Glutamate Neurotoxicity Is Independent of Calpain I Inhibition in Primary Cultures of Cerebellar Granule Cells

Glutamate-induced neurotoxicity and calpain activity were studied in primary cultures of rat cerebellar granule neurons and glial cells. Calpain activation, as monitored by quantitative immunoblotting of spectrin, required micromolar concentrations of Ca2+ in neuronal homogenates (calpain I) and millimolar Ca2+ concentrations in glial homogenates (calpain II). Glutamate-induced toxicity and calpain activation were observed in neuronal, but not in glial, cultures. In neurons, calpain I activation by glutamate was dose-dependent and persisted after withdrawal of neurotoxic doses of glutamate. Natural (GM1) and semisynthetic (LIGA4) gangliosides or the glutamate receptor blocker MK-801 prevented calpain I activation and delayed neuronal death elicited by glutamate. GM1 and LIGA4 had no effect on calpain I activity in neuronal homogenates, however. Furthermore, two calpain I inhibitors (leupeptin and N-acetyl-Leu-Leu-norleucinal) prevented glutamate-induced spectrin degradation, but failed to affect glutamate neurotoxicity. These results thus suggest that glutamate-induced neurotoxicity is independent of calpain I activation.     

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.     

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.     

Activation of proteolytic enzymes and depression of the sarcolemmal Na+/K+-ATPase in ischemia-reperfused heart may be mediated through oxidative stress

We tested whether the activation of proteolytic enzymes, calpain, and matrix metalloproteinases (MMPs) during ischemia-reperfusion (I/R) is mediated through oxidative stress. For this purpose, isolated rat hearts were subjected to a 30?min global ischemia followed by a 30?min reperfusion. Cardiac function was monitored and the activities of Na(+)/K(+)-ATPase, Mg(2+)-ATPase, calpain, and MMP were measured. Depression of cardiac function and Na(+)/K(+)-ATPase activity in I/R hearts was associated with increased calpain and MMP activities. These alterations owing to I/R were similar to those observed in hearts perfused with hypoxic medium, H(2)O(2) and xanthine plus xanthine oxidase. The I/R-induced changes were attenuated by ischemic preconditioning as well as by perfusing the hearts with N-acetylcysteine or mercaptopropionylglycine. Inhibition of MMP activity in hearts treated with doxycycline depressed the I/R-induced changes in cardiac function and Na(+)/K(+)-ATPase activity without affecting the calpain activation. On the other hand, inhibition of calpain activity upon treatment with leupeptin or MDL 28170 significantly reduced the MMP activity in addition to attenuating the I/R-induced alterations in cardiac function and Na(+)/K(+)-ATPase activity. These results suggest that the I/R-induced depression in Na(+)/K(+)-ATPase and cardiac function may be a consequence of the increased activities of both calpain and MMP because of oxidative stress in the heart.     

In vivo effect of a beta-adrenergic agonist on activity of calcium-dependent proteinases, their specific inhibitor, and cathepsins B and H in skeletal muscle

DEAE-Sephacel and phenyl-Sepharose chromatography were compared as methods for separating and quantitatively isolating calpain I, calpain II, and calpastatin from lamb muscle extracts. DEAE-Sephacel chromatography gave greater than 90% recovery of all three proteins, while phenyl-Sepharose gave only 70, 66, and 48% of the DEAE recovery of calpain I, calpain II, and calpastatin, respectively. Additionally, DEAE-Sephacel chromatography was shown to effectively separate calpastatin and calpain I. Consequently DEAE-Sephacel appears to be superior to phenyl-Sepharose for quantitative isolation of the components of the calcium-dependent proteinase system from muscle extracts. Dietary administration of beta-agonist (L-644, 969; Merck Sharpe & Dohme Research Laboratories) decreases extractable calpain I activity in lamb longissimus dorsi (LD) muscle by 10-14% (P less than 0.05), increases calpain II activity by 34-42% (P less than 0.001), and increases calpastatin activity by 59-75% (P less than 0.001). Additionally, net cathepsin B activity is reduced by 30% (P less than 0.05) in the LD of beta-agonist-treated lambs. Reduced activity of the calcium-dependent or catheptic proteinase systems may contribute to the increased protein accretion in muscles of beta-agonist-treated lambs.     

Ischemia-reperfusion-induced calpain activation and SERCA2a degradation are attenuated by exercise training and calpain inhibition

The Ca2+-activated protease calpain has been shown to play a deleterious role in the heart during ischemia-reperfusion (I/R). We tested the hypothesis that exercise training would minimize I/R-induced calpain activation and provide cardioprotection against I/R-induced injury. Hearts from adult male rats were isolated in a working heart preparation, and myocardial injury was induced with 25 min of global ischemia followed by 45 min of reperfusion. In sedentary control rats, I/R significantly increased calpain activity and impaired cardiac performance (cardiac work during reperfusion = 24% of baseline). Compared with sedentary animals, exercise training prevented the I/R-induced rise in calpain activity and improved cardiac work (recovery = 80% of baseline). Similar to exercise, pharmacological inhibition of calpain activity resulted in comparable cardioprotection against I/R injury (recovery = 86% of baseline). The exercise-induced protection against I/R-induced calpain activation was not due to altered myocardial protein levels of calpain or calpastatin. However, exercise training was associated with increased myocardial antioxidant enzyme activity (Mn-SOD, catalase) and a reduction in oxidative stress. Importantly, exercise training also prevented the I/R-induced degradation of sarco(endo)plasmic reticulum Ca2+-ATPase (SERCA)2a. These findings suggest that increases in endogenous antioxidants may diminish the free radical-mediated damage and/or degradation of Ca2+ handling proteins (such as SERCA2a) typically observed after I/R. In conclusion, these results support the concept that calpain activation is an important component of I/R-induced injury and that exercise training provides cardioprotection against I/R injury, at least in part, by attenuating I/R-induced calpain activation.     

Ca2+-protease--an enzyme of the metabolism of cytoskeletal proteins in the olfactory membrane of vertebrates

Two forms of Ca(++)-activated protease (calpain I and calpain II) associated with an endogenous inhibitor (calpastatin) were detected in a cytosolic fraction of the olfactory tissue of vertebrates (pig, rat). Using ion exchange chromatography on DEAE-cellulose column, calpain I is divided into 2 peaks (eluting by 0.07-0.15 and 0.22-0.25 M NaCl), and calpain II is eluted by 0.35-0.40 M NaCl. The calpain activity was detected in fractions eluted by 0.1-0.17 M NaCl. The Ca(++)-activated protease was demonstrated also in a fraction of cytoskeleton of olfactory tissue insoluble in a 1% solution of Triton X-100. The activity can be detected by Ca(++)-dependent destruction of exogenous substrate (casein), and by Ca(++)-dependent degradation of cytoskeletal endogenous proteins (16, 18 and 20 kDa), of which one may be calmodulin.     

Role of calpain in hypoxic inhibition of nitric oxide synthase activity in pulmonary endothelial cells

Pulmonary artery endothelial cells (PAEC) were exposed to normoxia or hypoxia (0% O(2)-95% N(2)-5% CO(2)) in the presence and absence of calpain inhibitor I or calpeptin, after which endothelial nitric oxide synthase (eNOS) activity and protein content were assayed. Exposure to hypoxia decreased eNOS activity but not eNOS protein content. Both calpain inhibitor I and calpeptin prevented the hypoxic decrease of eNOS activity. Incubation of calpain with total membrane preparations of PAEC caused dose-dependent decreases in eNOS activity independent of changes in eNOS protein content. Exposure of PAEC to hypoxia also caused time-dependent decreases of heat shock protein 90 (HSP90) that were prevented by calpain inhibitor I and calpeptin. Moreover, the HSP90 content in anti-eNOS antibody-induced immunoprecipitates from hypoxic PAEC lysates was reduced, and repletion of HSP90 reversed the decrease of eNOS activity in these immunoprecipitates. Incubation of PAEC with a specific inhibitor of HSP90 (geldanamycin) mimicked the hypoxic decrease of eNOS activity. These results indicate that the hypoxia-induced reduction in eNOS activity in PAEC is due to a decrease in HSP90 caused by calpain activation.     

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+].     

Calpain inhibitor I reduces the activation of nuclear factor-kappaB and organ injury/dysfunction in hemorrhagic shock.

There is limited evidence that inhibition of the activity of the cytosolic cysteine protease calpain reduces ischemia/reperfusion injury. The multiple organ injury associated with hemorrhagic shock is due at least in part to ischemia (during hemorrhage) and reperfusion (during resuscitation) of target organs. Here we investigate the effects of calpain inhibitor I on the organ injury (kidney, liver, pancreas, lung, intestine) and dysfunction (kidney) associated with hemorrhagic shock in the anesthetized rat. Hemorrhage and resuscitation with shed blood resulted in an increase in calpain activity (heart), activation of NF-kappaB (kidney), expression of iNOS and COX-2 (kidney), and the development of multiple organ injury and dysfunction, all of which were attenuated by calpain inhibitor I (10 mg/kg i.p.), administered 30 min prior to hemorrhage. Chymostatin, a serine protease inhibitor that does not prevent the activation of NF-kappaB, had no effect on the organ injury/failure caused by hemorrhagic shock. Pretreatment (for 1 h) of murine macrophages or rat aortic smooth muscle cells (activated with endotoxin) with calpain inhibitor I attenuated the binding of activated NF-kappaB to DNA and the degradation of IkappaBalpha, IkappaBbeta, and IkappaBvarepsilon. Selective inhibition of iNOS activity with L-NIL reduced the circulatory failure and liver injury, while selective inhibition of COX-2 activity with SC58635 reduced the renal dysfunction and liver injury caused by hemorrhagic shock. Thus, we provide evidence that the mechanisms by which calpain inhibitor I reduces the circulatory failure as well as the organ injury and dysfunction in hemorrhagic shock include 1) inhibition of calpain activity, 2) inhibition of the activation of NF-kappaB and thus prevention of the expression of NFkappaB-dependent genes, 3) prevention of the expression of iNOS, and 4) prevention of the expression of COX-2. Inhibition of calpain activity may represent a novel therapeutic approach for the therapy of hemorrhagic shock.     

Proteolytic conversion of xanthine dehydrogenase to xanthine oxidase: evidence against a role for calcium-activated protease (calpain)

The present study tested the hypothesis that calpain is responsible for the limited proteolytic conversion of xanthine dehydrogenase (XD) to xanthine oxidase (XO). We compared the effects of various proteases on the activity and molecular weight of a purified preparation of xanthine dehydrogenase from rat liver. In agreement with previous reports, trypsin treatment produced a complete conversion of XD to XO accompanied by a limited proteolysis of XDH from an Mr of 140 kD to an Mr of 90 kD. Treatment with calpain I or calpain II did not produce a conversion from XD to XO nor did it result in partial proteolysis of the enzyme. Similarly, trypsin treatment partially degraded a reversibly oxidized form of xanthine dehydrogenase while calpain I or calpain II were ineffective. The possibility that an endogenous inhibitor prevented the proteolysis of XDH by calpain I or II was excluded by verifying that brain spectrin, a known calpain substrate, was degraded under the same incubation conditions. The results indicate that calpain is not likely to be responsible for the in vivo conversion of XD to XO under pathological conditions.     

Mutations in calpain 3 associated with limb girdle muscular dystrophy: analysis by molecular modeling and by mutation in m-calpain

Limb-girdle muscular dystrophy type 2A (LGMD2A) is an autosomal recessive disorder characterized by selective atrophy of the proximal limb muscles. Its occurrence is correlated, in a large number of patients, with defects in the human CAPN3 gene, a gene that encodes the skeletal muscle-specific member of the calpain family, calpain 3 (or p94). Because calpain 3 is difficult to study due to its rapid autolysis, we have developed a molecular model of calpain 3 based on the recently reported crystal structures of m-calpain and on the high-sequence homology between p94 and m-calpain (47% sequence identity). On the basis of this model, it was possible to explain many LGMD2A point mutations in terms of calpain 3 inactivation, supporting the idea that loss of calpain 3 activity is responsible for the disease. The majority of the LGMD2A mutations appear to affect domain/domain interaction, which may be critical in the assembly and the activation of the multi-domain calpain 3. In particular, we suggest that the flexibility of protease domain I in calpain 3 may play a critical role in the functionality of calpain 3. In support of the model, some clinically observed calpain 3 mutations were generated and analyzed in recombinant m-calpain. Mutations of residues forming intramolecular domain contacts caused the expected loss of activity, but mutations of some surface residues had no effect on activity, implying that these residues in calpain 3 may interact in vivo with other target molecules. These results contribute to an understanding of structure-function relationships and of pathogenesis in calpain 3.     

Identification of an endogenous activator of calpain in rat skeletal muscle

An additional component of the regulatory system of rat skeletal muscle calpain has been identified. It exerts a potent activating effect on calpain activity and is a heat stable small molecular weight protein. Of the two calpain isozymes present in muscle, the activator is specific for calpain II, being uneffective with calpain I. It promotes activation of the proteinase by reducing 50 fold, from 1 mM to of 20 microM, the requirement of Ca2+ for maximum catalytic activity of the proteinase. However in the presence of the activator calpain II expresses a consistent fraction of the maximum activity even at significantly lower concentrations of Ca2+ (below 5 microM Ca2+). The activator effect follows kinetics that are consistent with the presence of specific binding sites on the calpain molecules. The activator not only removes in a dose dependent fashion the inhibition of calpain by calpastatin, but also prevents inhibition of the proteinase upon the addition of calpastatin. Competition experiments revealed that the proteinase contains distinct sites for the activator and the inhibitor, and that both ligands can bind to calpain with the formation of an almost fully active ternary complex.     

Association of the calpain/calpastatin network with subcellular organelles

The calcium-activated cysteine protease calpain is intimately involved in modulating cell adhesion and migration. The two ubiquitous isoforms of this protease, calpain I and II, are considered to be cytosolic proteins that can translocate to both focal complexes/adhesions or the plasma membrane. Using confocal microscopy and isopycnic density centrifugation, the results demonstrate that calpain I and II, the 30kDa regulatory subunit, and calpastatin associate with the endoplasmic reticulum and Golgi apparatus. Confocal microscopy reveals that calpain II colocalizes with the subcellular proteins calnexin and Rab6 in cells bound to laminin. To further verify this association, cell lysates prepared from laminin stimulated and unstimulated cells were subjected to isopycnic density centrifugation. The results reveal an increased association of calpain I, II, calpastatin, and the 30kDa regulatory subunit with the endoplasmic reticulum and Golgi apparatus as evidenced by their position in the gradient relative to calnexin, Rab6, caveolin, and beta1 integrin after laminin stimulation. This correlates with the accumulation of inducible calpain activity at the endoplasmic reticulum-Golgi apparatus interface. Further experiments established that calpain II colocalizes with phosphatidylinositol 4,5-bisphosphate. Finally, calpain II associates with membrane lipid rafts. These results provide new insights into how the calpain/calpastatin network is spatially and temporally regulated in cells binding to the extracellular matrix.     

Calpain I Activity and Its Relationship with Hippocampal Neuronal Death in Pilocarpine-Induced Status Epilepticus Rat Model

This study aims to establish pilocarpine-induced rat model of status epilepticus (SE), observe the activity of calpain I in the rat hippocampus and the subsequent neuronal death, and explore the relationship between calpain I activity and neuronal death in the hippocampus. Fifty-eight adult male Wistar rats were assigned randomly into either control group (n = 8) or epilepsy group (n = 50). SE was induced in the epilepsy group using pilocarpine. Before the injection, the rats were given atropine sulfate to reduce the side effect of pilocarpine. All rats in the seizure group were grouped into either SE or non-SE, depending on whether they developed convulsive seizures. The rats in SE group were treated with chloral hydrate to stop seizures after 60 min. Control animals were treated with the same dose of 0.9 % saline. All rats were monitored for seizures. At 24 h after SE, the rats’ left brain tissues were stained by HE and TUNEL. Neuronal necrosis and apoptosis in the hippocampal CA3 area were observed. Calpain I activity in the right hippocampus was also observed using western blotting. Eighty percent of the rats in the seizure group developed SE, of which 35 % died. No rat died in both the control and non-SE groups. At 24 h after SE, the number of HE-stained neurons decreased (SE group: 55.19 ± 8.23; control group: 102.13 ± 3.73; non-SE group: 101.2 ± 2.86) and the number of TUNEL-positive neurons increased (SE group: 4.91 ± 1.35; non-SE and control group: 0). No obvious changes were observed in the neurons of the control and non-SE group animals. The 76 kDa cleavage of calpain I (the average optical density ratio is 0.096 ± 0.015) emerged in the SE group. Neuronal death has a direct relationship with calpain I activity. There is high success rate and lower death rate for pilocarpine to induce SE. At 24 h after SE, activity of calpain I, neuronal necrosis and apoptosis increased in the hippocampus. Neuronal death has a direct relationship with calpain I activity, which suggests that calpain I plays an important role in neuronal damage during SE.     

Truncation and activation of calcineurin A by calpain I in Alzheimer disease brain

A disturbance of calcium homeostasis is believed to play an important role in the neurodegeneration of the brains of Alzheimer disease (AD) patients, but the molecular pathways by which it contributes to the disease are not well understood. Here we studied the activation of two major Ca(2+)-regulated brain proteins, calpain and calcineurin, in AD brain. We found that calpain I is activated, which in turn cleaves and activates calcineurin in AD brain. Mass spectrometric analysis indicated that the cleavage of calcineurin by calpain I is at lysine 501, a position C-terminal to the autoinhibitory domain, which produces a 57-kDa truncated form. The 57-kDa calcineurin maintains its Ca(2+)/calmodulin dependence of the phosphatase activity, but the phosphatase activity is remarkably activated upon truncation. The cleavage and activation of calcineurin correlate to the number of neurofibrillary tangles in human brains. These findings suggest that the overactivation of calpain I and calcineurin may mediate the role of calcium homeostatic disturbance in the neurodegeneration of AD.     

Murine erythroleukemia cell differentiation: possible involvement of a calcium dependent neutral proteinase

Murine erythroleukemia cells contain a single type of calpain classified, on the basis of its calcium requirement, as a type I proteinase. The enzyme is practically inactive at concentrations of calcium below 10 microM and expresses maximal activity in the presence of 0.12-0.15 mM Ca2+. The affinity for Ca2+ cannot be reduced by exposure of the enzyme to conditions known to promote autoproteolysis of calpain. Expression of catalytic activity at lower concentrations of Ca2+, is promoted by the interaction with phospholipid vesicles or plasma membranes. Conditions that promote activation of calpain, induce also the self-inactivation of the enzyme. During terminal differentiation of murine erythroleukemia cells induced by HMBA, the intracellular level of calpain activity undergoes significative reduction. Similar decrease in calpain activity progressively occurs during the loss of sensitivity to HMBA as a result of density growth arrest.     

Differential compartmentalization of the calpain/calpastatin network with the endoplasmic reticulum and Golgi apparatus

Calpain, a calcium-activated cysteine protease, is involved in modulating a variety of cell activities such as shape change, mobility, and apoptosis. The two ubiquitous isoforms of this protease, calpain I and II, are considered to be cytosolic proteins that can translocate to various sites in the cell. The activity of calpain is modulated by two regulatory proteins, calpastatin, the specific endogenous inhibitor of calpain, and the 28-kDa regulatory subunit. Using velocity gradient centrifugation, the results of this study confirm and greatly expand upon our previous finding that the calpain/calpastatin network is associated with the endoplasmic reticulum and Golgi apparatus in cells. Moreover, confocal microscopy demonstrates that calpain II colocalizes with specific proteins found in these organelles. Additional experiments reveal that hydrophobic rather than electrostatic interactions are responsible for the association of the calpain/calpastatin network with these organelles. Treatment of the organelles with Na2CO3 or deoxycholate reveal that calpain I, 78-kDa calpain II, and the regulatory subunit are "embedded" within the organelle membranes similar to integral membrane proteins. Proteinase K treatment of the organelles shows that calpain I and II, calpastatin, and the regulatory subunit localize to the cytosolic surface of the organelle membranes, and a subset of calpain II and the regulatory subunit are also found within the lumen of these organelles. These results provide a new and novel explanation for how the calpain/calpastatin network is organized in the cell.     

Nerve growth factor-induced decrease in the calpain activity of PC12 cells

PC12 cells are a nerve growth factor-responsive clone derived from a rat pheochromocytoma. Treatment with nerve growth factor causes the cells to differentiate. One of the hallmarks of this differentiation is the generation of neurites. PC12 cells contain both calpain I and calpain II; about 90% of the total calpain activity is due to calpain II. Treatment of the cells with nerve growth factor causes a time-dependent decrease in calpain activity, more than 50% being lost over a 5-day period. Both the decrease in calpain activity and the growth of neurites are reversible upon the removal of nerve growth factor from the cultures. Agents other than nerve growth factor that cause neurite outgrowth, such as fibroblast growth factor and dibutyryl cyclic AMP, also cause a decrease in calpain activity. Calpain levels, as detected with immunoblotting or immunohistochemistry, show no decrease. Removal of calpastatin, the endogenous inhibitor of the calpains, by phenyl-Sepharose chromatography increases the calpain activity of extracts from both control and nerve growth factor-treated cells and brings the activity in the extracts from treated cells up to the activity in those from controls. Calpastatin-containing fractions from extracts of nerve growth factor-treated cells inhibit more calpain activity than do comparable fractions from control cells. These studies suggest that nerve growth factor causes a decrease in the activity of calpain in morphologically differentiating PC12 cells by causing an increase in the activity of calpastatin.     

Calmodulin and protein kinase C antagonists also inhibit the Ca2+-dependent protein protease, calpain I

The calmodulin and C-kinase antagonists melittin, calmidazolium, N-(6-aminohexyl)-5-chloro-1-napthalenesulfonamide (W7), and trifluoperazine (TFP) also inhibit the activity of the human erythrocyte Ca2+-dependent protease, calpain I. W-5, the nonchlorinated derivative of W-7, was ineffective as an inhibitor of calpain I just as it is for calmodulin and protein kinase C. Dose response studies provided the following IC50 values: melittin, 2.6 microM; calmidazolium, 6.2 microM; trifluoperazine, 130 microM; W-7, 251 microM. These IC50 values indicate that the compounds have affinities 10 to 600 fold less for calpain I than for calmodulin; however, the affinities of the inhibitory compounds are comparable for calpain I and protein kinase C. Kinetic analysis indicates that the compounds are competitive inhibitors of calpain I with respect to substrate.