Flexibility analysis and structure comparison of two crystal forms of calcium-free human m-calpain

The calpains form a growing family of structurally related intracellular multidomain cysteine proteinases containing a papain-related catalytic domain, whose activity depends on calcium. The calpains are believed to play important roles in cytoskelatel remodeling processes, cell differentiation, apoptosis and signal transduction, but are also implicated in a number of diseases. Recent crystal structures of truncated rat and full-length human apo-m-calpain revealed the domain arrangement and explained the inactivity of m-calpain in the absence of calcium by a disrupted catalytic domain. Proteolysis studies have indicated several susceptible sites, in particular in the catalytic subdomain IIb and in the following domain III, which are more accessible to attacking proteinases in the presence than in the absence of calcium. The current view is that m-calpain exhibits a number of calcium binding sites, which upon calcium binding cooperatively interact, triggering the reformation of a papain-like catalytic domain, accompanied by enhanced mobilisation of the whole structure. To further analyse the flexibility of m-calpain, we have determined and refined the human full-length apo-m-calpain structure of a second crystal form to 3.15 A resolution. Here we present this new structure, compare it with our first structure now re-refined with tighter constrain parameters, discuss the flexibility in context with the proteolysis and calcium binding data available, and suggest implications for the calcium-induced activation process.     

The calpains: modular designs and functional diversity

The calpain family is named for the calcium dependence of the papain-like, thiol protease activity of the well-studied ubiquitous vertebrate enzymes calpain-1 (μ-calpain) and calpain-2 (m-calpain). Proteins showing sequence relatedness to the catalytic core domains of these enzymes are included in this ancient and diverse eukaryotic protein family. Calpains are examples of highly modular organization, with several varieties of amino-terminal or carboxy-terminal modules flanking a conserved core. Acquisition of the penta-EF-hand module involved in calcium binding (and the formation of heterodimers for some calpains) seems to be a relatively late event in calpain evolution. Several alternative mechanisms for binding calcium and associating with membranes/phospholipids are found throughout the family. The gene family is expanded in mammals, trypanosomes and ciliates, with up to 26 members in Tetrahymena, for example; in striking contrast to this, only a single calpain gene is present in many other protozoa and in plants. The many isoforms of calpain and their multiple splice variants complicate the discussion and analysis of the family, and challenge researchers to ascertain the relationships between calpain gene sequences, protein isoforms and their distinct or overlapping functions. In mammals and plants it is clear that a calpain plays an essential role in development. There is increasing evidence that ubiquitous calpains participate in a variety of signal transduction pathways and function in important cellular processes of life and death. In contrast to relatively promiscuous degradative proteases, calpains cleave only a restricted set of protein substrates and use complex substrate-recognition mechanisms, involving primary and secondary structural features of target proteins. The detailed physiological significance of both proteolytically active calpains and those lacking key catalytic residues requires further study.     

Autolysis of calpain large subunit inducing irreversible dissociation of stoichiometric heterodimer of calpain

Calpain, a calcium dependent cysteine protease, consists of a catalytic large subunit and a regulatory small subunit. Two models have been proposed to explain calpain activation: an autolysis model and a dissociation model. In the autolysis model, the autolyzed form is the active species, which is sensitized to Ca2+. In the dissociation model, dissociated large subunit is the active species. We have reported that the Ca2+ concentration regulates reversible dissociation of subunits. We found further that in chicken micro/m-calpain autolysis of the large subunit induces irreversible dissociation from the small subunit as well as activation. So we could propose a new mechanism for activation of the calpain by combining our findings. Our model insists that autolyzed large subunit remains dissociated from the small subunit even after the removal of Ca2+ to keep it sensitized to Ca2+. This model could be expanded to other calpains and give a new perspective on calpain activation.     

Activation of calpains, calpastatin and spectrin cleavage in the brain during the pathology of fatal murine cerebral malaria

Neuronal calpains appear to be activated uncontrollably by sustained elevation of cytosolic calcium levels under pathological conditions as well as neurodegenerative diseases. In the present study, we have characterized calpain activation in cytosolic extract of mice cerebral cortex and cerebellum using an experimental model of fatal murine cerebral malaria (FMCM). Pathology of FMCM resulted in the increase in activity of calpains in both cerebral cortex and cerebellum. Western blot analysis revealed an increase in the levels of mu-calpain (calpain-1) in the cytosolic fraction of infected cerebral cortex and cerebellum although a decrease in the level of m-calpain was observed in the cytosolic fraction of infected cerebellum and cerebral cortex. Calpain activation was further confirmed by monitoring the formation of calpain-specific spectrin breakdown products (SBDP). Protease-specific SBDP revealed the formation of calpain-generated 150kDa product in the infected cerebral cortex and cerebellum. The specific signature fragment of calpain activation and spectrin breakdown after Plasmodium berghei ANKA infection provide a strong evidence of the role of calpains during the cell death in cerebral cortex and cerebellum. Given the role of calpains in neurodegeneration and cell death, our results strongly suggest that calpains are important mediators of cell injury and neurological sequelae associated with FMCM.     

Calpain specificity and expression in chicken tissues

We have compared ubiquitous calpains in chicken (Gallus gallus), turkey (Meleagris gallopavo) and mammals. In chicken, we studied their distribution in different tissues. The calpain activity was determined by casein zymography, a technique avoiding any prior sample purification, thus limiting any autolysis and denaturation reactions. Our results show that two ubiquitous calpains are present in chicken: (1) a mu-calpain having a greater calcium sensitivity and a lower electrophoretic mobility than the mammalian one, (2) a mu/m-calpain, named like this by Sorimachi et al. [Sorimachi, H., Tsukahara, T., Okada-Ban, M., Sugita, H., Ishiura, S., Suzuki, K., 1995. Identification of a third ubiquitous calpain species-chicken muscle expresses four distinct calpains. Biochim. Biophys. Acta, 1261, 381-93.], having a calcium sensitivity intermediate between that of the two mammalian mu-calpain and the m-calpain. Tissue distribution of the two chicken isozymes vary and mu/m-calpain predominates, whereas mu-calpain levels are very low in some tissues, unlike in mammalian tissues. The characteristics of mu/m-calpain and its preponderance in all organs suggest that it may play a different role in chicken than in mammals.     

Mu-calpain binds to lipid bilayers via the exposed hydrophobic surface of its Ca2+-activated conformation

Mu- and m-calpain are cysteine proteases requiring micro- and millimolar Ca2+ concentrations for their activation in vitro. Among other mechanisms, interaction of calpains with membrane phospholipids has been proposed to facilitate their activation by nanomolar [Ca2+] in living cells. Here the interaction of non-autolysing, C115A active-site mutated heterodimeric human mu-calpain with phospholipid bilayers was studied in vitro using protein-to-lipid fluorescence resonance energy transfer and surface plasmon resonance. Binding to liposomes was Ca2+-dependent, but not selective for specific phospholipid head groups. [Ca2+]0.5 for association with lipid bilayers was not lower than that required for the exposure of hydrophobic surface (detected by TNS fluorescence) or for enzyme activity in the absence of lipids. Deletion of domain V reduced the lipid affinity of the isolated small subunit (600-fold) and of the heterodimer (10- to 15-fold), thus confirming the proposed role of domain V for membrane binding. Unexpectedly, mutations in the acidic loop of the 'C2-like' domain III, a putative Ca2+ and phospholipid-binding site, did not affect lipid affinity. Taken together, these results support the hypothesis that in vitro membrane binding of mu-calpain is due to the exposed hydrophobic surface of the active conformation and does not reduce the Ca2+ requirement for activation.     

Digestion of mu- and m-calpain by trypsin and chymotrypsin

Proteolytic digestion by trypsin and chymotrypsin was used to probe conformation and domain structure of the mu- and m-calpain molecules in the presence and the absence of Ca(2+). Both calpains have a compact structure in the absence of Ca(2+); incubation with either protease for 120 min results in only three or four major fragments. A 24-kDa fragment was produced by removal of the Gly-rich area in domain V of the 28-kDa subunit. The other fragments were from the 80-kDa subunit. Except for trypsin digestion of m-calpain, the region between amino acids 245 and 265 (human sequence) was very susceptible to cleavage by both proteases in the absence of Ca(2+); this region is in domain II (IIb of the crystallographic structure). Although no proteolytically active fragments could be isolated from either tryptic or chymotryptic digests, the calpain molecule can remain assembled in a proteolytically active complex even after the 80-kDa subunit has been completely degraded. The results suggest that interaction among different regions of the entire calpain molecule is required for its full proteolytic activity. In the presence of 1 mM Ca(2+), both calpains are degraded to fragments less than 40-kDa in less than 5 min. The C-terminal ends of both subunits, from amino acids 503 to 506 to the end of the 80-kDa subunit and from amino acids 85 to 88 to the end of the 28-kDa subunit, were resistant to degradation by either protease in the presence or in the absence of Ca(2+). Hence, this part of the calpain molecule is in a compact structure that does not change significantly in the presence of Ca(2+).     

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.     

Domain III of calpain is a ca2+-regulated phospholipid-binding domain

The X-ray structure of m-calpain shows that domain III of the large subunit is structurally related to C2 domains, Ca2+-regulated lipid binding modules in many enzymes. To address whether this structural similarity entails functional analogy, we have characterized recombinant domain III from rat micro- and m-calpain and Drosophila CALPB. In a Ca2+ overlay assay domain III displays a large capacity for Ca2+ binding, commensurable with that of domain IV, the principal Ca2+-binding domain of calpains. The amount of Ca2+ bound to domain III increases 2- to 10-fold upon the addition of liposomes containing 20-40% di- and triphosphoinositides. Conversely, phospholipid-binding in spin-column size-exclusion chromatography is significantly promoted by Ca2+, in a manner similar to known C2 domains. These results suggest that domain III might be the primary lipid binding site of calpain and may play a decisive role in orchestrating Ca2+- and lipid activation of the enzyme.     

The crystal structures of human calpains 1 and 9 imply diverse mechanisms of action and auto-inhibition

Calpains are calcium activated cysteine proteases found throughout the animal, plant, and fungi kingdoms; 14 isoforms have been described in the human genome. Calpains have been implicated in multiple models of human disease; for instance, calpain 1 is activated in the brains of individuals with Alzheimer's disease, and the digestive tract specific calpain 9 is down-regulated in gastric cancer cell lines. We have solved the structures of human calpain 1 and calpain 9 protease cores using crystallographic methods; both structures have clear implications for the function of non-catalytic domains of full-length calpains in the calcium-mediated activation of the enzyme. The structure of minicalpain 1 is similar to previously solved structures of the protease core. Auto-inhibition in this system is most likely through rearrangements of a central helical/loop region near the active site cysteine, which occlude the substrate binding site. However, the structure of minicalpain 9 indicates that auto-inhibition in this enzyme is mediated through large intra-domain movements that misalign the catalytic triad. This disruption is reminiscent of the full-length inactive calpain conformation. The structures of the highly conserved, ubiquitously expressed human calpain 1 and the more tissue specific human calpain 9 indicate that although there are high levels of sequence conservation throughout the calpain family, isolated structures of family members are insufficient to explain the molecular mechanism of activation for this group of proteins.     

Sidekicks: synaptic adhesion molecules that promote lamina-specific connectivity in the retina

Ca(2+) signaling by calpains leads to controlled proteolysis during processes ranging from cytoskeleton remodeling in mammals to sex determination in nematodes. Deregulated Ca(2+) levels result in aberrant proteolysis by calpains, which contributes to tissue damage in heart and brain ischemias as well as neurodegeneration in Alzheimer's disease. Here we show that activation of the protease core of mu calpain requires cooperative binding of two Ca(2+) atoms at two non-EF-hand sites revealed in the 2.1 A crystal structure. Conservation of the Ca(2+) binding residues defines an ancestral general mechanism of activation for most calpain isoforms, including some that lack EF-hand domains. The protease region is not affected by the endogenous inhibitor, calpastatin, and may contribute to calpain-mediated pathologies when the core is released by autoproteolysis.     

Crystal structure of calpain reveals the structural basis for Ca(2+)-dependent protease activity and a novel mode of enzyme activation

The combination of thiol protease activity and calmodulin-like EF-hands is a feature unique to the calpains. The regulatory mechanisms governing calpain activity are complex, and the nature of the Ca(2+)-induced switch between inactive and active forms has remained elusive in the absence of structural information. We describe here the 2.6 A crystal structure of m-calpain in the Ca(2+)-free form, which illustrates the structural basis for the inactivity of calpain in the absence of Ca(2+). It also reveals an unusual thiol protease fold, which is associated with Ca(2+)-binding domains through heterodimerization and a C(2)-like beta-sandwich domain. Strikingly, the structure shows that the catalytic triad is not assembled, indicating that Ca(2+)-binding must induce conformational changes that re-orient the protease domains to form a functional active site. The alpha-helical N-terminal anchor of the catalytic subunit does not occupy the active site but inhibits its assembly and regulates Ca(2+)-sensitivity through association with the regulatory subunit. This Ca(2+)-dependent activation mechanism is clearly distinct from those of classical proteases.     

Ca²+-induced release of mitochondrial m-calpain from outer membrane with binding of calpain small subunit and Grp75

Although mitochondrial μ- and m-calpains play significant roles in apoptotic cell death, their activating mechanisms have not been determined. The purpose of this study was to determine the core factors that are involved in activating mitochondrial outer membrane (OM)-bound calpains. To accomplish this, we solubilized OM-bound calpains and separated them by DEAE-Sepharose column chromatography, and identified them by immunoblots. We also determined the core factors that activated the OM-bound calpains and release them from the OM by calpain assays, immunoprecipitations, and immunoblots. The OM-bound m-calpain large subunit was not associated with the small subunit or with Grp75 chaperone. Free calpain small subunit was located in the IMS and caused the release of the OM-bound m-calpain large subunit from the OM together with Grp75, ATP, and Ca2+. Our results showed that the activating mechanism of mitochondrial OM-bound m-calpain and the release of mitochondrial m-calpain from the OM have important implications in facilitating apoptotic cell death.     

Ca-induced release of mitochondrial m-calpain from outer membrane with binding of calpain small subunit and Grp75

Although mitochondrial μ- and m-calpains play significant roles in apoptotic cell death, their activating mechanisms have not been determined. The purpose of this study was to determine the core factors that are involved in activating mitochondrial outer membrane (OM)-bound calpains. To accomplish this, we solubilized OM-bound calpains and separated them by DEAE-Sepharose column chromatography, and identified them by immunoblots. We also determined the core factors that activated the OM-bound calpains and release them from the OM by calpain assays, immunoprecipitations, and immunoblots. The OM-bound m-calpain large subunit was not associated with the small subunit or with Grp75 chaperone. Free calpain small subunit was located in the IMS and caused the release of the OM-bound m-calpain large subunit from the OM together with Grp75, ATP, and Ca²⁺. Our results showed that the activating mechanism of mitochondrial OM-bound m-calpain and the release of mitochondrial m-calpain from the OM have important implications in facilitating apoptotic cell death.     

m-Calpain colocalizes with the calcium-sensing receptor (CaR) in caveolae in parathyroid cells and participates in degradation of the CaR

The calcium-sensing receptor (CaR) is a G protein-coupled, seven-transmembrane receptor and resides within caveolin-rich membrane domains in bovine parathyroid cells. The proenzyme of calpain 2 (m-calpain) is a heterodimeric calcium-dependent cysteine protease consisting of catalytic and regulatory subunits. The effects of calcium on the enzyme include activation, autolysis, and subunit dissociation. Here, we examine the potential role of caveolin-1 and caveolae in regulating the cellular distribution and function of m-calpain in parathyroid cells. We show that the inactive heterodimeric forms of m-calpain are concentrated in caveolin-rich membrane fractions prepared from parathyroid cells incubated with low extracellular calcium (Ca2+(o)). In contrast, in cells incubated with 3 mm Ca2+(o), which activates the CaR and increases intracellular calcium, there is a reduction in m-calpain in association with an increase in CaR protein and phosphorylated protein kinase C alpha and beta in caveolin-rich fractions. To assess the impact of activation of calpain on CaR protein in caveolar fractions, we analyzed the effects of m-calpain on the CaR. Activation of the CaR with high Ca2+(o) induced the release of lower molecular weight fragments of the receptor into the cell culture medium, and calpain inhibitors blocked this effect. Moreover, the fragments of the CaR as well as caveolin-1, m-calpain, and alkaline phosphatase were localized in membrane vesicles shed by parathyroid cells, supporting the association of these proteins in living cells. Treatment of CaR proteins in vitro with m-calpain also resulted in the appearance of lower molecular weight fragments of the CaR. Our data suggest that localization of m-calpain within caveolae may contribute to maintenance of the enzyme in an inactive state and that m-calpain may also contribute to the regulation of CaR levels.     

Severe Acute Respiratory Syndrome Coronavirus Replication Is Severely Impaired by MG132 due to Proteasome-Independent Inhibition of M-Calpain

The ubiquitin-proteasome system (UPS) is involved in the replication of a broad range of viruses. Since replication of the murine hepatitis virus (MHV) is impaired upon proteasomal inhibition, the relevance of the UPS for the replication of the severe acute respiratory syndrome coronavirus (SARS-CoV) was investigated in this study. We demonstrate that the proteasomal inhibitor MG132 strongly inhibits SARS-CoV replication by interfering with early steps of the viral life cycle. Surprisingly, other proteasomal inhibitors (e.g., lactacystin and bortezomib) only marginally affected viral replication, indicating that the effect of MG132 is independent of proteasomal impairment. Induction of autophagy by MG132 treatment was excluded from playing a role, and no changes in SARS-CoV titers were observed during infection of wild-type or autophagy-deficient ATG5(-/-) mouse embryonic fibroblasts overexpressing the human SARS-CoV receptor, angiotensin-converting enzyme 2 (ACE2). Since MG132 also inhibits the cysteine protease m-calpain, we addressed the role of calpains in the early SARS-CoV life cycle using calpain inhibitors III (MDL28170) and VI (SJA6017). In fact, m-calpain inhibition with MDL28170 resulted in an even more pronounced inhibition of SARS-CoV replication (>7 orders of magnitude) than did MG132. Additional m-calpain knockdown experiments confirmed the dependence of SARS-CoV replication on the activity of the cysteine protease m-calpain. Taken together, we provide strong experimental evidence that SARS-CoV has unique replication requirements which are independent of functional UPS or autophagy pathways compared to other coronaviruses. Additionally, this work highlights an important role for m-calpain during early steps of the SARS-CoV life cycle.     

Proteolysis of nuclear proteins by mu-calpain and m-calpain.

Purified calpains are capable of proteolyzing several high Mr nuclear proteins and solubilizing a histone H1 kinase activity from rat liver nuclei upon exposure to 10(-6) - 10(-5) M Ca2+. Major nuclear substrates displayed apparent molecular masses of 200, 130, 120, and 60 kDa on Coomassie Blue-stained SDS-PAGE gels. The nuclear proteins and the H1 kinase were released from Triton-treated nuclei following incubation with buffer containing 0.5 M NaCl. They therefore appeared to be internal nuclear matrix proteins. The nuclear H1 kinase activity solubilized by incubation with m-calpain was eluted in the void volume of a Bio-Gel A-1.5m column, indicating an apparent mass greater than 1,500 kDa. Treatment of the calpain-solubilized kinase with 0.5 M NaCl dissociated it to a form having an apparent mass of 300 kDa (Stokes radius = 5.6 nm), suggesting that the 300-kDa (Stokes radius = 5.6 nm), nuclei by calpain treatment as a large complex containing other internal matrix proteins. Purified human erythrocyte mu-calpain was capable of proteolyzing the nuclear matrix proteins at 10(-6) M Ca2+. In contrast, human erythrocyte multicatalytic protease complex produced little cleavage of the nuclear proteins. Proteolysis of nuclear proteins by either mu-calpain or m-calpain was inhibited by calpastatin. These experiments suggest a physiologic role for the calpains in the turnover of nuclear proteins.     

Group B Streptococcus induces macrophage apoptosis by calpain activation

Group B Streptococcus (GBS) has developed several strategies to evade immune defenses. We show that GBS induces macrophage (Mphi) membrane permeability defects and apoptosis, prevented by inhibition of calcium influx but not caspases. We analyze the molecular mechanisms of GBS-induced murine Mphi apoptosis. GBS causes a massive intracellular calcium increase, strictly correlated to membrane permeability defects and apoptosis onset. Calcium increase was associated with activation of calcium-dependent protease calpain, demonstrated by casein zymography, alpha-spectrin cleavage to a calpain-specific fragment, fluorogenic calpain-substrate cleavage, and inhibition of these proteolyses by calpain inhibitors targeting the calcium-binding, 3-(4-Iodophenyl)-2-mercapto-(Z)-2-propenoic acid, or active site (four different inhibitors), by calpain small-interfering-RNA (siRNA) and EGTA. GBS-induced Mphi apoptosis was inhibited by all micro- and m-calpain inhibitors used and m-calpain siRNA, but not 3-(5-Fluoro-3-indolyl)-2-mercapto-(Z)-2-propenoic acid (micro-calpain inhibitor) and micro-calpain siRNA indicating that m-calpain plays a central role in apoptosis. Calpain activation is followed by Bax and Bid cleavage, cytochrome c, apoptosis-inducing factor, and endonuclease G release from mitochondria. In GBS-induced apoptosis, cytochrome c did not induce caspase-3 and -7 activation because they and APAF-1 were degraded by calpains. Therefore, apoptosis-inducing factor and endonuclease G seem the main mediators of the calpain-dependent but caspase-independent pathway of GBS-induced apoptosis. Proapoptotic mediator degradations do not occur with nonhemolytic GBS, not inducing Mphi apoptosis. Apoptosis was reduced by Bax siRNA and Bid siRNA suggesting Bax and Bid degradation is apoptosis correlated. This signaling pathway, different from that of most pathogens, could represent a GBS strategy to evade immune defenses.     

The role of autolysis in activity of the Ca2+-dependent proteinases (mu-calpain and m-calpain)

A recent hypothesis suggests that proteolytic activity of the micromolar and millimolar Ca2+-requiring forms of the Ca2+-dependent proteinases (mu- and m-calpain, respectively) is regulated in vivo by their association with a phosphatidylinositol-containing site on the plasma membrane followed by autolysis of the proteinases. Phosphatidylinositol association lowers the Ca2+ concentration needed for autolysis, and autolysis, in turn, lowers the Ca2+ concentration needed for proteolytic activity. To test this hypothesis, we have compared the Ca2+ concentrations needed for autolysis and for proteolytic activity of the calpains both in the presence and the absence of phosphatidylinositol. Bovine skeletal muscle mu-calpain required 40-50 microM Ca2+ for half-maximal rate of proteolysis of a casein substrate, 140-150 microM Ca2+ for half-maximal autolysis in the presence of 80 microM phosphatidylinositol, and 190-210 microM Ca2+ for half-maximal autolysis in the absence of phosphatidylinositol. Consequently, mu-calpain is an active proteinase and does not require autolysis for activation. Bovine skeletal muscle m-calpain required 700-740 microM Ca2+ for half-maximal rate of proteolysis of a casein substrate, 370-400 microM Ca2+ for half-maximal autolysis in the presence of 80 microM phosphatidylinositol, and 740-780 microM Ca2+ for half-maximal autolysis in the absence of phosphatidylinositol. These results are consistent with the idea that m-calpain functions in its autolyzed form, but the results do not demonstrate that unautolyzed m-calpain is inactive. 80 microM phosphatidylinositol had no effect on the Ca2+ requirement of the autolyzed forms of either mu- or m-calpain but lowered the specific activity of mu-calpain to 20% of its activity in the absence of phosphatidylinositol. Of the four forms of the calpains, unautolyzed m-calpain, autolyzed m-calpain, and unautolyzed mu-calpain would not be proteolytically active at the free Ca2+ concentrations of 300-1200 nM present inside normal cells, and neither mu- nor m-calpain would undergo autolysis at these Ca2+ concentrations, even in the presence of phosphatidylinositol. Cells must contain a mechanism other than or in addition to membrane association and autolysis to activate the calpains.