Refolding of serine proteinases

Bovine trypsinogen and chymotrypsinogen were successfully refolded as the mixed disulfide of glutathione using cysteine as the disulfide interchange catalyst. The native structures were regenerated with yields of 40%-50% at pH 8.6 and 4 degrees C, and the half-time for the refolding was approximately 60-75 min. We then refolded threonine-neochymotrypsinogen, which is a two-chain structure held together by disulfide bonds and produced on cleavage of Tyr 146-Thr 147 in native chymotrypsinogen [Duda CT, Light A, J Biol Chem 257 9866-9871, 1982]. Neochymotrypsinogen was denatured and fully reduced, and the thiols were converted to the mixed disulfide of glutathione. The two polypeptide fragments, representing the amino- and carboxyl-terminal domains, were separated on Sephadex G-75. Mixtures of the polypeptide fragments varying in the ratio of their concentration from 1:5 to 5:1 were refolded with yields of 21-28%. The lack of dependence on the concentration of either fragment and the relatively high yields suggest independent folding of the amino- and carboxyl-terminal domains. When the globular structures of the domains formed, they then interacted with one another and produced the native intermolecular disulfide bridge and the proper geometry of the active site.     

ATP-dependent proteinases in bacteria

Cytoplasmic proteolysis is an indispensable process for proper function of a cell. Degradation of many intracellular proteins is initiated by ATP-dependent proteinases, which are involved in the regulation of the level of proteins with short half-lives. In addition, they remove many damaged and abnormal proteins and thus play also an important role during stress. ATP-dependent proteinases are large multi-subunit assemblies composed of proteolytic core domains and ATPase-containing regulatory domains on a single polypeptide chain or on distinct subunits, which can act as molecular chaperones. This review briefly summarizes the data about four main groups of these proteinases in bacteria (i.e. Lon, Clp family, HsIUV and FtsH) and characrizes their structure, mechanism of action and properties.     

Autodegradation of lysosomal cysteine proteinases

Repeated injections of Ep-475, a potent cysteine proteinase inhibitor, into rats caused several-fold increase in the hepatic contents of the lysosomal cysteine proteinases cathepsin B, H and L and in the activities of other lysosomal hydrolases. The rates of degradation of these lysosomal enzymes, estimated by repeated injections of cycloheximide, were found to be retarded in Ep475-treated rats, indicating that lysosomal cysteine proteinases are involved in degradation of lysosomal enzymes including proteinases.     

Immobilization of proteinases on Chitosan

Summary Trypsin, pronase and subtilisin were immobilized on chitosan by glutaraldehyde coupling. Significant retention of activity was observed when synthetic substrates as well as casein were used. The specific activities of the bound proteinases ranged from 38% to 79% of their initial specific activities. The pH-activity profile of trypsin was slightly shifted toward alkaline values, and its thermal stability was increased. Immobilized trypsin was found to be less sensitive to its natural inhibitors than the soluble enzyme.A preliminary report of this work has already been presented at the First European Congress on Biotechnology (September 25–30, 1978, Interlaken, Switzerland).     

Cysteine proteinases of parasitic protozoa

Proteinases are involved with many processes in living organisms. In recent years, there has been increasing interest in elucidating the functions the enzymes perform in parasites. These studies have revealed that one class of proteinases, the cysteine proteinases, predominates in many parasitic protozoa. In this article Mick North, Jeremy Mottram and Graham Coombs review what is known about the cysteine proteinases of parasitic protozoa and discuss the approaches being pursued in attempts to design antiparasite drugs based on inhibitors or substrates of these enzymes.     

Protein inhibitors of serine proteinases

Serine proteinases and their natural protein inhibitors belong to the most intensively studied models of protein-protein recognition. Protein inhibitors do not form a single group but can be divided into about 20 different families. Global structures of proteins representing different inhibitor families are completely different and comprise alpha-helical proteins, beta-sheet proteins, alpha/beta-proteins and different folds of small disulfide-rich proteins. Three different types of inhibitors can be distinguished: canonical (standard mechanism) inhibitors, non-canonical inhibitors, and serpins. The canonical inhibitor binds to the enzyme through the exposed and convex binding loop, which is complementary to the active site of the enzyme. The mechanism of inhibition in this group is consistently very similar and resembles that of an ideal substrate. Non-canonical inhibitors, originating from blood sucking organisms, specifically block enzymes of the blood clotting cascade. The interaction is mediated through inhibitor N-terminus which binds to the proteinase forming a parallel beta-sheet. There are also extensive secondary interactions which provide an additional buried area and contribute significantly to the strength and specificity of recognition. Serpins are major proteinase inhibitors occurring in plasma. Similarly to canonical inhibitors, serpins interact with their target proteinases in a substrate-like manner. However, in the case of serpins, cleavage of a single peptide bond in a flexible and exposed binding loop leads to dramatic structural changes.     

Candida proteinases and candidosis

Infections caused by the opportunistic yeast pathogen, Candida albicans, are becoming increasingly important. Superficial Candida infections, particularly those of the mouth and vagina, are very common; for example, candidal vaginitis plaques millions of women worldwide, often proving refractory to treatment. Systemic candidosis is much rarer, but it is an important hazard of modern medical procedures such as transplant surgery, i.v. hyperalimentation, and immunosuppressive therapy. One significant virulence factor of C. albicans is its ability to secrete extracellular acid proteinase. This attribute is shared by C. tropicalis and C. parapsilosis, but not by other less pathogenic Candida species. The enzymes produced by these yeasts are all carboxyl proteinases capable of degrading secretory IgA, the major immunoglobulin of mucous membranes. Some have keratino- or collagenolytic activity. Two secretory proteinases of C. albicans have been purified and characterized; their properties are reviewed. Possible applications of this work to the treatment and diagnosis of candidosis are discussed.     

Engineered resistance against proteinases

Exogenous proteinase inhibitors are valuable and economically interesting protective biotechnological tools. We examined whether small proteinase inhibitors when fused to a selected target protein can protect the target from proteolytic degradation without simultaneously affecting the function and activity of the target domain. Two proteinase inhibitors were studied: a Kazal-type silk proteinase inhibitor (SPI2) from Galleria mellonella, and the Cucurbita maxima trypsin inhibitor I (CMTI I). Both inhibitors target serine proteinases, are small proteins with a compact structure stabilized by a network of disulfide bridges, and are expressed as free polypeptides in their natural surroundings. Four constructs were prepared: the gene for either of the inhibitors was ligated to the 5' end of the DNA encoding one or the other of two selected target proteins, the coat protein (CP) of Potato potyvirus Y or the Escherichia coli beta-glucuronidase (GUS). CMTI I fused to the target proteins strongly hampered their functions. Moreover, the inhibitory activity of CMTI I was retained only when it was fused to the CP. In contrast, when fused to SPI2, specific features and functions of both target proteins were retained and the inhibitory activity of SPI2 was fully preserved. Measuring proteolysis in the presence or absence of either inhibitor, we demonstrated that proteinase inhibitors can protect target proteins used either free or as a fusion domain. Interestingly, their inhibitory efficiency was superior to that of a commercial inhibitor of serine proteinases, AEBSF.     

Serine proteinases of lower vertebrates

Recent data on the effect of serine proteinases of lower vertebrates are generalized. Hydrolysis specificity and kinetics of different synthetic substrates, dependence of the activity of enzymes on pH, their irreversible inhibition by chloromethyl ketones of amino acids and peptides as well as high-molecular proteinase inhibitors are considered in detail. The data testify to the fact that chymotrypsins and trypsins of higher vertebrates and serine proteinases of lower vertebrates act as an acid-base catalysis. Enzymes in the pyloric cacca of fishes are in the state of proenzymes and are transformed into an active form with the aid of their own proteolytic factors. The esterase and proteolytic activity of fish proteinases is concentrated in the same active site and reaches the highest values at pH 7,8. New data are presented on particularities of the lower vertebrate proteinases, on the similarity and differences in their specificity. A distinct difference is shown in the nature of the binding site of the active centre in a number of serine proteinases of fishes as compared to chymotrypsin and trypsin of higher vertebrates.     

Cysteine proteinases in chondrosarcomas

The aim of the present study was to define the role of cathepsins B, H, K, L and S in the pathogenesis of human chondrosarcomas. For this purpose 40 tumour samples obtained from 12 patients with the diagnosis of conventional chondrosarcoma were systematically investigated for the expression of cathepsin mRNAs by Northern hybridisation, and for immunohistochemical localisation of the proteins. Northern analysis demonstrated the highest levels of cathepsins B and L in a recurring grade 1 chondrosarcoma, and in a grade 3 chondrosarcoma and in fibrous histiocytomas. Increased expression of cathepsin K mRNA was seen in seven chondrosarcomas, as well as in control tumours; fibrous histiocytomas, osteosarcomas, enchondromas and a giant cell tumour of bone. Cathepsin L was immunolocalised within the large chondrocytes, while cathepsin K was predominantly localised in large multinucleated osteoclastic cells and in some hypertrophic chondrocytes. These results suggest that chondrosarcoma can be included in the growing list of tumours, where cathepsins may well be involved in tumour progression. The simultaneous upregulation of cathepsins B and L, together with matrix metalloproteinase-13, and the association of cathepsin K with negative prognostic parameters suggests that an aggressive biological behaviour of chondrosarcoma may be related to the synthesis of cysteine proteinases and activation of other proteolytic enzymes. If this turns out to be the case, cathepsin inhibitors could provide the much needed adjuvant therapy for chondrosarcomas.     

Mass-spectrometric determination of specificity of proteinases

Analysis of methods of the proteinase substrate specificity determination revealed that Michaelis constants found from the rates of hydrolysis of small synthetic substrates cannot be a good measure of selectivity, especially for proteinases of broad specificity used for hydrolysis of substrates of high molecular mass with multiple cleavage sites. Mass-spectrometric studies (ERIAD) of the hydrolysis of the insulin B chain with trypsin, chymotrypsin, and proteinase I showed that monitoring of the reaction mixtures by means of this technique gives more reliable information on the selectivity of proteinase towards high-molecular substrates.     

Diisopropyl fluorophosphate labeling of sperm-associated proteinases

Proteinase inhibitors have been shown to be capable of preventing various aspects of fertilization. Diisopropyl fluorophosphate (DFP) is an irreversible inhibitor of trypsin-like enzymes that is commercially available in a radiolabeled form. The experiments described herein were designed to determine if DFP would prevent sperm function in live, motile sperm and to identify the sperm proteins bound with DFP. DFP at 5 mM concentrations had no observable effect on sperm motility, but inhibited the penetration of zona-free hamster ova by human sperm (5.5%) compared to controls (33.5%). Acid extracts of motile sperm that had been incubated with radiolabeled DFP and collected by the swim-up procedure demonstrated the presence of radiolabeled DFP, and the autoradiography of the sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) gels of these extracts localized the uptake of radiolabeled DFP to proteins in the molecular weight region of the proacrosin-acrosin system. Acid-extracted proteinases from semen samples incubated with DFP demonstrated a concentration-dependent inhibition of both esterolytic hydrolysis of benzoyl-arginine ethyl ester on spectrophotometric analysis and proteolytic activity on gelatin SDS-PAGE zymography. DFP-labeled proteins were precipitated by highly specific antibodies to proacrosin. These results demonstrated that DFP is capable of inhibiting sperm function, and that it associates with the proacrosin-acrosin system in live motile sperm.     

Midgut proteinases of the cockroachNauphoeta cinerea

The study of properties of proteolytic enzymes in midgut of imago of the cockroachNauphoeta cinerea Oliv. Has been carried out. It is shown that the total proteolytic activity of digestive proteases, measured with azocasein as substrate, is maximal at pH 11.5 both in the anterior and in the posterior parts of the midgut. The predominant part of this activity (67%) was present in the posterior part. Fractionation of preparation from the posterior part on a column with Sephadex G-50 and subsequent analysis of the activity in the obtained fractions using specificp-nitroanilide substrates and effects of activators and inhibitors of active center have allowed revealing three types of activity of serine proteinases and one cysteine proteinase. No activity of aspartic and metalloproteinases were detected. Among serine proteinases, one trypsin-like, one unusual SHdependent serine, one chymotrypsin-like, and not less than two enzymes hydrolyzing specific substrate of subtilisin were established. The fractionation of the preparation from the anterior part has allowed revealing only three proteinases that were similar by their properties to cysteine, SHdependent serine, and chymotrypsin-like ones in the posterior part of midgut. Their activity was lower in the anterior, than in the posterior part of the midgut. The probable causes of the low proteolytic activity in the anterior part of the midgut are discussed.     

Naturally occurring inhibitors of intracellular proteinases

The papain inhibitor isolated from chicken egg white inhibits the enzymatic activity of cathepsin B1 and cathepsin C. The inhibitor bears two nonoverlapping reactive sites: one binds cathepsin B1, papain, ficin, and bromelain, the other one cathepsin C. The inhibitor decreases the degree of an immunologic hypersensitive reaction, the so-called Arthus reaction. A statistically significant inhibition of this immunologically developed inflammation occurs only if the inhibitor is applied intradermally and simultaneously with the provoking dose of the antigen to rabbits sensitized to the same antigen. The pepsin inhibitor from the body walls of the roundworm Ascaris lumbricoides inhibits the proteolytic activity of cathepsin E. This inhibitor covalently bound to Sepharose 4B was used for affinity chromatography of cathepsin E. A cathepsin D inhibitor was isolated from potato tubers and its inhibitory and chemical characteristics were studied. The inhibitor does not inhibit either cathepsin E or pepsin yet inhibits trypsin in the alkaline pH-range. The molecular weight of the inhibitor is 21 790 and its molecule consists of 199 amino acid residues. The sequence of 17 amino acid residues was determined by Edman degradation of the inhibitor molecule.     

Polymorphism of membrane proteinases from mitochondria

Using native polyacrylamide gel electrophoresis in the absence of sodium dodecyl sulfate, the detergent extracts of sonic submitochondrial particles (SMP) were separated into three protein fractions capable of accomplishing the proteolysis of cytochrome c and three other fractions catalyzing the hydrolysis of N-a-benzoyl-L-arginine-p-nitroanilide (BAPA) and N-a-benzoyl-L-arginine-B-naphthylamide (BANA). The fractions isolated from the gel were subjected to a thorough anaylsis. Cytochrome c hydrolases were shown to have identical molecular weights (17000) but different isoelectric points (4.0, 4.2 and 4.4). The total cytochrome c hydrolase activity of these enzymes was inhibited by phenylmethylsulfonylfluoride but was insensitive to ethylenediaminetetraacetate and o-phenanthroline. Three BANA (BAPA) hydrolases have identical Mr values (approximately 17500) but different pI values (4.2, 4.3 and 4.7). Apart from the indicated hydrolases, the detergent extracts of SMP were shown to contain minor components with identical activities distinguished by the tightness of binding to the inner mitochondrial membrane, Mr and sensitivity to proteinase inhibitors. The observed phenomenon is considered to be due to the polymorphism of proteinases coupled with the inner mitochondrial membrane.     

Pepsinogen activation by microbial proteinases

Serine proteinase and metalloproteinase of Asp. oryzae, extracellular metalloproteinase of L. pneumophila and chymotrypsin-like proteinase of S. rutgersensis can hydrolyze pepsinogen by converting it into pepsin (pH 5.0, 37 degrees C). The localization of the site of hydrolysis depends on the nature of the enzyme: serine proteinase from Asp. oryzae induces the synthesis of a mixture of 60% pepsin, 25% leucyl-pepsin and 15% alanyl-leucyl-pepsin; metalloproteinase of Asp. oryzae converts pepsinogen only into leucyl-pepsin, while metalloproteinase of L. pneumophila yields a mixture of 33% pepsin, 53% leucyl-pepsin and 14% alanyl-leucyl-pepsin. Thus, the region of the activating pepsinogen peptide--Ala 42P-Ile 1 bond--seems to the most probable site for hydrolysis by exogenous proteinases. This site contains a Leu 44P-Ile 1 bond which is subjected to intermolecular hydrolysis during autocatalytic activation of pepsinogen. The experimental results emphasize the importance of the intermolecular pathway of pepsinogen activation.