Cytosolic calcium dependent proteinase of human erythrocytes: formation of an enzyme-natural inhibitor complex induced by Ca2+ ions

Interaction between calpain-1 and HSP90: new insights into the regulation of localization and activity of the protease

Here we demonstrate that heat shock protein 90 (HSP90) interacts with calpain-1, but not with calpain-2, and forms a discrete complex in which the protease maintains its catalytic activity, although with a lower affinity for Ca²⁺. Equilibrium gel distribution experiments show that this complex is composed by an equal number of molecules of each protein partner. Moreover, in resting cells, cytosolic calpain-1 is completely associated with HSP90. Since calpain-1, in association with HSP90, retains its proteolytic activity, and the chaperone is displaced by calpastatin also in the absence of Ca²⁺, the catalytic cleft of the protease is not involved in this association. Thus, calpain-1 can form two distinct complexes depending on the availability of calpastatin in the cytosol. The occurrence of a complex between HSP90 and calpain-1, in which the protease is still activable, can prevent the complete inhibition of the protease even in the presence of high calpastatin levels. We also demonstrate that in basal cell conditions HSP90 and calpain-1, but not calpain-2, are inserted in the multi-protein N-Methyl-D-Aspartate receptor (NMDAR) complex. The amount of calpain-1 at the NMDAR cluster is not modified in conditions of increased [Ca²⁺]_i, and this resident protease is involved in the processing of NMDAR components. Finally, the amount of calpain-1 associated with NMDAR cluster is independent from Ca²⁺-mediated translocation. Our findings show that HSP90 plays an important role in maintaining a given and proper amount of calpain-1 at the functional sites.

Evidence for alteration of calpain/calpastatin system in PBMC of cystic fibrosis patients

We are here reporting that in peripheral blood mononuclear cells (PBMC) of patients homozygous for F508del-CFTR the calpain-calpastatin system undergoes a profound alteration. In fact, calpain basal activity, almost undetectable in control PBMC, becomes measurable at a significant extent in cells from cystic fibrosis (CF) patients, also due to a 40-60% decrease in both calpastatin protein and inhibitory activity. Constitutive protease activation in CF patients' cells induces a large accumulation of the mutated cystic fibrosis transmembrane conductance regulator (CFTR) in the 100kD+70kD split forms as well as a degradation of proteins associated to the CFTR complex. Specifically, the scaffolding protein Na(+)/H(+) exchanger 3 regulatory factor-1 (NHERF-1) is converted in two distinct fragments showing masses of 35kD and 20kD, being however the latter form the most represented one, thereby indicating that in CF-PBMC the CFTR complex undergoes a large disorganization. In conclusion, our observations are providing new information on the role of calpain in the regulation of plasma membrane ion conductance and provide additional evidence on the transition of this protease activity from a physiological to a pathological function.

Calpain digestion and HSP90-based chaperone protection modulate the level of plasma membrane F508del-CFTR

We are here showing that peripheral mononuclear blood cells (PBMC) from cystic fibrosis (CF) patients contain almost undetectable amounts of mature 170 kDa CF-transmembrane conductance regulator (CFTR) and a highly represented 100 kDa form. This CFTR protein, resembling the form produced by calpain digestion and present, although in lower amounts, also in normal PBMC, is localized in cytoplasmic internal vesicles. These observations are thus revealing that the calpain-mediated proteolysis is largely increased in cells from CF patients. To characterize the process leading to the accumulation of such split CFTR, FRT cells expressing the F508del-CFTR mutated channel protein and human leukaemic T cell line (JA3), expressing wild type CFTR were used. In in vitro experiments, the sensitivity of the mutated channel to the protease is identical to that of the wild type, whereas in Ca(2+)-loaded cells F508del-CFTR is more susceptible to digestion. Inhibition of intracellular calpain activity prevents CFTR degradation and leads to a 10-fold increase in the level of F508del-CFTR at the plasma membrane, further indicating the involvement of calpain activity in the maintenance of very low levels of mature channel form. The higher sensitivity to calpain of the mutated 170 kDa CFTR results from a reduced affinity for HSP90 causing a lower degree of protection from calpain digestion. The recovery of HSP90 binding capacity in F508del-CFTR, following digestion, explains the large accumulation of the 100 kDa CFTR form in circulating PBMC from CF patients.

Role of calpain in the regulation of CFTR (cystic fibrosis transmembrane conductance regulator) turnover

The level of the mature native 170 kDa form of CFTR (cystic fibrosis transmembrane conductance regulator) at the plasma membrane is under the control of a selective proteolysis catalysed by calpain. The product of this limited digestion, consisting of discrete fragments still associated by strong interactions, is removed from the plasma membrane and internalized in vesicles and subject to an additional degradation. This process can be monitored by visualizing the accumulation of a 100 kDa fragment in a proliferating human leukaemic T-cell line and in human circulating lymphocytes. In reconstructed systems, and in intact cells, the conversion of native CFTR into the 100 kDa fragment linearly correlated with calpain activation and was prevented by addition of synthetic calpain inhibitors. A reduction in Ca2+ influx, by blocking the NMDA (N-methyl-D-aspartate) receptor Ca2+ channel, inhibited the conversion of the native 170 kDa fragment into the 100 kDa fragment, whereas an endosome acidification blocker promoted accumulation of the digested 100 kDa CFTR form. An important role in calpain-mediated turnover of CFTR is exerted by HSP90 (heat-shock protein 90), which, via association with the protein channel, modulates the degradative effect of calpain through a selective protection. Taken together these results indicate that CFTR turnover is initiated by calpain activation, which is induced by an increased Ca2+ influx and, following internalization of the cleaved channel protein, and completed by the lysosomal proteases. These findings provide new insights into the molecular mechanisms responsible for the defective functions of ion channels in human pathologies.

Adaptive modifications in the calpain/calpastatin system in brain cells after persistent alteration in Ca2+ homeostasis

Persistent dysregulation in Ca(2+) homeostasis is a pervasive pathogenic mechanism in most neurodegenerative diseases, and accordingly, calpain activation has been implicated in neuronal cells dysfunction and death. In this study we examined the intracellular functional state of the calpain-calpastatin system in -G93A(+) SOD1 transgenic mice to establish if and how uncontrolled activation of calpain can be prevented in vivo during the course of prolonged [Ca(2+)](i) elevation. The presented data indicate that 1) calpain activation is more extensive in motor cortex, in lumbar, and sacral spinal cord segments compared with the lower or almost undetectable activation of the protease in other brain areas, 2) direct measurements of the variations of Ca(2+) levels established that the degree of the protease activation is correlated to the extent of elevation of [Ca(2+)](i), 3) intracellular activation of calpain is always associated with diffusion of calpastatin from perinuclear aggregated forms into the cytosol and the formation of a calpain-calpastatin complex, and 4) a conservative fragmentation of calpastatin is accompanied by its increased expression and inhibitory capacity in conditions of prolonged increase in [Ca(2+)](i). Thus, calpastatin diffusion and formation of the calpain-calpastatin complex together with an increased synthesis of the inhibitor protein represent a cellular defense response to conditions of prolonged dysregulation in intracellular Ca(2+) homeostasis. Altogether these findings provide a new understanding of the in vivo molecular mechanisms governing calpain activation that can be extended to many neurodegenerative diseases, potentially useful for the development of new therapeutic approaches.

Ca2+-Mg2+-dependent ATP-ase activity and calcium homeostasis in children with chronic kidney disease

Extracellular calcium concentrations in humans are thousands times higher than within cells. Maintenance of such gradient requires specific regulation including intracellular stores, Ca binding proteins and transmembrane protein systems. The aim of the study was to estimate PMCA (plasma membrane Ca-transporting adenosine triphosphatase; ATPase 3.6.1.38) activity and calcium homeostasis in erythrocytes of children with chronic kidney disease (CKD). Twenty-one children wth CKD stages 1-3 (group I) and 18 healthy children (group II) were examined. Group I was divided into two subgroups: Ia (8 patients with normal intact parathyroid hormone, iPTH, serum levels) and Ib (13 patients with increased iPTH). iPTH, urea, creatinine, inorganic phosphorus, cytosolic Ca2+ in red blood cells (R-Ca), and PMCA were determined. Significantly elevated R-Ca levels were observed in children from subgroup Ib in comparison with group II and subgroup Ia. The lowest activity of PMCA was found in subgroup Ia and Ib in comparison with group II. There was a negative correlation between PMCA and R-Ca in group Ia and Ib (r=-0.8, r=-0.9, respectively). In children with CKD treated conservatively, activity of PMCA in erythrocytes is disturbed. An increase in R-Ca and decrease in PMCA activity are also observed.

Regulation of Calpain Activity in Rat Brain with Altered Ca2+ Homeostasis

Activation of calpain occurs as an early event in correlation with an increase in [Ca2+]i induced in rat brain upon treatment with a high salt diet for a prolonged period of time. The resulting sequential events have been monitored in the brain of normal and hypertensive rats of the Milan strain, diverging for a constitutive alteration in the level of [Ca2+]i found to be present in nerve cells of hypertensive animals. After 2 weeks of treatment, the levels of the plasma membrane Ca2+-ATPase and of native calpastatin are profoundly decreased. These degradative processes, more pronounced in the brain of hypertensive rats, are progressively and efficiently compensated in the brain of both rat strains by different incoming mechanisms. Along with calpastatin degradation, 15-kDa still-active inhibitory fragments are accumulated, capable of efficiently replacing the loss of native inhibitor molecules. A partial return to a more efficient control of Ca2+ homeostasis occurs in parallel, assured by an early increase in the expression of Ca2+-ATPase and of calpastatin, both producing, after 12 weeks of a high salt (sodium) diet, the restoration of almost original levels of the Ca2+ pump and of significant amounts of native inhibitor molecules. Thus, conservative calpastatin fragmentation, associated with an increased expression of Ca2+-ATPase and of the calpain natural inhibitor, has been demonstrated to occur in vivo in rat brain. This represents a sequential adaptive response capable of overcoming the effects of calpain activation induced by a moderate long term elevation of [Ca2+]i.

Interaction between catalytically inactive calpain and calpastatin. Evidence for its occurrence in stimulated cells

Conformational changes in the calpain molecule following interaction with natural ligands can be monitored by the binding of a specific monoclonal antibody directed against the catalytic domain of the protease. None of these conformational states showed catalytic activity and probably represent intermediate forms preceding the active enzyme state. In its native inactive conformation, calpain shows very low affinity for this monoclonal antibody, whereas, on binding to the ligands Ca(2+), substrate or calpastatin, the affinity increases up to 10-fold, with calpastatin being the most effective. This methodology was also used to show that calpain undergoes similar conformational changes in intact cells exposed to stimuli that induce either a rise in intracellular [Ca(2+)] or extensive diffusion of calpastatin into the cytosol without affecting Ca(2+) homeostasis. The fact that the changes in the calpain state are also observed under the latter conditions indicates that calpastatin availability in the cytosol is the triggering event for calpain-calpastatin interaction, which is presumably involved in the control of the extent of calpain activation through translocation to specific sites of action.

Purification of active calpain by affinity chromatography on an immobilized peptide inhibitor

Most purification schemes of calpain (CANP) involve a number of chromatographic steps. The final preparations often contain impurities, including degradation fragments. Two peptide-affinity columns were developed, using peptides of 27 amino acids and 30 amino acids, corresponding to the products of exons 1B and 1C, respectively, of the natural inhibitor (calpastatin) gene, coupled to CNBr-activated Sepharose 4B. Crude preparations of calpain, isolated by anion-exchange chromatography on a DEAE-Sepharose column, were incubated with a reversible or an irreversible synthetic inhibitor which blocks the catalytic subunit of the enzyme in the inactive 80-kDa form. The crude preparation was then loaded onto the peptide column in the presence of calcium. Calpain was eluted with an EGTA-containing buffer. Using the two peptide-affinity columns connected in tandem, calpain was isolated with a high degree of purity, suitable for structural and mechanistic studies, i.e. as an 80/30-kDa heterodimer or in the form of dissociated monomers.

Autolysis of human erythrocyte calpain produces two active enzyme forms with different cell localization

The 80 kDa human erythrocyte calpain, when exposed to Ca2+, undergoes autoproteolysis that generates a 75 kDa species, with an increase in Ca2+ affinity. It is demonstrated here that this proteolytic modification proceeds through an initial step producing a 78 kDa form which is rapidly converted to the 75 kDa one. In the presence of the calpain inhibitor E-64, the 78 kDa form accumulates and only small amounts of the 75 kDa polypeptide are formed. Following loading of erythrocytes with micromolar concentration of Ca2+, in the presence of the ionophore A23187, the native 80 kDa calpain subunit is extensively translocated and retained at the plasma membrane, this process is accompanied by the appearance of only a small amount of the 75 kDa subunit which is released into the soluble fraction of the cells. Following exposure to microM Ca2+, membrane-bound 80 kDa calpain is converted to the 78 kDa form, this conversion being linearly correlated with the expression of the proteinase activity. Taken together, these results demonstrate that the initial step in calpain activation involves Ca(2+)-induced translocation to the inner surface of plasma membranes. In the membrane-bound form the native inactive 80 kDa subunit is converted through intramolecular autoproteolysis to a locally active 78 kDa form. Further autoproteolytic intermolecular digestion converts the 78 kDa to the 75 kDa form, no longer being retained by the membrane. This process generates two active forms of calpain, with different intracellular localisations.

PEST sequences do not influence substrate susceptibility to calpain proteolysis

Mutations lowering the PEST score of domains surrounding the calmodulin (CaM)-binding region of the plasma membrane Ca(2+)-ATPase failed to influence the susceptibility of the enzyme to mu-calpain (mu-CANP). Synthetic peptides corresponding to the high PEST score C-terminal sequences A18 and B28 had no effect on the rate of pump proteolysis by mu-CANP, i.e. the peptides did not compete for a putative high PEST score recognition site for mu-CANP in the pump molecule. An accessible CaM-binding region appears to be critical for substrate (i.e. the Ca2+ pump) proteolysis and probably also for its recognition by mu-CANP; phosphorylation of the CaM-binding domain of the pump or its occupation by CaM significantly decreased the rate of proteolysis.

Modulation of the intracellular Ca(2+)-dependent proteolytic system is critically correlated with the kinetics of differentiation of murine erythroleukemia cells

Calpain has been identified as the intracellular proteinase that catalyzes the selective down-regulation of protein kinase C (PKC) isoforms, occurring in the early stages of commitment to terminal erythroid differentiation of murine erythroleukemia (MEL) cells induced by hexamethylenebisacetamide. This conclusion has been reached through direct experiments performed with two MEL cell clones, one characterized by a high and the other by a low rate of differentiation. In both cell types, introduction of an anti-calpain antibody resulted in a significant delay in the onset of down-regulation of PKC isoforms, and in an increase in the latent period that precedes differentiation. Both cell lines also displayed reduced rates of PKC decay and accumulation of mature erythroid cells. Furthermore, in the fast-responding clone, calpastatin, the natural calpain-inhibitor protein, was found to be almost completely absent, resulting in activation and expression of proteolytic activity of calpain even at micromolar concentrations of Ca2+, a condition not sufficient to trigger calpain activation in the slowly responding clone which contains high levels of calpastatin. The fast-responding MEL cell clone, enriched with calpastatin, displayed a lower rate of cell differentiation, with a kinetics almost identical to that observed following introduction of the anti-calpain antibody. It is proposed that Ca(2+)-dependent proteolysis plays a crucial role for the progress of MEL cell differentiation through the specific degradation of PKC isozymes.

The plasma membrane calcium pump is the preferred calpain substrate within the erythrocyte

The activation of calpain in normal human erythrocytes incubated in the presence of Ca2+ and the Ca2+ ionophore A23187 led to the decline of the Ca(2+)-dependent ATPase activity of the cells. Preloading of the erythrocyte with an anticalpain antibody prevented the decline. The pump was also inactivated by applied to isolated erythrocyte plasma membranes. The decline of the pump activity corresponded to the degradation of the pump protein and was inversely correlated to the amount of the natural inhibitor of calpain, calpastatin, present in the cells. In erythrocytes containing only 50% of the normal level the degradation started at a concentration of Ca2+ significantly lower than in normal cells. A comparison of the concentrations of Ca2+ required for the degradation of a number of erythrocyte membrane proteins showed that the Ca2+ pump and band 3 were the most sensitive. All other membrane proteins tested were attacked at higher levels of intracellular Ca2+. Thus, the degradation of the Ca2+ pump protein may be a simple and sensitive means to monitor calpain activation in vivo. Furthermore, the results have shown that the calpastatin level correlated directly with the amount of activable calpain and with the concentration of Ca2+ required to trigger the activation process.

Calcium-activated neutral protease activities in brain trauma

This paper investigates the level of cytosolic and synaptosomal forms of calcium activated neutral protease activities in the normal brain and their changes following a freezing lesion in the rabbit. From 1 to 24 hours post lesion we observe a progressive disappearing of the enzyme activities from the cytosolic compartment and concurrently their increase in the membranal fraction. These changes are likely to be due to a rise in intracellular calcium concentration, a well documented consequence of many cellular insults. The specific role of the activation of calpain activities in the pathophysiology of trauma is discussed, an enhancement of excitotoxic mechanisms is proposed.

The loss of enzyme activity from erythroid cells during maturation

Erythrocyte enzyme activities in patients with reticulocytosis or transient erythroblastopenia show that loss of age-dependent enzyme activity is not a simple exponential process occurring throughout the life-span of the cell. In vivo studies of reticulocyte maturation in rabbits indicate that there are multiple mechanisms of enzyme decay, and that proteolysis continues after the maturation of (morphologically recognisable) reticulocytes into young erythrocytes. Most reticulocyte hexokinase is degraded by lysosomal proteolysis, apparently triggered by an initial attack by lipoxygenase.

Calpain inhibitor I prevents rapid postmortem degradation of benzodiazepine binding proteins: fluorographic and immunological evidence

Endogenous proteolysis of the major central benzodiazepine (BZ) binding protein of 53K occurs rapidly postmortem and leads to a fragment of 47K. To determine indirectly the protease responsible for this proteolysis, membranes of porcine cortex were prepared from homogenates, which were either frozen immediately or left at room temperature for 12 h in the presence or absence of various representative protease inhibitors. Membranes were subsequently photolabeled with [3H]flunitrazepam, and subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorography or immunoblotted using an alpha-subunit-specific monoclonal antibody bd-24. Both fluorographs and immunoblots revealed that calpain inhibitor I, Ep-459 (E-64 analogue), and EDTA (greater than or equal to 1 mM) prevent endogenous proteolysis. In future studies one of these inhibitors should be added to receptor preparations. The results indicate that calpain is the responsible protease.

Comparative action of calpain on erythrocyte Ca2(+)-pumping ATPase in sickle cell anaemia, essential hypertension and kwashiorkor

Calpain, a calcium-dependent, neutral cysteine-protease was purified from the erythrocyte cytosol of subjects having essential hypertension (HTN), sickle cell anaemia, (SCA), or kwashiorkor (KWA). Identical electrophoretic mobility on SDS-polyacrylamide gradient gel, sensitivity to micromolar amounts of Ca2+, absolute requirement for a reducing environment and a high susceptibility to inhibition by leupeptin and thiol-group modifying reagents confirm that calpain preparations from these erythrocytes are equivalent to calpain I. Whereas the extent of calpain activation of erythrocyte membrane Ca2(+)-pumping ATPase of normal subjects was almost equal to that due to calmodulin, calpain activation of the HTN and SCA pump was greater than activation by calmodulin. Like in normal membranes, exogenous calmodulin protected the Ca2(+)-pumping ATPase of these erythrocytes against calpainization; the degree of protection by calmodulin is least in SCA and HTN. Electrophoretic separation of erythrocyte membranes and the purified Ca2(+)-pumping ATPase of HTN, SCA and KWA subjects does not indicate the presence of fragments resulting from the proteolytic action of calpain.

In vitro digestion of spectrin, protein 4.1 and ankyrin by erythrocyte calcium dependent neutral protease (calpain I)

1. In whole ghosts, ankyrin, protein 4.1, protein band 3 and spectrin are lysed by purified calpain I in the presence of calcium. 2. Limited calpain lysis of purified ankyrin results in several peptides, including a 85 kD peptide bearing the ankyrin interaction site for the protein band 3 internal fragment (43 kD), and a 55 kD peptide carrying the ankyrin-spectrin interaction site. 3. These peptides are differently phosphorylated: the 85 kD by cytosol casein kinase, and the 55 kD by membrane casein kinase. 4. Protein 4.1 lysis mainly produces a 30 kD peptide resistant to proteolysis. 5. The spectrin beta-chain is more sensitive to calpain cleavage than the alpha chain; both chains seem to be cleaved in a similar sequential manner. 6. Limited proteolysis of spectrin dimer does not impede tetramerization in vitro.

Proteolysis of N-ethylmaleimide-modified aldolase loaded into erythrocyte ghosts: prevention by inhibitors of calpain

1. When rabbit muscle aldolase labelled with tritium and inactivated by N-ethylmaleimide (NEM) was loaded into erythrocyte ghosts, significant proteolysis of the loaded protein occurred. The major product of this proteolysis, separated by electrophoresis under dissociating conditions, was found to be approx. 2 kDa smaller than the parent protein. 2. Proteolysis was detectable during erythrocyte ghost loading at 0 degrees C, reaching a plateau after approx. 12 min. Subsequent incubation at 37 degrees C to allow resealing of the ghosts resulted in additional proteolysis, and up to 20% of the loaded protein was converted to the smaller 38 kDa derivative. 3. EDTA, EGTA, leupeptin and chymostatin, each inhibitors of calcium-activated neutral proteinases (calpains), were the most effective inhibitors of the proteolysis of NEM-inactivated aldolase in ghosts. Other proteinase inhibitors were ineffective, while phenylmethanesulphonyl fluoride was only partially effective. 4. Inhibition of the proteolysis by EGTA was prevented by CaCl2, supporting the involvement of erythrocyte calpain. 5. Pretreatment of ghosts with EGTA prior to loading of NEM-modified aldolase followed by microinjection of the protein into HeLa cells did not result in a different rate of its overall breakdown to acid-soluble products. EGTA is suggested as a useful agent for the erythrocyte ghost-mediated microinjection of calpain-sensitive proteins.

Characterization of the calpastatin defect in erythrocytes from patients with essential hypertension

In erythrocytes of patients with essential hypertension the level of calpastatin activity was found to be significantly lower than in red cells of normotensive subjects (1). We now demonstrate, by Western blot analysis, that the decreased inhibitory activity is due to a corresponding decrease in the amount of the inhibitor protein. This is also supported by the observation that calpastatins isolated and purified from erythrocytes of normotensive and hypertensive patients, have identical specific activity. Data are presented indicating that the decreased level of calpastatin cannot be ascribed to an accelerated decay of the inhibitor during the erythrocyte life span. Taken together the previous and present results further emphasize that an umbalanced proteolytic system may represent one of the molecular mechanisms responsible for those membrane abnormalities underlying the development of essential hypertension and its clinical complications.

Erythrocyte deficiency in calpain inhibitor activity in essential hypertension

The calpain-calpain inhibitor system was evaluated in erythrocytes of patients with essential hypertension and normotensive controls, either with or without a family history of hypertension. Calpain levels were similar in the controls and hypertensive patients, whereas the inhibitor activity level was significantly reduced in the latter (301.8 +/- 26.4 vs 220 +/- 14 U/mg hemoglobin, p less than 0.001). Borderline hypertensive patients and a few controls with a history of hypertension showed low inhibitor activity. Similar results have recently been reported in genetically hypertensive rats of the Milan strain. A significant inverse correlation (r = -0.43, p less than 0.001) was found between mean arterial pressure and calpain inhibitor. Although the pathophysiological significance of these observations is not yet clear, they suggest a new area of investigation into the molecular mechanisms underlying essential hypertension and its complications.

Characterization of hydrazine-stimulated proteolysis in human erythrocytes

The ability of hydrazine, acetylphenylhydrazine, methylhydrazine, and phenylhydrazine to stimulate proteolysis in red cells has been characterized. All four hydrazines effectively stimulated proteolysis in red cells and in hemolysate as evidenced by a two- to threefold increase in the rate of tyrosine release. The rate of tyrosine release varied linearly with time, increased with increasing concentration of hydrazine, and also increased as a function of hematocrit. The rank order for stimulation of proteolysis in red cells was phenylhydrazine greater than methylhydrazine greater than hydrazine approximately equal to acetylphenylhydrazine. Inhibitors of glycolysis in red cells only minimally (13-27%) decreased the rate of tyrosine release stimulated by the different hydrazines. Agents which diminished electron transport decreased the rate of tyrosine release. NADP inhibited the rate of tyrosine release stimulated by hydrazine, methylhydrazine, and acetylphenylhydrazine by approximately 36 to 41%; 2'-AMP was less effective. The rate of tyrosine release resulting from insult by the hydrazines was increased slightly by methylene blue, moderately inhibited (approximately 10 to 27%) by the chelator o-phenanthroline and inhibited approximately 30 to 40% by N-ethylmaleimide. Use of an oxygen-depleted atmosphere (N2) increased slightly the rate of tyrosine release stimulated by the hydrazines; in contrast, carbon monoxide decreased proteolysis stimulated by hydrazine, methylhydrazine, and acetylphenylhydrazine by approximately 50%. Although the antioxidants dimethylfuran, dimethylthiourea, and methylsulfoxide failed to diminish proteolysis stimulated by the hydrazines, N-acetylcysteine exerted a protective effect, decreasing hydrazine-stimulated tyrosine release in red cells approximately 30 to 50%. Inclusion of 3-amino-1,2,4-triazole in the incubation failed to increase further the rate of hydrazine-stimulated proteolysis. These data suggest that more reactive free radicals generated from the hydrazine are responsible for protein damage, that damaged protein (hemoglobin) is degraded via proteolysis, and that an ATP-independent process primarily participates in the degradation of abnormal proteins in the red cell. Thus, proteolytic enzymes present in the erythrocyte appear to exert a protective effect against cellular damage through the removal of abnormal proteins generated as a consequence of xenobiotic insult. The ability of proteolytic enzymes to recognize and degrade abnormal proteins may be of importance in using protein (hemoglobin)-xenobiotic adducts to assess exposure to toxic agents (risk assessment).

Excitatory amino acids activate calpain I and induce structural protein breakdown in vivo

Neuronal activity regulates the catabolism of specific structural proteins in adult mammalian brain. Pharmacological stimulation of rat hippocampal neurons by systemic or intraventricular administration of the excitatory amino acids kainate or N-methyl-D-aspartate induces selective loss of brain spectrin and the microtubule-associated protein MAP2, as determined by quantitative immunoblotting, but not of actin, the high molecular weight neurofilament polypeptide, or glial fibrillary acidic protein. The spectrin decrease occurs primarily by enhanced proteolysis, as levels of the major breakdown products of the alpha-subunit increase more than 7-fold. This proteolysis may occur from activation of the calcium-dependent neutral protease calpain I. The immunopeptide maps produced by alpha-spectrin degradation, selective loss of spectrin and MAP2, and decrease in calpain I levels are all consistent with calpain I activation accompanied by autoproteolysis. We propose that calcium influx and calpain I activation provide a mechanism by which neuronal activity regulates the degradation of specific neuronal structural proteins and may thereby modify neuronal morphology.

Activation of the Ca2+-ATPase of human erythrocyte membrane by an endogenous Ca2+-dependent neutral protease

Limited proteolysis of the plasma membrane calcium transport ATPase (Ca2+-ATPase) from human erythrocytes by trypsin produces a calmodulin-like activation of its ATP hydrolytic activity and abolishes its calmodulin sensitivity. We now demonstrate a similar kind of activation of the human erythrocyte membrane Ca2+-ATPase by calpain (calcium-dependent neutral protease) isolated from the human red cell cytosol. Upon incubation of red blood cell membranes with purified calpain in the presence of Ca2+ the membrane-bound Ca2+-ATPase activity was increased and its sensitivity to calmodulin was lost. In contrast to the action of other proteases tested, proteolysis by calpain favors activation over inactivation of the Ca2+-ATPase activity, except at calpain concentrations more than 2 orders of magnitude higher. Exogenous calmodulin protects the Ca2+-ATPase against calpain-mediated activation at concentrations which also activate the Ca2+-ATPase activity. Calcium-dependent proteolytic modification of the Ca2+-ATPase could provide a mechanism for the irreversible activation of the membrane-bound enzyme.

Proteolysis of tubulin and microtubule-associated proteins 1 and 2 by calpain I and II. Difference in sensitivity of assembled and disassembled microtubules

Calpain I and II (EC 3.4.22.17) are Ca2+-activated neutral thiol-proteases. Isolated brain tubulin and microtubule-associated proteins were found to be good substrates for proteolytic degradation by brain calpain I and II. The assembly of microtubules was totally inhibited when the calpains were allowed to act on microtubule proteins initially, and a complete disassembly was found after addition of calpain I to assembled microtubules. The high-molecular weight microtubule-associated proteins were degraded within a few minutes following incubation with calpain as shown by SDS-polyacrylamide gel electrophoresis and electron microscopy. When calpain was added to pre-formed microtubules, either in the presence or in the absence of microtubule-associated proteins, the proteolysis was significantly reduced. When tubulin was pre-assembled by taxol, the formation of proteolytic fragments was decreased indicating that assembly alters the availability of tubulin sites for proteolytic cleavage by calpain. Digested tubulin spontaneously formed aberrant polymers. No considerable change of apparent net charge was seen, thus indicating that calpain cleaves off fragments containing neutral amino acid residues and/or that the fragments of tubulin remain associated as an entity with the same charge as native tubulin. The results suggest that the calpains act as irreversible microtubule regulators.

The Ca2+-dependent protease inhibitor of rat ventral prostate: properties of the inhibitor and effects of castration on Ca2+-dependent protease and inhibitor activities

1. The rat ventral prostate contains a heat stable inhibitor of Ca2+-dependent protease. This inhibitor was found to exist in a wide range of molecular weights (approx. 40-270 kDa) in adult rats. 2. However, in rats immediately post puberty (45 days of age) the inhibitor was predominantly of the higher molecular weight forms. 3. The inhibitor was also found in the dorsolateral and anterior (coagulating gland) prostate lobes but was of lower specific activity than in the ventral lobe. 4. Although the activities of the Ca2+-dependent protease and inhibitor decreased per ventral prostate gland after castration, these activities were not different during the first 10 days postcastration when expressed per g wet wt or per unit cytosol protein. 5. With a longer duration of castration, there was a decline in the specific activity (per unit protein) of the protease and an increase in that of the inhibitor. 6. Thus, the activities of the protease and inhibitor change in concert with the amount of cellular cytosol protein during the active period of castration-induced atrophy. 7. However, in long term castrated rats, functions carried out by the Ca2+-dependent protease may be effectively suppressed. 8. These data suggest that the Ca2+-activated protease probably is involved in the regulation of some metabolic processes in the active gland and is not prominent in the castration induced atrophy of the ventral prostate unless it functions through the proteolysis of some select protein(s).

Third form of calcium-activated neutral proteinase from calf brain: purification, partial characterization and comparison of properties with other forms

A third form (CANP3) of calcium-activated neutral proteinase (CANP) has been purified, 3900-fold, to near homogeneity from calf brain cortex. The purification procedure is based on the one recently developed for the purification of CANP1 and CANP2. The molecular weight of CANP3, as judged on SDS-polyacrylamide gel electrophoresis was Mr 78,000. A protein with an apparent Mr 17,000 co-purified with the proteinase. At neutral pH (7.2), it was maximally active at 260 microM CaCl2. In the presence of CaCl2, CANP1 and CANP3 were autolyzed very rapidly, whereas the autolysis of CANP2 was slow and gradual. The autolyzed CANP1 and CANP3 responded differently to CaCl2; CANP1 lost activity completely, whereas CANP3 was fully active at 0.5 microM CaCl2. Despite the opposite behavior of these proteinases in the presence of Ca2+, no significant differences in the peptide maps of the three proteinases were observed. Neurofilaments, neurotubules and myelin basic protein (MBP) were degraded by each of the proteinases. Monoclonal antibodies raised against CANP2 reacted almost equally with CANP1 and CANP3. As with CANP1 and CANP2, leupeptin and sulfhydryl-modifying compounds, NEM and iodoacetic acid, inhibited the activity of CANP3.

Calcium-dependent proteolysis in the myocardium of rats subjected to stress

Activity of a calcium-dependent neutral protease (calpain II) and its specific endogenous inhibitor was investigated in the myocardium of rats subjected to different stressors: cold, anaesthesia, 24 and 48 h starvation and food restriction for 7 and 14 days. Enzyme and inhibitor activities were determined in the 37,200 g supernatant of homogenates prepared from the free left ventricular wall of the heart. The specific activity of the myocardial calcium-dependent proteinase increased in all rats exposed to stressful stimuli, reaching maximum values in animals starved for 48 hours. Decrease in the specific activity of the inhibitor accompanied the changes in enzyme activity. Differences from normal control values were statistically significant in the starved animals and in animals fed a restricted diet for 7 or 14 days. These observations suggest that interaction between calpain II and its specific inhibitor plays a role in the regulation of the enzyme activity and furthermore, that stressful stimuli lead to increased calcium-dependent proteolysis in the myocardium.

Protein kinase C activity and hexamethylenebisacetamide-induced erythroleukemia cell differentiation

Hexamethylenebisacetamide (HMBA) is a potent inducer of murine erythroleukemia (MEL) cell differentiation. The mechanism of action of HMBA is not known. In this study we provide evidence that protein kinase C has a role in inducer-mediated MEL cell differentiation: (i) HMBA induces the formation of a soluble, proteolytically activated form of protein kinase C that is catalytically active in the absence of Ca2+ and phospholipid; (ii) the protease inhibitor leupeptin blocks formation of this activated form of the kinase and inhibits HMBA-induced MEL cell hemoglobin accumulation; (iii) phorbol 12-myristate 13-acetate (PMA) inhibits HMBA-induced MEL differentiation and causes depletion of total protein kinase C activity; (iv) MEL cells depleted in protein kinase C activity by culture with PMA are resistant to induction by HMBA; (v) upon removal of PMA, restoration of MEL cell sensitivity to HMBA is correlated with reaccumulation of protein kinase C activity; and (vi) MEL cells grown to density arrest are both depleted of protein kinase C activity and resistant to HMBA. Together, these results suggest that HMBA-mediated MEL cell differentiation involves a protein kinase C-related mechanism and the proteolytically activated form of the kinase, which does not require Ca2+ or phospholipid for its catalytic activity.

Calcium-activated neutral protease inhibitor from rabbit erythrocytes lacks the N-terminal region of the liver inhibitor but retains three inhibitory units

Endogenous inhibitors for calcium-activated neutral protease (CANP) were purified from rabbit erythrocytes and liver. The purified inhibitors showed single bands but with significantly different mobilities on sodium dodecylsulfate-polyacrylamide gel electrophoresis. Peptide mapping and sequencing analyses have revealed that the erythrocyte inhibitor (429 residues) retains the C-terminal three repetitive units of the liver inhibitor (639 residues), which contains four potential repetitive units for inhibition of CANP. The erythrocyte and liver inhibitors inhibited 3 and 4 moles of CANP on the basis of the molecular weights of 46,000 and 68,000, respectively.

Procalpain is activated on the plasma membrane and the calpain acts on the membrane

The mechanism of activation of human erythrocyte calpain was investigated using the immunoblotting technique with anticalpain monoclonal antibody. The purified calpain underwent a Ca2+-induced fragmentation of the 80 kDa subunit to 76 kDa and 36 kDa fragments. The behavior of the 76 kDa fragment in electrophoresis corresponded to the proteinase activity of calpain, whereas the behavior of the 80 kDa subunit and the 36 kDa fragment did not. When inside-out membrane vesicles were added to the reaction mixture of calpain and Ca2+ and the vesicles were separated from the supernatant solution by centrifugation, the 80 kDa subunit and 76 kDa fragment were found in the vesicle fraction. No other fragments were found in this fraction. On the other hand, the 80 kDa subunit and 36 kDa fragment were found in the supernatant fraction. When right-side-out membrane vesicles were added to the reaction mixture and the vesicles were separated from the supernatant fraction, no fragment was found in the vesicle fraction, while only the 36 kDa fragment was found in the supernatant fraction. These results indicate that the 80 kDa subunit of procalpain was bound in a Ca2+-dependent manner to the cytosolic surface of the plasma membrane and then underwent fragmentation to produce the 76 kDa fragment (active form) and that it expressed its proteinase activity at the surface of the membrane.

Decreased level of calpain inhibitor activity in kidney from Milan hypertensive rats

Rat kidney contains two different calpain isozymes distinguishable on the basis of their Ca2+ requirement and of their activation mechanisms. The two calpain isozymes are present in comparable amounts in kidney of normotensive and hypertensive rats of the Milan strain. Conversely, the level of the natural inhibitor of calpain is significantly decreased in kidney of hypertensive rats as compared to control normotensive rats. This deficiency is more pronounced in the cortical region than in other kidney fractions. These results taken together with previous observations indicating the existence of an identical defect in red cells from the same hypertensive rat strain, (Pontremoli, S., Melloni, E., Salamino, F., Sparatore, B., Viotti, P., Michetti, M., Duzzi, L., and Bianchi, G. (1986) Biochem. Biophys. Res. Commun. 138, 1370-1375) emphasize the possible role of an unbalanced intracellular proteolytic system in the development of genetically determined hypertension.

Micromolar Ca2+ requiring protease from human platelets: purification, partial characterization and effect on the cytoskeletal proteins

A calcium-activated neutral protease (CANP) has been purified 2,800 fold, to near homogeneity, from human platelets. The purification procedure involved ammonium sulfate fractionation of the platelet cytosol followed by chromatography on Sephacryl S-200, DEAE-Sephacel, Agarose-Hexylamine, Agarose-Octylamine and alpha-casein-Sepharose 4B affinity gel. The protease consisted of two polypeptides of Mr = 74,000 and 28,000 as judged on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. It hydrolyzed [methyl-14C] alpha-casein at a significant rate of 37 degrees C which was, therefore, used as an exogenous substrate. Microtubules and intermediate filament proteins were also susceptible to hydrolysis by the purified protease. It attained maximum activity at 0.06 uM CaCl2 and displayed two pH maxima: one at 5.5 and the other at 6.5. The protease was fully active in the presence of MnCl2 and was about 75% active with BaCl2 and SrCl2. Among the actinomycete protease inhibitors, leupeptin, antipain and pepstatin, the order of inhibition was: leupeptin greater than antipain greater than pepstatin. The protease was also inhibited by sulfhydryl modifying agents.

Irreversible inactivation of calcium-dependent proteinases from rat liver by biological disulfides

The effect of low-molecular-mass biological disulfides and their related reduced compounds on the activity of two calcium-dependent neutral proteinases (calpains) from rat liver has been investigated. L-Cystine and L-cystamine bring about the inactivation of both enzymes, while the related reduced compounds L-cysteine and L-cysteamine are without effect. Calpain II is more sensitive to the inactivating effect of glutathione disulfide in comparison with calpain I. The inactivation rates of both calpains depend on the concentration of glutathione disulfide. Reduced glutathione, added at physiological concentration (5 mM), neither affects the proteinase activities nor protects the enzymes from the inactivating effect of glutathione disulfide. The enzymes inactivated by biological disulfides cannot be restored by a large excess of a reducing thiolic compound (dithiothreitol). It is suggested that calcium-dependent proteinases might be inactivated also in vivo by enhanced level of glutathione disulfide.

Calcium-activated protease in hamster cardiomyopathy

A high calcium-requiring protease was purified from the hearts of myopathic hamsters. The biochemical properties of the enzyme were studied with [3H]acetylcasein as substrate. Comparison of the enzyme from hamster and rat hearts indicated no species specificity. Increased levels of the enzyme were associated with the development of cardiac lesions in myopathic hamsters.

Oxidative inactivation of the calcium-stimulated neutral proteinase from human red blood cells by divicine and intracellular protection by reduced glutathione

Calpain, the micromolar Ca2+-requiring form of Ca2+-stimulated neutral proteinase purified from human red cells, is remarkably inactivated during autoxidation of divicine (2,6-diamino-4,5-dihydroxypyrimidine), an aglycone implicated in the pathogenesis of favism. Inactivation of purified calpain is produced, in decreasing order of efficiency, by transient, probably semiquinonic species arising from autoxidation of divicine, by the H2O2 that is formed upon autoxidation itself, and by quinonic divicine, respectively. Purified procalpain, the millimolar Ca2+-requiring form that can be converted to the fully active calpain form by a variety of mechanisms, is less susceptible than calpain itself to inactivation by the same by-products of divicine autoxidation. When intact red cells are exposed to autoxidizing divicine, procalpain undergoes a significant loss of activity. At 1 mM divicine, intracellular inactivation is observed with procalpain only, while the activity of a number of red cell enzymes is unaffected. Inactivation of procalpain is consistently greater in red cells from glucose-6-phosphate dehydrogenase-deficient subjects than in normal cells. Restoration of normal levels of glucose-6-phosphate dehydrogenase activity by means of entrapment of homogeneous human glucose-6-phosphate dehydrogenase in the deficient red cells results in normal stability of intracellular reduced glutathione; decreased susceptibility of procalpain to inactivation by autoxidizing divicine. These findings suggest that in the glucose-6-phosphate dehydrogenase-deficient red cells the procalpain-calpain system is a major target of divicine cytotoxicity.

Calcium-activated neutral proteinase of human brain: subunit structure and enzymatic properties of multiple molecular forms

Calcium-activated neutral proteinase (CANP) was purified 2,625-fold from postmortem human cerebral cortex by a procedure involving chromatography on diethylaminoethyl (DEAE)-cellulose, phenyl-Sepharose, Ultrogel AcA-44, and DEAE-Biogel A. The major active form of CANP exhibited a molecular weight of 94-100 kilodaltons (Kd) by gel filtration on Sephacryl 300 and consisted of 78-Kd and 27-Kd subunits. Two-dimensional gel electrophoresis resolved the small subunit into two molecular species with different isoelectric points. CANP degraded most human cytoskeletal proteins but was particularly active toward fodrin and the neurofilament protein subunits (145 Kd greater than 200 Kd greater than 70 Kd). The enzyme required 175 microM Ca2+ for half-maximal activation and 2 mM Ca2+ for optimal activity toward [methyl-14C]azocasein. Other divalent metal ions were poor activators of the enzyme, and some, including copper, lead, and zinc, strongly inhibited the enzyme. Aluminum, a neurotoxic ion that induces neurofilament accumulations in mammalian brain, inhibited the enzyme 47% at 1 mM and 100% at 5 mM. A second CANP form lacking the 27-Kd subunit was partially resolved from the 100-Kd heterodimer during DEAE-Biogel A chromatography. The 78-Kd monomer exhibited the same specific activity, calcium ion requirement, pH optimum, and specificity for cytoskeletal proteins as the 100-Kd heterodimer, suggesting that the 27-Kd subunit is not essential for the major catalytic properties of the enzyme. The rapid autolysis of the 27-Kd subunit to a 18-Kd intermediate when CANP is exposed to calcium may explain differences between our results and previous reports, which describe brain mCANP in other species as a 76-80-Kd monomer or a heterodimer containing 76-80-Kd and 17-20-Kd subunits. The similarity of the 100-Kd human brain CANP to CANPs in nonneural tissues indicates that the heterodimeric form is relatively conserved among various tissues and species.

Fusion of rat erythrocytes by membrane-mobility agent A2C depends on membrane proteolysis by a cytoplasmic calpain

The membrane-mobility agent 2-(2-methoxyethoxy)ethyl-cis-8-(2-octylcyclopropyl)octanoate (A2C) promotes fusion of rat, but not of human, erythrocytes. The difference in fusibility was shown to be correlated with membrane proteolysis, a process induced by Ca2+ in the rat erythrocytes or hemolysate-loaded ghosts, but not in the human cell. Membrane proteolysis is necessary but not sufficient for fusion. Fusion requires both Ca2+ and A2C [Kosower, N. S., Glaser, T. and Kosower, E. M. (1983) Proc. Natl Acad. Sci USA 80, 7542-7546]. Membrane proteolysis (Ca2+-dependent) and fusion (Ca2+ and A2C-dependent) requires a Ca2+-activated cytoplasmic thiol protease, as shown by the following observations. In intact rat erythrocytes, proteolysis and fusion are prevented by thiol alkylation and by inhibitors of Ca2+-dependent thiol proteases. Inhibitors to other proteases have no effect. Erythrocyte ghosts undergo proteolysis and fusion only when loaded with non-inhibited hemolysate, irrespective of membrane status (native or alkylated membrane). A partially purified cytosolic enzyme, identified as calpain I, promotes proteolysis in rat erythrocyte ghosts. A2C induces fusion only in such calpain-treated ghosts.

Characterization of the defective calpain-endogenous calpain inhibitor system in erythrocytes from Milan hypertensive rats

In mature red cells of rats from Milan normal (MNS) and hypertensive strains (MHS), the soluble Ca2+ dependent neutral proteinase (calpain) is present in similar amounts with identical Mr of 110 kDa and a dimeric structure composed of two unequal subunits of Mr of 84 and 26 kDa. Conversely, the amount of the endogenous inhibitor is now confirmed by analysis of the specific activity to be approximately 10 times less in red cells of MHS rats. The inhibitor is present in red cells of both strains in three different oligomeric forms of Mr of 240, 120 and 64 kDa. This last molecular species corresponds to the single basic constituent subunit which is the reacting inhibitor form. The apparent equilibrium between the three oligomeric structures is Ca2+-dependent. The high (0.1 mM) Ca2+ requirement for the activity of calpain from erythrocytes of both strains is reduced to 1-5 microM in the presence of plasma membrane phospholipids. Activation of the enzyme in these conditions is prevented by the natural inhibitor. These results strongly support and further emphasize the hypothesis that the structural and functional abnormalities in MHS rats red cells result from an impairment in the modulation of intracellular calpain activity by interaction with its endogenous inhibitor.

Decreased level of calpain inhibitor activity in red blood cells from Milan hypertensive rats

In mature red cells of rats from Milan Normal (MNS) and Hypertensive Strains (MHS), the soluble Ca2+-dependent neutral proteinase (calpain) is present in similar amounts as the form requiring 0.1-0.2 mM Ca2+ for maximum catalytic activity. The amount of the endogenous calpain inhibitor, however, differs greatly in the red cells of the two strains. In red cells from hypertensive rats the activity of the inhibitor is 10 times less with a ratio of inhibitor to calpain activity (unit/unit) of 0.2; compared to red cells from normal rats, in which this ratio is approximately 2. This is the first demonstration of the existence, in a mammalian cell, of such a low ratio of calpain to inhibitor and implies the occurrence of a potentially "unregulated" intracellular soluble proteinase. This abnormal condition may be responsible for some of the structural and metabolic changes reported in rats of the genetically determined MHS strain.

Calcium-induced alterations in the levels and subcellular distribution of proteolytic enzymes in human red blood cells

Human red cells were treated with 100 microM Ca2+ and ionophore A 23187. This treatment induces remarkable changes in the activities of the two major proteolytic systems of red cells, i.e. Ca2+-dependent neutral proteinase and acid endopeptidases. Ca2+-dependent neutral proteinase undergoes intracellularly preliminary activation of the inactive proenzyme species, followed by eventual inactivation through self-proteolysis. Transient activation is shown by selective degradation of cytoskeletal proteins known to be targets of this enzyme system. Concomitantly, acid endopeptidase activity is substantially released from the membrane into the cytosol. Preliminary inactivation of the Ca2+-dependent neutral proteinase by exposure of Glucose 6-phosphate dehydrogenase-deficient red cells to auto-oxidizing divicine prevents alterations induced by Ca2+ loading on cytoskeletal membrane proteins, while leaving solubilization of acid endopeptidase activity unaffected. The two events, although dependent on Ca2+ loading, are therefore unrelated to each other.

Two different molecular species of pig calpastatin. Structural and functional relationship between 107 kDa and 68 kDa molecules

Calpastatin, the inhibitor protein acting specifically on calpain (EC 3.4.22.17; Ca2+-dependent cysteine proteinase), is known to be widely distributed in mammalian and avian cells. Two different molecular species of calpastatin were isolated and purified to homogeneity from pig heart muscle and from pig erythrocytes, and shown to be of 107 kDa and 68 kDa respectively on SDS/polyacrylamide-gel electrophoresis. Both calpastatins had very similar amino acid compositions when expressed as mol per cent of the residues, differed by only 0.1 pH unit in their isoelectric points, and showed immunological cross-reactivity. One molecule of the 107 kDa species could bind approx. 8 calpain molecules, whereas the 68 kDa inhibitor could bind approx. 5 calpain molecules. These findings suggest similar protein structures of the 107 kDa and 68 kDa calpastatins, each being composed of extended multidomains, with unit inhibitor domains aligned along the polypeptide chain of the molecule. The present study does not conclude, however, whether or not the 68 kDa calpastatin found in erythrocytes is a derived product from the 107 kDa species, which is present as such in heart muscle.