Multiple molecular interactions implicate the connectin/titin N2A region as a modulating scaffold for p94/calpain 3 activity in skeletal muscle

p94/calpain 3 is a skeletal muscle-specific Ca(2+)-regulated cysteine protease (calpain), and genetic loss of p94 protease activity causes muscular dystrophy (calpainopathy). In addition, a small in-frame deletion in the N2A region of connectin/titin that impairs p94-connectin interaction causes a severe muscular dystrophy (mdm) in mice. Since p94 via its interaction with the N2A and M-line regions of connectin becomes part of the connectin filament system that serves as a molecular scaffold for the myofibril, it has been proposed that structural and functional integrity of the p94-connectin complex is essential for health and maintenance of myocytes. In this study, we have surveyed the interactions made by p94 and connectin N2A inside COS7 cells. This revealed that p94 binds to connectin at multiple sites, including newly identified loci in the N2A and PEVK regions of connectin. Functionally, p94-N2A interactions suppress p94 autolysis and protected connectin from proteolysis. The connectin N2A region also contains a binding site for the muscle ankyrin repeat proteins (MARPs), a protein family involved in the cellular stress responses. MARP2/Ankrd2 competed with p94 for binding to connectin and was also proteolyzed by p94. Intriguingly, a connectin N2A fragment with the mdm deletion possessed enhanced resistance to proteases, including p94, and its interaction with MARPs was weakened. Our data support a model in which MARP2-p94 signaling converges within the N2A connectin segment and the mdm deletion disrupts their coordination. These results also implicate the dynamic nature of connectin molecule as a regulatory scaffold of p94 functions.     

The importance of conserved amino acid residues in p94 protease sub-domain IIb and the IS2 region for constitutive autolysis

p94/calpain 3, a skeletal muscle-specific member of calpain protease family, is characterized by apparent Ca(2+)-independence during exhaustive autolysis and concomitant proteolysis of non-self substrates. The purpose of our study was to comprehensively profile the structural basis of p94 enabling activation in the cytosol without an extra Ca(2+). Ca(2+)-dependent p94 mutants were screened using "p94-trapping", which is an application of yeast genetic reporter system called "proteinase-trapping". Several amino acids were revealed as critical for apparent Ca(2+)-independent p94 activity. These results highlight the importance of conserved amino acids in domain IIb as well as in the p94-specific IS2 region.     

Possible regulation of the conventional calpain system by skeletal muscle-specific calpain, p94/calpain 3

p94 (also called calpain 3) is the skeletal muscle-specific calpain and is considered to be a "modulator protease" in various cellular processes. Analysis of p94 at the protein level is an urgent issue because the loss of p94 protease activity causes limb-girdle muscular dystrophy type 2A. In this study, we enzymatically characterized one alternatively spliced variant of p94, p94:exons 6(-)15(-)16(-) (p94delta), which lacks two of the p94-specific insertion sequences. In contrast to p94, which has hardly been studied enzymatically due to its rapid, thorough, and apparently Ca(2+)-independent autolytic activity, p94delta was stably expressed in COS and insect cells. p94delta showed Ca(2+)-dependent caseinolytic and autolytic activities and an inhibitor spectrum similar to those of the conventional calpains. However, calpastatin did not inhibit p94delta and is a substrate for p94delta, which is consistent with the properties of p94, presenting p94 as a possible regulator of the conventional calpain system. We also established a semi-quantitative fluorescence resonance energy transfer assay using the calpastatin sequence specifically to measure p94 activity. This method detects the activity of COS-expressed p94 and p94delta, suggesting that it has potential to evaluate p94 activity in vivo and in the diagnosis of limb-girdle muscular dystrophy type 2A.     

Ca2+ dependency of calpain 3 (p94) activation

Calpain 3, commonly called p94 in the literature, is the abundant skeletal muscle-specific calpain that is genetically linked to limb girdle muscular dystrophy type 2A. Recently, we showed that p94's insertion sequence 1 (IS1) is a propeptide that must be autoproteolytically cleaved to provide access of substrates and inhibitors to the enzyme's active site. Removal of IS1 from the core of p94 by recombinant methods produced a fully active enzyme. Here we have resolved the discrepancies in the literature about the Ca(2+) requirement of p94 using the protease core. Even at substoichiometric levels of Ca(2+), and in competition with EDTA, autoproteolyzed enzyme slowly accumulated. Because the initial autoproteolytic cleavage is an intramolecular reaction, transient binding of two Ca(2+) ions to the core would be sufficient to promote the reaction that is facilitated by having the scissile peptide lying close to the active site cysteine. The second autolytic cleavage was much slower and required higher Ca(2+) levels, consistent with it being an intermolecular reaction. Other metal ions such as Na(+), K(+), and Mg(2+) cannot substitute for Ca(2+) in catalyzing the intramolecular autoproteolysis of the p94 core or in the subsequent hydrolysis of exogenous substrates. These metal ions increase moderately the activity of this enzyme but only at very high concentrations. Thus, the proteolytic activity of the core of p94 and its deletion mutant lacking NS and IS1 was shown to be strictly Ca(2+)-dependent. We propose a two-stage model of activation of the proteolytic core of p94.     

Heterogeneous nuclear ribonucleoprotein K interacts with and is proteolyzed by calpain in vivo

Calpain is a cytosolic "modulator protease" that modulates cellular functions in response to Ca2+. To identify in vivo substrates of calpain, yeast two-hybrid screening was done using the 5-EF-hand (penta-EF-hand; PEF) domain of the micro-calpain large subunit (domain IV), since several possible in vivo substrates for calpain have been previously reported to bind to the 5-EF-hand domains. Other than the regulatory subunit of calpain, which binds to the domain IV, heterogeneous nuclear ribonucleoproteins (hnRNP) K and R were identified, and shown to be proteolyzed by micro-calpain in vitro. When expressed in COS7 cells, hnRNP K and micro-calpain co-localized in the cytosol, and Ca2+-ionophore stimulation of the cells resulted in proteolysis of hnRNP K, indicating that hnRNP K is an in vivo substrate for calpain. Now, hnRNP K is considered to function as a scaffold protein for its binding proteins, such as PKCdelta and C/EBPbeta, which were reported to be calpain substrates, suggesting that hnRNP-K is a scaffold for calpain to proteolyze these proteins.     

Expression, partial purification and functional properties of themuscle-specific calpain isoform p94.

The muscle-specific calpain isoform p94 has high propensity to autocatalytic degradation, thus no significant amounts of the intact active protein have been available so far. As a result, aspects like its regulation (via Ca2+ and other factors) and its intracellular localization are unknown or obscure. In this work, large amounts of human p94 have been produced in insect cells using a recombinant baculovirus expression system. Although most of the protease was recovered in an insoluble and catalytically inactive form, the soluble fraction contained amounts of intact active p94 adequate for its characterization. His-tagged recombinant p94, obtained by the same expression system, was partially purified as an active product. Both the unmodified and the partially purified His-tagged p94 bound calcium with high affinity, and their autolytic activity required Ca2+. The sensitivity of the catalytic activity of the recombinant protease to Ca2+ was very high. In fact, p94 in soluble cell extracts autolysed to a significant extent even in the presence of submicromolar Ca2+ levels. Thus, in analogy to what demonstrated for the ubiquitous m- and micro-calpain isoforms, intracellular Ca2+ might be one of the factors controlling the activity of this muscle-specific calpain isoform.     

Insertion sequence 1 of muscle-specific calpain, p94, acts as an internal propeptide

The physiological role of the skeletal muscle-specific calpain 3, p94, is presently unknown, but defects in its gene cause limb girdle muscular dystrophy type 2A. This calcium-dependent cysteine protease resembles the large subunit of m-calpain but with three unique additional sequences: an N-terminal region (NS), and two insertions (IS1 and IS2). The latter two insertions have been linked to the chronic instability of the whole enzyme both in vivo and in vitro. We have shown previously that the core of p94 comprising NS, domains I and II, and IS1 is stable as a recombinant protein in the absence of Ca(2+) and undergoes autolysis in its presence. Here we show that p94I-II cannot hydrolyze an exogenous substrate before autolysis but is increasingly able to do so when autolysis proceeds for several hours. This gain in activity is caused by cleavage of IS1 during autolysis because a deletion mutant lacking the NS region (p94I-II DeltaNS) shows the same activation profile. Similarly, the calpain inhibitors E-64 and leupeptin have almost no inhibitory effect on substrate hydrolysis by p94I-II soon after calcium addition but cause complete inhibition when autolysis progresses for several hours. As autolysis proceeds, there is release of the internal IS1 peptide, but the two portions of the core remain tightly associated. Modeling of p94I-II suggests that IS1 contains an amphipathic alpha-helix flanked by extended loops. The latter are the targets of autolysis and limited digestion by exogenous proteases. The presence and location of the alpha-helix in recombinant IS1 were confirmed by circular dichroism and by the introduction of a L286P helix-disrupting mutation. Within p94I-II, L286P caused premature autoproteolysis of the enzyme. IS1 is an elaboration of a loop in domain II near the active site, and it acts as an internal autoinhibitory propeptide, blocking the active site of p94 from substrates and inhibitors.     

Newly identified exons encoding novel variants of p94/calpain 3 are expressed ubiquitously and overlap the alpha-glucosidase C gene

There are two classes of an intracellular 'modulator protease', calpain: ubiquitous and tissue-specific. p94/calpain 3 is an example of the latter, predominantly expressed in muscle. A defect in the p94 gene causes muscular dystrophy. Here we report that human and mouse p94 genes have a possible novel alternative promoter expressing p94 variants in all tissues examined including human lens epithelial cells. The possible promoter region and the following novel exons overlap the 3' region of the neutral alpha-glucosidase C gene. Unlike p94, the novel p94 variants expressed in COS7 cells do not undergo rapid autolysis, suggesting basic functions different from p94.     

Involvement of the glucose-regulated protein 94 (Dd-GRP94) in starvation response of Dictyostelium discoideum cells

Upon deprivation of nutrients, Dictyostelium discoideum Ax-2 cells arrest proliferation and initiate a metamorphosed developmental program including induction of altered gene expressions which are necessary for differentiation. In Ax-2 cells, we found out a member of Hsp90 family usually contained in the endoplasmic reticulum (ER), Dd-GRP94 (Dictyostelium discoideum glucose-regulated protein 94). In general, GRP94 are induced either by glucose-depletion or by depletion of Ca(2+) in intracellular Ca(2+) stores. Unexpectedly, however, the expression of Dd-grp94 was greatly reduced within 60 min of starvation. Dd-grp94-overexpressing cells (GRP94(OE) cells) collected without forming distinct aggregation streams, and never formed normal fruiting bodies. Also, prespore differentiation as well as maturation into spores and stalk cells were particularly impaired in the GRP94(OE) cells. Thus Dd-GRP94 seems to be crucial in late differentiation as well as in starvation response.     

Calpain-mediated cleavage of the cyclin-dependent kinase-5 activator p39 to p29.

The activity of cyclin-dependent kinase-5 (Cdk5) is tightly regulated by binding of its neuronal activators p35 and p39. Upon neurotoxic insults, p35 is cleaved to p25 by the Ca(2+)-dependent protease calpain. p25 is accumulated in ischemic brains and in brains of patients with Alzheimer's disease. p25 deregulates Cdk5 activity by causing prolonged activation and mislocalization of Cdk5. It is unknown whether p39, which is expressed throughout the adult rat brain, is cleaved by calpain, and whether this contributes to deregulation of Cdk5. Here, we show that calpain cleaved p39 in vitro, resulting in generation of a C-terminal p29 fragment. In vivo, p29 was generated in ischemic brain concomitant with increased calpain activity. In fresh brain lysates, generation of p29 was Ca(2+)-dependent, and calpain inhibitors abolished p29 production. The Ca(2+) ionophore ionomycin and the excitotoxin glutamate induced production of p29 in cultures of cortical neurons in a calpain-dependent manner. Like p25, p29 was more stable than p39 and caused redistribution of Cdk5 in cortical neurons. Our data suggest that neurotoxic insults lead to calpain-mediated conversion of p39 to p29, which might contribute to deregulation of Cdk5.     

The endoplasmic reticulum chaperone glycoprotein GRP94 with Ca(2+)-binding and antiapoptotic properties is a novel proteolytic target of calpain during etoposide-induced apoptosis.

GRP94 is a 94-kDa chaperone glycoprotein with Ca(2+)-binding properties. We report here that during apoptosis induced by the topoisomerase II inhibitor etoposide, a fraction of GRP94 associated with the endoplasmic reticulum membrane undergoes specific proteolytic cleavage, coinciding with the activation of the caspase CPP32 and initiation of DNA fragmentation. In vivo, inhibitors of caspases able to block etoposide-induced apoptosis can only partially protect GRP94 from proteolytic cleavage, whereas complete inhibition is observed with calpain inhibitor I but not with the proteasome inhibitor. In vitro, GRP94 is not a substrate for CPP32; rather, it can be completely cleaved by calpain, a Ca(2+)-regulated protease. The cleavage of GRP94 by calpain is Ca(2+)-dependent and generates a discrete polypeptide of 80 kDa. In contrast, calpain has no effect on other stress proteins such as GRP78 or HSP70. Further, immunohistochemical staining reveals specific co-localization of GRP94 with calpain in the perinuclear region following etoposide treatment. We further showed that reduction of GRP94 by antisense decreased cell viability in etoposide-treated Jurkat cells. Our studies provide new evidence that the cytoprotective GRP94, as in the case of the antiapoptotic protein Bcl-2, can be targets of proteolytic cleavage themselves during the apoptotic process.     

Sequence comparison among muscle-specific calpain, p94, and calpain subunits.

While conventional calpains, m- and mu-calpains named according to their calcium-dependence, are expressed in almost every tissues, mRNA of newly identified p94, which has a significant sequence similarity to the conventional calpain large subunits, is abundantly expressed only in skeletal muscle. In addition to this specific expression, p94 is distinct from conventional calpains in that it contains three unique regions showing no similarity to conventional calpain subunits. When rat and human p94 are compared, overall sequence similarity is 94.0%, which is close to those for m- and mu-calpain large subunits; 93.1% and 95.4% between human and rabbit, respectively, suggesting the evolutionary importance of p94. These calpain large subunit proteins, p94, m- and mu-types, can be considered to constitute a super family, whose p94, m- and mu-types represent the three major types. Sequences of the calpain large-subunit family members, including the recently reported Schistosoma calpain, are compared. Their evolutionary correlation and function are discussed on the basis of the results thus far obtained.     

Heterogeneous Nuclear Ribonucleoprotein K Interacts with and Is Proteolyzed by Calpain in vivo

Calpain is a cytosolic “modulator protease” that modulates cellular functions in response to Ca²⁺. To identify in vivo substrates of calpain, yeast two-hybrid screening was done using the 5-EF-hand (penta-EF-hand; PEF) domain of the μ-calpain large subunit (domain IV), since several possible in vivo substrates for calpain have been previously reported to bind to the 5-EF-hand domains. Other than the regulatory subunit of calpain, which binds to the domain IV, heterogeneous nuclear ribonucleoproteins (hnRNP) K and R were identified, and shown to be proteolyzed by μ-calpain in vitro. When expressed in COS7 cells, hnRNP K and μ-calpain co-localized in the cytosol, and Ca²⁺-ionophore stimulation of the cells resulted in proteolysis of hnRNP K, indicating that hnRNP K is an in vivo substrate for calpain. Now, hnRNP K is considered to function as a scaffold protein for its binding proteins, such as PKCδ and C/EBPβ, which were reported to be calpain substrates, suggesting that hnRNP-K is a scaffold for calpain to proteolyze these proteins.     

Calpain-dependent proteolytic cleavage of the p35 cyclin-dependent kinase 5 activator to p25

Cyclin-dependent kinase 5 (CDK5) is a unique CDK, the activity of which can be detected in postmitotic neurons. To date, CDK5 purified from mammalian brains has always been associated with a truncated form of the 35-kDa major brain specific activator (p35, also known as nck5a) of CDK5, known as p25. In this study, we report that p35 can be cleaved to p25 both in vitro and in vivo by calpain. In a rat brain extract, p35 was cleaved to p25 by incubation with Ca(2+). This cleavage was inhibited by a calpain inhibitor peptide derived from calpastatin and was ablated by separating the p35.CDK5 from calpain by centrifugation. The p35 recovered in the pellet after centrifugation could then be cleaved to p25 by purified calpain. Cleavage of p35 was also induced in primary cultured neurons by treatment with a Ca(2+) ionophore and Ca(2+) and inhibited by calpain inhibitor I. The cleavage changed the solubility of the CDK5 active complex from the particulate fraction to the soluble fraction but did not affect the histone H1 kinase activity. Increased cleavage was detected in cultured neurons undergoing cell death, suggesting a role of the cleavage in neuronal cell death.     

Stomach-specific calpain, nCL-2, localizes in mucus cells and proteolyzes the beta-subunit of coatomer complex, beta-COP

Calpain is a Ca2+-regulated cytosolic protease. Mammals have 14 calpain genes, half of which are predominantly expressed in specific organ(s); the rest are expressed ubiquitously. A defect in calpains causes lethality/pathogenicity, indicating their physiological indispensability. nCL-2/calpain-8a was identified as a stomach-specific calpain, whose physiological functions are unclear. To elucidate these, we characterized nCL-2 in detail. Unexpectedly, nCL-2 was localized strictly to the surface mucus cells in the gastric epithelium and the mucus-secreting goblet cells in the duodenum. Yeast two-hybrid screening identified several nCL-2-interacting molecules. Of these, the beta-subunit of coatomer complex (beta-COP) occurs in the stomach pit cells and is proteolyzed by nCL-2 in vitro. Furthermore, beta-COP and nCL-2 co-expressed in COS7 cells co-localized in the Golgi, and Ca2+-ionophore stimulation caused the proteolysis of beta-COP near the linker region, resulting in the dissociation of beta-COP from the Golgi. These results strongly suggest novel functions for nCL-2 that involve the membrane trafficking of mucus cells via interactions with coat protein.     

Regulation of InsP3 receptor activity by neuronal Ca2+-binding proteins

Inositol 1,4,5-trisphosphate receptors (InsP(3)Rs) were recently demonstrated to be activated independently of InsP(3) by a family of calmodulin (CaM)-like neuronal Ca(2+)-binding proteins (CaBPs). We investigated the interaction of both naturally occurring long and short CaBP1 isoforms with InsP(3)Rs, and their functional effects on InsP(3)R-evoked Ca(2+) signals. Using several experimental paradigms, including transient expression in COS cells, acute injection of recombinant protein into Xenopus oocytes and (45)Ca(2+) flux from permeabilised COS cells, we demonstrated that CaBPs decrease the sensitivity of InsP(3)-induced Ca(2+) release (IICR). In addition, we found a Ca(2+)-independent interaction between CaBP1 and the NH(2)-terminal 159 amino acids of the type 1 InsP(3)R. This interaction resulted in decreased InsP(3) binding to the receptor reminiscent of that observed for CaM. Unlike CaM, however, CaBPs do not inhibit ryanodine receptors, have a higher affinity for InsP(3)Rs and more potently inhibited IICR. We also show that phosphorylation of CaBP1 at a casein kinase 2 consensus site regulates its inhibition of IICR. Our data suggest that CaBPs are endogenous regulators of InsP(3)Rs tuning the sensitivity of cells to InsP(3).     

The protease core of the muscle-specific calpain,p94, undergoes Ca2+-dependent intramolecular autolysis

Limb girdle muscular dystrophy type 2A is linked to a skeletal muscle-specific calpain isoform known as p94. Isolation of the intact 94-kDa enzyme has been difficult to achieve due to its rapid autolysis, and uncertainty has arisen over its Ca2+-dependence for activity. We have expressed a C-terminally truncated form of the enzyme that comprises the protease core (domains I and II) along with its insertion sequence, IS1, and N-terminal leader sequence, NS. This 47-kDa p94I-II mini-calpain was stable during purification. In the presence of Ca2+, p94I-II cleaved itself within the NS and IS1 sequences. Mapping of the autolysis sites showed that NS and IS1 have the potential to be removed without damage to the protease core. Ca2+-dependent autolysis must be an intramolecular event because the inactive p94I-II C129S mutant was not cleaved by incubation with wild-type p94I-II. In addition, the rate of autolysis of p94I-II was independent of the concentration of the enzyme.