Interaction of the cysteine proteinase inhibitor chicken cystatin with papain

The two forms of chicken cystatin, with different isoelectric points, that have been described previously were indistinguishable in analyses of amino- and carboxy-terminal residues, amino acid composition, and peptide maps. The two forms thus are highly similar and most likely differ only in an amide group or in a small charged substituent. The binding of either cystatin form to highly purified, active papain was accompanied by the same pronounced changes in near-ultraviolet circular dichroism, ultraviolet absorption, and fluorescence emission. These changes were compatible with perturbations of the environment of aromatic residues in one or both proteins of the complex, arising from local interactions or from a conformational change. Modification of the single tryptophan residue of cystatin, at position 104, with N-bromosuccinimide resulted in considerably smaller spectroscopic changes on binding of the inhibitor to papain, indicating that the environment of this residue is affected by the binding. Analogous modification of Trp-69 and Trp-177 of papain markedly affected the fluorescence changes observed on binding of cystatin to the enzyme, similarly suggesting that these two residues of papain are involved in the interaction. The fluorescence increase of papain at alkaline pH, arising from Trp-177 and due to deprotonization of the adjacent His-159, was abolished on binding of cystatin to the enzyme, further supporting the proposal that this region of papain participates in the interaction with the inhibitor. A stoichiometry of binding of either cystatin form to papain of 1:1 and a lower limit for the binding constant of 10(9) M-1 were determined by titrations monitored by either the ultraviolet absorption or fluorescence changes induced by the interaction.     

Association of human neuroglobin with cystatin C, a cysteine proteinase inhibitor

Neuroglobin (Ngb) is a newly discovered globin that is expressed in vertebrate brain. It has been reported that Ngb levels increase in neurons in response to oxygen deprivation, and that Ngb protects neurons from hypoxia. However, the mechanism of this neuroprotection remains unclear. In the present study, we identified human cystatin C, a cysteine proteinase inhibitor, as an Ngb-binding protein by using a yeast two-hybrid system. Surface plasmon resonance experiments verified that Ngb binds to cystatin C dimers, not to the monomers. Because both intracellular cystatin C and the amyloidogenic variant of cystatin C form dimers, Ngb may modulate the intracellular transport (or secretion) of cystatin C to protect against neuronal death under conditions of oxidative stress and/or it may have a role in the development of neurodegenerative diseases.     

Binding energetics of the inhibitor cystatin to the cysteine proteinase actinidin

The binding energetics of actinidin to chicken cystatin was determined from fluorometric titrations at different temperatures. It is shown that the association of actinidin with cystatin is both enthalpically and entropically driven, with a negative change in the heat capacity. The molecular basis of these contributions are analyzed within the framework of surface-area models, using a 3D model of the actinidin-cystatin complex, which was obtained using the x-ray structure of the homologous complex papain-stefin B as template.     

Affinity chromatography of a cysteine proteinase inhibitor from chicken egg protein

A method of affinity chromatography of the inhibitor of cysteine proteinases from chick egg protein using immobilized ficin has been developed. This method yields a highly active inhibitor in an essentially homogeneous state. The molecular weight of the inhibitor is 14,000. The inhibitor suppresses the activity of ficin and papain but produces no effect on the proteolytic activity of trypsin, chymotrypsin, Asp. oryzae serine proteinase or subtilisine. Isoelectric focusing of the inhibitor has revealed the major band with pI 4.35.     

Characterization of a new cysteine proteinase inhibitor of human saliva, cystatin SN, which is immunologically related to cystatin S

A new cysteine proteinase inhibitor, cystatin SN, was purified from human whole saliva by chromatography with DE32, Sephacryl S200, and CM-Sepharose CL6B. Cystatin SN is immunologically related to cystatin S and both inhibitors have a similar molecular mass of about 13 kDa. The new inhibitor, however, was clearly distinguished from cystatin S by its much higher pI value. These inhibitors showed similar inhibitory activity for ficin, but cystatin SN was a much better inhibitor for papain and dipeptidyl peptidase I. The amino acid sequence of cystatin SN deduced in the light of the known structure of cystatin S indicates that they have 10 different amino acid residues in the sequence comprising in total 113 residues.     

Production of the cysteine proteinase inhibitor cystatin C by rat Sertoli cells.

The Sertoli cells of the rat testis produce cystatin C, a cysteine proteinase inhibitor. Primary culture of Sertoli cells secreted both unglycosylated and glycosylated forms of rat cystatin C. Despite the low concentration of cystatin C in rete testis fluid, equilibrium dissociation constants (Ki) for the interaction between cystatin C and lysosomal cathepsins indicate that this molecule could be involved in the local regulation of testicular cysteine proteinase activity which may be necessary for spermatogenesis and spermiogenesis.     

Identification of the probable inhibitory reactive sites of the cysteine proteinase inhibitors human cystatin C and chicken cystatin

When an excess of human cystatin C or chicken cystatin was mixed with papain, an enzyme-inhibitor complex was formed immediately. The residual free cystatin was then progressively converted to a form with different electrophoretic mobility and chromatographic properties. The modified cystatins were isolated and sequenced, showing that there had been cleavage of a single peptide bond in each molecule: Gly11-Gly12 in cystatin C, and Gly9-Ala10 in chicken cystatin. The residues Gly11 (cystatin C) and Gly9 (chicken cystatin) are among only three residues conserved in all known sequences of inhibitory cystatins. The modified cystatins were at least 1000-fold weaker inhibitors of papain than the native cystatins. An 18-residue synthetic peptide corresponding to residues 4-21 of cystatin C did not inhibit papain but was cleaved at the same Gly-Gly bond as cystatin C. When iodoacetate or L-3-carboxy-trans-2,3-epoxypropionyl-leucylamido-(4-guanidin o)butane was added to the mixtures of either cystatin with papain, modification of the excess cystatin was blocked. Papain-cystatin complexes were stable to prolonged incubation, even in the presence of excess papain. We conclude that the peptidyl bond of the conserved glycine residue in human cystatin C and chicken cystatin probably is part of a substrate-like inhibitory reactive site of these cysteine proteinase inhibitors of the cystatin superfamily and that this may be true also for other inhibitors of this superfamily. We also propose that human cystatin C and chicken cystatin, and probably other cystatins as well, inhibit cysteine proteinases by the simultaneous interactions with such proteinases of the inhibitory reactive sites and other, so far not identified, areas of the cystatins. The cleavage of the inhibitory reactive site glycyl bond in mixtures of papain with excess quantities of cystatins is apparently due to the activity of a small percentage of atypical cysteine proteinase molecules in the papain preparation that form only very loose complexes with cystatins under the conditions employed and degrade the free cystatin molecules.     

Partial purification and characterization of cysteine proteinase inhibitor from chicken plasma

A high-molecular-weight cysteine proteinase inhibitor (CPI) was purified from chicken (Gallus gallus) plasma using polyethylene glycol (PEG) fractionation and affinity chromatography on carboxymethyl–papain–Sepharose-4B. The CPI was purified 96.8-fold with a yield of 28.9%. Based on inhibitory activity staining for papain, CPI was shown to have an apparent molecular mass of 122 kDa. No inhibitory activity was obtained under reducing condition, indicating that CPI from chicken plasma was stabilized by disulfide bonds. CPI was stable in temperature ranges from 40 to 70 °C for 10 min; however, more than 50% of the inhibitory activity towards papain was lost within 30 min of heating at 90 °C. CPI was stable in the presence of salt up to 3%. The purified CPI exhibited the inhibitory activity toward autolysis of arrowtooth flounder (Atheresthes stomias) and Pacific whiting (Merluccius productus) natural actomyosin (NAM) in a concentration-dependent manner.     

Structure and expression of the gene encoding cystatin D, a novel human cysteine proteinase inhibitor

A new member of the human cystatin multigene family has been cloned from a genomic library using a cystatin C cDNA probe. The complete nucleotide sequence of a 4.3-kilobase DNA segment, containing a complete gene with structure very similar to those of known Family 2 cystatin genes, was determined. The novel gene, called CST4, is composed of three exons and two introns. It contains the coding information for a protein of 142 amino acid residues, which has been tentatively called cystatin D. The deduced amino acid sequence includes a putative signal peptide and presents 51-55% identical residues with the sequences of either cystatin C or the secretory gland cystatins S, SN, or SA. The cystatin D sequence contains all regions of relevance for cysteine proteinase inhibitory activity and also the 4 cysteine residues that form disulfide bridges in the other members of cystatin Family 2. Northern blot analysis revealed that the cystatin D gene is expressed in parotid gland but not in seminal vesicle, prostate, epididymis, testis, ovary, placenta, thyroid, gastric corpus, small intestine, liver, or gall-bladder tissue. This tissue-restricted expression is in marked contrast with the wider distribution of all the other Family 2 cystatins, since cystatin C is expressed in all these tissues and the secretory gland cystatins are present in saliva, seminal plasma, and tears. Cystatin D, being the first described member of a third subfamily within the cystatin Family 2, thus appears to have a distinct function in the body in contrast to other cystatins.     

Growth inhibition of a human oral bacterium Porphyromonas gingivalis by rat cysteine proteinase inhibitor cystatin S

T. UMEMOTO, Y. NAITO, M. LI, I. SUZUKI AND I. NAMIKAWA. 1996. Agar diffusion analysis demonstrated that rat cystatin S, a cysteine proteinase inhibitor, inhibited the growth of all tested strains of a human oral, Gram-negative anaerobic periodontopathogen Porphyromonas gingivalis. Its specific inhibitory activity against this tissue-invasive bacterium but not against other tested oral bacterial species emphasized the importance of specific cysteine proteinases for growth of P. gingivalis.     

Purification and complex formation analysis of a cysteine proteinase inhibitor (cystatin) from seeds of Wisteria floribunda

Seeds of Wisteria floribunda contain several kinds of cysteine proteinase inhibitor (cystatin). We purified and characterized one of these inhibitors, named WCPI-3. The molecular weight of WCPI-3 was estimated to be 17,500 and 15,700 by gel filtration and SDS-PAGE, respectively. The isoelectric point was 5.7. WCPI-3 formed an equimolar complex with native papain and the dissociation constant was estimated to be 6.1 nM. Complex formation between WCPI-3 and Cys25-modified papain, such as S-carboxy-methylated or S-carbamoylmethylated papain, could not be observed by gel filtration or native PAGE analysis. A peptide fragment derived from WCPI-3 digested by Achromobacter proteinase (lysyl endopeptidase) had the amino acid sequence of VVAGVNYRFVLK. The VVAG sequence in this fragment corresponds to the conserved sequence QVVAG which is considered to be one of binding regions to cysteine proteinases. The amino acid sequence of the amino-terminal portion (34 residues) of WCPI-3 was highly homologous to that of oryzacystatin from rice seeds.     

Salivary histatin 5 is a potent competitive inhibitor of the cysteine proteinase clostripain

Histatin 5 is a low molecular weight salivary protein which is known to exhibit inhibitory activity against several proteinases, including the cysteine proteinases gingipains. The purpose of this study was to characterize the effect of salivary histatin on the proteolytic activity of the cysteine proteinase clostripain derived from the pathogen Clostridium histolyticum. Using a synthetic nitroanilide substrate, we studied in detail the inhibition of clostripain by histatin 5 and compared the effect of this peptide to that of leupeptin, a known competitive inhibitor of clostripain. It was found that the concentration of histatin 5 required to inhibit 50% of clostripain activity was 23.6+/-1.6 nM. Kinetic analysis revealed that histatin 5 is a competitive inhibitor of clostripain with an inhibition constant (K(i)) of 10 nM. The K(i) for the inhibition of clostripain activity against nitroanilide substrate by leupeptin was found to be 60 nM, significantly higher than that of histatin 5. Thus, histatin 5 inhibits clostripain more effectively than leupeptin and other cysteine protease inhibitors studied here. No significant proteolysis of histatin 5 was observed when histatin 5 was incubated at physiologic concentrations with clostripain. The potent inhibition of clostripain by histatin 5 points towards the possibility that this protein may prevent establishment of clostridial infections and therefore may have significant potential for the treatment of diseases associated with this enzyme.     

Proteolysis of the 85-kilodalton crystalline cysteine proteinase inhibitor from potato releases functional cystatin domains.

The protein crystals found in potato (Solanum tuberosum L.) tuber cells consist of a single 85-kD polypeptide. This polypeptide is an inhibitor of papain and other cysteine proteinases and is capable of binding several proteinase molecules simultaneously (P. Rodis, J.E. Hoff [1984] Plant Physiol 74: 907-911). We have characterized this unusual inhibitor in more detail. Titrations of papain activity with the potato papain inhibitor showed that there are eight papain binding sites per inhibitor molecule. The inhibition constant (Ki) value for papain inhibition was 0.1 nM. Treatment of the inhibitor with trypsin resulted in fragmentation of the 85-kD polypeptide into a 32-kD polypeptide and five 10-kD polypeptides. The 32-kD and 10-kD fragments all retained the ability to potently inhibit papain (Ki values against papain were 0.5 and 0.7 nM, respectively) and the molar stoichiometries of papain binding were 2 to 3:1 and 1:1, respectively. Other nonspecific proteinases such as chymotrypsin, subtilisin Carlsberg, thermolysin, and proteinase K also cleaved the 85-kD inhibitor polypeptide into functional 22-kD and several 10-kD fragments. The fragments obtained by digestion of the potato papain inhibitor with trypsin were purified by reverse-phase high-performance liquid chromatography, and the N-terminal amino acid sequence was obtained for each fragment. Comparison of these sequences showed that the fragments shared a high degree of homology but were not identical. The sequences were homologous to the N termini of members of the cystatin superfamily of cysteine proteinase inhibitors. Therefore, the inhibitor appears to comprise eight tandem cystatin domains linked by preteolytically sensitive junctions. We have called the inhibitor potato multicystatin (PMC). By immunoblot analysis and measurement of papain inhibitory activity, PMC was found at high levels in potato leaves (up to 0.6 microgram/g fresh weight tissue), where it accumulated under conditions that induce the accumulation of other proteinase inhibitors linked to plant defense. PMC may have a similar defensive role, for example in protecting the plant from phytophagous insects that utilize cysteine proteinases for dietary protein digestion.     

Different roles of the two disulfide bonds of the cysteine proteinase inhibitor, chicken cystatin, for the conformation of the active protein.

The Cys-71-Cys-81 disulfide bond of the cysteine proteinase inhibitor, chicken cystatin, was specifically reduced by thioredoxin or low concentrations of dithiothreitol. This cleavage, followed by S-carbamoylmethylation, induced a conformational change of the protein, as evidenced by changes in isoelectric point and circular dichroism spectra and by an increased susceptibility to digestion by nontarget proteinases. The proteinase binding ability and the immunological properties of the inhibitor, however, were not detectably altered, indicating that the conformational change was limited to the region around the disrupted bond. In contrast, reduction of both disulfide bonds of cystatin by higher concentrations of dithiothreitol and subsequent alkylation led to the slow conversion of the inhibitor into two forms lacking proteinase binding ability, indicative of more extensive conformational changes. Together, these results suggest that the less accessible Cys-95-Cys-115 disulfide bond of chicken cystatin, but not the more accessible Cys-71-Cys-81 bond, is of importance for maintaining the conformation of the inhibitor required for binding of target proteinases.     

Candida albicans produces a cystatin-type cysteine proteinase inhibitor.

A cysteine proteinase inhibitor was found in culture media of Candida albicans. Purification to homogeneity of the inhibitor was performed by carboxymethyl-papain-Sepharose affinity, DE-52 ion-exchange, and reverse-phase high performance liquid chromatographies. The purified inhibitor had an M(r) of 15 kDa and a pI of 4.9. It was more stable to heat and pH than most proteins. The N-terminal sequence of the first 30 residues demonstrated high similarity with that of human cystatin A. Thus, C. albicans cysteine proteinase inhibitor seems to belong to the cystatin superfamily. The inhibitor activity of the yeast cellular form was 4.0 times higher than that of the hyphal cellular form in 7-day culture media. It is suggested that the inhibitor has regulatory functions similar to those of its counterpart proteinases in the invasion of host cells.     

Acidic cysteine proteinase inhibitor in seminal plasma

A cysteine proteinase inhibitor with acidic isoelectric point (pI = 4.7-5.0) was found in human seminal plasma. Its apparent molecular mass is 16 kDa. It inhibits cysteine proteinases like ficin, cathepsin H, cathepsin B and papain. The inhibitory activity of seminal plasma against ficin is almost the same as that of human serum.     

A novel inhibitor protein for Bombyx cysteine proteinase is homologous to propeptide regions of cysteine proteinases

A cDNA clone for an inhibitor of Bombyx cysteine proteinase was isolated and sequenced. Active inhibitor proteins were expressed in Escherichia coli using the cDNA. The open reading frame of the cDNA encodes a 105 residues protein with 19 residues of a signal sequence. The inhibitor has amino acid sequences homologous to several cysteine proteinases, but only to their propeptide sequences. The results suggest that some cysteine proteinase proregions may have evolved as autonomous modules and become inhibitor proteins for cysteine proteinases.     

Cystatin S: a cysteine proteinase inhibitor of human saliva

An acidic protein of human saliva, which we named SAP-1 previously, is now shown to be an inhibitor of several cysteine proteinases. The protein inhibited papain and ficin strongly, and stem bromelain and bovine cathepsin C partially. However, it did not inhibit either porcine cathepsin B or clostripain. The mode of the inhibition of papain was found to be non-competitive. The name cystatin S has been proposed for this salivary protein in view of the similarities in activity and structure to other cysteine proteinase inhibitors such as chicken egg-white cystatin and human cystatins A, B, and C. The cystatin S antigen was detected immunohistochemically in the serous cells of human parotid and submaxillary glands.     

Bombyx cysteine proteinase inhibitor (BCPI) homologous to propeptide regions of cysteine proteinases is a strong, selective inhibitor of cathepsin L-like cysteine proteinases.

Bombyx cysteine proteinase inhibitor (BCPI) is a novel cysteine proteinase inhibitor. The protein sequence is homologous to the proregions of certain cysteine proteinases. Here we report the mechanism of its inhibition of several cysteine proteinases. BCPI strongly inhibited Bombyx cysteine proteinase (BCP) activity with a K(i) = 5.9 pM, and human cathepsin L with a K(i) = 36 pM. The inhibition obeyed slow-binding kinetics. The inhibition of cathepsin H was much weaker (K(i) = 82 nM), while inhibition of papain (K(i) > 1 microM) and cathepsin B (K(i) > 4 microM) was negligible. Following incubation with BCP, BCPI was first truncated at the C-terminal end, and then gradually degraded over time. The truncation mainly involved two C-terminal amino acid residues. Recombinant BCPI lacking the two C-terminal amino acid residues still retained substantial inhibitory activity. Our results indicate that BCPI is a stable and highly selective inhibitor of cathepsin L-like cysteine proteinases.