Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0029713 (immaturity)
 4,335 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The dwarf mutation in mice interferes with the development of those anterior pituitary cells responsible for production of thyroid stimulating hormone, growth hormone, and prolactin. Myosin isozyme transitions in both cardiac and skeletal muscle were also found to be affected in this mutant. Electrophoresis of native myosins demonstrated that the fetal (V3) to adult (V1) ventricular cardiac isozyme transition was completely blocked in dwarf mice; in contrast, the neonatal to adult fast myosin transition in hind limb skeletal muscle was slowed but not totally inhibited. The persistence of neonatal myosin heavy chain for up to 55-75 d after birth in dwarf mice, as compared with 16 d in normal mice, was directly demonstrated by polypeptide and immunopolypeptide mapping. Morphological examination of 18-36-d-old dwarf skeletal muscles by optical and electron microscopy revealed a relative immaturity, but no signs of gross pathology were evident. Immunocytochemical analysis showed that the abnormal persistence of neonatal myosin occurs in most of the fibers. Multiple injections of thyroxine restored a normal isozyme complement to both cardiac and skeletal muscles within 11-15 d. Therefore, the effects of the dwarf mutation on myosin isozymes can be explained by the lack of thyroid hormone in these animals. Because the synthesis of growth hormone is not stimulated by thyroid hormone in dwarf mice as it would be in normal animals, these results demonstrate that thyroid hormone promotes myosin isozyme transitions independent of growth hormone production.
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PMID:Hereditary pituitary dwarfism in mice affects skeletal and cardiac myosin isozyme transitions differently. 401 84

Recently described techniques for separating myosin isoenzymes have been adapted for analysis of myosins from diseased and developing human skeletal muscle. The method is highly suitable for analysis of human myosins because only 2 - 3 mg of muscle are required for routine analyses. Human embryonic/foetal myosins are electrophoretically distinct from mature skeletal myosins, and are not normally detected beyond the first month of post-natal life, except in premature infants. They have a high alkaline calcium-activated ATPase activity. This would account for the histochemical classification of foetal fibres as "Type II", although physiological differences between adult fast-twitch muscle and foetal muscle are well recognized. Foetal myosins are also synthesized in human skeletal muscle under certain pathological circumstances. Their presence in Duchenne dystrophy probably reflects the associated marked muscle regeneration, with immaturity of some muscle cells. The large amounts of foetal myosin present in many cases of infantile spinal muscular atrophy is evidence that innervation is necessary for the normal cessation of foetal myosin synthesis.
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PMID:Embryonic and foetal myosins in human skeletal muscle. The presence of foetal myosins in duchenne muscular dystrophy and infantile spinal muscular atrophy. 731 Apr 40

The expression of laminin subunits M, A, B1 and B2 was studied immunocytochemically in 25 cases of classical congenital muscular dystrophy (CMD), 11 hypotonic infants, 20 cases of a variety of inherited and acquired neuromuscular disorders, and 11 controls. Merosin, as indicated by labelling for the M chain, was deficient in 12 (48%) of the cases of classical CMD. Seven cases had no detectable labelling for the M chain whereas five showed traces, including three cousins from the same family. This suggests that very low expression may relate to a possible difference in the molecular defect, compared with cases completely devoid of the M chain. The A chain was abundant in regenerating fibres and in immature fibres expressing fetal myosin. In all merosin-deficient cases the A chain was over-expressed but this was not due to immaturity. A secondary reduction in sarcolemmal expression of the B1 chain occurred in five merosin-deficient cases, whilst expression in vascular tissue was normal. B1 was also reduced in one merosin-positive case of CMD, suggesting that other subunits may be involved in other forms of CMD. No differences in the expression of the B2 chain were observed in any of the cases studied. No abnormality in laminin subunits was found in controls or other neuromuscular disorders.
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PMID:Expression of laminin subunits in congenital muscular dystrophy. 758 Feb 44

In sheep, the muscle component of the proximal sesamoidean ligament, which is well developed at birth, undergoes a progressive involution postnatally. The development of muscle fibres in the proximal sesamoidean ligament was compared with masseter and semimembranosus muscles from before birth into adult life, using histochemical, immunohistochemical and biochemical methods. Neonatal myosin (a marker for developmental immaturity) disappeared earlier, and the adult pattern of myosin expression and fibre type composition was reached earlier in the proximal sesamoid ligament than masseter and semimembranosus. Proximal sesamoid ligament muscle fibres therefore complete normal development, but with a faster time course than the other muscles. Invasion of fibrous connective tissue between muscle fibres of the proximal sesamoidean ligament adjoining the tendinous component (one feature of the involution) was found to begin perinatally, eventually resulting in a marked fibrosis and atrophy of peripheral fibres. Regeneration of muscle fibres was absent or abortive, even near areas of fibre necrosis.
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PMID:Natural involution of muscle in the proximal sesamoidean ligament in sheep. 764 19

We studied muscle biopsies from 36 Becker muscular dystrophy patients, and correlated dystrophin negative fibers with regenerating and degenerating myofibers. Dystrophin immunohistochemistry was used to identify dystrophin-negative and dystrophin-positive fibers. Immunohistochemical staining for fetal myosin and acid ATPase identified regenerating fibers, and calcium glioxalate and beta-spectrin staining identified necrotic fibers. All Becker biopsies contained detectable dystrophin in the majority of muscle fibers. 13 cases (36%) showed no dystrophin negative fibers, 9 cases (25%) showed a generalized, markedly decreased immunostaining pattern, and 14 cases (39%) showed a subset of dystrophin negative fibers (0.3-8% of total). Most dystrophin-negative fibers in Becker muscle were judged to be in the process of regeneration, and not in degeneration. No correlation was observed between the age of the patients and number of dystrophin negative fibers. We conclude that the absence of dystrophin and spectrin labeling in some BMD myofibers is associated with regeneration, probably due to incomplete expression of dystrophin secondary to myofibers immaturity. Our results might be explained by a developmental delayed expression of these two proteins, or by abnormal assembling in membrane's components during regeneration in dystrophy. Furthermore, our results rationalize the recently reported finding of some dystrophin-negative fibers in polymyositis.
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PMID:Absence of dystrophin and spectrin in regenerating muscle fibers from Becker dystrophy patients. 806 27

The South American opossum, Monodelphis domestica, is very immature at birth, and we wished to assess its potential for studies of jaw muscle development. Given the lack of prior information about any Monodelphis fiber types or spindles, our study aimed to identify for the first time fiber types in both adult and neonatal muscles and the location of spindles in the jaw muscles. Fiber types were identified in frozen sections of adult and 6-day-old jaw and limb muscles by using myosin ATPase and metabolic enzyme histochemistry and by immunostaining for myosin isoforms. The distribution of fiber types and muscle spindles throughout the jaw-closer muscles was identified by immunostaining of sections of methacarnoy-fixed, wax-embedded heads. Most muscles contained one slow (type I) and two fast fiber types (equivalent to types IIA and IIX), which were similar to those in eutherian muscle, and an additional (non-IIB) fast type. In jaw-closer muscles, the main extrafusal fiber type was IIM (characteristic of these muscles in some eutherians), and almost all spindles were concentrated in four restricted areas: one in masseter and three in temporalis. Six-day neonatal muscles were very immature, but future spindle-rich areas were revealed by immunostaining and corresponded in position to the adult areas. Extrafusal and spindle fiber types in Monodelphis share many similarities with eutherian mammalian muscle. This finding, along with the immaturity of myosin isoform expression observed 6 days postnatally, indicates that Monodelphis could provide a valuable model for studying early developmental events in the jaw-closer muscles and their spindles.
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PMID:Skeletal fiber types and spindle distribution in limb and jaw muscles of the adult and neonatal opossum, Monodelphis domestica. 971 89

Cell differentiation markers on placental villi from the first trimester of human pregnancy have been studied by indirect immunofluorescence. Fluorescence labelling with antibodies against CD34 and CD31 was conspicuous in the vascular cells. The vascular paracellular clefts were labelled by anti-cadherin-5. A few vascular cells exhibited a positive reaction for von Willebrand factor, high-molecular-weight melanoma-associated-antibody and alpha-sm-actin compared to term pregnancy, indicating changes in protein expression during vascular differentiation. The poor anti-collagen IV reaction and the absence of a sm-myosin fluorescent signal observed around the vessels confirned the immaturity of the vessels. In contrast, strong reactions have previously been obtained with the latter antibodies in similar locations using term placental villi. A labelling was observed for antibodies against alpha3 and alpha5 integrins in these immature placental vessels suggesting cell-matrix interactions with specific domains of laminin or fibronectin. The vascular cells were also stained by anti-CD26. Surprisingly, the fetal vascular cells exhibited immunostainings in common with the villous cytotrophoblast (CD26) or the syncytiotrophoblast (cadherin-5) and cell islands cytotrophoblast (CD31, cadherin-5, alpha3 and alpha5 integrin subunits). These observations suggested a two step process for fetal vasculogenesis in the villi: i/ the formation of peripheral vessels induced by growth factors or cytokines derived from the nearby trophoblast, ii/ the development of muscular vessels due to growth factors or cytokines production induced by circulatory changes.
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PMID:Characterization of first trimester human fetal placental vessels using immunocytochemical markers. 1193 78

Golden retriever muscular dystrophy (GRMD), a degenerative myopathy due to the absence of dystrophin, is genetically homologous to human Duchenne muscular dystrophy (DMD). Spontaneous death of GRMD neonates within the first 2 weeks of life occurs frequently. This report describes the microscopical muscle lesions that developed in 12 GRMD puppies aged 1-8 days of age, and makes a comparison with three normal age-matched siblings and two older GRMD dogs. Immunohistochemical methods were used to confirm dystrophin deficiency in GRMD puppies. Muscle lesions were assessed on sections stained with haematoxylin-eosin-saffron, Gomori's trichrome and alizarin red S, and their severity was graded semi-quantitatively. Muscle fibre types were determined immunohistochemically on the basis of the pattern of expression of developmental, slow and fast isoforms of myosin. Muscle lesions in the GRMD puppies were characterized by massive necrosis, affecting most muscles of the proximal limbs, trunk and neck at birth. Lingual lesions began to develop in utero, and respiratory muscles underwent terminal diffuse necrosis resulting in death from acute respiratory failure. However, GRMD puppies do not invariably die in the neonatal period. Muscle in 2-month-old GRMD dogs showed signs of regeneration (immunohistochemical immaturity of muscle tissue), which suggested that all GRMD dogs suffer from massive post-natal myonecrosis, whether fatal or not. Muscle lesions in neonates consisted mainly of hyalinization, hypertrophy, calcification and necrosis, followed by regeneration. Such "phase I" lesions due to the absence of dystrophin are found in all species in which dystrophin deficiency has been described (human beings, dogs, cats and mice), whereas the endomysial fibrosis and myofibre atrophy found in 2-month-old GRMD dogs constituted "phase II" lesions, which are specific to GRMD and human DMD.
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PMID:Muscle lesions associated with dystrophin deficiency in neonatal golden retriever puppies. 1194 98

The adult human myocardium is incapable of regeneration; yet, the zebrafish (Danio rerio) can regenerate damaged myocardium. Similar to the zebrafish heart, hearts of neonatal, but not adult mice are capable of myocardial regeneration. We performed a proteomics analysis of adult zebrafish hearts and compared their protein expression profile to hearts from neonatal and adult mice. Using difference in-gel electrophoresis (DIGE), there was little overlap between the proteome from adult mouse (>8weeks old) and adult zebrafish (18months old) hearts. Similarly, there was a significant degree of mismatch between the protein expression in neonatal and adult mouse hearts. Enrichment analysis of the selected proteins revealed over-expression of DNA synthesis-related proteins in the cardiac proteome of the adult zebrafish heart similar to neonatal and 4days old mice, whereas in hearts of adult mice there was a mitochondria-related predominance in protein expression. Importantly, we noted pronounced differences in the myofilament composition: the adult zebrafish heart lacks many of the myofilament proteins of differentiated adult cardiomyocytes such as the ventricular isoforms of myosin light chains and nebulette. Instead, troponin I and myozenin 1 were expressed as skeletal isoforms rather than cardiac isoforms. The relative immaturity of the adult zebrafish heart was further supported by cardiac microRNA data. Our assessment of zebrafish and mammalian hearts challenges the assertions on the translational potential of cardiac regeneration in the zebrafish model. The immature myofilament composition of the fish heart may explain why adult mouse and human cardiomyocytes lack this endogenous repair mechanism.
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PMID:"Young at heart": Regenerative potential linked to immature cardiac phenotypes. 2682 99