segment. Determination of the accessible surface area of the three-dimensional model of hirudin HM2 showed that the sites of preferential cleavages are at the surface of the polypeptide molecule.

Importance of peptide amino and carboxyl termini to the stability of MHC class I molecules

An influenza virus matrix peptide in which either the charged amino or carboxyl terminus was substituted by methyl groups promoted folding of the class I human histocompatibility antigen (HLA-A2). A peptide modified at both termini did not promote stable folding. The thermal stability of HLA-A2 complexed with peptides that did not have either terminus was approximately 22 degrees C lower than that of the control peptide, whereas matrix peptide in which both anchor positions were substituted by alanines had its stability decreased by only 5.5 degrees C. Thus, the conserved major histocompatibility complex class I residues at both ends of the peptide binding site form energetically important sites for binding the termini of short peptides.

Protein stabilization by hydrophobic interactions at the surface

The contribution of the solvent-exposed residue 63 to thermal stability of the thermolysin-like neutral protease of Bacillus stearothermophilus was studied by analyzing the effect of twelve different amino acid substitutions at this position. The thermal stability of the enzyme was increased considerably by introducing Arg, Lys or bulky hydrophobic amino acids. In general, the effects of the mutations showed that hydrophobic contacts in this surface-located region of the protein are a major determinant of thermal stability. This observation contrasts with general concepts concerning the contribution of surface-located residues and surface hydrophobicity to protein stability and indicates new ways for protein stabilization by site-directed mutagenesis.

Phosphopeptide mapping and phosphoamino acid analysis by electrophoresis and chromatography on thin-layer cellulose plates

Identification of protein phosphorylation sites is essential in order to evaluate the contribution of individual sites to the regulation of a particular protein by phosphorylation. Here we review a method we have developed for the identification of phosphorylation sites based on digestion of 32P-labeled proteins with site-specific proteases and separation of the digestion products in two dimensions on thin-layer cellulose plates using electrophoresis in the first dimension followed by chromatography. This method is very sensitive, requiring only a few hundred 32P-disintegrations per minute to obtain reproducible phosphopeptide maps. We also report methods for the analysis of the phosphoamino acid content of both intact phosphoproteins and individual phosphopeptides recovered from two-dimensional separations, in which the material is subjected to partial acid hydrolysis, and the hydrolysis products are separated on thin-layer cellulose plates by electrophoresis in one or two dimensions. Finally, we describe methods for analyzing the structure of isolated phosphopeptides by secondary digestion with site-specific proteases, by manual Edman degradation, and by immunoprecipitation, and indicate how this information can be used in conjunction with the two-dimensional mobility of the peptide to deduce the identity of a phosphopeptide from the known sequence of a protein.

Structural stability of Bacillus thuringiensis delta-endotoxin homolog-scanning mutants determined by susceptibility to proteases

Forty homolog-scanning (double-reciprocal-crossover) mutant proteins of two Bacillus thuringiensis delta-endotoxin genes (cryIAa and cryIAc) were examined for potential structural alterations by a series of proteolytic assays. Three groups of mutants could be identified. Group 1, consisting of 13 mutants, showed no delta-endotoxin present during overexpression conditions in Escherichia coli (48 h at 37 degrees C, with a ptac promoter). These mutants produced full-sized delta-endotoxin detectable by polyacrylamide gel electrophoresis with Coomassie blue staining or Western immunoanalysis after 24 h of growth but not after 48 h, suggesting sensitivity to intracellular proteases. Group 2 consisted of 13 mutants that produced stable delta-endotoxins that were completely digested by 2% bovine trypsin. In contrast, native delta-endotoxin produces a 65,000-Da trypsin-resistant peptide, which is the active toxin. Group 3 mutants expressed delta-endotoxin and trypsin-stable toxins, similar to the wild type. In this study, 12 group 3 mutant toxins were compared with wild type toxins by thermolysin digestion at a range of temperatures. The two wild-type toxins exhibited significant differences in thermolysin digestion midpoints. Among the group 3 mutants, most possessed significantly different protein stabilities relative to their parental toxins. Two of the group 3 mutants were observed to have exchanged the thermolysin sensitivity properties of the parental toxins.

Prediction and analysis of structure, stability and unfolding of thermolysin-like proteases

Bacillus neutral proteases (NPs) form a group of well-characterized homologous enzymes, that exhibit large differences in thermostability. The three-dimensional (3D) structures of several of these enzymes have been modelled on the basis of the crystal structures of the NPs of B. thermoproteolyticus (thermolysin) and B. cereus. Several new techniques have been developed to improve the model-building procedures. Also a 'model-building by mutagenesis' strategy was used, in which mutants were designed just to shed light on parts of the structures that were particularly hard to model. The NP models have been used for the prediction of site-directed mutations aimed at improving the thermostability of the enzymes. Predictions were made using several novel computational techniques, such as position-specific rotamer searching, packing quality analysis and property-profile database searches. Many stabilizing mutations were predicted and produced: improvement of hydrogen bonding, exclusion of buried water molecules, capping helices, improvement of hydrophobic interactions and entropic stabilization have been applied successfully. At elevated temperatures NPs are irreversibly inactivated as a result of autolysis. It has been shown that this denaturation process is independent of the protease activity and concentration and that the inactivation follows first-order kinetics. From this it has been conjectured that local unfolding of (surface) loops, which renders the protein susceptible to autolysis, is the rate-limiting step. Despite the particular nature of the thermal denaturation process, normal rules for protein stability can be applied to NPs. However, rather than stabilizing the whole protein against global unfolding, only a small region has to be protected against local unfolding. In contrast to proteins in general, mutational effects in proteases are not additive and their magnitude is strongly dependent on the location of the mutation. Mutations that alter the stability of the NP by a large amount are located in a relatively weak region (or more precisely, they affect a local unfolding pathway with a relatively low free energy of activation). One weak region, that is supposedly important in the early steps of NP unfolding, has been determined in the NP of B. stearothermophilus. After eliminating this weakest link a drastic increase in thermostability was observed and the search for the second-weakest link, or the second-lowest energy local unfolding pathway is now in progress. Hopefully, this approach can be used to unravel the entire early phase of unfolding.

Stabilization of Bacillus stearothermophilus neutral protease by introduction of prolines

The thermostability of neutral proteases has been shown to depend on autolysis which presumably occurs in flexible regions of the protein. In an attempt to rigidify such a region in the neutral protease of Bacillus stearothermophilus, residues in the solvent-exposed 63-69 loop were replaced by proline. The mutations caused large positive (Ser-65-->Pro, Ala-69-->Pro) or negative (Thr-63-->Pro, Tyr-66-->Pro) changes in thermostability, which were explained on the basis of molecular modelling of the mutant proteins. The data show that the introduction of prolines at carefully selected positions in the protein can be a powerful method for stabilization.

Arthrobacter D-xylose isomerase: partial proteolysis with thermolysin

The pattern and kinetics of partial proteolysis of Arthrobacter D-xylose isomerase tetramer was studied in order to determine the flexibility of surface loops that may control its stability. It was completely resistant to trypsin, chymotrypsin and elastase at 37 degrees C, but thermolysin cleaved specifically and quantitatively at Thr-347-Leu-348 between helices 10 and 11 to remove 47 residues from the C-terminus of each 43.3 kDa subunit. At high temperatures, helices 9 and 10 were removed from each 38 kDa subunit to give a 36 kDa tetramer. The kinetics of nicking by thermolysin indicated that the Thr-347-Leu-348 loop is locked at low temperatures, but 'melts' at 25 degrees C and is fully flexible above 34 degrees C. The flexibility appears to be associated with binding of Ca2+ ions at the active site, since Co2+, Mg2+ and xylitol protect in proportion to their ability to displace Ca2+. The missing C-terminal helices make many intersubunit contacts that appear in the structure to stabilize the tetramer, but the properties of the purified nicked proteins are almost indistinguishable from the native enzyme. Both the 38 kDa tetramer and the 36 kDa tetramer are identically active and dissociate similarly in urea or SDS to fully active dimers, but the nicked dimers are slightly less stable to urea at 62 degrees C. In the Mg2+ form the thermostability of the 38 kDa tetramer is identical with that of the native enzyme, but the 36 kDa tetramer has a slightly lower 'melting point' (70 degrees C versus 80 degrees C), which may be due to unravelling from the end of helix 8. Since elimination of all the C-terminal helices and many intersubunit contacts has so little effect, one can conclude that the 'weak point' that controls the protein's thermostability lies within the N-terminal beta-barrel domain.

Two conditional tsA mutant simian virus 40 T antigens display marked differences in thermal inactivation

We have characterized the simian virus 40 (SV40) origin-containing DNA (ori-DNA) replication functions of two SV40 conditional mutant T antigens: tsA438 A-V (tsA58) and tsA357 R-K (tsA30). Both tsA mutant T antigens, immunopurified from recombinant baculovirus-infected insect cells, mediated replication of SV40 ori-DNA in vitro to similar extents as did wild-type T antigen in reactions at 33 degrees C. However, at 41 degrees C, the restrictive temperature, while tsA438 T antigen still generated substantial levels of replication products, tsA357 T antigen did not support any detectable DNA synthesis. Furthermore, preincubation for approximately fourfold-longer time periods at 41 degrees C was required to heat inactivate tsA438 T antigen than to heat inactivate tsA357 T antigen. Unexpectedly, results of analyses of the various DNA replication activities of the two mutant T antigens did not correlate with results from ori-DNA replication reactions. In particular, although tsA357 T antigen was incapable of mediating replication at 41 degrees C at all protein concentrations examined, it displayed either wild-type levels or only partial reductions of the several T-antigen replication-associated activities. These data suggest either that tsA357 T antigen is defective in an as yet unidentified replication function of T antigen or that the combination of its partial defects result in a protein that is unable to support replication. The data also show that two conditional mutant T antigens can be markedly different with respect to thermal sensitivity.

Effects of changing the interaction between subdomains on the thermostability of Bacillus neutral proteases

Variants of the thermolabile neutral protease (Npr) of B. subtilis (Npr-sub) and the thermostable neutral protease of B. stearothermophilus (Npr-ste) were produced by means of site-directed mutagenesis and the effects of the mutations on thermostability were determined. Mutations were designed to alter the interaction between the middle and C-terminal subdomain of these enzymes. In all Nprs a cluster of hydrophobic contacts centered around residue 315 contributes to this interaction. In thermostable Nprs (like Npr-ste) a 10 residue beta-hairpin, covering the domain interface, makes an additional contribution. The hydrophobic residue at position 315 was replaced by smaller amino acids. In addition, the beta-hairpin was deleted from Npr-ste and inserted into Npr-sub. The changes in thermostability observed after these mutations confirmed the importance of the hydrophobic cluster and of the beta-hairpin for the structural integrity of Nprs. Combined mutants showed that the effects of individual mutations affecting the interaction between the subdomains were not additive. The effects on thermostability decreased as the strength of the subdomain interaction increased. The results show that once the subdomain interface is sufficiently stabilized, additional stabilizing mutations at the same interface do not further increase thermostability. The results are interpreted on the basis of a model for the thermal inactivation of neutral proteases, in which it is assumed that inactivation results from the occurrence of local unfolding processes that render these enzymes susceptible to autolysis.

Leishmania mexicana mexicana gp63 is a site-specific neutral endopeptidase

Leishmania mexicana, like other species of the genus, has a major 63-kDa surface glycoprotein (gp63) that is an active protease. Reports differ as to whether gp63 is a neutral or an acidic protease. Using three radiolabeled synthetic peptide substrates, gp63 purified from L. m. mexicana is most active at pH 6.5-7.5, in three different buffer systems, and appears to be a sequence-specific endopeptidase. The full extent of sequence specificity is undetermined, but these experiments suggest a strong preference for cleavage at serine or threonine residues. In common with other metalloproteases, the cleavage is on the amino side of the recognition residue.

The histidines reacting with ethoxyformic anhydride in porcine pancreatic lipase: their relationships with enzyme activity

The activities of porcine pancreatic lipase (449 amino acid residues) toward two different substrates, p-nitrophenylacetate and tributyrylglycerol, and their dependence on histidine ethoxyformylation were studied. In parallel, the ethoxyformylation of the lipase fragment constituting the C-terminal sequence of lipase (residues 336 to 449) was also investigated. This fragment was found to have retained the ability of lipase to catalyse p-nitrophenylacetate hydrolysis. The first histidine to react either in lipase or in the lipase fragment was His-354. The activities of the two compounds toward p-nitrophenyl-acetate were lost but that of the enzyme toward tributyrylglycerol was almost entirely retained. When a larger excess of ethoxyformic anhydride was used for the lipase reaction, 2.8 histidine residues were ethoxyformylated and characterised as His-354, His-156 and His-75, which resulted in an 85% inhibition of the tributyrylglycerol hydrolysis by the enzyme. Hydroxylamine treatment reactivated most of the lipase and lipase fragment. This is the first demonstration that the two lipase activities are not associated with the same active site. The loss of activity toward triacylglycerol hydrolysis suggests that His-156 and/or His-75 belong(s) to the active site or that a conformational change resulting from the ethoxyformylation renders the lipase inactive.

Thermolysin treatment: a new method for dermo-epidermal separation

The epidermis of superficial human skin samples could easily be separated from the dermis following incubation at +4 degrees C for 1 h in a solution containing 250-500 micrograms/ml thermolysin, a proteolytic enzyme hitherto mostly used for protein analysis. Light and electron microscopy revealed that the dermo-epidermal separation occurred at the basement membrane between the sites of bullous pemphigoid antigen and laminin and that the hemidesmosomes were selectively disrupted. The cohesion and morphology of the separated epidermis as well as the immunologic parameters investigated were not altered by this procedure. The clear cut dermo-epidermal separation produced by thermolysin treatment differed from the separation obtained with trypsin, which predominantly occurred between basal and suprabasal cells by disruption of desmosomes.