Limited autolysis reduces the Ca2+ requirement of a smooth muscle Ca2+-activated protease

Calpains promote α2β1 integrin turnover in nonrecycling integrin pathway

A novel virus- and integrin clustering–specific pathway diverts integrin from its normal endo/exocytic traffic to a nonrecycling degradative endosomal route. Clustering of α2β1 integrin causes redistribution of the integrin to perinuclear endosomes, leading to enhanced integrin turnover promoted by calpains.

Collagen receptor integrins recycle between the plasma membrane and endosomes and facilitate formation and turnover of focal adhesions. In contrast, clustering of α2β1 integrin with antibodies or the human pathogen echovirus 1 (EV1) causes redistribution of α2 integrin to perinuclear multivesicular bodies, α2-MVBs. We show here that the internalized clustered α2 integrin remains in α2-MVBs and is not recycled back to the plasma membrane. Instead, receptor clustering and internalization lead to an accelerated down-regulation of α2β1 integrin compared to the slow turnover of unclustered α2 integrin. EV1 infection or integrin degradation is not associated with proteasomal or autophagosomal processes and shows no significant association with lysosomal pathway. In contrast, degradation is dependent on calpains, such that it is blocked by calpain inhibitors. We show that active calpain is present in α2-MVBs, internalized clustered α2β1 integrin coprecipitates with calpain-1, and calpain enzymes can degrade α2β1 integrin. In conclusion, we identified a novel virus- and clustering-specific pathway that diverts α2β1 integrin from its normal endo/exocytic traffic to a nonrecycling, calpain-dependent degradative endosomal route.

Expanding members and roles of the calpain superfamily and their genetically modified animals

Calpains are intracellular Ca²(+)-dependent cysteine proteases (Clan CA, family C02, EC 3.4.22.17) found in almost all eukaryotes and some bacteria. Calpains display limited proteolytic activity at neutral pH, proteolysing substrates to transform and modulate their structures and activities, and are therefore called "modulator proteases". The human genome has 15 genes that encode a calpain-like protease domain, generating diverse calpain homologues that possess combinations of several functional domains such as Ca²(+)-binding domains and Zn-finger domains. The importance of the physiological roles of calpains is reflected in the fact that particular defects in calpain functionality cause a variety of deficiencies in many different organisms, including lethality, muscular dystrophies, lissencephaly, and tumorigenesis. In this review, the unique characteristics of this distinctive protease superfamily are introduced in terms of genetically modified animals, some of which are animal models of calpain deficiency diseases.

μ-Calpain and calpain-3 are not autolyzed with exhaustive exercise in humans

μ-calpain and calpain-3 are Ca2+-dependent proteases found in skeletal muscle. Autolysis of calpains is observed using Western blot analysis as the cleaving of the full-length proteins to shorter products. Biochemical assays suggest that μ-calpain becomes proteolytically active in the presence of 2–200 μM Ca2+. Although calpain-3 is poorly understood, autolysis is thought to result in its activation, which is widely thought to occur at lower intracellular Ca2+concentration levels ([Ca2+]i; ∼1 μM) than the levels at which μ-calpain activation occurs. We have demonstrated the Ca2+-dependent autolysis of the calpains in human muscle samples and rat extensor digitorum longus (EDL) muscles homogenized in solutions mimicking the intracellular environment at various [Ca2+] levels (0, 2.5, 10, and 25 μM). Autolysis of calpain-3 was found to occur across a [Ca2+] range similar to that for μ-calpain, and both calpains displayed a seemingly higher Ca2+sensitivity in human than in rat muscle homogenates, with ∼15% autolysis observed after 1-min exposure to 2.5 μM Ca2+in human muscle and almost none after 1- to 2-min exposure to the same [Ca2+]ilevel in rat muscle. During muscle activity, [Ca2+]imay transiently peak in the range found to autolyze μ-calpain and calpain-3, so we examined the effect of two types of exhaustive cycling exercise (30-s “all-out” cycling, n = 8; and 70% V̇o2 peakuntil fatigue, n = 3) on the amount of autolyzed μ-calpain or calpain-3 in human muscle. No significant autolysis of μ-calpain or calpain-3 occurred as a result of the exercise. These findings have shown that the time- and concentration-dependent changes in [Ca2+]ithat occurred during concentric exercise fall near but below the level necessary to cause autolysis of calpains in vivo.

Effect of phosphatidylinositol and inside-out erythrocyte vesicles on autolysis of μ- and m-calpain from bovine skeletal muscle

The finding that phospholipid micelles lowered the Ca2+ concentration required for autolysis of the calpains led to a hypothesis suggesting that the calpains are translocated to the plasma membrane where they interact with phospholipids to initiate their autolysis. However, the effect of plasma membranes themselves on the Ca2+ concentration required for calpain autolysis has never been reported. Also, if interaction with a membrane lowers the Ca2+ required for autolysis, the membrane-bound-calpain must autolyze itself, because it would be the only calpain having the reduced Ca2+ requirement. This implies that the autolysis is an intramolecular process, although several studies have shown that autolysis of the calpains in an in vitro assay and in the absence of phospholipid is an intermolecular process. Inside-out vesicles prepared from erythrocytes had no effect on the Ca2+ concentration required for autolysis of either mu- or m-calpain, although phosphatidylinositol (PI) decreased the Ca2+ concentration required for autolysis of the same calpains. The presence of a substrate for the calpains, beta-casein, reduced the rate of autolysis of both mu- and m-calpain both in the presence and in the absence of PI, suggesting that mu- and m-calpain autolysis is an intermolecular process in the presence of PI just as it is in its absence. Because IOV have no effect on the Ca2+ concentration required for calpain autolysis, association with the plasma membrane, at least with erythrocyte plasma membranes, does not initiate calpain autolysis by reducing the Ca2+ concentration required for autolysis as suggested by the membrane-activation hypothesis. Interaction with a membrane may serve to bind calpains to their substrates rather than promoting autolysis.

Effects of autolysis on properties of mu- and m-calpain

Although the biochemical changes that occur during autolysis of mu- and m-calpain are well characterized, there have been few studies on properties of the autolyzed calpain molecules themselves. The present study shows that both autolyzed mu- and m-calpain lose 50-55% of their proteolytic activity within 5 min during incubation at pH 7.5 in 300 mM or higher salt and at a slower rate in 100 mM salt. This loss of activity is not reversed by dialysis for 18 h against a low-ionic-strength buffer at pH 7.5. Proteolytic activity of the unautolyzed calpains is not affected by incubation for 45 min at ionic strengths up to 1000 mM. Size-exclusion chromatography shows that ionic strengths of 100 mM or above cause dissociation of the two subunits of autolyzed calpains and that the dissociated large subunits (76- or 78-kDa) aggregate to form dimers and trimers, which are proteolytically inactive. Hence, instability of autolyzed calpains is due to aggregation of dissociated heavy chains. Autolysis removes the N-terminal 19 (m-calpain) or 27 (mu-calpain) amino acids from the large subunit and approximately 90 amino acids from the N-terminus of the small subunit. These regions form contacts between the two subunits in unautolyzed calpains, and their removal leaves only contacts between domain IV in the large subunit and domain VI in the small subunit. Although many of these contacts are hydrophobic in nature, ionic-strength-induced dissociation of the two subunits in the autolyzed calpains indicates that salt bridges have an important, possibly indirect, role in the domain IV/domain VI interaction.

The calpains in aging and aging-related diseases

Calpains are a family of calcium-dependent cysteine proteases under complex cellular regulation. By making selective limited proteolytic cleavages, they modulate the activity of enzymes, including key signaling molecules, and induce specific cytoskeletal rearrangements, accounting for their roles in cell motility, signal transduction, vesicular trafficking and structural stabilization. Calpain activation has been implicated in various aging phenomena and diseases of late life, including cataract formation, erythrocyte senescence, diabetes mellitus type 2, hypertension, arthritis, and neurodegenerative disorders. The early and pervasive involvement of calpains in Alzheimer's disease potentially influences the development of beta-amyloid and tau disturbances and their consequences for neurodegeneration and neuronal cell loss.

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.

SNAP-23 is a target for calpain cleavage in activated platelets

The role of calpain in platelet function is generally associated with aggregation and clot retraction. In this report, data are presented to show that one component of the platelet secretory machinery, SNAP-23, is specifically cleaved by calpain in activated cells. Other proteins of the membrane fusion machinery, e.g. syntaxins 2 and 4 and alpha-SNAP, are not affected. In vitro studies, using permeabilized platelets, demonstrate that cleavage is time- and calcium-dependent. Analysis of SNAP-23 cleavage products suggests that the calpain cleavage site(s) is in the C-terminal third of the molecule potentially between the cysteine-rich acyl attachment sites and the C-terminal coiled-coil domain. The time course of cleavage is most consistent with late calpain-mediated events such as pp60(c-src) cleavage, but not early events such as protein-tyrosine phosphatase-1B activation. SNAP-23 cleavage is inhibited by calpeptin, calpastatin, calpain inhibitor IV, and E-64d, but not by caspase 3 inhibitor III or cathepsin inhibitor I. When tested for their effect on secretion, none of the calpain-specific inhibitors significantly affected release of soluble components from any of the three platelet granule storage pools. These results indicate that SNAP-23 cleavage occurs after granule release and therefore may play a role in affecting granule membrane exteriorization. This is consistent with the ultrastructural morphology of calpeptin-treated platelets after activation.

Immunoaffinity purification of the calpains

A monoclonal antibody to the small subunit common to both mu- and m-calpains can be used in an immunoaffinity column to purify either mu- or m-calpain in a proteolytically active form. Extracts in 150 mM NaCl, pH 7.5, are loaded onto a column containing the anti-28-kDa antibody; the column is washed with 500 mM NaCl, pH 7.5, and the bound calpain is eluted with 150 mM NaCl, 50 mM Tris-HCl, pH 9.5, and 1 mM EDTA. These elution conditions do not affect the proteolytic activity of either mu- or m-calpain. It is most efficient to reduce the volume and to remove any proteolytic activity from crude extracts by using successive phenyl Sepharose and ion-exchange columns before loading onto the immunoaffinity column. The column purifies m-calpain more effectively than mu-calpain; m-calpain is greater than 90% pure after a single pass through this column, whereas mu-calpain can be purified to >70% purity. The epitope for the monoclonal antibody is between amino acids 92 and 104 (numbers for human calpain) in the 28-kDa subunit. Evidently, this area is shielded in the calpain molecule in a way that affects binding of the antibody to the native molecule.

Autolysis of mu- and m-calpain from bovine skeletal muscle

The rate of autolysis of mu- and m-calpain from bovine skeletal muscle was measured by using densitometry of SDS polyacrylamide gels and determining the rate of disappearance of the 28 and 80 kDa subunits of the native, unautolyzed calpain molecules. Rate of autolysis of both the 28 and 80 kDa subunits of mu-calpain decreased when mu-calpain concentration decreased and when beta-casein, a good substrate for the calpains, was present. Hence, autolysis of both mu-calpain subunits is an intermolecular process at pH 7.5, 0 or 25.0 degrees C, and low ionic strength. The 78 kDa subunit formed in the first step of autolysis of m-calpain was not resolved from the 80 kDa subunit of the native, unautolyzed m-calpain by our densitometer, so autolysis of m-calpain was measured by determining rate of disappearance of the 28 kDa subunit and the 78/80 kDa complex. At Ca2+ concentrations of 1000 microM or higher, neither the m-calpain concentration nor the presence of beta-casein affected the rate of autolysis of m-calpain. Hence, m-calpain autolysis is intramolecular at Ca2+ concentrations of 1000 microM or higher and pH 7.5. At Ca2+ concentrations of 350 microM or less, the rate of m-calpain autolysis decreased with decreasing m-calpain concentration and in the presence of beta-casein. Thus, m-calpain autolysis is an intermolecular process at Ca2+ concentrations of 350 microM or less. If calpain autolysis is an intermolecular process, autolysis of a membrane-bound calpain would require selective participation of a second, cytosolic calpain, making it an inefficient process. By incubating the calpains at Ca2+ concentrations below those required for half-maximal activity, it is possible to show that unautolyzed calpains degrade a beta-casein substrate, proving that unautolyzed calpains are active proteases.

The ultrastructure of skeletal and smooth muscle in experimental protein malnutrition in rats fed a low protein diet

Light microscopy of the pectoralis muscle of rats on a low protein diet did not show such morphological alterations as atrophy, degeneration, or sarcoplasmic edema, but electron microscopy occasionally demonstrated ultrastructural changes only in the sarcomeres of myofibrils. In the affected sarcomeres, the Z-line was disrupted and often showed a jagged structure. The Z-substance with electron opacity was frequently present flowing along the long axis of myofibrils, here referred to as the streaming of Z-lines. In addition, regular striations formed by the reciprocal arrangement of thick and thin filaments disappeared from the affected sarcomeres, though these filaments were still discernible. Two or more consecutive sarcomeres in a single myofibril were occasionally involved in these changes. A further two or more neighboring sarcomeres at the same level of myofibrils were affected transversely by these structural alterations. On the other hand, the ultrastructure of the intestinal smooth muscle was not affected by protein deficiency. The study suggests that the ultrastructural damage induced by a low protein diet is attributed to the activation of endogenous protease by the excess leaking of Ca2+ into the cytosol as a result of lipid peroxidation of cell membrane by raised free radicals, owing to the depletion of glutathione production by protein deficiency. It also suggests that the smooth muscle cells differ in their susceptibility to protein deficiency from the skeletal muscle cells.

Calpains and muscular dystrophies

Calpains are a ubiquitous, well-conserved family of calcium-dependent, cysteine proteases. Their function in muscle has received increased interest because of the discoveries that the activation and concentration of the ubiquitous calpains increase in the mouse model of Duchenne muscular dystrophy (DMD), but null mutations of muscle specific calpain causes limb girdle muscular dystrophy 2A (LGMD2A). These findings indicate that modulation of calpain activity contributes to muscular dystrophies by disrupting normal regulatory mechanisms influenced by calpains, rather than through a general, nonspecific increase in proteolysis. Thus, modulation of calpain activity or expression through pharmacological or molecular genetic approaches may provide therapies for some muscular dystrophies.

The bovine calpastatin gene promoter and a new N-terminal region of the protein are targets for cAMP-dependent protein kinase activity

To investigate the regulation of calpastatin gene expression, we isolated bovine heart calpastatin cDNAs and 5'-regions of the calpastatin gene. Analysis of 5'-cDNA sequence identified a new translation initiation site that is in frame and 204 nucleotides upstream of the previously designated start site. Conceptual translation from this upstream AUG produces a protein containing 68 additional N-terminal amino acids. This "XL" region contains three potential PKA phosphorylation sites but shares no homology with other regions of calpastatin or with any known protein. Immunoblot studies demonstrated that heart and liver contain a calpastatin protein of 145 kDa on SDS-polyacrylamide gel electrophoresis that comigrates with full-length bacterially expressed calpastatin and calpastatin produced by coupled in vitro transcription-translation from the upstream AUG. An antibody raised against the XL region recognized the 145-kDa band, demonstrating that the upstream AUG is utilized and that the 145-kDa band represents full-length calpastatin in vivo. Transient transfection assays demonstrated that sequence within 272 nucleotides upstream of transcription initiation of the calpastatin gene is sufficient to direct moderate level transcription. Promoter sequences further upstream act to inhibit or stimulate transcriptional activity. Exposure of transfected cells to dibutyryl cAMP resulted in a 7-20-fold increase in promoter activity for constructs containing at least 272 nucleotides of upstream promoter sequence. Deletion analysis indicates that at least one cAMP-responsive element resides within 102 nucleotides of transcription initiation.

Functional properties of recombinant calpain I and of mutants lacking domains III and IV of the catalytic subunit

The catalytic subunit (L-microCANP) of human calpain I (muCANP, the high Ca2+ affinity form) and two of its mutants were expressed in Escherichia coli or using the baculovirus Sf9 system. The mutants lacked domain III (L-mu CANPDelta3) and the calmodulin-like domain IV (L-mu CANPDelta4), respectively. The bacterially expressed proteins were solubilized from the inclusion bodies and refolded with polyethylene glycol. In Sf9 cells, co-expression of the inhibitor calpastatin was necessary to prevent autolysis of L-muCANP, whereas co-expression of the regulatory subunit enhanced it. Only very low levels of mRNA of the truncated form L-mu CANPDelta4 were found in bacmid-transfected Sf9 cells, and it proved impossible to isolate this mutant using the baculovirus expression system. While the apparent Km(Ca2+) of freshly isolated human erythrocyte muCANP was about 60 microM, the recombinant monomeric forms L-mu CANP and L-mu CANPDelta3 required 65-215 and 400-530 microM Ca2+, respectively. Bacterially expressed L-mu CANPDelta4 was Ca2+-independent; the presence of inhibitors during its renaturation was necessary to prevent its autolysis. A chimeric form (L-mu mCANP) composed by domains I-III of muCANP and domain IV of calpain II (mCANP, the low Ca2+ affinity form) was also expressed in Sf9 cells. This mutant required less Ca2+ (about 50 microM) than native erythrocyte calpain for half-maximal activity and had the highest specific activity of all calpains tested. Domain III proved unnecessary for the activity of the recombinant catalytic subunit, but its absence raised the Km(Ca2+) and removed its inactivation at high Ca2+ concentrations. All recombinant proteins were active as monomers in polyethylene glycol-containing buffers; the in vitro association with the regulatory subunit enhanced only slightly the Vmax and the Ca2+ dependence of the expressed proteins. Activation by Ca2+ promoted the separation of the two subunits of the expressed recombinant proteins.

Distinct substrate specificities and functional roles for the 78- and 76-kDa forms of mu-calpain in human platelets

The intracellular thiol protease mu-calpain exists as a heterodimeric proenzyme, consisting of a large 80-kDa catalytic subunit and a smaller 30-kDa regulatory subunit. Activation of mu-calpain requires calcium influx across the plasma membrane and the subsequent autoproteolytic conversion of the 80-kDa large subunit to a 78-kDa "intermediate" and a 76-kDa fully autolyzed form. Currently, there is limited information on the substrate specificities and functional roles of these distinct active forms of mu-calpain within the cell. Using antibodies that can distinguish among the 80-, 78-, and 76-kDa forms of mu-calpain, we have demonstrated a close correlation between the autolytic generation of the 78-kDa enzyme and the proteolysis of the non-receptor tyrosine phosphatase, PTP-1B, in ionophore A23187-stimulated platelets. Time course studies revealed that pp60(c-)src proteolysis lagged well behind that of PTP-1B and correlated closely with the generation of the fully proteolyzed form of mu-calpain (76 kDa). In vitro proteolysis experiments with purified mu-calpain and immunoprecipitated PTP-1B or pp60(c-)src confirmed selective proteolysis of pp60(c-)src by the 76-kDa enzyme, whereas PTP-1B cleavage was mediated by both the 76- and 78-kDa forms of mu-calpain. Studies using selective pharmacological inhibitors against the different autolytic forms of mu-calpain have demonstrated that the initial conversion of the mu-calpain large subunit to the 78-kDa form is responsible for the reduction in platelet-mediated clot retraction, whereas complete proteolytic activation of mu-calpain (76 kDa) is responsible for the shedding of procoagulant-rich membrane vesicles from the cell surface. These studies demonstrate the existence of multiple active forms of mu-calpain within the cell, that have unique substrate specificities and distinct functional roles.

Calpain II expression is increased by changes in mechanical loading of muscle in vivo

In the present investigation, we have tested the hypothesis that calpain expression or activity in skeletal muscle is influenced by changes in mechanical loading in vivo. Muscle unloading for 10 days produced no change in the concentrations of calpain I, or II, and no change in calpain activation, as assessed by measurements of the proportion of calpain I or II isoforms that exhibited autoproteolytic modifications. However, muscle reloading for 2 days produced a 90% increase in calpain II concentration per unit wet weight of muscle relative to ambulatory controls. Although no change in the activation index for calpain I or II was identified for reloaded muscle, this index is an expression of the proportion of the total mass of each calpain isoform that is autoproteolyzed. Thus, there is also approximately a 90% increase in autolyzed calpain II in muscle experiencing increased loading than in controls. Northern analysis shows that the concentration of mRNA for calpain II is increased in reloaded muscle, but no change in calpain II mRNA concentration in unloaded muscle. In situ reverse transcription polymerase chain reaction was used to confirm that nearly all calpain II mRNA in reloaded muscle is located in muscle fibers, with very little detectable calpain II mRNA in non-muscle cells present in the tissue. Together, these findings show that increased muscle loading causes a selective increase in the expression of calpain II isoform, thereby indicating that its regulation is independent from other calpain isoforms.

An immunocytochemical study of calpain II in the hippocampus of rats injected with kainate

The distributions of the kainate/DL-alpha-amino-3-hydroxy-5-methylisoxazolepropionic acid (KA/ AMPA) receptors GluR1 and calcium-activated neutral protease II (calpain II) in the hippocampus of normal and kainate-lesioned rats were studied by immunocytochemistry. There was a reduction in GluR1 immunoreactivity and a slight increase in calpain II immunoreactivity on the dendrites of pyramidal neurons in CA fields affected by the kainate at 18 h postinjection. Calpain II immunore-activity was associated with amyloid fibrils at electron microscopy. These fibrils were most often intracellular, in membrane-bound profiles, some of which were contacted by axon terminals and were identified as degenerating dendrites. There was extensive destruction of mitochondrial membranes in degenerating profiles, and accumulations of amyloid fibrils were often localised in mitochondria in a calpain-positive profile. This was unlike other, calpain-negative degenerating profiles, that contained tubulovesicular profiles or multilamellar bodies, where mitochondrial membranes were preserved. Many more calpain-positive profiles were observed at electron microscopy 6 days after kainate injection. The enzyme was present in macrophages and astrocytes in lesioned areas.

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

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

Separation of proteases: old and new approaches

All methods of protein separations can be applied to proteases. Some emphasis is put in this review on a powerful technique specific to proteases purification: cyclic peptide antibiotics may be seen as general affinity ligands for proteases. Also, some examples of affinity chromatography of proteases on ligands with narrower specificity are given. The special interest of hydrophobic interaction chromatography for proteases purification is discussed. The merits of immobilized dye chromatography for proteases purification and the interest in empirically screening many immobilized dyes, as well as several eluents are discussed.

Selective proteolysis of arrestin by calpain. Molecular characteristics and its effect on rhodopsin dephosphorylation

Visual arrestin (48 kDa) plays a role in the deactivation of rhodopsin by binding to the light-activated, phosphorylated form of the receptor. In bovine rod outer segments that were prepared in the presence of protease inhibitors, two faster migrating forms of arrestin, with apparent molecular masses of 46 and 44 kDa, were observed by Western blot analysis. The 46-kDa form was more evident in rod outer segments of eyes kept in the light than those placed in darkness and was found to be identical to that generated by in vitro proteolysis of arrestin by pure retinal calpain II. In vitro analysis showed that arrestin was proteolyzed only when bound to rhodopsin; soluble arrestin was not significantly cleaved by calpain. Proteolysis involves sequential cleavage at two, possibly three sites, resulting in the removal of 27 amino acids from the COOH terminus. The remaining 46-kDa protein was resistant to further proteolysis by calpain. Unlike intact arrestin, the 46-kDa truncated arrestin was not readily released from the receptor after the receptor had lost its chromophore, nor was it released upon the addition of 11-cis-retinal to regenerate the receptor. Truncated arrestin was found to inhibit receptor dephosphorylation to the same extent as intact arrestin. In conclusion, these results provide evidence that a 46-kDa form of arrestin in rod outer segments is a product of selective proteolysis by calpain. Furthermore, they suggest that this proteolysis may provide a mechanism for prolonging the phosphorylated state of the visual receptor.

Fodrin degradation and subcellular distribution of calpains after neonatal rat cerebral hypoxic-ischemia

Neonatal rats were subjected to transient cerebral hypoxic-ischemia (unilateral occlusion of the common carotid artery + 7.70% O2 for 100 min). Ipsi-and contralateral parietal cerebral cortex was assayed with Western blotting for fodrin breakdown product (FBDP). Calpain immunoreactivity was assayed in the cytosolic fraction (CF) and the membrane and microsomal fraction (MMF). Calpain immunoreactivity decreased bilaterally in the CF during the insult (62-68% of controls) and remained significantly lower during early recovery, whereas the MMF showed no significant changes. This relative redistribution of calpains coincided with the appearance of FBDP in the left, ipsilateral hemisphere, displaying a significantly higher level of FBDP from immediately after the insult until at least 1 day of recovery (204-292% of controls). No significant changes in FBDP could be detected in the right, contralateral hemisphere, indicating that although redistribution of calpains occurred, hypoxia per se did not suffice to initiate fodrin degradation in this model of neonatal hypoxic-ischemia.

Calpains are activated in necrotic fibers from mdx dystrophic mice

Death of dystrophin-deficient muscle purportedly results from increases in [Ca]in that cause the activation of calpains. We have tested whether calpains play a role in this process by assaying for changes in calpain concentration and activation in peak necrotic mdx mice (4 weeks of age) and in completely regenerated mdx mice (14 weeks of age). Biochemical fractionation and immunoblotting with epitope-specific antisera allowed measurement of the concentrations of m- and mu-calpains and the extent of autoproteolytic modification. Our findings show that total calpain concentration is elevated in both 4-week and 14-week mdx mice. This increase in concentration was shown to result primarily from a significant increase in m-calpain concentration at 4 weeks. Northern analysis demonstrated that neither m- nor mu-calpain mRNA concentrations differed between mdx and controls suggesting that the increased calpain concentration results from post-translational regulation. Immunoblotting with antibodies directed against amino-terminal peptides revealed an increase in autoproteolysis of mu-calpain, indicative of increased activation. The extent of autoproteolysis of mu-calpain returns to control levels during regeneration. This is not a consequence of increased calpastatin mRNA or protein. The findings reported here support a role for calpains in both the degenerative and regenerative aspects of mdx dystrophy.

Is calpain activity regulated by membranes and autolysis or by calcium and calpastatin?

Although the Ca(2+)-dependent proteinase (calpain) system has been found in every vertebrate cell that has been examined for its presence and has been detected in Drosophila and parasites, the physiological function(s) of this system remains unclear. Calpain activity has been associated with cleavages that alter regulation of various enzyme activities, with remodeling or disassembly of the cell cytoskeleton, and with cleavages of hormone receptors. The mechanism regulating activity of the calpain system in vivo also is unknown. It has been proposed that binding of the calpains to phospholipid in a cell membrane lowers the Ca2+ concentration, [Ca2+], required for the calpains to autolyze, and that autolysis converts an inactive proenzyme into an active protease. Recent studies, however, show that the calpains bind to specific proteins and not to phospholipids, and that binding to cell membranes does not affect the [Ca2+] required for autolysis. It seems likely that calpain activity is regulated by binding of Ca2+ to specific sites on the calpain molecule, with binding to each site eliciting a response (proteolytic activity, calpastatin binding, etc.) specific for that site. Regulation must also involve an, as yet, undiscovered mechanism that increases the affinity of the Ca(2+)-binding sites for Ca2+.

Preference of calcium-dependent interactions between calmodulin-like domains of calpain and calpastatin subdomains

Calpastatin molecule contains four repeated inhibition domains, each having highly conserved internal regions A, B and C. The synthetic oligopeptides of regions A and C had no calpain inhibition activity while region B oligopeptide showed weak inhibition activity. Real-time biomolecular interaction analysis using a BIAcore instrument revealed that the bacterially expressed calmodulin-like domain of the calpain large subunit (L-CaMLD) and that of the small subunit (S-CaMLD) interacted, in a Ca(2+)-dependent fashion, preferentially with the immobilized synthetic oligopeptide of region A and that of region C, respectively. Calmodulin showed no specific binding to these oligopeptides. The tripartite structure of the calpastatin functional domain may confer the specific interactions with the protease domain and the two CaMLDs of calpain.

Studies on the autolysis of m-calpain from the skeletal muscle of the amphibian Rana ridibunda

The autolytic mechanisms responsible for the regulation of m-calpain purified from the skeletal muscle of the amphibian Rana ridibunda were examined. Both subunits of the calpain molecule were found to undergo autolysis in the presence of Ca2+. Various divalent cations were examined for their ability to induce calpain autolysis. The concentrations of these cations required for the complete calpain autolysis were: 500 microM Ca2+, 800 microM Mn2+, 2 mM Sr2+, 10 mM Ba2+, whereas Mg2+, even at 10 mM did not induce any autolysis. Calpain autolysis induced by the above divalent cations is a temperature dependent process. Presence of Mn2+ or Sr2+ reduces the Ca2+ requirement of calpain for autolysis. The rate of autolysis depends on the protease concentration; protease inhibitors such as E-64, leupeptin, antipain, and iodoacetic acid inhibit the autolysis of calpain; E-64 inhibits irreversibly while leupeptin inhibits reversibly the autolysis; and irreversibly inactivated by E-64 calpain is fully digested by native calpain. Autolysis of calpain in the presence of alkali denatured casein increases the Ca2+ sensitivity of the protease for its half maximal and maximal caseinolytic activity. Limited autolysis of calpain is also induced in the presence of the endogenous substrate G-actin, and the rate of autolysis is slower than that obtained in the absence of substrates.

Calcium-activated neutral proteinase (calpain) system in aging and Alzheimer's disease

Calpains (CANPs) are a family of calcium-dependent cysteine proteases under complex cellular regulation. By making selective limited proteolytic cleavages, they activate or alter the regulation of certain enzymes, including key protein kinases and phosphatases, and induce specific cytoskeletal rearrangements, accounting for their suspected involvement in intracellular signaling, vesicular trafficking, and structural stabilization. Calpain activity has been implicated in various aging phenomena, including cataract formation and erythrocyte senescence. Abnormal activation of the large stores of latent calpain in neurons induces cell injury and is believed to underlie neurodegeneration in excitotoxicity, Wallerian degeneration, and certain other neuropathologic states involving abnormal calcium influx. In Alzheimer's disease, we found the ratio of activated calpain I to its latent precursor isoform in neocortex to be threefold higher than that in normal individuals and those with Huntington's or Parkinson's disease. Immunoreactivity toward calpastatin, the endogenous inhibitor of calpain, was also markedly reduced in layers II-V of the neocortex in Alzheimer's disease. The excessive calpain system activation suggested by these findings represents a potential molecular basis for synaptic loss and neuronal cell death in the brain in Alzheimer's disease given the known destructive actions of calpain I and its preferential neuronal and synaptic localization. In surviving cells, persistent calpain activation may also contribute to neurofibrillary pathology and abnormal amyloid precursor protein trafficking/processing through its known actions on protein kinases and the membrane skeleton. The degree of abnormal calpain activation in the brain in Alzheimer's disease strongly correlated with the extent of decline in levels of secreted amyloid precursor protein in brain. Cytoskeletal proteins that are normally good calpain substrates become relatively calpain resistant when they are hyperphosphorylated, which may contribute to their accumulation in neurofibrillary tangles. As a major effector of calcium signals, calpain activity may mirror disturbances in calcium homeostasis and mediate important pathologic consequences of such disturbances.

Regulation of the phosphorylation of calpain II and its inhibitor

Phosphorylation of calpain II (or its inhibitor) by the catalytic subunit of cyclic AMP-dependent protein kinase (A-PK), cyclic GMP-dependent protein kinase (G-PK), and protein kinase C (PK-C) was analyzed by SDS-polyacrylamide gel electrophoresis and autoradiography. Among these protein kinases, the catalytic subunit of A-PK exhibited the strongest phosphorylations of both calpain II and its inhibitor. Arachidonic acid and staurosporine effectively inhibited phosphorylation regardless the type of kinase tested. Despite its lack of effect on the phosphorylation of calpain II by the catalytic subunit of A-PK, sphingosine moderately enhanced the phosphorylation of calpain II by G-PK. Other agents, including phosphatidylethanolamine, phosphatidylinositol and 1, 2-dioleoyl-sn-glycerol, had no significant effect.

Purification and characterization of m-calpain from the skeletal muscle of the amphibian Rana ridibunda

Calpain was purified to apparent homogeneity from the skeletal muscle of the amphibian Rana ridibunda. It is composed of two subunits of 78 and 28 kDa, respectively. The enzyme exhibits kinetic properties similar to those of mammalian and avian skeletal muscle m-calpains. Ca2+ requirements for half and maximum activities are 400 microM and 1.5 mM, respectively. It is strongly inhibited by thiol protease inhibitors such as leupeptin, E-64, and antipain and by alkylating thiol group agents such as iodoacetic acid (IAA), iodoacetamide (IAM), and N-ethylmaleimide (NEM). Its activity is enhanced by reduced thiols such as dithiothreitol (DTT), cysteine, and 2-mercaptoethanol. The enzyme is stable in the absence of Ca2+ at 55 degrees C, it displays maximum activity at 25 degrees C, and it shows a broad pH optimum between 6.5 and 7.8. In the absence of Ca2+, various divalent cations such as Sr2+, Mn2+, and Ba2+ strongly activate, while other divalent cations such as Ni2+, Co2+, Cd2+, Zn2+, and Cu2+ have no effect on its activity. In the presence of Ca2+, the cations Sr2+, Mn2+, and Ba2+ show a synergistic effect, while the cations of the other group strongly inhibit the calpain activity. The above data demonstrate that calpain from the skeletal muscle of the amphibian Rana ridibunda is a neutral, Ca(2+)-activated thiol protease and that it belongs to the class of m-calpains.

Concurrent identification of calpains I and II from chicken skeletal muscle

A single anion-exchange column resolved two peaks of calcium-activated neutral protease activity, corresponding to the two calpain forms chicken skeletal muscle. Multiple columns have previously been needed to resolve the two isoforms from avian tissue. Calcium requirement assays confirmed one form to require approximately 100 microM Ca2+ for half-maximal activity, while the other required approximately 500 microM Ca2+. Electrophoresis revealed that the enzymes were not purified to homogeneity.

Structural modifications associated with the change in Ca2+ sensitivity on activation of m-calpain

Autolysis of the Ca(2+)-dependent cysteine protease m-calpain involves cleavage of the large (80 kDa) and small (30 kDa) subunits of the enzyme, and an increase in Ca2+ sensitivity. The appearance of increased Ca2+ sensitivity was found to correlate with the cleavage of the large subunit after residue 9.

Calpain processing of brain microtubules from the Atlantic cod, Gadus morhua

Microtubules isolated from Atlantic cod (Gadus morhua) brains retained assembly competence and ultraculture, although treatment with rabbit calpain resulted in loss of MAPs. In addition, spirals and aberrant structures formed when calpain I was activated post assembly. No such effect was seen with calpain II. Soluble fractions from cod brain were found to contain proteolytic activity that could be blocked by exogenously added calpastatin. Calpain was also isolated from cod muscle tissue with 10 times less yield, compared to rabbit lung. On the basis of Ca(2+)-requirements for activation in the mM range, electrophoretic mobility, antigenicity and hydrophobicity, we conclude that the proteolytic activity was attributable to calpain II. There was no difference in effects of rabbit and cod calpain II on cod microtubule proteins, indicating that calpain is a conserved protein. Our results suggest that calpains might be involved in the Ca(2+)-dependent irreversible regulation of cod brain microtubules.

Myocardial mechanical, biochemical, and structural alterations induced by chronic ethanol ingestion in rats

To determine the effects of moderate ethanol consumption on the mechanical, biochemical, and structural characteristics of the heart, myocardial mechanical performance, contractile protein enzyme activity, and the number and size of myocytes were measured in male Fischer 344 rats after the ingestion of 30% oral ethanol. Papillary muscles removed from the left ventricle were greater in length, weight, and cross-sectional area than the corresponding muscles from the right side. However, no differences were found between control and ethanol-treated myocardium when either the left or right side was compared separately. Chronic ethanol ingestion resulted in an increase in resting tension in left ventricular muscles, with no alteration in peak developed tension. Moreover, time to peak tension was significantly prolonged, whereas a depression was observed in the peak rate of isometric tension development. Isotonically, left muscles from ethanol-treated rats revealed a prolongation of time to peak shortening and a marked depression in the velocity of shortening at physiological loads. No changes were noted in muscles from the right ventricle. Contractile protein enzyme activity revealed no differences in myofibrillar Mg(2+)-ATPase activity in right and left ventricular myocardium between control and ethanol-treated rats in the presence of EGTA. However, at physiological activating levels of calcium, an upward shift of the myofibrillar Mg(2+)-ATPase activity-calcium curve occurred in left myocardium, whereas a depression in this relation was seen in the right ventricle. As a result of chronic ethanol intake, a decrease was noted in the volume percent of myocardium occupied by myocytes, and that myocyte cell volume per nucleus was found to remain essentially constant throughout the various layers of the ventricular wall. Importantly, a 14% significant decrease in the total number of myocyte nuclei was demonstrated in the left ventricular myocardium of rats on chronic ethanol consumption. Thus, chronic but moderate alcohol ingestion resulted in depressed contractile performance, alterations in myofibrillar Mg(2+)-ATPase activity, and myocyte loss. These events may serve to function as preliminary indicators of the onset of heart failure of alcoholic origin in this animal model.

Comparative studies on heat stability and autolysis of scallop (Patinopecten yessoensis) calpain II-like proteinase and rabbit calpain II

1. The scallop calpain-like proteinase is about five times more labile than the rabbit calpain II upon heat treatment at 35 degrees C. 2. By autolysis of the scallop proteinase of two 100 kDa subunits, 90, 45 and 30 kDa fragments were formed. Thereby the activity decreased monophasically in the presence of millimolar order of Ca2+, but did not increase in the presence of micromolar order of Ca2+ unlike the rabbit calpain II.

The role of Ca(2+)-dependent proteases (calpains) in post mortem proteolysis and meat tenderness

This manuscript summarizes research results from our laboratory regarding the role of endogenous proteases in post mortem proteolysis resulting in meat tenderization. Proteolysis of key myofibrillar proteins is the principal reason for ultrastructural changes in skeletal muscle associated with meat tenderization. Proteases should have the following characteristics to be considered as possible candidates for bringing about post mortem changes: i) to be located within skeletal muscle cells; ii) to have access to the substrate ie, myofibrils); and iii) to be able to hydrolyze the same proteins that are degraded during post mortem storage. Of the proteases located within skeletal muscle cells and thus far characterized, only calpains have all of the above characteristics. Numerous experiments conducted in our laboratory have indicated that the calcium-dependent proteolytic system (calpains) is responsible for post mortem proteolysis. Some of this evidence includes: 1) incubation of muscle slices with buffer containing Ca2+ accelerates post mortem proteolysis; 2) incubation of muscle slices with Ca2+ chelators inhibits post mortem proteolysis; 3) infusion or injection of carcasses with a solution of calcium chloride accelerates post mortem proteolysis and the tenderization process such that post mortem storage beyond 24 h to ensure meat tenderness is no longer necessary; 4) infusion of carcasses with zinc chloride, a potent inhibitor of calpains, blocks post mortem proteolysis and the tenderization process; and 5) feeding a beta-adrenergic agonist to lambs results in a reduction of the proteolytic capacity of the calpain system, which leads to a decreased rate of post mortem proteolysis and produces tough meat.(ABSTRACT TRUNCATED AT 250 WORDS)

Chronic nonocclusive coronary artery constriction impairs ventricular function, myocardial structure, and cardiac contractile protein enzyme activity in rats

To determine the effects of chronic nonocclusive coronary constriction on cardiac hemodynamics, structural integrity, and contractile protein enzyme activity, the left coronary artery was narrowed in rats, and measurements of ventricular performance, magnitude, and distribution of tissue damage and myofibrillar Mg2+ and Ca2+ myosin ATPase activities were evaluated 1 month later. In the presence of coronary artery stenosis averaging 58%, three levels of involvement of global cardiac performance were identified, and the rats were divided accordingly. In the first group, only left ventricular end-diastolic pressure (LVEDP) was increased; in the second group, LVEDP and left ventricular +dP/dt and/or -dP/dt were affected; and in the third group, LVEDP, left ventricular +dP/dt and -dP/dt, and right ventricular end-diastolic pressure were impaired. Thus, left ventricular moderate dysfunction, severe dysfunction, and failure occurred with coronary narrowing. On a structural basis, coronary constriction resulted in an ongoing process characterized by acute myocytolytic necrosis and foci of replacement fibrosis in different stages of healing. The number of these lesion profiles in the left ventricular myocardium increased 4.7-, 4.4-, and 8.3-fold in rats with moderate dysfunction, severe dysfunction, and failure, respectively. Biochemically, Mg(2+)-ATPase activity of myofibrils increased biventricularly when moderate dysfunction was present. However, this parameter decreased with the appearance of severe dysfunction, reaching control values in ventricular failure. Ca2+ myosin ATPase activity was reduced in the left ventricle of rats with severe dysfunction and failure, whereas it was elevated in the right ventricle of rats with severe dysfunction. In conclusion, a fixed lesion of the left main coronary artery with a modest reduction in vessel luminal diameter generates a conditioned state of the heart characterized by a continuous loss of myocytes and replacement scarring, which, in combination with alterations in contractile protein enzyme activity, may be responsible for a number of abnormalities in cardiac dynamics ranging from moderate dysfunction to pump failure.

Activation of calpain I and hydrolysis of calpain substrates (actin-binding protein, glycoprotein Ib, and talin) are not a function of thrombin-induced platelet aggregation

Calcium-activated neutral proteinase (calpain) has been shown to cleave proteins involved in the maintenance of cell structure. In human platelets, substrates of calpain include glycoprotein Ib (GPIb), actin-binding protein (ABP), and talin. GPIb-ABP complexes can be isolated in detergent extracts and are thought to represent membrane-cytoskeleton attachment sites. It has been hypothesized that the hydrolysis of GPIb-ABP by calpain is regulated by the extent of binding of this proteinase to the plasma membrane-cytoskeleton interface with platelet activation. Recently, another calpain substrate (talin) has been shown to redistribute from the cytoplasm to the plasma membrane-cytoskeleton interface as the result of thrombin stimulation. To investigate the intracellular distribution of calpain I, we employed the monoclonal antibody B27D8, specific for the heavy chain (catalytic subunit) of calpain I. Indirect immunofluorescent staining of resting human platelets revealed undetectable surface antigen. Permeabilization with Triton X-100, however, revealed a diffuse intracellular antigen consistent with a cytosolic distribution. To determine whether this antigen distribution reflected the proenzyme or the activated form of calpain I and to assess the degree of hydrolysis of ABP, GPIb, and talin, we employed B27D8 and murine monoclonal antibodies against ABP (1B3 and 3D1), GPIb (LJIb10), and rabbit polyclonal antibodies against talin (A2 and B11) in a quantitative immunotransblot assay. Examination of resting platelets revealed that calpain I existed as the 85-kd proenzyme form and that ABP, GPIb, and talin existed in their native intact forms. When platelets were aggregated with thrombin, autoproteolysis of calpain I occurred within the 30 seconds required to completely solubilize platelet aggregates in sodium dodecyl sulfate-containing buffer and not as a direct result of thrombin-induced activation.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparison of the autolyzed and unautolyzed forms of mu- and m-calpain from bovine skeletal muscle

Bovine skeletal muscle mu- and m-calpain autolyze when incubated with Ca2+. During the first 30 to 300 s, autolysis: (1) has little effect on the specific proteolytic activity of either mu- or m-calpain when assayed at 5 mM Ca2+; and (2) produces two new proteolytically active forms of calpain in addition to the original mu- and m-calpain. The four proteolytically active forms of calpain are: (1) autolyzed mu-calpain, having polypeptide subunits of 76 and 18 kDa and requiring 0.60 microM Ca2+ for half-maximal activity; (2) mu-calpain with 80- and 28-kDa subunits and requiring 7.1 microM Ca2+ for half-maximal activity; (3) autolyzed m-calpain with 78- and 18-kDa subunits and requiring 180 microM Ca2+ for half-maximal activity; and (4) m-calpain with 80- and 28-kDa subunits and requiring 1000 microM Ca2+ for half-maximal activity. All four forms of the calpains have similar pH optima (7.4 to 7.6) and almost identical circular dichroism spectra in the far ultraviolet (all four have little secondary structure with 26-30% alpha-helix and less than 10% beta-sheet structure). Autolyzed mu- and unautolyzed mu-calpain are fully activated proteolytically by Mn2+ with activity starting at 125 microM Mn2+. Autolyzed m-calpain is also activated by Mn2+ up to 80% of the maximum proteolytic activity obtained with Ca2+; Mn2+ activation begins at 320 microM Mn2+. Unautolyzed m-calpain has only 6 to 8% as much activity in the presence of Mn2+ as it does in the presence of Ca2+. Autolysis increases the axial ratios of the calpains from 3.5 to 4.6 for mu-calpain and from 3.7 to 5.0 for m-calpain (assuming 20% hydration). The estimated length of the calpain molecules increases by 13% upon autolysis from 73 to 84 A for mu-calpain and from 76 to 90 A for m-calpain (assuming 20% hydration). The autolyzed calpains elute after their unautolyzed counterparts off a DEAE-ion exchange column. Because autolyzed forms of the calpains are not found in DEAE elution profiles of cell extracts, bovine skeletal muscle cells must contain very little (less than 5% of total calpain) or none of the autolyzed form of the calpains.

Digestion of cardiac and skeletal muscle junctional sarcoplasmic reticulum vesicles with calpain II. Effects on the Ca2+ release channel

The Ca2+ release channel and ryanodine receptor are activities copurifying with the 400,000-450,000 Da high molecular weight protein of cardiac and skeletal junctional sarcoplasmic reticulum. Calpain II, an endogenous cytosolic protease, was used to selectively degrade the high molecular weight protein in cardiac and skeletal muscle sarcoplasmic reticulum vesicles, and its effects on the activity of the Ca2+ release channel and [3H]ryanodine binding sites were analyzed. Degradation of the high molecular weight protein was associated with appearance of 315,000 and 150,000 Da proteolytic fragments and with a change in the ultrastructure of the "feet," extravesicular projections that protrude from the junctional sarcoplasmic reticulum membrane. The maximal number of [3H]ryanodine binding sites and the affinities of the sites for ryanodine were not remarkably affected by calpain II. Ca2+ release channels recorded from nondegraded cardiac and skeletal membrane vesicle preparations had slope conductances of 85 and 110 pS, respectively, measured with 1 microM cis-Ca2+ and 50 mM trans-Ba2+. Proteolysis did not alter the unitary channel conductances but did increase the percentage of channel open times from 36% to more than 90%. After proteolysis, channel opening remained dependent on micromolar cis-Ca2+, and high concentrations of ryanodine (300 microM) still blocked the channel. Our results suggest that proteolysis of the Ca2+ release channel with calpain II selectively impairs its inactivation, leaving its unitary conductance and the requirement for micromolar Ca2+ intact.

Digestion of proteins associated with the Z-disc by calpain

The Z-disc of striated muscle is degraded by the Ca2(+)-activated proteinase, calpain, during autolysis of muscle fibres. The effect of calpain on proteins in preparations of Z-discs isolated from Lethocerus flight muscle has been studied. Calpain releases alpha-actinin from the Z-disc and digests two hydrophobic proteins associated with the Z-disc, zeelin 1 (35 kD) and zeelin 2 (23 kD). The Ca2+ sensitivity of zeelin digestion is shifted to lower Ca2+ concentrations (within the physiological range) in the presence of the phospholipids phosphatidyl inositol or phosphatidyl choline and diacylglycerol. The release of alpha-actinin is not affected by phospholipid. Preparations of isolated Z-discs have five times as much associated phospholipid (w/w) as myofibrils and the composition of the lipid differs from that of myofibrils. In muscle fibres the action of calpain on zeelins may be controlled by the composition of phospholipid in the fibres as well as by Ca2+.

Regulatory proteins in hamster cardiomyopathy

We have shown in genetic myopathic hamsters that cardiac myofibrillar ATPase regulation by calcium is altered and that there are shifts in myosin isozyme distribution (V1----V3) suggesting abnormalities in multiple components of the contractile apparatus. To focus more on the regulatory proteins (troponin and tropomyosin), individual proteins of the skeletal and cardiac actomyosin system were reconstituted under controlled conditions. In this way, myosin plus actin and troponin-tropomyosin from the normal and myopathic animals could be studied enzymatically. The proteins were isolated from the skeletal or cardiac muscle of random-bred control and cardiomyopathic hamsters (BIO 53:58) at 7 months of age. Sodium dodecyl sulfate gel electrophoretic patterns indicated differences in the troponin I and troponin C regions of myopathic skeletal muscle, but cardiac samples from control and myopathic hamsters showed similarities in their mobilities. This suggests the possibility of different cardiac isozymes in the regulatory protein complex, as reported in our previous studies of cardiac myosin in cardiomyopathy. Calcium sensitivity was markedly decreased in the actomyosin reconstituted with troponin-tropomyosin from skeletal as well as cardiac muscle from myopathic animals. In summary, our data show that the regulatory proteins in skeletal and cardiac muscle of the myopathic hamsters have decreased inhibitory action on Mg2(+)-actomyosin ATPase activity. This loss of calcium regulation along with shifts in cardiac myosin heavy chain may be partially responsible for the impaired cardiac function in the hearts of myopathic hamsters.

Fluorescence spectroscopic analysis of calpain II interactions with calcium and calmodulin antagonists

1. The intrinsic fluorescence of epoxysuccinyl-inhibited calpain II undergoes a Ca2(+)-dependent decrease which contrasts with the increase observed for calmodulin. 2. Calpain II was inhibited by the calmodulin antagonist toluidinylnaphthalenesulfonate (TNS), and a Ca2(+)-dependent increase in TNS fluorescence intensity was observed for epoxysuccinyl-inhibited calpain II. 3. The calmodulin antagonists calmidazolium CDZ and felodipine both caused decreases in the intrinsic fluorescence of epoxysuccinyl-inhibited calpain II. 4. Increasing concentrations of Ca2+ caused an increase in the fluorescence intensity of the inhibited enzyme in the presence of (CDZ), and a decrease in the presence of felodipine. 5. It is concluded from these studies that Ca2+ and calmodulin antagonists induce conformational changes in calpain II, and that changes occur in regions other than the Ca2(+)-binding domains.

Ca2(+)-dependent proteolytic modification of the cAMP-dependent protein kinase in Drosophila wild-type and dunce memory mutants

Two cAMP-dependent protein kinases with different activation constants were separated from Drosophila melanogaster head extracts. Both are only found in nervous tissue. The first cAMP-dependent kinase, with Mr = 190,000, has been already characterized as tetrameric Drosophila type II cAMP-dependent protein kinase R2C2. The second purified cAMP-dependent protein kinase, with Mr = 80,000, is dimeric in structure RPC, and the cAMP-concentration required for half maximal activation is 4 fold lower than for the type II kinase. The generation of RP can be stimulated in vitro by addition of exogenous calcium and is due to an endogenous Ca2(+)-dependent protease that selectively degrades the regulatory subunit. Extraction in the presence of various protease inhibitors does not affect the amounts of RP, suggesting that the observed quantitative change in RP occurs in vivo. The amounts of RP in the nervous tissue of the memory mutants dunce1 and dunce2, which have increased cAMP levels, are different from the amount of RP in wild-type flies. Also treatments of wild-type flies with drugs affecting cAMP-metabolism and acetylcholine levels led to amounts of RP different from untreated flies.