A Ca2+-activated protease possibly involved in myofibrillar protein turnover. Subcellular localization of the protease in porcine skeletal muscle

Ventilator-induced diaphragm dysfunction: phenomenology and mechanism(s) of pathogenesis

Mechanical ventilation (MV) is used to support ventilation and pulmonary gas exchange in patients during critical illness and surgery. Although MV is a life-saving intervention for patients in respiratory failure, an unintended side-effect of MV is the rapid development of diaphragmatic atrophy and contractile dysfunction. This MV-induced diaphragmatic weakness is labelled as 'ventilator-induced diaphragm dysfunction' (VIDD). VIDD is an important clinical problem because diaphragmatic weakness is a risk factor for the failure to wean patients from MV. Indeed, the inability to remove patients from ventilator support results in prolonged hospitalization and increased morbidity and mortality. The pathogenesis of VIDD has been extensively investigated, revealing that increased mitochondrial production of reactive oxygen species within diaphragm muscle fibres promotes a cascade of redox-regulated signalling events leading to both accelerated proteolysis and depressed protein synthesis. Together, these events promote the rapid development of diaphragmatic atrophy and contractile dysfunction. This review highlights the MV-induced changes in the structure/function of diaphragm muscle and discusses the cell-signalling mechanisms responsible for the pathogenesis of VIDD. This report concludes with a discussion of potential therapeutic opportunities to prevent VIDD and suggestions for future research in this exciting field.

Influence of unilateral tooth loss in the temporomandibular joint and masseter muscle of rabbits

OBJECTIVE

The purpose of this study was to evaluate the influence of the masticatory system in patients with missing teeth.

STUDY DESIGN

The influence of tooth loss on the masticatory system was analyzed with the use of bone scintigraphy ((99m)Tc-MDP) and histochemistry. Eight white rabbits (New Zealand, 12 weeks old) were used. The rabbits were divided into 2 groups: 6 weeks and 12 weeks. Teeth were extracted unilaterally in each rabbit under general anesthesia. Six and 12 weeks after extraction, scintigraphy was conducted, and the rabbits were killed and their masseter muscles removed for histochemical analysis.

RESULTS

The results of bone metabolism (relative ratio) measured by bone scintigraphy were 48.27% at extraction sites and 51.73% at nonextraction sites at 6 weeks and 39.96% at extraction sites and 60.04% at nonextraction sites at 12 weeks. There was a significant difference at 12 weeks (P < .05). Tissue calcium contents and osteoclast counts showed different results between the extraction and nonextraction sites, but these differences did not reach statistical significance.

CONCLUSIONS

The bone metabolism of temporomandibular joints and histochemical aspects of masticatory muscles may be associated with occlusal alterations following tooth loss.

Drosophila Calpain B is monomeric and autolyzes intramolecularly

Drosophila calpains, Calpain A and Calpain B, show typical calpain domain structures similar to mammalian calpains. However, the small subunit of mammalian calpains, shown to be essential in both genetic and biochemical aspects, is absent in Drosophila calpains and is not required for enzymatic activity. How they compensate for the lack of small subunit is mostly unknown. Here we conducted experiments using recombinant Drosophila Calpain B for further characterization of the enzyme with particular focuses on two issues: possibility of homodimerization and mode of autolysis. The native molecular weight of Calpain B indicates that the active enzyme is primarily monomeric. Co-expression of two recombinant Calpain B proteins each with a unique affinity tag and a subsequent single round of affinity tag purification resulted in isolation of only one recombinant calpain type, suggesting there is no homodimeric interaction. Also the C-termini of Drosophila calpains lack many of the key hydrophobic residues considered to be important in the dimerization of mammalian calpains. Further, initial autolysis of Calpain B seems to occur intramolecularly, which supports the monomeric nature of Drosophila calpains. These results strongly suggest that dimerization is not an essential requirement for Drosophila calpains.

Effect of postmortem storage on activity of mu- and m-calpain in five bovine muscles

An in situ system involving incubation of 60- to 80-g pieces of muscle at 4 degrees C under different conditions was used to determine the effects of time of postmortem storage, of pH, and of temperature on activities of mu- and m-calpain activity in bovine skeletal muscle. Casein zymograms were used to allow measurement of calpain activity with a minimum of sample preparation and to ensure that the calpains were not exposed to ionic strengths of 100 or greater before assay of their activities. In 4 of the 5 muscles (longissimus dorsi, lumbar; longissimus dorsi, thoracic; psoas major; semimembranosus; and triceps brachii) studied, mu-calpain activity decreased nearly to zero within 48 h postmortem. Activity of m-calpain also decreased in the in situ system used but at a much slower rate. Activities of both mu- and m-calpain decreased more slowly in the triceps brachii muscle than in the other 4 muscles during postmortem storage. Although previous studies have indicated that mu-calpain but not m-calpain is proteolytically active at pH 5.8, these studies have used calpains obtained from muscle at death. Both mu- and m-calpain are proteolytically inactive if their activities are measured at pH 5.8 and after incubating the muscle pieces for 24 h at pH 5.8. Western analysis suggested that neither the large 80-kDa subunit nor the small 28-kDa subunit of m-calpain was autolyzed during postmortem storage of the muscle pieces. As has been reported previously, the 80-kDa subunit of mu-calpain was autolyzed to 78- and then to a 76-kDa polypeptide after 7 d postmortem, but the 28-kDa small subunit was not autolyzed; hence, the autolyzed mu-calpain molecule in postmortem muscle is a 76-/28-kDa molecule and not a 76-/18-kDa molecule as previously assumed. Because both subunits were present in the postmortem calpains, loss of mu-calpain activity during postmortem storage is not due to dissociation of the 2 subunits and inactivation. Although previous studies have shown that the 76-/18-kDa mu-calpain molecule is completely active proteolytically, it is possible that the 76-/28-kDa mu-calpain molecule in postmortem muscle is proteolytically inactive and that this accounts for the loss of mu-calpain activity during postmortem storage. Because neither mu- nor m-calpain is proteolytically active at pH 5.8 after being incubated at pH 5.8 for 24 h, other proteolytic systems such as the caspases may contribute to postmortem proteolysis in addition to the calpains.

Subcellular localization and in vivo subunit interactions of ubiquitous mu-calpain

Ubiquitously expressed calpains are Ca(2+)-dependent, intracellular cysteine proteases comprising a large catalytic subunit (domains DI-DIV) and a noncovalently bound small regulatory subunit (domains DV and DVI). It is unclear whether Ca(2+)-induced calpain activation is followed by subunit dissociation or not. Here, we have applied advanced fluorescence microscopy techniques to study calpain subunit interactions in living cells using recombinant calpain subunits or domains fused to enhanced cyan and enhanced yellow fluorescent reporter proteins. All of the overexpressed variants of the catalytic subunit (DI-IV, DI-III, and DI-IIb) were active and Ca(2+)-dependent. The intact large subunit, but not its truncated variants, associates with the small subunit under resting and ionomycin-activated conditions. All of the variants were localized in cytoplasm and nuclei, except DI-IIb, which accumulates in the nucleus and in nucleoli as shown by microscopy and cell fractionation. Localization studies with mutated and chimeric variants indicate that nuclear targeting of the DI-IIb variant is conferred by the two N-terminal helices of DI. Only those variants that contain DIII migrated to membranes upon the addition of ionomycin, suggesting that DIII is essential for membrane targeting. We propose that intracellular localization and in particular membrane targeting of activated calpain, but not dissociation of its intact subunits, contribute to regulate its proteolytic activity in vivo.

Early changes induced in the left ventricle by pressure overload. An experimental study on swine heart

The purpose of this study was to evaluate the early changes in sarcoplasmic reticulum (SR) function and the parallel morphological and hemodynamic modifications occurring in the heart following pressure overload. As regards SR function, we also explored the levels of acylphosphatase, an enzyme which might have a regulatory effect on the SR Ca(2+) pump by hydrolyzing the phosphorylated intermediate of this transport system. Pigs subjected to pressure overload by aortic stenosis for 6, 12, 24, 48, 72, and 96 h were compared to sham-operated controls. At each of the considered times both SR Ca(2+)-ATPase activity and Ca(2+) uptake, as well as acylphosphatase activity, were significantly enhanced in the pressure overloaded compared to the control hearts, with a maximal increase at 6 h; moreover, a positive and significant correlation was found between these parameters. The modifications in the activities of Ca(2+)-ATPase and acylphosphatase reflected an increased expression of these proteins, while phospholamban did not show significant changes in its concentration nor in its phosphorylation status. As for hemodynamic parameters, rapid changes in the left ventricular function were observed and especially the early hours following the aortic stenosis appeared to be crucial for the adjustment of heart function. The most relevant morphological finding was a focal disarrangement of the myofibrillar pattern which was very evident at 6 h, and progressively attenuated at later times. Taken together our data suggest that an early adaptation to the increased hemodynamic working overload is a consistent activation of the contractile apparatus which reflects, at least in part, an enhanced SR function. Besides the changes in Ca(2+) pump protein expression, increased acylphosphatase levels might also contribute to this effect.

Morphologic and biochemical changes of the masseter muscles induced by occlusal wear: studies in a rat model

Occlusal alterations may result in changes in the functional performance of masticatory muscles. In this study, we set up an experimental model in rats to examine whether masticatory muscle abnormalities occur after a malocclusion is induced. Rats underwent unilateral amputation of the molar cusps to simulate an occlusal wear situation. The masseter muscles ipsilateral and contralateral to the amputated molars were excised at different experimental times. Sham-operated rats were used as controls. The tissue samples were studied by light and electron microscopy and morphometry. Tissue calcium content, a biochemical index of muscle injury, was also determined. The results show that occlusal dysfunction leads to microvessel constriction and clear-cut morphologic damage of muscular fibers and blood capillary endothelium, as well as to elevation of tissue calcium content, in the ipsilateral masseter muscle. These changes are likely related to muscle fatigue and ischemia. The early signs of injury do not involve the entire muscle but are mostly restricted to tissue areas rich in type I (slow) muscle fibers, which are characterized by a predominantly aerobic metabolism. The muscle damage becomes more extended and severe with time. On the other hand, the contralateral muscles show only slight alterations which are reversible with time, possibly due to an adaptive response.

Distribution of mu-calpain proenzyme in the brain and other neural tissues in the rat

We raised antibodies against the acetyl N-terminal peptide of the human mu-calpain 80 kDa (80 K) subunit (N-acetyl SEETPVYCT-GVSAQVQKQRARELG) in the rabbit. A specific antibody was purified using N-acetyl SEEITPVYCTGVSAQVQKQ peptide-conjugated Sepharose 4B as an affinity gel support. Epitope analysis revealed that the purified antibody reacted only with mu-calpain N-terminal peptides containing N-acetyl SEETT structure but no reactions occurred with other analogous peptides. Western blot analysis showed that the antibody reacted with both human and rat mu-calpain proenzymes but not with the activated calpains lacking N-terminal peptide. Using this antibody we investigated immunohistochemically the distribution of mu-calpain proenzyme in central and peripheral nervous systems as well as other non-neural tissues in the rat. The proenzyme was detected mainly in neurons both in the central and peripheral nervous tissues, but not in non-neural tissues except for red blood cells. Immunoreaction was stronger in the perikarya and/or in the nuclei than in-the cytoplasm. Specificity of the antibody was verified by an absorption test. In summary, the mu-calpain proenzyme is mainly distributed in the perikarya and/or nuclei or neurons. Our present antibody specific to the N-terminus of the mu-calpain 80 K subunit could serve as a useful tool to detect various functions of mu-calpain as well as the damage in neurons caused by the enzyme.

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+.

Immunohistochemical localization of calpains and calpastatin in the rabbit eye

The localization of the two Ca-activated extralysosomal proteases m-calpain and mu-calpain in the eye of the adult rabbit was examined by immunohistochemistry, using poly- and monoclonal antibodies against the corresponding rabbit antigens. Immunoreactivity against the two forms of calpains was observed in the epithelial cells on the external and internal surface of the cornea as well as in the epithelial cells covering the iris and ciliary body. The sclera and choroid layers showed a relatively weak immunoreactivity. Using anti m-calpain antibodies, the pigment epithelium in the retina was heavily labelled as well as the outer and inner plexiform layers. The other and inner borders of the Müller cells were clearly labelled. The outer segments of the receptor cells showed a strong immunoreactivity for both mu-calpain and m-calpain. Labelling was also observed in the retinal ganglion cells and in the nerve fiber layer. The immunohistochemical localization of calpastatin, an endogenous inhibitor of both m- and mu-calpain was also examined. A high level of calpastatin immunoreactivity was observed in the outer segments of the receptor cells. The results may be compatible with a role for calpains, especially m-calpain, in the secretory/phagocytic process and as modulators of the cytoskeleton in cell processes.

A comparison of the intracellular distribution of mu-calpain, m-calpain, and calpastatin in proliferating human A431 cells

Little is known about the relative intracellular localizations of the calcium-dependent proteases, calpains, and their naturally occurring inhibitor, calpastatin. In the present study, the intracellular localization of mu-calpain, m-calpain, and calpastatin was studied at the light microscopic level in proliferating A431 cells. Highly specific antibodies against the three antigens revealed distinct staining patterns in interphase and mitotic cells. Most notably, calpastatin in interphase cells was localized near the nucleus in tube-like, or large granular structures, while the calpains were more uniformly distributed through the cytoplasm in either a fibrillar form (mu-calpain) or a diffuse or fine granular form (m-calpain). The distribution patterns of the two calpain isozymes were distinctly different during mitosis. m-Calpain was concentrated at the mitotic spindle poles and midbody, while mu-calpain appeared to accumulate at the cell membrane and the spindles. Four other human cell lines as well as normal human monocytes were examined to determine if the calpains-calpastatin segregation patterns are common to other cells or are unique to the A431 line. With the exception of abundant nuclear mu-calpain in the C-33A cervical carcinoma, the segregation of the proteins was similar to that of A431. These studies indicate that calpains may be localized at regions which are relatively poor in calpastatin content. Proteins at these sites may be susceptible to calpain-catalyzed cleavage.

Calpain inhibitor in rabbit skeletal muscle: an immunochemical and histochemical study

Calpastatin, the endogenous inhibitor of calcium-activated neutral proteases (calpains; EC 3.4.22.17), was studied in the rabbit vastus lateralis muscle by means of immunochemical and immunohistochemical techniques. Immunoaffinity chromatography using an antibody raised against the 34-kDa monomer of the 68-kDa dimeric inhibitor allowed us to isolate three main proteins (130-, 100- and 80-kDa). These proteins strongly inhibited calpain activity in muscle homogenate (I50 at about 50 micrograms/ml). Immunohistochemical experiments showed that calpastatin-related immunoreactivity was present in all fibre types (oxidative, glycolytic, oxidative-glycolytic) at both surface and cytoplasmic level. However, a few (20%) of the slow-twitch, oxidative fibres (5% of the total fibres), did not contain the cytoplasmic inhibitor. Specific immunoreactivity for calpastatin was also associated with the interstitial connective tissue. These results suggest that (i) calpastatin in skeletal muscle, as in other tissues, is present as a mixture of proteins of various molecular weights and (ii) the inhibitor may act not only in the cytoplasm but also at the surface or extracellular level.

Localization of the Ca(2+)-dependent proteinases and their inhibitor in normal, fasted, and denervated rat skeletal muscle

Immunofluorescence and immunogold localization studies show that the two Ca(2+)-dependent proteinases (mu-calpain for the micromolar Ca(2+)-requiring proteinase and m-calpain for the millimolar Ca(2+)-requiring proteinase) and their protein inhibitor (calpastatin) are located exclusively intracellularly in normal rat soleus muscle. Quantitative immunogold studies indicate that binding of antibodies to both calpains and to calpastatin is approximately two times greater at the Z-disk of myofibrils than it is at the I-band or A-band regions. Mitochondria and nuclei in muscle cells contain both calpains and calpastatin at concentrations approximately one-tenth and one-fifth, respectively, of the concentration at the Z-disk, as estimated by antibody binding. Very little calpain or calpastatin was seen in the cytoplasmic intermyofibrillar spaces, and most of the calpain and calpastatin in muscle cells is associated with intracellular structures. Immunofluorescence results suggest that concentration of m-calpain but not mu-calpain or calpastatin is, in some instances, slightly higher near the intracellular surface of the plasma membrane than elsewhere in the muscle cell. Most m-calpain, however, is distributed throughout the interior of mature rat skeletal muscle cells. Denervation, or fasting and refeeding increases the concentration of the calpains and calpastatin in the muscle cell but does not change their distribution. Some mu- and m-calpain and calpastatin is found extracellularly in denervated soleus muscle or soleus muscle from fasting rats, but the extracellular calpains and calpastatin seem to originate from "leakage" of these proteins out of the cell because serum creatine kinase levels are much higher than normal in denervated or fasting rats.

Changes in brain calpain activity as a result of in vitro ischemia and pH alterations

Calpains and calpastatin in the brain of the rabbit were examined in experimental situations that could mimic some features of brain ischemia. Incubations of bisected brains in saline at 39 degrees C for 0.5, 1, or 1.5 h resulted in a decreased calpain I activity in the cytosol and in an increased hydrophobicity of cytosolic calpain II activity. Incubation of brain homogenates at different pH levels demonstrated an almost-complete transfer of calpains from the cytoplasmic compartment to the membranes when pH was lowered from 6 to 5. At pH values lower than 5, the total calpain activity (soluble plus membrane-bound) markedly decreased. No significant changes of calpastatin activity or its subcellular distribution was found following incubation of the homogenates at different pH levels.

Differential response of cultured adult cardiac muscle cells to a tumor promotor: analysis of myofibrillar organization

Cultured adult rat ventricular cardiac muscle cells were exposed to varying concentrations of 12-0-tetradecanoyl-phorbol-13 acetate (TPA) for two weeks. A considerable number of cardiac myocytes exposed to a medium with less than 200 ng/ml TPA were rich in myofibrils. The rest of the myocytes lacked organized myofibrils; the terminal parts of these myofibrils were transformed into cord-like structures largely consisting of dense Z-band materials. Some of these aberrant myofibrils contained short normal myofibrillar segments, with sarcomeres. A number of myocytes exposed to 200-250 ng/ml TPA contained myofibrils, which terminated in cord-like structures. The Z-band materials appeared as amorphous dense matrices and some sarcomeres were replaced completely or partially by leptomeres; the myocytes contained autophagosomes. The other myocytes did not contain myofibrils when exposed to the above higher concentrations of TPA. The patches of Z-band materials and structures containing Z-band materials attached to thin filaments on either side were scattered throughout the sarcoplasm of the cells, which were packed with myofilaments and 10 nm microfilaments. Some of these myocytes assumed a spindle shape and contained myofilaments, 10 nm microfilaments and leptomeres. Some of the myocytes, treated with TPA for 1-7 days and then allowed to recover in control medium for 7 days, contained various stages of myofibrillar organization, which did not differ significantly from those of the myofibril-containing cells exposed continuously to TPA as discussed above. The rest of the myocytes during the recovery period in control medium did not contain myofibrils. Rough endoplasmic reticulum and Golgi bodies in TPA-treated myocytes were found to be highly developed as compared to the controls. It is evident from these studies that the responsiveness of cardiac myocytes to TPA not only differs from that of skeletal muscle cells studied by others, but also varies within a population of cardiac myocytes.

Sequential disassembly of myofibrils induced by myristate acetate in cultured myotubes

The phorbol ester TPA induces the sequential disassembly of myofibrils. First the alpha-actin thin filaments are disrupted and then, hours later, the myosin heavy chain (MHC) thick filaments. TPA does not induce the disassembly of the beta- and gamma-actin thin filaments of stress fibers in presumptive myoblasts or fibroblasts, nor does it block the reemergence of stress fibers in 72-h myosacs that have been depleted of all myofibrillar molecules. There are differences in where, when, and how myofibrillar alpha-actin and MHC are degraded and eliminated from TPA-myosacs. Though the anisodiametric myotubes have begun to retract into isodiametric myosacs after 5 h in TPA, staining with anti-MHC reveals normal tandem A bands. In contrast, staining with mAb to muscle actin fails to reveal tandem I bands. Instead, both mAb to muscle actin and rhophalloidin brilliantly stain numerous disk-like bodies approximately 3.0 micron in diameter. These muscle actin bodies do not fuse with one another, nor do they costain with anti-MHC. All muscle actin bodies and/or molecules disappear in 36-h myosacs. The collapse of A bands is first initiated in 10-h myosacs. Their loss correlates with the appearance of immense, amorphous MHC patches. MHC patches range from a few micrometers to over 60 micron in size. They do not costain with antimuscle actin or rho-phalloidin. While diminishing in number and fluorescence intensity, MHC aggregates are present in 30% of the 72-h myosacs. Myosacs removed from TPA rapidly elongate, and after 48 h display normal newly assembled myofibrils. TPA reversibly blocks incorporation of [35S]methionine into myofibrillar alpha-actin, MHC, myosin light chains 1 and 2, the tropomyosins, and troponin C. It does not block the synthesis of beta- or gamma-actins, the nonmyofibrillar MHC or light chains, tubulin, vimentin, desmin, or most household molecules.

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.

Sensory meat quality and its assessment

Several aspects of meat quality are briefly discussed, outlining the complex of parameters affecting meat quality as a whole. Particular attention is paid to the main sensory meat quality characteristics, which can be assessed analytically, and are known to be related to consumers' appreciation, when buying, preparing and consuming meat. After some compositional and structural characteristics of muscle have been outlined, the major physiological factors effecting the conversion of muscle into meat are discussed. Finally commonly used methods for the assessment of sensory meat quality are reviewed.

Autolysis in the tail muscles of metamorphosing tadpoles

Degradation of muscle homogenate from the metamorphosing tadpole tail of bullfrog, Rana catesbeiana, was examined at acid and neutral pHs. More rapid and complete degradation was observed at acid pH. Proteinases working at acid pH were not inhibited by pepstatin but were inhibited by leupeptin. However, the inhibition by leupeptin was enhanced by pepstatin. These results show that lysosomal proteinases, a thiol proteinase(s) rather than cathepsin D, are involved in the degradation of tail muscle proteins.

Comparison of the ultrastructural myopathy induced by anticholinesterase agents at the end plates of rat soleus and extensor muscles

Rats were treated with single subcutaneous injections of the irreversible AChE inhibitors, sarin (90 to 100 micrograms/kg) or soman (55 micrograms/kg), and with chronic doses of the reversible carbamate inhibitor, pyridostigmine. In surviving animals with severe behavioral symptoms, we examined the end-plate regions of the slow-twitch soleus and the fast-twitch extensor digitorum longus muscles, using the electron microscope. Within 30 min, sarin administration caused a recognizable subjunctional myopathy. The progress of morphologic damage was followed for 7 days, during which time the occurrence of damage diminished. The initial swelling of subjunctional organelles and vacuole generation progressed to the point where nerve terminals and attached postjunctional folds were lifted away from the muscle surface. This appeared to be caused by a combination of enlarging vacuoles and insertion of Schwann and macrophage cells into the lesions, and was followed by degeneration of the postjunctional folds. A new component of anti-AChE myopathy was recognized: progressive swelling of chromatin in subjunctional muscle nuclei. The soleus muscle was considerably more sensitive to these effects than the extensor muscle. Soman had a much less prominent ultrastructural effect on the muscle end plates. Chronic pyridostigmine treatment had effects similar to those of a single sarin injection on the soleus as well as a pronounced effect on the extensor muscle.

Leupeptin, a protease inhibitor, blocks insemination-induced flight muscle histolysis in the fire ant Solenopsis

The effect of the protease inhibitor leupeptin on flight muscle histolysis in queen fire ants was studied by electron microscopy. In untreated animals artificially inseminated, muscle involution was apparent at 6 hr post-insemination and complete by 24 hr post-insemination. However, in animals pre-treated with leupeptin and subsequently artificially inseminated, no morphologic evidence of flight muscle breakdown was seen at any interval between 6 and 24 hr post-insemination. Such information appears to indicate that one or more proteases are involved in the process of insemination-induced muscle atrophy in fire ants. The most likely candidate is a soluble, calcium-activated myofilament-associated protease.

Degenerative processes in skeletal muscle of Cd2+-treated rats and Cd2+ inhibition of mitochondrial Ca2+ transport

In rat skeletal muscle, chronic exposure to 50 ppm Cd2+ in drinking water produced both ultrastructural and functional damage, which took place successively and increased gradually with duration of treatment. Ultrastructurally, the first effect was a regression of the sarcoplasmic reticulum, mitochondrial cristae, and glycogen granules. Then, the number of mitochondria diminished and a degeneration of myofilaments appeared. During the 9-month course of treatment, however, the terminal cisternae and the lateral saccules of sarcoplasmic reticulum remained, and the Z lines maintained their tight and rigorously parallel appearance. Functionally, the activities of two cytosolic Ca2+-sensitive enzymes (lactate dehydrogenase and malate dehydrogenase) decreased. Their partial restoration by EGTA and EDTA suggested the presence of inhibitory divalent cations in the cytosol of treated rats. Cd2+ also inhibited Ca2+ transport in mitochondria through the uncoupling of oxidative phosphorylation. Hence, an increase of Ca2+ concentration of the cytosol of Cd2+-treated rats, activating degradative enzymes such as phospholipases, proteases and phosphorylase b kinase, can be incriminated. A direct inhibitory action of Cd2+ on the activities of lactate dehydrogenase and malate dehydrogenase also occurred. Direct action of Cd2+ on certain other Ca2+-sensitive enzymes, thereby aggravating the indirect damage induced through increasing the Ca2+ concentration in cytosol, is hypothesized. In mitochondria, a Cd2+ activation of phospholipase A2 and/or a Ca2+-sensitive protease is a unique possibility, since Ca2+ accumulation was prevented by cytosolic Cd2+.

Ultrastructural changes after concentric and eccentric contractions of human muscle

Four normal subjects performed a 20 min step test using a step of the same relative height. During the test the quadriceps muscle of one leg contracted concentrically throughout by stepping up, while the contralateral muscle contracted eccentrically by controlling the step down. Thus both muscles performed the same amount of work. Three subjects had bilateral needle biopsies just prior to exercise. All four had bilateral biopsies immediately after exercise, and 24-48 hours later when the muscles which had contracted eccentrically were painful. The samples were examined by light and electron microscopy. No abnormalities were seen in pre-exercise samples nor after exercise in muscles which had contracted concentrically. The muscles which had contracted eccentrically showed some damage immediately after exercise. In the samples taken 24-48 hours after exercise the damage was more marked and involved a greater percentage of fibres. In view of the known differences between these types of contractions it is suggested that the initial damage is mechanically induced. The exacerbation of damage with time could be due to mechanical or chemical factors.

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.

A comparison of lysosomal involvements in the degradation of normal and abnormal endogenous proteins of differing half-lives in MRC5 cells

Protein degradation by diploid human-embryo lung fibroblasts (MRC5 cells) in monolayer culture was studied. 1. Varying the labelling period of proteins was found to alter the half-lives of labelled abnormal canavanine-containing proteins to an extent very similar to that obtained with normal proteins. 2. By manipulating the times of labelling it was possible to generate a species of abnormal protein with a greater half-life than that of a species of normal protein. A comparison of the lysosomal involvement in their degradation as determined both by inhibition by methylamine, a lysosomotropic agent, and by the degree of increase in protein degradation in step-down conditions, indicated that the degree of lysosomal involvement was not entirely dependent upon the half-life of the protein, but that abnormal proteins are preferentially degraded non-lysosomally. 3. The microtubule inhibitors colchicine and vinblastine were found to stimulate statistically basal protein degradation of normal long-labelled protein, whereas they had less effect upon the basal degradation of the other species of proteins studied and very little effect upon step-down degradation of all proteins studied. The stimulation in protein degradation found did not seem to involve the acid proteinases of lysosomes.

Investigations into the mechanism of excitant amino acid cytotoxicity using a well-characterized glutamatergic system

The cytotoxicity of glutamate and several analogues was investigated using a well characterized glutamatergic system; the neuromuscular system of the locust leg. In the presence of Con A (10(-6) M) (which blocks glutamate receptor desensitization) bath application on L-glutamate to isolated nerve-muscle preparations induced degeneration of the muscle cells in a dose-dependent manner. The ability of glutamate analogues to cause similar damage corresponded to their pharmacological potency, i.e. L-quisqualate greater than L-glutamate greater than L-cysteine greater than L-aspartate and L-kainate. Glutamate and the more potent agonists initially caused muscle swelling. This was followed by an increase in opacity of the muscle due to vacuolation resulting from disruption of the sarcoplasmic reticulum. Ca2+-free saline slowed the cytotoxic action of these amino acids, whilst saline containing high concentrations of Ca2+ (20 mM; substituted for Na+) accelerated muscle destruction. Denervation induces supersensitivity of locust muscle to L-glutamate; in denervated muscles the cytotoxicity of L-glutamate was enhanced. Muscles swollen by exposure to high-potassium saline (100 mM; substituted for sodium) were not damaged. We conclude that in this insect glutamatergic system, when desensitization is prevented, activated glutamate receptors gate the influx of Ca2+ and Na2+ causing an ionic imbalance which results in cellular damage. This mechanism could also account for at least some of the neurotoxic effects of amino acids in the vertebrate central nervous system. The results of our studies also indicate that other transmitters which gate non-desensitizing cationic channels should, in principle, also be cytotoxic.

A high-molecular-weight cysteine endopeptidase from rat skeletal muscle

A cytosolic enzyme of high molecular weight (about 500 000), which attacks native or denatured proteins (inter alia, casein, globin and hexokinase) was purified about 1000-fold from mixed rat skeletal muscles, including muscles freed of mast cells by prior treatment of the animals with the degranulator, compound 48/80. Peptides of varying size were generated from radioactively labelled globin, but no free amino acids were formed; free tyrosine was also not released from azocasein. The pH optimum was 7.5 and the presence of an essential cysteine group was suggested because dithiothreitol (1 mM) stimulated the activity and N-ethylmaleimide (5 mM) and p-chloromercuriphenylsulphonic acid (1 mM) were inhibitors. The activity was markedly inhibited by Zn2+ but not by leupeptin, chymostatin or pepstatin. The enzyme was stabilized by ATP, at concentrations as low as 0.1 mM, against inactivation at 42 degrees C. The endopeptidase was clearly separated on gel chromatography from another large protease, also sensitive to Zn2+, but with marked aminopeptidase activity and the properties of hydrolase H. The activity levels of the protease, assayed after chromatography on Sepharose 6B of high-speed supernatant fractions, did not vary significantly in skeletal muscle samples which were derived from denervated, starved, diabetic or hyperthyroid animals, in all of which the abnormal physiological states expressed themselves as enhanced rates of tyrosine released by incubated soleus and extensor digitorum longus muscles. Nevertheless, the enzyme described here may be part of an ATP-dependent, multi-component proteolytic system similar to that already known to be present in reticulocytes.

Histochemical evidence for the role of Ca2+ and neutral protease in the development of the subacute myopathy induced by organophosphorous compounds

A temporal and causal relationship has been established between inhibition of acetylcholinesterase (AChE) by organophosphorous compounds, accumulation of Ca2+, an increase of neutral protease activity and the development of the ultrastructural signs of subacute myopathy.

Characterization of myosin heavy chain by cyanogen bromide peptide maps

Procedures have been developed for the preparation of pure myosin heavy chain (h-myosin) by preparative gel electrophoresis, and for the characterization of h-myosin by cyanogen bromide peptide mapping. Major sources of error are the oxidation of methionine and the proteolytic splitting of the chain during purification. These errors have been eliminated. A peculiar feature is the doubling or quadrupling of a peptide of molecular weight 17 000. The results show structural differences between isomyosins derived from myonal types within the same animal, as well as interspecies differences.

Comparison of three alkaline proteases from digestive fluid of the silkworm, Bombyx mori L

1. Digestive fluid proteases of the silkworm, 6B1-3, were separated, partially purified and their properties were compared. 2. These proteases were different in the substrate specificity, effect of inhibitors, Km and influence of Mn2+. 3. Hydrolyzing ability for natural substrates was comparatively high in 6B1, whereas the hydrolysis of synthetic substrates of trypsin by 6B1 was lower than that by 6B2 or 3. 4. The protease activity was sensitive to DFP and PMSF. The soybean trypsin inhibitor differentially affected three proteases. Silkworm haemolymph strongly inhibited the protease activity of 6B2 and 3, but scarcely affected 6B1.

A light and electron microscopic histochemical study on the mechanism of DFP-induced acute and subacute myopathy

The histochemical changes occurring in association with the development of acute and subacute myopathy have been studied in the rat diaphragm 30 min-48 h after a single i.p. injection of 1.82 mg/kg of the irreversible cholinesterase inhibitor organophosphate, diisopropylfluorophosphate (DFP). In addition to a considerable inhibition of the AChE activity of the motor end-plates, accumulation of ionic Ca2+ and an increase in neutral protease activity in the subjunctional sarcoplasm have been demonstrated. A temporal and causal relationship has been established between the histochemical changes and the development of the ultrastructural signs of myopathy.

Myofiber damage accompanying intramuscular parasitism by Sarcocystis muris

Myofiber degeneration which results from Sarcocystis infection exhibits a number of fine structural features suggestive of other myopathies and several well-defined fine structural features not characteristic of other myopathies. Some of these fine structural features are similar to those observed in intramuscular infections of Trichinella spiralis, another muscle parasite. Major alterations of the myofibrillar contractile apparatus occur at the periphery of the membrane bound parasitophorous vacuole which include splitting and fragmentation of the myofibrils at the longitudinal ends of the parasitophorous vacuole and Z line dissolution at the radial periphery. Membranous structural elements including mitochondria, sarcoplasmic reticulum and T system components become disarrayed as the myofibrils degenerate. Some minor hypertrophy of the sarcoplasmic reticulum occurs in conjunction with initial fragmentation of the myofibrils bu no major dilation or hypertrophy has been observed. There is a distinctive membranous organization of the interface of the parasitophorous vacuole. The presence of pycnotic and fragmenting nuclei, sarcolemmal invaginations with accompanying fibrous connective tissue invasion and large areas of undifferentiated cytoplasm suggest the ultimate necrosis and destruction of infected myofibers. The similarity between morphological features of myofibrillar degeneration accompanying intramuscular Sarcocystis muris infections and those associated with a variety of myopathies resulting from other causes suggests that a common mechanism of muscle response to damage might result in the observed structural degeneration.

Increased rates of myofibrillar protein breakdown in muscle-wasting diseases

The excretion of endogenous creatinine and 3-methylhistidine by subjects with muscle diseases has been measured in order to assess muscle mass and fractional rates of myofibrillar protein degradation. Increases in the rates of myofibrillar protein breakdown were observed in all subjects with Duchenne, Becker, autosomal recessive Duchenne-like, and limb-girdle muscular dystrophy; dystrophia myotonica; myotonia congenita; peroneal muscular atrophy; myasthenia gravis; and central core disease; in some cases of spinal muscular atrophy; but in no cases of facioscapulohumeral muscular dystrophy of dystonia musculorum deformans. All increases in myofibrillar protein breakdown were associated with reductions in muscle proportion below the normal. Muscle-wasting diseases may respond to therapy directed towards an inhibition of muscle protease activity; the efficacy of such therapy can be monitored by the 3-methylhistidine-to-creatinine excretion ratio.

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.

Differential effects of proteinase inhibitors and amines on the lysosomal and non-lysosomal pathways of protein degradation in isolated rat hepatocytes

Ammonia, which like other lysosomotropic amines inhibits protein degradation in isolated rat hepatocytes by 70---80%, was utilized as a diagnostic tool to distinguish between the relative effects of various proteinase inhibitors on the lysosomal and non-lysosomal pathways of intracellular protein degradation. Leupeptin was found to inhibit lysosomal protein degradation by 80---85%, and non-lysosomal degradation by about 15%. Antipain had a similar, but somewhat weaker effect. Pepstatin, bestatin and aprotinin (Trasylol) produced minor inhibitory effects (possibly on both degradation pathways), whereas bacitracin and soybean trypsin inhibitor were ineffective. Chymostatin inhibited lysosomal protein degradation by about 45%, whereas the non-lysosomal pathway was inhibited by more than 50%. Chymostatin was unique among the inhibitors tested in causing such a pronounced effect on non-lysosomal protein degradation, and appeared to selectively inhibit the energy-dependent portion of this pathway. The effects of the various inhibitors were additive to the extent expected on the basis of their known actions only sosomal and non-lysosomal protein degradation. Thus, a combination of methylamine, leupeptin and chymostatin inhibited overall protein degradation by about 90%, resulting in a substantial improvement of the cellular nitrogen balance. The degradation inhibitors caused a partial inhibition of protein synthesis, apparently mainly by shutting down the supply of amino acids from the lysosomes. The inhibitory effects of leupeptin and antipain were completely reversed by amino acid addition, whereas some inhibition remained in the case of chymostatin and the lysosomotropic amines, possibly reflecting a certain nonspecific toxicity.

2,4-dinitrophenol, lysosomal breakdown and rapid myofilament degradation in vertebrate skeletal muscle

1. The possibility that rapid Ca2+-uptake by skeletal muscle mitochondria may cause local reductions in pHi (by H+/Ca2+ exchange) and so promote lysosomal breakdown has been explored using amphibian and mammalian preparations. Recent studies suggested that such a sequence of events is possible in cardiac muscle. 2. However, extensive muscle damage can still be initiated in skeletal muscle when the mitochondria are uncoupled so that Ca2+-uptake is prevented. 3. DNP alone induces extensive myofilament degradation which is similar to that produced by A23187 and caffeine and described previously. 4. It is suggested that (a) the known action of DNP in promoting lysosomal labilization in living cells is produced by mitochondrial uncoupling and the release of stored Ca2+, (b) raised [Ca2+]i promotes lysosomal breakdown in skeletal muscle, so that the hydrolases released effect myofilament dissolution rapidly. 5. DNP also rapidly causes septation and division of the mitochondria in mammalian skeletal muscle.

The effect of protease inhibitors and decreased temperature on the degradation of different classes of proteins in cultured hepatocytes

Leupeptin, chymostatin and antipain inhibited the degradation of long-lived proteins in cultured rat hepatocytes by 20-30%, probably by inhibiting lysosomal proteases: (1) Leupeptin and chymostatin decreased to a similar extent the degradation of an exogenous protein 125I-asialo fetuin, a process known to occur within lysosomes. (2) In extracts of cells treated with leupeptin, cathepsin B activity was inhibited by 35-50%. (3) Leupeptin, chymostatin and antipain inhibited proteolysis by homogenates of liver lysosomes but not by the supernatant fraction. These agents, however, do not appear to rapidly permeate the membrane of isolated lysosomes. Leupeptin, chymostatin and antipain did not inhibit the breakdown of short-lived normal cell proteins, and ones containing amino acid analogs. Even when the amount of abnormal proteins was increased, such that it comprised a large fraction of cell protein, the degradation of these polypeptides was still very rapid and not affected by these inhibitors. The pathway for the degradation of short-lived cell proteins thus appears distinct from that responsible for degradation of long-lived cell proteins. In accord with this conclusion, reduction of the temperature of cultures inhibited the breakdown of long-lived proteins to a much greater extent than it affected the breakdown of short-lived ones. Treatment of cultured hepatocytes with glucagon, or deprivation for serum or amino acids stimulated the degradation of the more stable cell proteins but did not affect the breakdown of 125I-asialo-fetuin. Under these conditions leupeptin and chymostatin inhibited the breakdown of long-lived cell proteins to the same extent as in control cultures. Thus, lysosomal enzymes seem to play an important role in protein breakdown both in fed hepatocytes and in cells where proteolysis is accelerated.

Purification and some physico-chemical and enzymic properties of a calcium ion-activated neutral proteinase from rabbit skeletal muscle

Ca(2+)-activated neutral proteinase was purified from rabbit skeletal muscle by a method involving DEAE-Sephacel chromatography, affinity chromatography on organomercurial-Sepharose and gel filtration on Sephacryl S-200 and Sephadex G-150. The SDS (sodium dodecyl sulphate)/polyacrylamide-gel-electrophoresis data show that the purified enzyme contains only one polypeptide chain of mol.wt. 73000. The purification procedure used allowed us to eliminate a contaminant containing two components of mol.wt. about 30000 each. Whole casein or alpha(1)-casein were hydrolysed with a maximum rate at 30 degrees C, pH7.5, and with 5mm-CaCl(2), but myofibrils were found to be a very susceptible substrate for this proteinase. This activity is associated with the destruction of the Z-discs, which is caused by the solubilization of the Z-line proteins. The activity of the proteinase in vitro is not limited to the removal of Z-line. SDS/polyacrylamide-gel electrophoresis on larger plates showed the ability of the proteinase to degrade myofibrils more extensively than previously supposed. This proteolysis resulted in the production of a 30000-dalton component as well as in various other higher- and lower-molecular-weight peptide fragments. Troponin T, troponin I, alpha-tropomyosin, some high-molecular-weight proteins (M protein, heavy chain of myosin) and three unidentified proteins are degraded. Thus the number of proteinase-sensitive regions in the myofibrils is greater than as previously reported by Dayton, Goll, Zeece, Robson & Reville [(1976) Biochemistry15, 2150-2158]. The Ca(2+)-activated neutral proteinase is not a chymotrypsin- or trypsin-like enzyme, but it reacted with all the classic thiol-proteinase inhibitors for cathepsin B, papain, bromelain and ficin. Thus the proteinase was proved to have an essential thiol group. Antipain and leupeptin are also inhibitors of the Ca(2+)-activated neutral proteinase.