Increased calcium-activated neutral protease activity in muscles of dystrophic hamsters and mice

Calpains in muscle wasting

Calpains are intracellular nonlysosomal Ca(2+)-regulated cysteine proteases. They mediate regulatory cleavages of specific substrates in a large number of processes during the differentiation, life and death of the cell. The purpose of this review is to synthesize our current understanding of the participation of calpains in muscle atrophy. Muscle tissue expresses mainly three different calpains: the ubiquitous calpains and calpain 3. The participation of the ubiquitous calpains in the initial degradation of myofibrillar proteins occurring in muscle atrophy as well as in the necrosis process accompanying muscular dystrophies has been well characterized. Inactivating mutations in the calpain 3 gene are responsible for limb-girdle muscular dystrophy type 2A and calpain 3 has been found to be downregulated in different atrophic situations, suggesting that it has to be absent for the atrophy to occur. The fact that similar regulations of calpain activities occur during exercise as well as in atrophy led us to propose that the calpains control cytoskeletal modifications needed for muscle plasticity.

Proteolysis results in altered leak channel kinetics and elevated free calcium in mdx muscle

Resting free calcium levels ([Ca2+]i) are elevated in Duchenne human myotubes and mdx mouse muscle and myotubes which lack the gene product dystrophin at the sarcolemma. Increased net muscle protein degradation has been directly related to this elevated [Ca2+]i. The [Ca2+]i rise may result from increased calcium influx via leak channels, which have increased opening probabilities (Po) in dystrophic cells. Dystrophin, therefore, might directly regulate leak channel activity. In intact mdx soleus muscles, protein degradation was reduced to normal levels by leupeptin, a thiol protease inhibitor. In muscle homogenates, leupeptin also abolished calcium-induced increases in protein degradation. When mouse myotubes were cultured in the continuous presence of leupeptin (50 microM), the elevation in mdx resting [Ca2+]i was prevented. Leak channel Po increased with age in mdx myotubes, whereas leupeptin-treated mdx leak channel opening probabilities were always lower or equal to the Po for untreated normal myotubes. These results indicate that increased leak channel activity in dystrophic muscle results in elevated [Ca2+]i levels, but also suggest that dystrophin does not directly regulate channel activity. Instead the results suggest that proteolysis may be responsible for the altered gating of calcium leak channels. The resultant increased channel Po in turn elevates [Ca2+]i, which further increases proteolytic activity in a positive feedback loop, leading to the eventual necrosis of the muscle fibers.

Distribution of calcium-activated protease calpain in the rat brain

Calpain is a calcium-activated neutral protease that degrades a number of cytoskeletal proteins. It may participate in the maintenance of the cytoskeleton and in the rapid turnover of structural proteins associated with synaptic plasticity. Calpain may also be involved in the neurodegeneration that accompanies aging and age-related diseases. To aid in the interpretation of disease-related alterations in staining patterns, the present study examined calpain's normal distribution in the mammalian brain and spinal cord. A monoclonal antibody was employed with the avidin-biotin-peroxidase immunocytochemical technique on samples of rat tissue. Glia (astrocytes, microglia) and virtually all neurons were immunopositive, although neuronal processes exhibited varying staining patterns. The axonal staining pattern depended upon either the origin or destination of the process: those axons remaining within the brain (e.g., corpus callosum) were only lightly immunoreactive, whereas spinal cord and peripheral axons (trigeminal nerve) were more darkly labeled. The architecture of the dendritic tree determined the dendritic staining pattern: neurons with prominent apical and basal dendritic trees (e.g., pyramidal cells) were immunolabeled along their entire extent; labeling of multipolar cells (e.g., hilar cells of dentate gyrus) was limited to the proximal dendrites. The ubiquitous distribution of calpain argues against a primary role for the enzyme in the regional pattern of neuronal death seen in Alzheimer's disease. An alteration in the concentration, localization, or inhibition of the enzyme could, however, lead to the abnormal accumulations of cytoskeletal elements seen with the disease.

High molecular weight kininogen, the extracellular inhibitor of thiol proteases, is deficient in hamsters with muscular dystrophy

High molecular weight kininogen has been shown to be the principal plasma inhibitor of cellular thiol proteases including cathepsins B, H and L and calpains 1 and 2. Since these same enzymes have been reported to be elevated in animals with muscular dystrophy, we studied plasmas from hamsters with muscular dystrophy and compared these to normal hamster plasma. The ability of plasma to inhibit purified platelet calpain was assayed and found to be 62% of normal. Since low molecular weight kininogen can also inhibit calpain, the coagulant activity of kininogen, an activity unique for high molecular weight kininogen, was determined in dystrophic hamster plasma and found to be 69% of normal in close agreement with the calpain inhibitory activity. The contribution of the other plasma calpain inhibitor alpha 2-macroglobulin appeared small since inactivation with methylamine did not alter the ability to inhibit calpain in either normal or dystrophic plasma. We conclude that there is a selective deficiency of plasma high molecular weight kininogen in dystrophic hamsters, an abnormality which could play a role in the pathogenesis of this disorder.

Oxidative stress and muscular dystrophy

Oxidative stress may be the fundamental basis of many of the structural, functional and biochemical changes characteristic of the inherited muscular dystrophies in animals and humans. The presence of by-products of oxidative damage, and the compensatory increases in cellular antioxidants, both indicate oxidative stress may be occurring in dystrophic muscle. Changes in the proportions and metabolism of cellular lipids, abnormal functions of cellular membranes, altered activity of membrane-bound enzymes such as the SR Ca2+-ATPase, disturbances in cellular protein turnover and energy production and a variety of other changes all indicate that these inherited muscular dystrophies appear more like the results of oxidative stress to muscle than any other type of underlying muscle disturbance. Particular details of these altered characteristics of dystrophic muscle, in combination with current knowledge on the processes of oxidative damage to cells, may provide some insight into the underlying biochemical defect responsible for the disease, as well as direct research towards the ultimate goal of an effective treatment.

Calpain and calpastatin levels in dystrophic hamster skeletal muscles

1. Two fast-twitch skeletal muscles from normal and dystrophic hamsters were analysed for their calpain and calpastatin contents. 2. Assays of wide-specificity calpain II showed that the activity levels in the two muscles were increased 1.5 and 1.6 times in dystrophic animals. 3. Analysis of calpastatin levels showed that the respective dystrophic muscles had activity levels of 2.2 and 2.8 times those of control muscles. 4. These results contrast with previous studies on denervated hamster muscles which showed that denervation causes an increase in calpain levels but a decrease in calpastatin levels.

Effects of denervation on calpain and calpastatin in hamster skeletal muscles

Three leg muscles (soleus, extensor digitorum longus, and plantaris) of adult male golden Syrian hamsters were denervated by bilateral transecting of the sciatic nerve. Eighteen days after denervation, wet weights, amounts of soluble protein, and activities of wide-specificity calpain II, intermediate filament protein-specific calpain I, and calpastatin were measured by protein determination and enzyme and immunological assays. In comparison with control (nondenervated) muscles and depending on the specific muscle and protein, the activities of the calpains increased 1.3 to 1.9 times the control values, whereas the calpastatin decreased to one-half and one-third of control values. The muscle which showed the greatest increase in both calpain activities and the largest decrease in calpastatin activity was the plantaris (a fast-twitch, oxidative glycolytic muscle). The extensor digitorum longus (fast-twitch glycolytic) showed increases in calpain II activity similar to those in the plantaris, but smaller changes in calpain I and calpastatin. The soleus (slow-twitch, oxidative) showed the smallest changes in calpain II and calpastatin activities, although an increase in the calpain I activity was seen after denervation. These results suggest a possible relationship between the presence of fast-twitch, oxidative glycolytic fibers in a muscle and increased potential for intracellular proteolysis following denervation.

Calcium-dependent proteolysis in the myocardium of rats subjected to stress

Activity of a calcium-dependent neutral protease (calpain II) and its specific endogenous inhibitor was investigated in the myocardium of rats subjected to different stressors: cold, anaesthesia, 24 and 48 h starvation and food restriction for 7 and 14 days. Enzyme and inhibitor activities were determined in the 37,200 g supernatant of homogenates prepared from the free left ventricular wall of the heart. The specific activity of the myocardial calcium-dependent proteinase increased in all rats exposed to stressful stimuli, reaching maximum values in animals starved for 48 hours. Decrease in the specific activity of the inhibitor accompanied the changes in enzyme activity. Differences from normal control values were statistically significant in the starved animals and in animals fed a restricted diet for 7 or 14 days. These observations suggest that interaction between calpain II and its specific inhibitor plays a role in the regulation of the enzyme activity and furthermore, that stressful stimuli lead to increased calcium-dependent proteolysis in the myocardium.

Calcium-activated neutral protease and its endogenous inhibitor in tissues of dystrophic and normal mice

Calcium-activated neutral protease (milli-CANP) and its endogenous inhibitor are elevated in muscle tissues, primarily the skeletal muscle and heart, of dystrophic mice (C57BL/6J dy/dy) as compared to the control strain (C57BL/10J). Tissues showing relative increase of CANP also show significant loss of enzymes such as CK, LDH in comparison to plasma, where these enzymes register a significant increase. PK is lost minimally from these tissues, probably showing a "sparing effect." Absence of any significant change in CANP activity in the liver points to a specific role of CANP in the dystrophic process. In the skeletal muscle the endogenous CANP inhibitor registers a concomitant increase with CANP without altering the enzyme/inhibitor ratio.

Brain spectrin, calpain and long-term changes in synaptic efficacy

This chapter discusses the possibility that proteolytic digestion of cytoskeletal proteins, in particular spectrin, is part of the mechanisms through which physiological activity elicits structural and chemical changes in brain synapses. Recent work from several laboratories has produced a description of the initial events that trigger the long-term potentiation (LTP) of synaptic responses that appears in hippocampus after brief episodes of high frequency electrical stimulation. A likely sequence is as follows: suppression of IPSPs, prolongation of EPSPs, activation of N-methyl-D-aspartate (NMDA) receptors, influx of calcium into target cells. After briefly describing the evidence for this triggering sequence, the review takes up the question of what types of calcium sensitive chemistries are available to synaptic region that could produce functional changes lasting for weeks (i.e., for LTP). It is argued that the partial degradation of spectrin by a calcium-activated protease (calpain) provides a mechanism of this type. Spectrin is a substrate for calpain and both it and a breakdown product comparable to that produced by calpain are found in postsynaptic densities. Moreover, there is substantial evidence that spectrin regulates the surface chemistry and morphology of cells and thus its partial degradation would be expected to produce pronounced and persistent modifications in synapses. To reinforce this point, the review discusses recent findings suggesting that calpain mediated proteolysis of spectrin and other cytoskeletal proteins produces substantial changes in the shape of blood-borne cells and the distribution of their surface receptors.(ABSTRACT TRUNCATED AT 250 WORDS)

Calcium-activated protease activity in tenotomized muscle

The purpose of this study was to investigate the possible role of calcium-activated neutral protease in the disorganization and dissolution of the myofibrils of the rat soleus that occurs following tenotomy. Rats were killed 3, 5, 7, 14, 21, and 42 days after tenotomy of the soleus, and the muscles were removed and assayed for calcium-activated protease activity. Maximal protease activity occurred 1 week after tenotomy, at the time when myofibril organization is completely disrupted. Activity was still high 2 and 3 weeks after the operation, but returned to normal levels by 6 weeks, when muscle histology had returned to normal. The time course of the calcium-activated protease activity corresponded closely to the time course of the morphological changes. Thus, calcium-activated neutral protease may play a major role in myofibrillar proteolysis following tenotomy and in making the myofibril susceptible to proteolytic attack by other, less specific proteases.

Characterization of calpains and calpastatins from hamster skeletal muscle

1. Hamster skeletal muscle contains a wide-specificity calpain which was found to be a calpain II type and which is composed of a single Mr 80,000 polypeptide. 2. The muscle also contains a calpain I type enzyme which is specific for desmin degradation, and this enzyme consists of a single subunit of Mr 67,000. 3. Three calpastatins were detected in the tissue, one of which inhibited both calpains, whereas the other two appeared to be specific for the desmin-specific calpain. These calpastatins possessed the same inhibition properties when assayed with chicken gizzard calpains.

Elevations of cathepsin B and cathepsin L activities in forelimb and hind limb muscles of genetically dystrophic mice

The combined activities of cathepsin B and cathepsin L were studied in the forelimb and hind limb muscles of dystrophic mice. The activities of these proteases in the forelimb and hind limb muscles of young and adult dystrophic mice were significantly higher than those in normal mice. However, clinical involvement of dystrophy appeared in the hind limbs but not in the forelimbs. We therefore suggest that the increase in protease activity begins at a very early age and that the clinical involvement is not linked with the increase in cathepsin B and L.

Beneficial effect of chymostatin on dystrophic mice

We studied the effect of chymostatin on dystrophic mice (C57BL/6J-dy). The locomotor activity of normal mice increased markedly, attaining a plateau at 8 weeks of age, whereas in dystrophic mice, it increased until the age of 7 weeks, and thereafter decreased gradually. Serum levels of creatine phosphokinase were significantly higher in dystrophic mice compared with normal mice, and dystrophic mice had a reduced muscle protein content. When 3-week-old dystrophic mice received chymostatin (1 mg/kg, i.p.), the decrease in locomotor activity was retarded, serum enzyme levels decreased significantly, and muscle protein content increased significantly. In addition, the survival time of treated dystrophic mice was prolonged. The locomotor activity, serum enzyme levels, and muscle protein content of normal mice were not affected by chymostatin. Therefore, we posit that chymostatin retarded the progression of dystrophy in mice.

Defective synthesis of polyunsaturated phosphatidylcholines as the primary lesion in Duchenne and murine dy muscular dystrophies

An impaired synthesis of highly unsaturated phosphatidylcholines of the sarcoplasmic reticulum is suggested to be the primary defect in Duchenne and murine dy muscular dystrophies. The lesion is proposed to occur at the level of de novo glycerophosphorylcholine synthesis. These phosphatidylcholine species are postulated to be required for the Ca2+ transport ATPase of this organelle.

Beneficial effect of new thiol protease inhibitors, epoxide derivatives, on dystrophic mice

We studied the effect of E-64, a new thiol protease inhibitor derived from Aspergillus japonicus TPR-64, and of its synthesized analogue, E-64-d, on dystrophic mice (C57BL/6J-dy). The locomotor activity of normal mice increased markedly, reaching a plateau at 8 weeks of age. In dystrophic mice, it increased until they were 7 weeks old, thereafter, it decreased gradually. This decrease reflected the degradation of the hind legs. Serum activities of creatine phosphokinase were significantly greater in dystrophic than in normal mice. When 3-week-old dystrophic mice were injected with E-64 (1 mg/kg, i.p.) or E-64-d (40 to 60 mg/kg, p.o.), the decrease in their locomotor activity was retarded and their serum enzyme activities decreased significantly. In addition, the survival time of treated dystrophic mice was prolonged. The locomotor activity of normal mice and their serum enzyme levels were not affected by the administration of E-64-d. We posit that the new thiol protease inhibitors we tested retard the progression of dystrophy in mice.

Muscle damage induced by the ionophore A23187 can be prevented by prostaglandin inhibitors and leupeptin

Frog skeletal muscle incubated in vitro with the ionophore A23187 shows extensive morphological alterations. Myofilament disruption, presumably mediated by excess intracellular calcium, can be partially prevented by preincubating the muscle with inhibitors of prostaglandin synthesis and the lysosomal thiol protease inhibitor leupeptin.

Distribution of calpain I, an enzyme associated with degenerative activity, in rat brain

The calcium-activated protease calpain I was localized in rat brain by immunocytochemistry. Calpain I-like immunoreactivity (CLI) was prominent in several structures in which degeneration is an ongoing feature, e.g. spinal motoneurons, olfactory nerve. Also noteworthy was the presence of CLI in regions susceptible to age-related pathologies, e.g. cerebellar Purkinje cells, substantia nigra and subiculum. This distribution suggests that calpain I may be involved with both normal and pathological neuronal degeneration.

Impaired biosynthesis of highly unsaturated phosphatidylcholines: a hypothesis on the molecular etiology of some muscular dystrophies

A brief review of the literature concerning the synthesis of phosphatidylcholine and phosphatidylethanolamine in muscle suggests that the cytidine pathways are replaced by the recently proposed acyl-specific de novo and salvage glycerolphosphodiester pathways (Infante, 1984) in fully differentiated muscle. An analysis of published data suggests an impaired synthesis of 4,7,10,13,16,19-docosahexaenoic phosphatidylcholine, at the level of de novo sn-3-glycerolphosphorylcholine synthesis, as the primary defect in Duchenne and (dy) murine muscular dystrophies. This phosphatidylcholine species is postulated to be required for optimum sarcoplasmic Ca2+ transport activity. It is proposed that this impairment initiates the secondary series of events which lead to the observed pathology of these diseases. Based on some predictions of the hypothesis, potential diagnosis and treatments are suggested.

Quantitation of tissue calpain activity after isolation by hydrophobic chromatography

A rapid and reliable method for quantitating tissue calpains (Ca2+-activated, neutral, thiol proteases) was developed using hydrophobic chromatography with phenyl-Sepharose. Calpains I and II isolated by this method are free of endogenous inhibitor(s) (calpastatin), activator(s), and nonspecific proteases. These calpains expose hydrophobic regions in the presence of Ca2+ and bind tightly to phenyl-Sepharose. Inactivation of bound calpain is prevented by the addition of leupeptin (20 microM). Calpains I and II bound initially by phenyl-Sepharose in a Ca2+-dependent manner are then eluted successively on the basis of their Ca2+-independent binding to phenyl-Sepharose. Because calpastatin may prevent binding of calpain to phenyl-Sepharose by forming a protease-inhibitor complex in the presence of Ca2+, preadsorbing the protease to a suspension of phenyl-Sepharose beads initially in the absence of Ca2+ separates most of the calpain present in tissue extracts from calpastatin. The isolated calpains obtained are assayed by casein digestion. This quantitation procedure is suitable for measuring calpain activity in various tissues and cells including erythrocytes.

Muscle cell membranes from early degeneration muscle cell fibers in Solenopsis are leaky to lanthanum: electron microscopy and X-ray analysis

Lanthanum infusion techniques, transmission electron microscopy, and X-ray microanalysis were utilized to compare the permeability of muscle cell membranes from normal and degenerating muscle fibers of Solenopsis spp. In normal fibers, the electron-dense tracer was limited to components of the sarcotubular system. However, the insemination-induced degeneration of muscle fibers was characterized by the presence of an electron-dense precipitate within the myofibrils and mitochondria as well as in the extramyofibrillar spaces. The electron-dense material was subsequently identified by elemental analysis to be lanthanum. Such data indicate that one of the earliest stages of muscle degeneration involves an alteration in cell membrane permeability.

Myofibrillar M-line structure in normal and dystrophic hamster muscle

The presence of the specific myofibrillar M-line marker, myomesin , in isolated myofibrils and cryosections of skeletal and heart muscle as well as its appearance during differentiation in skeletal and heart muscle cell cultures of normal and dystrophic hamsters were evaluated. By means of the indirect immunofluorescence technique employing antibodies against chicken M-line proteins, the appearance of antigen localized in the M-line was investigated. No difference could be found between the M-line structure of normal and dystrophic animals. The results suggest that the M-line proteins, apparently relatively stable, are not primarily affected by the disease.

Intracellular elemental content of cardiac and skeletal muscle of normal and dystrophic hamsters

To test the hypothesis that the genetic lesion causing muscular dystrophy might be reflected in an abnormal intracellular elemental content, the elemental content of individual cardiac and skeletal muscle fibers in 50-day-old male control and cardiomyopathic BIO 53.58 hamsters was determined. The technique of electron probe x-ray microanalysis of freeze-dried tissue was employed. No electrolyte content differences were found between control and diseased animals for nuclei, myofibrillar cytoplasm, or mitochondrially-enriched cytoplasm of cardiac myocytes. Sulfur was elevated in dystrophic cardiac myocytes and was the only element significantly different in heart tissue of control and cardiomyopathic animals. Sulfur was also elevated in dystrophic soleus muscle fibers. The pattern of electrolyte content of these cells reflected a mixture of normal cells and damaged cells with altered electrolyte content. In this hamster model, alteration of electrolyte content of myocytes appears to be a result of the disease process and not an inherent characteristic of muscular dystrophy. The elevated sulfur in dystrophic hamster myocytes reflects a biochemical lesion which deserves further study.

Ca2+-activated protease in denervated rat skeletal muscle measured by an immunoassay

Right hind leg muscles of adult male rats were denervated by transecting the sciatic nerve, while muscles of the left leg served as a control. On days 4, 9, and 18 after denervation, the rats were killed and the extensor digitorum longus and soleus muscles removed. Extracts were prepared which contained the Ca2+-activated protease. The molecular weight of the protease in the extracts, measured immunologically on Western blots of SDS-polyacrylamide gels, was identical to that of purified standard protease and was unaffected by denervation. The amount of protease in each extract was measured by a solid phase immunoassay using monospecific IgG labeled with 125I, and the results were expressed as units of protease activity per milligram noncollagen protein. There were increases of 40 to 80% in the mean values obtained for both denervated muscles compared with controls. Because the protease is probably localized on the cell membrane, these modest increases are likely to be a consequence of a generalized over-development of muscle membranes which follows denervation.

Calmodulin content and Ca-activated protease activity in dystrophic hamster muscles

As part of a study on the implication of elevated Ca2+ levels in the myofibrillar degeneration seen in dystrophic muscle, the content of calmodulin and the activity of Ca2+-activated neutral protease (CANP) have been measured in normal and dystrophic (UM-X7.1) hamsters. Calmodulin levels, expressed as micrograms +/- SEM per gram wet weight were highest in brain (385 +/- 24.7), followed by tongue (93.88 +/- 3.93), heart (42.13 +/- 2.93), and skeletal muscle (31.69 +/- 1.42). No significant increases in calmodulin were observed in the dystrophic tissues thus suggesting that the Ca2+ accumulations observed in dystrophic muscles are unrelated to changes in a calmodulin levels. Because of the complexity of regulation of CANP, a time-dependent study was done using extracts of skeletal, heart, and tongue muscles. Marginal increases in dystrophic CANP were seen in skeletal muscle at all times studied and in the heart and tongue at initial time points only. The data are discussed in terms of rising levels of Ca2+ in muscles of the UM-X7.1 hamster being sufficient to increase CANP activity (without increasing content) to where it causes Z-line dissolution.

Ca2+-uptake properties of two populations of mitochondria from normal and denervated rat soleus muscle

Ultraturrax- and Nagarse-released populations of mitochondria were characterized with respect to their Ca2+-uptake activities (i) by means of the indirect polarographic technique and (ii) directly by the 45Ca Ruthenium Red-quench method of Reed & Bygrave [(1974) Biochem. J. 140, 143-155]. The denervated-muscle subsarcolemmal and intermyofibrillar mitochondrial fractions displayed markedly decreased rates and capacities for Ca2+ uptake compared with their respective controls. The implications of these findings with respect to the process of cell necrosis are discussed.

Biochemical functioning of mitochondria in normal and denervated mammalian skeletal muscle

Mitochondrial preparations derived from denervated rat skeletal muscle and paired control muscle are characterized with respect to their oxidative and phosphorylative capacities. Our data indicate that there is an impairment within the first 2 energy coupling regions of the respiratory chain and within the ATPase complex itself.

Dynamic aspects of structural proteins in vertebrate skeletal muscle

In this review, our current knowledge on the structural proteins of vertebrate skeletal muscle is briefly outlined. Structural proteins include the contractile proteins (actin and myosin), the major regulatory proteins (troponin and tropomyosin), the minor regulatory proteins (M-protein, C-protein, F-protein, I-protein, and actinins), and the scaffold proteins (connectin, desmin, and Z-protein). In addition, the relative turnover rates of the muscle proteins (M-protein greater than or equal to troponin greater than soluble protein as a whole greater than tropomyosin not equal to alpha-actinin greater than myosin greater than 10S-actinin greater than actin) are discussed. The changes in the turnover of muscle proteins are compared in denervated and dystrophic muscles. The properties of the various proteases in muscle, including alkaline protease, calcium-activated neutral protease (CANP), and acidic protease (cathepsins), and the structural alterations of myofibrils by these proteases are also described. Finally, the role of proteases and their inhibitors in diseased muscle is summarized, with focus on CANP and its inhibitors, leupeptin and E-64.

Parathyroid ablation in dystrophic hamsters. Effects on Ca content and histology of heart, diaphragm, and rectus femoris

Cumulative evidence indicates that there is an increased accumulation of calcium in dystrophic muscle and that this may have a pathophysiological role in the progression of the dystrophic process. The accumulation may be related to a defect of the plasma membrane. Because parathyroid hormone (PTH) stimulates calcium influx into the cytosol, the chronic effects of surgical ablation of the parathyroid glands on muscle Ca, Mg, protein synthesis, and histology, as well as plasma creatine phosphokinase (CPK), Ca, and Mg, were studied in normal and dystrophic (BIO 14.6) hamsters. Thyroparathyroidectomized (TPTX) hamsters receiving replacement doses of l-thyroxine were killed at age 90 d, 55 d after TPTX. In intact dystrophic hamsters, the Ca content in the heart was 20 times higher than in normal animals and was reduced by half in TPTX dystrophic hamsters. Similar results were observed in diaphragm and rectus femoris. No abnormalities in Mg content were observed in intact or TPTX dystrophic hamsters. Ether-extractable fat of the heart and diaphragm was reduced in dystrophic hamsters and was not modified by TPTX. Protein synthesis was enhanced in the diaphragm of dystrophic hamsters but was not changed by TPTX. The concentration of CPK in plasma was elevated in dystrophic hamsters and fell significantly after TPTX. In the latter animals, microscopic examination of the heart showed lesser signs of dystrophy, particularly in the degree of fibrosis. To determine the degree of dystrophy at the age when TPTX was performed, identical analyses were made in 35-d-old hamsters. Definitive histological signs of dystrophy were observed, and although the Ca content in heart, diaphragm, and rectus femoris was elevated, the values were lower than in 90-d-old intact and TPTX dystrophic hamsters. This indicates that chronic TPTX in dystrophic hamsters reduces, but does not arrest, the dystrophic process. In normal hamsters, a 50% reduction in plasma Ca concentration was observed 6 h after TPTX; 55 d after TPTX, however, plasma Ca was within normal limits in both normal and dystrophic hamsters. No parathyroid tissue was observed in serial sections of the trachea and adjacent tissues in TPTX animals. This suggests that in chronically TPTX hamsters fed a standard laboratory diet, plasma Ca can be maintained by mechanisms independent of parathyroid function. THE DATA INDICATE THAT IN DYSTROPHIC HAMSTERS TPTX CAUSES A MARKED REDUCTION IN: (a) muscle Ca accumulation, (b) levels of plasma CPK and, (c) intensity of histological changes in the heart. These changes were independent of the levels of plasma Ca and were not observed in normal hamsters. We conclude that PTH accentuates the dystrophic process, probably by enhancing the already increased Ca flux into muscle (apparently caused by defective sarcolemma). We postulate that normal secretion of PTH may have a deleterious effect in congenital or acquired conditions associated with altered plasma membranes.

Increased muscle calcium. A possible cause of mitochondrial dysfunction and cellular necrosis in denervated rat skeletal muscle

Mitochondrial preparations derived from denervated rat skeletal muscle and paired controls were characterized with respect to their ability to take up externally added Ca2+. The denervated and control muscle homogenates and mitochondrial [Ca2+] were also determined. Our data indicate that the denervated mitochondria are able to take up less Ca2+ than the controls before uncoupling occurs. This defect is associated with elevated [Ca2+] in homogenate and mitochondrial fractions in the denervated state. The causal relationship between Ca2+ overload, mitochondrial functional damage and cell necrosis is discussed.

Protein degradation in the mouse visual system. I. Degradation of axonally transported and retinal proteins

The analysis of proteolysis in the nervous system is complicated by the heterogeneity of cell types, extensive reutilization of liberated amino acids, and artifacts that may arise when the integrity of the tissue is disrupted during experimentation. For these reasons, changes in proteolytic activity that are observed during brain development and in neuropathological states may often be difficult to interpret. To minimize these problems, we have developed a technique that permits protein degradation to be investigated specifically within axons of the mouse retinal ganglion cells (RGC). In the present study, the method has been used to examine the degradation of proteins conveyed in the slow phases of axoplasmic transport. When adult C57Bl/6J mice were injected intravitreally with L-[3H]proline, labeled proteins within the primary optic pathway (optic nerve and tract) after 5 days were almost exclusively the slow phase axonal proteins. The rate of degradation of these proteins was then determined within the excised, but otherwise intact, optic pathway by measuring the release of acid soluble radioactivity at 37 degrees C in vitro. At physiological pH, the amino acids released by proteolysis were extensively reutilized. Unless amino acid reutilization was prevented, protein degradative rates were artifactually lowered 3-fold. At least two proteolytic systems within RGC axons actively degraded the slowly transported axonal proteins. A 'neutral' system, stimulated by exogenous calcium ions, was optimally active within the physiological pH range (pH 7.0--7.8). The rate of protein degradation at pH 7.4 was uniform along the RGC axon. An 'acidic' system was optimally active with the incubation was carried out at pH 3.8. This proteolytic activity was calcium-independent and exhibited a proximodistal gradient within the RCG axon with higher activity proximally. Similar proteolytic activities were present in isolated intact retinas but in different proportions. The half-lives of axonal and retinal proteins were comparable to CNS protein half-lives estimated in vivo by methods that take amino acid reutilization into account. These and other recent findings demonstrate the utility of this neuron-specific approach in characterizing proteolytic processes within one cell type that may otherwise be obscured by proteolytic events in other cells when brain tissue is analyzed by conventional methods.

Intracellular calcium and pathogenesis and antenatal diagnosis of Duchenne muscular dystrophy

One of the earliest and most important abnormalities of fetal muscle in Duchenne muscular dystrophy is an increase in eosinophilic fibres (those that stain darkly with eosin). A study of normal and at-risk male fetuses after abortion was carried out, which showed that these eosinophilic fibres contain increased intracellular calcium, which suggests that this is an early biochemical change in the disorder. Since increased intracellular calcium would account for various biochemical and clinical features of the disease, it may be related to the primary defect. Thus an increase in muscle fibres containing increased intracellular calcium in at-risk fetuses may provide an additional means of assessing the validity of any future presumptive antenatal test for Duchenne muscular dystrophy.