Detection and some properties of calpain II (high-Ca2+-requiring form of calpain) in carp (Cyprinus carpio) erythrocytes

In order to examine the existence of calpain I, a low (micromolar)-Ca2+-requiring form of calpain, in fish tissues, carp erythrocytes were chosen as the experimental material, since only calpain I is known to exist in mammalian erythrocytes. By DEAE-cellulose chromatography, calpain and calpastatin (specific inhibitor for calpain) were separated from carp erythrocyte hemolysate. Carp erythrocyte calpain is classified as calpain II, a high (millimolar)-Ca2+-requiring form of calpain, from the result of Ca2+-requirement for the activity.     

Changes in contents of calpain and calpastatin in rat liver during growth

Variation of calpain I, calpain II, and calpastatin in rat liver during growth from 0 to 14 weeks was studied by chromatographic fractionation of the liver cytosol and enzyme assays on the eluted fractions. When compared in terms of units per g wet liver, high-Ca2+-requiring calpain II always exceeded low-Ca2+-requiring calpain I in male and female rats. The level of calpain II in neonatal (0 week) rat liver was 1.9-2.9 times higher than that for the adults (7 to 14 weeks). The contents of calpastatin, calpain-specific inhibitor protein, were were always higher than those of calpain II in adult rat liver, but the difference was much less, or sometimes even reversed, in neonatal and young (1 and 2 weeks) animals. In general, the variation was more pronounced in female than in male rats.     

Intracellular localization of two distinct Ca2+-proteases (calpain I and calpain II) as demonstrated by using discriminative antibodies

Intracellular localization of two molecular species of calpain (Ca2+-dependent cysteine proteinase) was studied by immunocyto- and histochemical methods employing antibodies strictly monospecific for the respective antigens. Apparent immunological cross-reactivity between the larger subunits of calpain I (low Ca2+-requiring form) and calpain II (high Ca2+-requiring form) was calculated to be 15-17%, and two steps of affinity chromatography were needed to obtain antibodies which can discriminate between the two proteases. Indirect immunofluorescent staining of cultured PK 15 cells revealed diffuse staining of the cytoplasm with both antibodies against calpain I and calpain II. Preincubation with Ca2+-ionophore had no effect on the staining patterns. Sections of porcine kidney were stained by the avidin-biotinylated peroxidase complex method. The proximal and distal tubules and collecting duct were stained, but the glomerulus, macula densa, and vascular vessels were not stained by either anti-calpain I or anti-calpain II antibodies.     

Purification and properties of carp (Cyprinus carpio) muscle calpain II (high-Ca2+-requiring form of calpain)

Calpain (Ca2+-dependent cysteine proteinase) was purified to apparent homogeneity from carp muscle by the method of DEAE-cellulose, hydroxylapatite and Ultrogel AcA 34 column chromatographies. The purified enzyme is classified as calpain II (high-Ca2+-requiring form of calpain) from the effects of Ca2+ concentration, pH and the antibiotics on the activity. Carp muscle calpain II was inhibited by rat liver calpastatin, the specific inhibitor for calpain. It is probable that the calpain-calpastatin system may play a biologically fundamental and common role in various cells, since the inhibitory effect of calpastatin on calpain from different tissues of different species is well conserved.     

Fragmentation of a 70000-dalton calpastatin molecule upon its complex formation with calpain

Homogenously purified porcine calpain I (Mr 112000), a low-Ca2+-requiring form of Ca2+-dependent cysteine proteinase [EC 3.4.22.17], was coupled to Sepharose 4B gel as an active form. It was used as a ligand to calpastatin (Mr 70000), calpain-specific inhibitor protein, for an affinity chromatography. Only in the presence of Ca2+, calpastatin bound to calpain-Sepharose, but the interaction resulted in rather extensive fragmentation of a calpastatin molecule into several peptides of Mr 14000 to 70000, which still retain inhibitory activities against calpain. Fragmentation was demonstrated both by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and by high-performance liquid chromatography in the presence of 6 M guanidine-HCl.     

ATP and other purine nucleotides stimulate the inactivation of ornithine transcarbamylase by broken lysosomes

Calpain II, a high Ca2+-requiring form of Ca2+-dependent cysteine proteinase (EC 3.4.22.17), isolated from bovine lens was found to cleave actin and vimentin, two major cytoskeletal elements of the lens. Polyacrylamide gel electrophoresis revealed that actin (Mr 43 000) was broken down through intermediary products of approximate Mr 42 000 and 40 000, while vimentin (Mr 57 000) was rapidly cleaved into several fragments ranging from Mr 44 000 to 20 000. The cleavage was dependent on Ca2+ and could be blocked by calpastatin , a calpain-specific inhibitor. These findings suggest that calpain might play a role in age-related degradation of the lens cytoskeleton.     

Identification of two calpastatin forms in rat skeletal muscle and their susceptibility to digestion by homologous calpains

Two forms of calpastatin, differing in their specificity for the homologous calpain isozymes I and II, have been separated from rat skeletal muscle extracts and purified to homogeneity. Calpastatin I, the first form to elute in chromatography on DE32, is more effective against calpain I, while calpastatin II is more effective as an inhibitor of calpain II. Based on their molecular mass (approximately 105 kDa) both calpastatin forms belong to the high molecular mass class found in muscles of other animal species (Murachi, T., 1989, Biochem. Int. 18, 263-294). For calpain I, which is active with low (mu-M) concentrations of Ca2+, maximum inhibition with either calpastatin form was observed over a wide range of Ca2+ concentrations. With calpain II, which requires high (mM) concentrations of Ca2+ for activity, maximum inhibition required Ca2+ concentrations above 1 mM. Both calpastatin forms were found to be highly sensitive to degradation by calpain II, but almost completely resistant to degradation by calpain I. Degradation of calpastatin by calpain II is competitively inhibited by the addition of a calpain substrate. Isovaleryl carnitine (IVC), an intermediate product of L-leucine catabolism, previously demonstrated to be a potent and specific activator of rat skeletal muscle calpain II (Pontremoli, S., Melloni, E., Viotti, P. L., Michetti, M., Di Lisa, F., and Siliprandi, N., 1990. Biochem. Biophys. Res. Commun. 167, 373-380) greatly enhances the rate of degradation of calpastatins by calpain II. IVC, which decreases the Ca2+ requirement for maximal calpain II activity, also decreases the concentration of Ca2+ required for digestion of the inhibitor. For calpain II, regulation by either calpastatins may occur only in the presence of high [Ca2+].     

Comparison of tryptic peptides from the heavy and light subunits of calpain I and calpain II by high performance liquid chromatography

Two different forms of Ca2+-dependent cysteine proteinase, low-Ca2+-requiring calpain I and high-Ca2+-requiring calpain II, are known to be heterodimers, each composed of one heavy (called 80K) and one light (called 30K) subunit. The most probable identity of the 30K and the substantial difference between the 80K subunits of porcine calpains I and II were clearly demonstrated by comparing the tryptic peptide maps obtained upon running a high performance liquid chromatography which permitted parallel detection of tryptophan-containing peptides by fluorometry. Comparison of the amino acid compositions of the two 30K and 80K subunits also confirmed this conclusion. The same chromatographical analysis also revealed close structural similarity of the human calpain I 30K subunit, and even some similarity existing between the calpain I 80K subunits of human and porcine origins.     

Evidence for membrane-associated calpain I in human erythrocytes. Detection by an immunoelectrophoretic blotting method using monospecific antibody

Low and high Ca2+-requiring forms of Ca2+-dependent cysteine proteinase are known as calpain I and calpain II, respectively. We have obtained, for the first time, monospecific antibodies for calpain I and for calpain II. Using these antibodies and an electrophoretic blotting method, we have found that a small, but reproducible, amount of calpain I was associated with human erythrocyte membranes while the bulk of the protease was contained in the cytosol. Most of membrane-associated calpain I was extractable with 1% Triton X-100, but not with 0.1% detergent. In the presence of 0.1 mM Ca2+ and 5 mM cysteine, membrane-associated calpain I degraded the membrane protein band 4.1 preferentially and band 3 protein only slowly. The Ca2+-induced autodigestion of the membrane preparation was inhibited by leupeptin but not by a cytosolic calpain inhibitor, calpastatin, added to the incubation medium. No calpain II was detected in either erythrocyte cytosol or membranes when anti-calpain II antibody was used under the same conditions as those for the detection of calpain I.     

Analysis of structure-function relationship of pig calpastatin by expression of mutated cDNAs in Escherichia coli

Structure-function relationships in pig calpastatin were investigated. Calpastatin is an endogenous inhibitor protein specifically acting on calpains (Ca2+-dependent cysteine endopeptidases). We recently cloned and sequenced the cDNA for pig heart calpastatin and determined the amino acid sequence of the molecule from the nucleotide sequence. Various deletion mutants in one of the four internally repetitive domains (Domain 3, approximately 140 amino acid residues) were created by in vitro site-directed mutagenesis of a cloned cDNA fragment and expressed in Escherichia coli. Deletion of a conserved region on either the amino-terminal or carboxyl-terminal side caused a drastic loss of inhibitory activity against calpain I (low Ca2+-requiring form) and, to a lesser degree, against calpain II (high Ca2+-requiring form). Inhibitory activities were below the detectable level in mutants deleted further toward the central region. Substitution of two amino acids in the latter region of the wild-type Domain 3 protein caused a drastic loss of activity against both calpains. The creation of lowered affinity inhibitors enabled us to perform a conventional kinetic analysis which showed the mode of inhibition to be competitive. Prediction of the secondary structure of Domain 3 suggests that both the amino- and carboxyl-terminal conserved regions form alpha-helical structures, which are largely located in the interior of the calpastatin molecule, whereas the central region does not form alpha-helix or beta-structure. The central region contains a 12-residue consensus sequence common to Domains 1, 2, and 4, and this portion is predicted to be located on the surface of the calpastatin molecule. These results suggest that the central conserved region of each domain of calpastatin is an area for direct interaction either with the active center of calpain or a region in close proximity, and the rest of the domain is a region stabilizing the functionally important tertiary structure of the domain.     

Inhibition of calpain by a synthetic oligopeptide corresponding to an exon of the human calpastatin gene

Calpastatin is a widely distributed endogenous inhibitor protein specifically acting on calpain (Ca2+-dependent cysteine endopeptidase). The inhibitor consists of four inhibitory domains (Domains 1-4) with mutually homologous sequences. NH2-terminal Domain L is non-homologous, and all domains have 120-140 residues each. A human calpastatin genomic DNA clone was isolated using a previously obtained human calpastatin cDNA probe. Sequence analysis has revealed that the clone contains Domain 1 and segments of neighboring domains (Domains L and 2). Each of three highly conserved, restricted regions within Domain 1 was located on separate exons, 1A, 1B, and 1C. Exon 2A, corresponding to the first exon of Domain 2, is homologous to Exon 1A and follows Exon 1D of Domain 1. A 27-residue peptide encoded by Exon 1B, including a 12-residue middle conserved sequence, was chemically synthesized and tested for protease inhibitory activities. The synthetic peptide showed strong inhibition against calpain I (low Ca2+-requiring form), and calpain II (high Ca2+-requiring form), but no inhibition against papain or trypsin. These results indicated that Exon 1B forms a self-sufficient functional subdomain of the calpastatin inhibitory domain.     

Hydrophobic association of calpains with subcellular organelles. Compartmentalization of calpains and the endogenous inhibitor calpastatin in tissues

Calpains I and II isolated from diverse tissues possess both Ca2+-independent, and Ca2+-dependent accessible hydrophobic regions. Possible subcellular organelle association of calpains involving these hydrophobic regions was studied. By homogenizing rat tissues directly in Ca2+ (50 microM), about 30-60% of the cytosolic calpain I and II activity reversibly associated with isolated subcellular fractions (microsomal greater than plasma membrane greater than nuclear). After binding to the particulate fraction, calpain II converted to a calpain I-like form exhibiting stronger Ca2+-independent binding to phenyl-Sepharose and a lower Ca2+ requirement for optimal activity. However, it retained its DEAE-cellulose chromatographic pattern, and precipitated with monospecific anti-calpain II antibodies. Although purified calpastatin (endogenous inhibitor) is known to form a Ca2+-dependent complex with calpains, it was not able to reverse the binding of calpains to the particulate fraction upon short incubation. It was, however, effective in blocking calpain binding when the isolated cytosolic fraction or a mixture of purified calpain and calpastatin was preincubated in the presence of Ca2+, and then added to the particulate fraction. Extraction of tissues under controlled conditions revealed that in fact calpains are already loosely associated with subcellular organelles even in the absence of Ca2+. This is the reason why in the crude homogenates with the addition of Ca2+, calpains strongly bind to the particulate fraction without interference by cytosolic calpastatin. Although calpastatin by complexing initially to calpain can prevent the association of this protease with subcellular organelles, it cannot dissociate calpains already bound to these subcellular fractions. By prior Ca2+-independent association with the hydrophobic proteins present in the subcellular fractions, calpains overcome the 3- to 30-fold inhibitory excess of calpastatin in tissues.     

Comparative specificity and kinetic studies on porcine calpain I and calpain II with naturally occurring peptides and synthetic fluorogenic substrates

Homogeneous porcine calpain (Ca2+-dependent cysteine proteinase) was found to hydrolyze a variety of peptides and synthetic substrates. Leu-Trp-Met-Arg-Phe-Ala, eledoisin-related peptide, alpha-neoendorphin, angiotensin I, luteinizing hormone-releasing hormone, neurotensin, dynorphin, glucagon, and oxidized insulin B chain were cleaved with a general preference for a Tyr, Met, or Arg residue in the P1 position preceded by a Leu or Val residue in the P2 position. No great difference in specificity was found between low-Ca2+-requiring calpain I and high-Ca2+-requiring calpain II. 4-Methylcoumaryl-7-amide (MCA) derivatives having a Leu(or Val)-Met(or Tyr)-MCA or a Leu-Lys-MCA sequence were also cleaved by either calpain I or calpain II with preference for Leu over Val by a factor of 9 to 16. Calpains I and II showed similar but not identical kinetic behavior for individual substrates. The Km and kcat values ranged from 0.23 to 7.08 mM and 0.062 to 0.805 s-1 for the calpains, while kcat/Km values for the calpains were only 1/433 to 1/5 of those for papain with a given substrate. With succinyl-Leu-Met(or Tyr)-MCA, calpains I and II were half-maximally activated at 12 and 260 microM Ca2+, respectively, and competitively inhibited by leupeptin (Ki = 0.32 microM for I and 0.43 microM for II) or antipain (Ki = 1.41 microM for I and 1.45 microM for II). Thus, this is the first report describing the specificity and kinetics of calpains I and II.     

Calpain from rat intestinal epithelial cells: Age-dependent dynamics during cell differentiation

Micromolar and millimolar Ca²⁺-requiring neutral protease (calpain I and calpain II) along with their endogenous inhibitor calpastatin were isolated and partially purified from the same preparation of rat intestinal epithelial cells. Calpain I and II were partially purified by 1300 and 900-fold with 57 and 53 per cent yield, respectively. The optimum assay conditions revealed pH 7.5, 20 min incubation at 25° C and 0.24% casein substrate for both calpains. The optimum calcium concentration obtained for calpain I and II were 25 M and 4 mM, respectively. Distribution of rat intestinal epithelial cells calpain I and II along with calpastatin during cell differentiation stages in weanling to senescence age were studied. Calpain I in weanling rats was in an increasing order from villus to crypt regions. Adult rats indicated well expressed consistent calpain I throughout the differentiation stages. Whereas, significant lowering towards crypt region cells were evident in old rats. Calpain II in weanling and adult rats was found to be consistent throughout the differentiation stages. Old animals revealed an increasing trend from villus to crypt region with insignificant activity present in upper villus cells. Concomitantly, different concentrations of calpastatin were observed throughout the differentiation stages in all the age groups. Moreover, the levels of calpains exceeded that of calpastatin in most of the epithelial cell populations during developmental stages. In addition to casein, intestinal epithelial cell membranes were found to be equally good substrates for calpains. Proteolytic susceptibility of weanling, adult and old rat membrane proteins varied significantly all along the ageing process in rats. Simultaneous age-dependent calpastatin response were also evident. Taken together the results obtained provided strong evidence that calpain plays significant role in rat intestinal cell differentiation and ageing process with calpastatin as its specific regulatory protein.Abbreviations DEAE-cellulose O-(Diethylaminoethyl)-cellulose - EDTA Ethylene Diamine Tetra Acetic Acid - Tris Tris (hydroxymethyl) amino methane - KH₂PO₄ potassium dihydrogen orthophosphate - Na₂HPO₄ disodium hydrogen phosphate - CaCl₂ Calcium Chloride - TCA Trichloroacetic Acid - PMSF Phenylmethylsulfonyl Fluoride     

Mechanism of action of the calpain activator protein in rat skeletal muscle.

Rat skeletal muscle contains a calpain activator protein characterized by a high specificity for calpain II, the high Ca(2+)-requiring isoform of this class of proteinases. The activator protein increases the rate of intramolecular conversion of the native 80-kDa catalytic subunit of calpain into the autolysed 75-kDa forms with maximal rate at concentrations of calcium approximately 25 times lower than those required by the native proteinase. The activator protein interacts with native calpain II forming a 1:1 complex; interaction does not occur with the fully activated form, produced by autoproteolysis. Even after immobilization to membranes, the activator binds to calpain, which then undergoes sequential activation and release from its bound form. The activator is itself resistant to digestion by calpain II, whereas it increases the rate at which homologous calpastatin is degraded by the proteinase. Taken together, these results are indicative of the existence in rat skeletal muscle of an activating system specific for calpain II which is potentially involved in the regulation of the inhibitory efficiency of calpastatin, through modulation of its intracellular level.     

Effect of Ca2+ on binding of the calpains to calpastatin

Autolyzed mu-calpain, unautolyzed mu-calpain, autolyzed m-calpain, and unautolyzed m-calpain (mu-calpain is the micromolar Ca2+-requiring proteinase, m-calpain is the millimolar Ca2+-requiring proteinase) were passed through a calpastatin-affinity column at different free Ca2+ concentrations, and binding of the calpains to calpastatin was compared with proteolytic activity of that calpain at each Ca2+ concentration. Unautolyzed m-calpain, autolyzed m-calpain, and autolyzed mu-calpain required less Ca2+ for half-maximal binding to calpastatin than for half-maximal activity. Unautolyzed mu-calpain, however, required slightly more Ca2+ for half-maximal binding to calpastatin than for half-maximal activity. Half-maximal binding of oxidatively inactivated mu- or m-calpain to calpastatin required approximately the same Ca2+ concentrations as half-maximal binding of unautolyzed mu- or m-calpain, respectively, to calpastatin. Binding of unautolyzed m-calpain and autolyzed mu-calpain to calpastatin occurred over a wide range of Ca2+ concentrations, and it seems likely that two or more Ca2+-binding sites with different Ca2+-binding constants are involved in binding of the calpains to calpastatin. Proteolytic activity occurs at different Ca2+ concentrations than calpastatin binding, suggesting a second set of Ca2+-binding sites associated with proteolytic activity. Third and fourth sets of Ca2+-binding sites may be involved in autolysis and in binding to phosphatidylinositol or cell membranes; these four Ca2+-dependent properties of the calpains may require the eight potential Ca2+-binding sites that amino acid sequences predict are present in the calpain molecules.     

Comparison of calpain I and calpain II from carp muscle

1. The content of calpain II is 3.4 times more than that of calpain I when estimated by the elution profiles from a column of DEAE-cellulose. 2. Calpain I required 1 mM Ca2+ and calpain II required 5 mM Ca2+ to show the full activities. These data demonstrated that Ca2+-sensitivities of both calpains were lower than those of mammalian calpains, respectively. 3. The optimum caseinolytic activity was pH 7.2 for calpain I and pH 7.5 for calpain II. 4. The molecular weight of calpain I was estimated to be 110 k and that of calpain II to be 120 k by gel filtration. 5. Calpain I was much more heat-stable than calpain II around 50-60 degrees C. 6. Both calpains were sensitive to calpastatin, an endogenous inhibitor for calpain.     

Rapid purification of calcium-activated protease by calcium-dependent hydrophobic-interaction chromatography

Both low Ca2+- and high Ca2+-requiring forms of Ca2+-activated protease (calpains I and II) were found to bind to phenyl-Sepharose in a calcium-dependent manner, suggesting that both enzymes expose a hydrophobic surface region in the presence of Ca2+. Inclusion of leupeptin in column buffers prevented the loss of activity during hydrophobic-interaction and substrate-affinity chromatography. Under these conditions calpain II (high calcium-requiring form) was rapidly purified from bovine brain and rabbit skeletal muscle using successive phenyl-Sepharose and casein-Sepharose columns.     

Distribution of calpains and calpastatin in human blood cells

The occurrence and molecular sizes of calpains and calpastatin in the lysates of human erythrocytes, platelets, lymphocytes/monocytes, and polymorphonuclear cells were studied by immunoelectrophoretic blot analysis. The basic uniformity among these cells of the 85-kDa and 83-kDa heavy subunits of low- and high-Ca2+-requiring calpains I and II, respectively, and of the 29-kDa light subunit was confirmed. Molecular diversity of calpastatin species, ranging from 70 kDa to 107 kDa, among different blood cells was also shown. The obtained data are consistent with those known for other animal tissues, thus settling hitherto uncertain or rather controversial issues on the distribution of calpains and calpastatin in human blood cells.