A second binding site revealed by C-terminal truncation of calpain small subunit, a penta-EF-hand protein.

The subunits in calpain and in the related penta-EF-hand (PEF) proteins are bound through contacts between the unpaired EF-hand 5 from each subunit. To study subunit binding further, a tetra-EF-hand 18 kDa N- and C-terminally truncated form of the calpain small subunit was prepared (18k). This protein does not combine with the calpain large subunit to form active calpain, but forms homodimers in solution, as shown by ultracentrifugation. The X-ray structure of the 18k protein in the presence of cadmium was solved to a resolution of 2.0 A. The structure of the monomer is almost identical to the known structure of the calpain small subunit, but the 18k protein forms an oligomer in the crystal by the use of two binding sites. One of these sites is an artefact arising from the C-terminal truncation, but the other is a naturally occurring site that is fully exposed to water in intact purified calpain. The characteristics of this site suggest that it may be important in binding other protein modulators involved in the regulation of calpain and of PEF proteins.

v-Src-induced modulation of the calpain-calpastatin proteolytic system regulates transformation.

v-Src-induced oncogenic transformation is characterized by alterations in cell morphology, adhesion, motility, survival, and proliferation. To further elucidate some of the signaling pathways downstream of v-Src that are responsible for the transformed cell phenotype, we have investigated the role that the calpain-calpastatin proteolytic system plays during oncogenic transformation induced by v-Src. We recently reported that v-Src-induced transformation of chicken embryo fibroblasts is accompanied by calpain-mediated proteolytic cleavage of the focal adhesion kinase (FAK) and disassembly of the focal adhesion complex. In this study we have characterized a positive feedback loop whereby activation of v-Src increases protein synthesis of calpain II, resulting in degradation of its endogenous inhibitor calpastatin. Reconstitution of calpastatin levels by overexpression of exogenous calpastatin suppresses proteolytic cleavage of FAK, morphological transformation, and anchorage-independent growth. Furthermore, calpastatin overexpression represses progression of v-Src-transformed cells through the G(1) stage of the cell cycle, which correlates with decreased pRb phosphorylation and decreased levels of cyclins A and D and cyclin-dependent kinase 2. Calpain 4 knockout fibroblasts also exhibit impaired v-Src-induced morphological transformation and anchorage-independent growth. Thus, modulation of the calpain-calpastatin proteolytic system plays an important role in focal adhesion disassembly, morphological transformation, and cell cycle progression during v-Src-induced cell transformation.

Reduced cell migration and disruption of the actin cytoskeleton in calpain-deficient embryonic fibroblasts.

The physiological functions and substrates of the calcium-dependent protease calpain remain only partly understood. The mu- and m-calpains consist of a mu- or m-80-kDa large subunit (genes Capn1 and Capn2), and a common 28-kDa small subunit (Capn4). To assess the role of calpain in migration, we used fibroblasts obtained from Capn4(-/-) mouse embryos. The cells lacked calpain activity on casein zymography and did not generate the characteristic calpain-generated spectrin breakdown product that is observed in wild-type cells. Capn4(-/-) cells had decreased migration rates and abnormal organization of the actin cytoskeleton with a loss of central stress fibers. Interestingly, these cells extended numerous thin projections and displayed delayed retraction of membrane protrusions and filopodia. The number of focal adhesions was decreased in Capn4(-/-) cells, but the cells had prominent vinculin-containing focal complexes at the cell periphery. The levels of the focal adhesion proteins, alpha-actinin, focal adhesion kinase (FAK), spectrin, talin, and vinculin, were the same in Capn4(+/+) and Capn4(-/-) cells. FAK, alpha-actinin, and vinculin were not cleaved in either cell type plated on fibronectin. However, proteolysis of the focal complex component, talin, was detected in the wild-type cells but not in the Capn4(-/-) cells, suggesting that calpain cleavage of talin is important during cell migration. Moreover, talin cleavage was again observed when calpain activity was partially restored in Capn4(-/-) embryonic fibroblasts by stable transfection with a vector expressing the rat 28-kDa calpain small subunit. The results demonstrate unequivocally that calpain is a critical regulator of cell migration and of the organization of the actin cytoskeleton and focal adhesions.

Dissociation and aggregation of calpain in the presence of calcium.

Calpain is a heterodimeric Ca(2+)-dependent cysteine protease consisting of a large (80 kDa) catalytic subunit and a small (28 kDa) regulatory subunit. The effects of Ca(2+) on the enzyme include activation, aggregation, and autolysis. They may also include subunit dissociation, which has been the subject of some debate. Using the inactive C105S-80k/21k form of calpain to eliminate autolysis, we have studied its disassociation and aggregation in the presence of Ca(2+) and the inhibition of its aggregation by means of crystallization, light scattering, and sedimentation. Aggregation, as assessed by light scattering, depended on the ionic strength and pH of the buffer, on the Ca(2+) concentration, and on the presence or absence of calpastatin. At low ionic strength, calpain aggregated rapidly in the presence of Ca(2+), but this was fully reversible by EDTA. With Ca(2+) in 0.2 m NaCl, no aggregation was visible but ultracentrifugation showed that a mixture of soluble high molecular weight complexes was present. Calpastatin prevented aggregation, leading instead to the formation of a calpastatin-calpain complex. Crystallization in the presence of Ca(2+) gave rise to crystals mixed with an amorphous precipitate. The crystals contained only the small subunit, thereby demonstrating subunit dissociation, and the precipitate was highly enriched in the large subunit. Reversible dissociation in the presence of Ca(2+) was also unequivocally demonstrated by the exchange of slightly different small subunits between mu-calpain and m-calpain. We conclude that subunit dissociation is a dynamic process and is not complete in most buffer conditions unless driven by factors such as crystal formation or autolysis of active enzymes. Exposure of the hydrophobic dimerization surface following subunit dissociation may be the main factor responsible for Ca(2+)-induced aggregation of calpain. It is likely that dissociation serves as an early step in calpain activation by releasing the constraints upon protease domain I.

Ca(2+)-induced structural changes in rat m-calpain revealed by partial proteolysis.

Partial proteolysis by exogenous proteases in the presence and absence of Ca(2+) was used to map the protease-resistant domains in m-calpain, and to obtain evidence for the conformational changes induced in this thiol protease by Ca(2+). The complication of autoproteolysis was avoided by using the inactive Cys105Ser calpain mutant. Both trypsin and chymotrypsin produced similar cleavage patterns from the large subunit (domains I-IV), while the small subunit (domain VI) was largely unaffected. N-Terminal sequencing of the major products showed that hydrolysis occurred in the N-terminal anchor peptide, which binds domain I to domain VI, at a site close to the C terminus of domain II, and at several sites within domain III. Of particular importance to the overall Ca(2+)-induced conformational changes was the increase in mobility and accessibility of domain III. The same sites were cleaved in the presence and absence of Ca(2+), but with one exception digestion was much more rapid in the presence of Ca(2+). The exception was a site close to residue 255 located within the active site cleft. This site was accessible to cleavage in the absence of Ca(2+), when the active site is not assembled, but was protected in the presence of Ca(2+). This result supports the hypothesis that Ca(2+) induces movement of domains I and II closer together to form the functional active site of calpain.

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.

Calpain mutants with increased Ca2+ sensitivity and implications for the role of the C(2)-like domain.

The ubiquitous calpain isoforms (mu- and m-calpain) are Ca(2+)-dependent cysteine proteases that require surprisingly high Ca(2+) concentrations for activation in vitro ( approximately 50 and approximately 300 microm, respectively). The molecular basis of such a high requirement for Ca(2+) in vitro is not known. In this study, we substantially reduced the concentration of Ca(2+) required for the activation of m-calpain in vitro through the specific disruption of interdomain interactions by structure-guided site-directed mutagenesis. Several interdomain electrostatic interactions involving lysine residues in domain II and acidic residues in the C(2)-like domain III were disrupted, and the effects of these mutations on activity and Ca(2+) sensitivity were analyzed. The mutation to serine of Glu-504, a residue that is conserved in both mu- and m-calpain and interacts most notably with Lys-234, reduced the in vitro Ca(2+) requirement for activity by almost 50%. The mutation of Lys-234 to serine or glutamic acid resulted in a similar reduction. These are the first reported cases in which point mutations have been able to reduce the Ca(2+) requirement of calpain. The structures of the mutants in the absence of Ca(2+) were shown by x-ray crystallography to be unchanged from the wild type, demonstrating that the increase in Ca(2+) sensitivity was not attributable to conformational change prior to activation. The conservation of sequence between mu-calpain, m-calpain, and calpain 3 in this region suggests that the results can be extended to all of these isoforms. Whereas the primary Ca(2+) binding is assumed to occur at EF-hands in domains IV and VI, these results show that domain II-domain III salt bridges are important in the process of the Ca(2+)-induced activation of calpain and that they influence the overall Ca(2+) requirement of the enzyme.

Roles of individual EF-hands in the activation of m-calpain by calcium.

m-Calpain is a heterodimeric, cytosolic, thiol protease, which is activated by Ca(2+)-binding to EF-hands in the C-terminal domains of both subunits. There are four potential Ca(2+)-binding EF-hands in each subunit, but their relative affinities for Ca(2+) are not known. In the present study mutations were made in both subunits to reduce the Ca(2+)-binding affinity at one or more EF-hands in one or both subunits. X-ray crystallography of some of the mutated small subunits showed that Ca(2+) did not bind to the mutated EF-hands, but that its binding at other sites was not affected. The structures of the mutant small subunits in the presence of Ca(2+) were otherwise identical to that of the Ca(2+)-bound wild-type small subunit. In the whole enzyme the wild-type macroscopic Ca(2+) requirement (K(d)) was approx. 350 microM. The mutations did not affect the maximum specific activity of the enzyme, but caused increases in K(d), which were characteristic of each site. All the EF-hands could be mutated in various combinations without loss of activity, but preservation of at least one wild-type EF-hand 3 sequence was required to maintain K(d) values lower than 1 mM. The results suggest that all the EF-hands can contribute co-operatively to calpain activation, but that EF-hand 3, in both subunits, has the highest intrinsic affinity for Ca(2+) and provides the major driving force for conformational change.

Disruption of the murine calpain small subunit gene, Capn4: calpain is essential for embryonic development but not for cell growth and division.

Calpains are a family of Ca(2+)-dependent intracellular cysteine proteases, including the ubiquitously expressed micro- and m-calpains. Both mu- and m-calpains are heterodimers, consisting of a distinct large 80-kDa catalytic subunit, encoded by the genes Capn1 and Capn2, and a common small 28-kDa regulatory subunit (Capn4). The physiological roles and possible functional distinctions of mu- and m-calpains remain unclear, but suggested functions include participation in cell division and migration, integrin-mediated signal transduction, apoptosis, and regulation of cellular control proteins such as cyclin D1 and p53. Homozygous disruption of murine Capn4 eliminated both mu- and m-calpain activities, but this did not affect survival and proliferation of cultured embryonic stem cells or embryonic fibroblasts, or the early stages of organogenesis. However, mutant embryos died at midgestation and displayed defects in the cardiovascular system, hemorrhaging, and accumulation of erythroid progenitors.

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.

Crystallization and X-ray crystallographic analysis of m-calpain, a Ca2+-dependent protease.

The absolute requirement of Ca(2+) for proteolytic activity is a feature unique to the calpains, a family of heterodimeric cysteine proteases. Conditions are described which give rise to diffraction-quality crystals of m-calpain in two crystal forms, P1 and P2(1). Data have been collected from native crystals of m-calpain in both P1 and P2(1) forms, to 2.6 and 2.15 A, respectively. Selenomethionine-containing crystals have been grown in both forms, and anomalous data from the P2(1) selenomethionine enzyme provided the location of 17 of the 19 Se atoms in the protein.

m-Calpain subunits remain associated in the presence of calcium.

The hypothesis that calpain subunits dissociate in the presence of Ca2+ has been tested by methods which avoid interference by Ca2+-induced aggregation and large subunit autolysis. Inactive Cys105Ser-m-calpain, bound either to Ni-NTA-agarose or to immobilized casein, after incubation with Ca2+, could be recovered in high yield as a heterodimer. Natural bovine m-calpain, after irreversible inhibition with Z-LLY-CHN2, also bound to immobilized casein and was eluted as a heterodimer. The Ca2+ requirements of calpain containing a small subunit with EF-hand mutations were higher, both before and after autolysis, than those of wild-type calpain. In mixtures of wild-type and mutant enzymes, subunit exchange did not occur in the presence of Ca2+. The results demonstrate that the subunits in both natural and recombinant m-calpain, in the given experimental conditions, remain associated in the presence of Ca2+ both before and after autolysis.

Structure of the mouse calpain small subunit gene.

The calpains comprise a family of heterodimeric (80+28 kDa) Ca2+-dependent cysteine proteases, probably having roles in signal transduction and cytoskeletal remodelling. We describe cloning and sequencing of the 28 kDa calpain subunit cDNA from mouse (coding for 268 amino acids), and characterization of its gene. The gene spans 7 kb and contains 11 exons. The promoter region, like those of other calpain genes, lacks an obvious TATA box, but contains several Sp1 binding sites.

Evidence for the participation of the proteasome and calpain in early phases of muscle cell differentiation.

Objectives were to investigate the role of the proteasome and m-calpain to muscle cell differentiation. Accordingly, we investigated the effects of lactacystin, a proteasome inhibitor, and calpain inhibitor-II (CI-II) on L8 muscle cell differentiation and assessed concentrations of proteasomal and calpain subunit mRNAs during differentiation. L8 myoblasts were induced to differentiate by culturing in mitogen-depleted medium. To assess the importance of the proteasome and calpain to differentiation, we examined effects of lactacystin and CI-II on creatine kinase (CK) activity. In the absence of inhibitor, CK activity was detectable within 48 h of mitogen depletion and myotubes were formed. Addition of lactacystin or CI-II to cultures drastically reduced CK activity and prevented formation of myotubes. Hence, proteasome and calpain are both necessary for differentiation. In order to identify which proteasomal subunits were regulated during differentiation, we examined the concentrations of two 20S core subunits (C8 and C9) and three 22S ATPases (MSS1, S4 and TBP1) during differentiation. Concentrations of m-calpain and beta-tubulin mRNAs were also assessed. Differentiation was associated with slight increases (ca. 30%) in concentrations of mRNAs encoding the proteasomal 20S core subunits (C8 and C9) and with large increases (approximately 2-fold) in mRNAs encoding the regulatory subunit ATPases. m-calpain mRNA concentration also increased two-fold following mitogen depletion. beta-Tubulin mRNA concentration remained unchanged early in the differentiation process and thereafter declined. Of interest, changes in proteasomal and m-calpain mRNAs occurred within 6-24 h of mitogen depletion (i.e., at least 24-36 h prior to detectable changes in creatine kinase activity). These results indicate that changes in expression of proteasome and calpains subunits occur early in the differentiation process. These changes may be required for the normal course of differentiation to proceed. Differentiation is associated with larger changes in proteasomal ATPase mRNAs than in 20S core particle mRNAs indicating that either turnover rates of the 22S ATPase subunits are more rapid in differentiating cells than of the 20S core particles or that functions of the regulatory subunits become more important during muscle cell differentiation.

Calpain activation is upstream of caspases in radiation-induced apoptosis.

The molecular events involved in apoptosis induced by ionizing radiation remain unresolved. In this paper we show that the cleavage of fodrin to a 150 kDa fragment is an early proteolytic event in radiation-induced apoptosis in the Burkitts' Lymphoma cell line BL30A and requires 100 microM zVAD-fmk for inhibition. Caspases-1, -3, -6 and -7 were shown to cleave fodrin to the 150 kDa fragment in vitro and all were inhibited by 10 microM zVAD-fmk. We also show that the in vitro cleavage of fodrin by calpain is inhibited by 100 microM zVAD-fmk as was the calpain-mediated hydrolysis of casein. We demonstrate that calpain is activated within 15 min after radiation exposure, concomitant with the cleavage of fodrin to the 150 kDa fragment whereas caspase-3 is activated at 2 h correlating with the cleavage of fodrin to the 120 kDa fragment. These results support a role for calpain in the early phases of the radiation-induced apoptosis pathway, upstream of the caspases.

The effects of truncations of the small subunit on m-calpain activity and heterodimer formation.

In order to study subunit interactions in calpain, the effects of small subunit truncations on m-calpain activity and heterodimer formation have been measured. It has been shown previously that active calpain is formed by co-expression of the large subunit (80 kDa) of rat m-calpain with a delta 86 form (21 kDa) of the small subunit. cDNA for the full-length 270 amino acid (28.5 kDa) rat calpain small subunit has now been cloned, both with and without an N-terminal histidine tag (NHis10). The full-length small subunit constructs yielded active calpains on co-expression with the large subunit, and the small subunit was autolysed to 20 kDa on exposure of these calpains to Ca2+. A series of deletion mutants of the small subunit, NHis10-delta 86, -delta 99, -delta 107, and -delta 116, gave active heterodimeric calpains with unchanged specific activities, although in decreasing yield, and with a progressive decrease in stability. NHis10-delta 125 formed a heterodimer which was inactive and unstable. Removal of 25 C-terminal residues from delta 86, leaving residues 87-245, abolished both activity and heterodimer formation. The results show that: (a) generation of active m-calpain in Escherichia coli requires heterodimer formation; (b) small subunit residues between 94 and 116 contribute to the stability of the active heterodimer but do not directly affect the catalytic mechanism; (c) residues in the region 245-270 are essential for subunit binding. Finally, it was shown that an inactive mutant Cys103-->Ser-80k/delta 86 calpain, used in order to preclude autolysis, did not dissociate in the presence of Ca2+, a result which does not support the proposal that Ca(2+)-induced dissociation is involved in calpain activation.

Structure of a calpain Ca(2+)-binding domain reveals a novel EF-hand and Ca(2+)-induced conformational changes.

The crystal structure of a Ca(2+)-binding domain (dVI) of rat m-calpain has been determined at 2.3 A resolution, both with and without bound Ca2+. The structures reveal a unique fold incorporating five EF-hand motifs per monomer, three of which bind calcium at physiological calcium concentrations, with one showing a novel EF-hand coordination pattern. This investigation gives us a first view of the calcium-induced conformational changes, and consequently an insight into the mechanism of calcium induced activation in calpain. The crystal structures reveal a dVI homodimer which provides a preliminary model for the subunit dimerization in calpain.

Autolysis, Ca2+ requirement, and heterodimer stability in m-calpain.

The roles of N-terminal autolysis of the large (80 kDa) and small (28 kDa) subunits in activation of rat m-calpain, in lowering its Ca2+ requirement, and in reducing its stability have been investigated with heterodimeric recombinant calpains containing modified subunits. Both autolysis and [Ca2+]0.5 were influenced by the ionic strength of the buffers, which accounts for the wide variations in previous reports. Autolysis of the small subunit (from 28 to 20 kDa) was complete within 1 min but did not alter either the Ca2+ requirement ([Ca2+]0.5) or the stability of the enzyme. Autolysis of the NHis10-80k large subunit at Ala9-Lys10 is visible on gels, was complete within 1 min, and caused a drop in [Ca2+]0.5 from 364 to 187 microM. The lower value of [Ca2+]0.5 is therefore a property of the Delta9-80k large subunit. Autolysis at Ala9-Lys10 of the unmodified 80-kDa large subunit is not detectable on gels but was assayed by means of the fall in [Ca2+]0.5. This autolysis was complete in 3.5 min and was inhibited by high [NaCl]. The autolysis product of these calpains, which is essentially identical to that of natural m-calpain, was unstable in buffers of high ionic strength. Calpain in which the large subunit autolysis site had been mutated was fully active but did not undergo a drop in [Ca2+]0.5, showing that m-calpain is active prior to autolysis. The main physiological importance of autolysis of calpain is probably to generate an active but unstable enzyme, thus limiting the in vivo duration of calpain activity.