Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C1762617 (weakness)
37,932 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Myosin constitutes the major part of the thick filaments in the contractile apparatus of striated muscle. MYH7 encodes the slow/beta-cardiac myosin heavy chain (MyHC), which is the main MyHC isoform in slow, oxidative, type 1 muscle fibers of skeletal muscle. It is also the major MyHC isoform of cardiac ventricles. Numerous missense mutations in the globular head of slow/beta-cardiac MyHC are associated with familial hypertrophic cardiomyopathy. We identified a missense mutation, Arg1845Trp, in the rod region of slow/beta-cardiac MyHC in patients with a skeletal myopathy from two different families. The myopathy was characterized by muscle weakness and wasting with onset in childhood and slow progression, but no overt cardiomyopathy. Slow, oxidative, type 1 muscle fibers showed large inclusions consisting of slow/beta-cardiac MyHC. The features were similar to a previously described entity: hyaline body myopathy. Our findings indicate that the mutated residue of slow/beta-cardiac MyHC is essential for the assembly of thick filaments in skeletal muscle. We propose the term myosin storage myopathy for this disease.
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PMID:Myosin storage myopathy associated with a heterozygous missense mutation in MYH7. 1452 Jun 62

The mdx mouse, a model of the human disease Duchenne muscular dystrophy, has skeletal muscle fibres which display incompletely understood impaired contractile function. We explored the possibility that action potential-evoked Ca(2+) release is altered in mdx fibres. Action potential-evoked Ca(2+)-dependent fluorescence transients were recorded, using both low and high affinity Ca(2+) indicators, from enzymatically isolated fibres obtained from extensor digitorum longus (EDL) and flexor digitorum brevis (FDB) muscles of normal and mdx mice. Fibres were immobilized using either intracellular EGTA or N-benzyl-p-toluene sulphonamide, an inhibitor of the myosin II ATPase. We found that the amplitude of the action potential-evoked Ca(2+) transients was significantly decreased in mdx mice with no measured difference in that of the surface action potential. In addition, Ca(2+) transients recorded from mdx fibres in the absence of EGTA also displayed a marked prolongation of the slow decay phase. Model simulations of the action potential-evoked transients in the presence of high EGTA concentrations suggest that the reduction in the evoked sarcoplasmic reticulum Ca(2+) release flux is responsible for the decrease in the peak of the Ca(2+) transient in mdx fibres. Since the myoplasmic Ca(2+) concentration is a critical regulator of muscle contraction, these results may help to explain the weakness observed in skeletal muscle fibres from mdx mice and, possibly, Duchenne muscular dystrophy patients.
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PMID:The action potential-evoked sarcoplasmic reticulum calcium release is impaired in mdx mouse muscle fibres. 1500 13

Distal myopathies are a heterogeneous group of genetic disorders characterized clinically by progressive muscular weakness and atrophy beginning in the hands or feet, and pathologically by myopathic changes in skeletal muscles. Five distinct distal myopathies are identified, among them four have been recently defined by their gene and causative mutations. They are classified according to age at onset, mode of inheritance, and muscle groups initially involved into the following: Laing myopathy (infancy onset, autosomal dominant inheritance, onset in anterior compartment of legs) caused by mutations in a myosin gene (MYH7) on chromosome 14q; Nonaka myopathy (early adult onset, autosomal recessive inheritance, onset in anterior compartment of legs), identical to quadriceps-sparing familial inclusion myopathy, caused by mutations in the GNE gene on chromosome 9p-q; Miyoshi myopathy (early adult onset, autosomal recessive inheritance, onset in posterior compartment of legs) caused by mutations in the dysferlin gene on chromosome 2p; Welander myopathy (late adult onset, autosomal dominant inheritance, onset in hands) linked to chromosome 2p; Udd/Markesbery-Griggs myopathy (late adult onset, autosomal dominant inheritance, onset in anterior compartment of legs) caused by mutations in the titin gene on chromosome 2q. Except for Miyoshi myopathy, which has a striking elevated serum creatine kinase level and the typical findings of muscular dystrophy, most of the distal myopathies have normal or midly elevated creatine kinase levels and share the common pathologic feature of rimmed vacuoles.
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PMID:[Distal myopathies]. 1503 79

Critical Illness Polyneuropathy (CIP) and Myopathy (CIM), either singly or in combination, are a common complication of critical illness. Both disorders may lead to severe weakness and require mechanical ventilation. CIP, as initially described by Bolton et al., in 1984, is a sensorimotor polyneuropathy that is often a complication of sepsis and multiorgan failure. In Japan, Horinouchi et al., first reported a case in 1994. CIM has been referred to by a number of different terms (acute quadriplegic myopathy, thick filament myopathy, acute necrotizing myopathy of intensive care, rapidly evolving myopathy with myosin-deficiency fibers) in the literature. A variety of serious problems (e.g., pneumonia, severe asthma, and lung or liver transplantation) and the concomitant use of high-dose intravenous corticosteroids and nondepolarizing neuromuscular blocking agents predispose to CIM. In Japan, Kawada et al., reported a first case as acute quadriplegic myopathy in 2000. There is no specific treatment for CIP and CIM. Minimizing the use of corticosteroids and nondepolarizing neuromuscular blocking agents in a critical illness setting may prove helpful in preventing the occurrence of these disorders. The prognosis is directly related to the age of the patient and the seriousness of the underlying illness.
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PMID:[Critical illness polyneuropathy and myopathy]. 1515 69

Duchenne muscular dystrophy is characterized by myofiber necrosis, muscle replacement by connective tissue, and crippling weakness. Although the mdx mouse also lacks dystrophin, most muscles show little myofiber loss or functional impairment. An exception is the mdx diaphragm, which is phenotypically similar to the human disease. Here we tested the hypothesis that the mdx diaphragm has a defective regenerative response to necrotic injury, which could account for its severe phenotype. Massive necrosis was induced in mdx and wild-type (C57BL10) mouse diaphragms in vivo by topical application of notexin, which destroys mature myofibers while leaving myogenic precursor satellite cells intact. At 4 h after acute exposure to notexin, >90% of diaphragm myofibers in both wild-type and mdx mice demonstrated pathological sarcolemmal leakiness, and there was a complete loss of isometric force-generating capacity. Both groups of mice showed strong expression of embryonic myosin within the diaphragm at 5 days, which was largely extinguished by 20 days after injury. At 60 days postinjury, wild-type diaphragms exhibited a persistent loss ( approximately 25%) of isometric force-generating capacity, associated with a trend toward increased connective tissue infiltration. In contrast, mdx diaphragms achieved complete functional recovery of force generation to noninjured values, and there was no increase in muscle connective tissue over baseline. These data argue against any loss of intrinsic regenerative capacity within the mdx diaphragm, despite characteristic features of major dystrophic pathology being present. Our findings support the concept that significant latent regenerative capacity resides within dystrophic muscles, which could potentially be exploited for therapeutic purposes.
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PMID:Regenerative capacity of the dystrophic (mdx) diaphragm after induced injury. 1519 2

Exercise intolerance is a condition commonly experienced by both the healthy and those with disease. Yet we have only a limited understanding of the underlying mechanisms and, consequently, the management of this condition. In this Symposium, a major objective was to address the role of the muscle cell in weakness and fatigue. We have focused on addressing the advances made in characterizing the basis of muscle cell contractility with particular respect to the processes and proteins involved in excitation and contraction, and how these processes can be modified during repetitive activity. Three reviews are provided on this subject. Each addresses a specific link in the cascade of events from neural activation of the muscle to the generation of force. In the first review the processes involved in signal transduction in the sarcolemma and T-tubule, and which regulate membrane excitability, are examined. The second review analyzes the sarcoplasmic reticulum regulation of the intracellular messenger that controls the myofibrillar complex, namely free calcium. The final review in this series deals with the events regulating actin-myosin behaviour and the mechanical response. All reviews place special emphasis on how different sites can be modified by repetitive activity and, as a consequence, how they can represent a potential source of fatigue. Since it is important to understand the nature, manifestations, and measurement of weakness and fatigue, a comprehensive review on these topics is also provided.
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PMID:Mechanisms and management of fatigue in health and disease: symposium introduction. 1519 31

Myosin, a molecular motor, converts chemical energy into mechanical force. The motor domain of myosin heavy chain (MyHC) includes an ATP binding region with ATPase activity and an actin-binding region. Motor function is achieved by conformational changes, at hydrolysis, of ATP causing a shift in the angle between the actin binding head and the rod region of the molecule. The elongated alpha-helical coiled-coil rod region of MyHC molecules constitutes the major part of the thick filaments of the sarcomere. Three major MyHC isoforms are expressed in human skeletal muscle (type I, MYH7, expressed in type 1 fibres; IIa, MYH2, expressed in 2A fibres; IIx, MYH1, expressed in 2B fibres). While mutations in slow/beta cardiac MyHC (MYH7) are a common cause of familial hypertrophic cardiomyopathy, no skeletal myopathies have, until recently, been associated with mutations in MyHC. A heterozygous mutation, Glu706Lys, in the core of the head of MyHC IIa is associated with a familial congenital myopathy, which, in most instances, has shown mild phenotypic expression in children but progressive course in some adults. There is a relationship between the level of expression of mutated MyHC IIa and muscle pathology. Some adults with a progressive course show muscle fibres with rimmed vacuoles and filaments of the type seen in inclusion body myositis/myopathy (IBM). Endurance training in a group of affected patients caused a shift in the expression of myosin from fast (IIx) to slow (I) isoforms but no reduction in the expression of MyHC IIa. A heterozygous mutation, Arg1845Trp, in the distal rod region of slow myosin (type I, MYH7) is associated with familial congenital myopathy, with large deposits of MyHC I in the subsarcolemmal region of type 1 muscle fibres, "Myosin storage myopathy". These patients showed slowly progressive muscle weakness but no overt cardiomyopathy. These two muscle diseases, which are caused by mutations in MyHC, form the basis of a novel entity: "Myosin myopathies".
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PMID:Myopathies associated with myosin heavy chain mutations. 1560 50

Although it is well established that patients suffering from malaria experience skeletal muscle problems (contracture, aches, fatigue, weakness), detailed studies have not been performed to investigate changes in the contractile function and biochemical properties of intact and skinned skeletal muscles of mammals infected with malaria. To this end, we investigated such features in the extensor digitorium longus (EDL, fast-twitch, glyocolytic) and in the soleus (SOL, slow-twitch, oxidative) muscles from mice infected with Plasmodium berghei. We first studied maximal tetanic force (T(max)) produced by intact control and malaria-infected muscles before, during and after fatigue. Triton-skinned muscle fibres were isolated from these muscles and used to determine isometric contractile features as well as a basic biochemical profile as analysed by silver-enhanced SDS-PAGE. We found that the T(max) of intact muscles and the maximal Ca2+-activated force (F(max)) of Triton-skinned muscle fibres were reduced by approximately 50% in malarial muscles. In addition, the contractile proteins of Triton-skinned muscle fibres from malarial muscles were significantly less sensitive to Ca2+. Biochemical analysis revealed that there was a significant loss of essential contractile proteins (e.g. troponins and myosin) in Triton-skinned muscle fibres from malarial muscles as compared to controls. The biochemical alterations (i.e., reduction of essential contractile proteins) seem to explain well the functional modifications resolved in both intact muscles and Triton-skinned muscle fibres and may provide a suitable paradigm for the aetiology of muscle symptoms associated with malaria.
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PMID:Functional and biochemical modifications in skeletal muscles from malarial mice. 1572 39

Mutations in myosin heavy chain (MyHC) genes recently have been shown to be associated with various forms of congenital myopathies: myosin myopathies. The MyHC IIa E706K mutation is associated with congenital joint contractures, early-onset muscle weakness, and progressive course with moderate to severe muscle weakness later in life. To study the pathogenicity of this MyHC mutation, we investigated the effect of the corresponding mutation (E710K) in the major MyHC isoform (MyHC B) of the body wall muscle of the nematode Caenorhabditis elegans. Worms with null mutations in the MyHC B gene (unc-54) are severely paralyzed and depleted of thick filaments in the body wall muscle sarcomeres. unc-54 null mutants with extrachromosomal arrays of a gene construct including the entire wild-type unc-54 gene were partially rescued as determined by a motility assay and by morphological analysis of the body wall muscle. Analysis of unc-54 null mutants with extrachromosomal arrays of the unc-54 gene with the E710K mutation were severely paralyzed but showed formation of thick filaments in the body wall muscle. We conclude that the MyHC E706K (E710K in C. elegans) mutation is pathogenic and that the effect is primarily functional rather than structural because thick filaments are formed. The C. elegans model may be useful to study suspected pathogenic mutations in MyHC genes associated with human muscle diseases.
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PMID:A Caenorhabditis elegans model of the myosin heavy chain IIa E706K [corrected] mutation. 1613 Jan 13

Neuromuscular disorders are increasingly recognized in the critically ill but conventional electrodiagnostic techniques often provide non-specific results or are hampered by local conditions that prevent adequate disease classification. Muscle fiber inexcitability is a common phenomenon in critical illness myopathy possibly secondary to disordered sodium channel fast inactivation and associated with loss of myosin staining. Direct muscle stimulation techniques, measuring evoked response amplitudes and comparison of nerve and muscle stimulated responses, are recognized methods of demonstrating this phenomenon. Other measures studied in this population include increased compound motor action potential duration, motor unit number estimates and mean step area of individual motor unit potentials during motor unit number estimate studies. An electrophysiologic approach to the study of patients with critical illness associated weakness is proposed.
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PMID:Electrophysiologic techniques in critical illness-associated weakness. 1641 74


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