Mitochondrial dysfunction causes Ca2+ overload and ECM degradation-mediated muscle damage in C. elegans

Mitochondrial dysfunction impairs muscle health and causes subsequent muscle wasting. This study explores the role of mitochondrial dysfunction as an intramuscular signal for the extracellular matrix (ECM)-based proteolysis and, consequentially, muscle cell dystrophy. We found that inhibition of the mitochondrial electron transport chain causes paralysis as well as muscle structural damage in the nematode Caenorhabditis elegans. This was associated with a significant decline in collagen content. Both paralysis and muscle damage could be rescued with collagen IV overexpression, matrix metalloproteinase (MMP), and Furin inhibitors in Antimycin A-treated animal as well as in the C. elegans Duchenne muscular dystrophy model. Additionally, muscle cytosolic calcium increased in the Antimycin A-treated worms, and its down-regulation rescued the muscle damage, suggesting that calcium overload acts as one of the early triggers and activates Furin and MMPs for collagen degradation. In conclusion, we have established ECM degradation as an important pathway of muscle damage.-Sudevan, S., Takiura, M., Kubota, Y., Higashitani, N., Cooke, M., Ellwood, R. A., Etheridge, T., Szewczyk, N. J., Higashitani, A. Mitochondrial dysfunction causes Ca2+ overload and ECM degradation-mediated muscle damage in C. elegans.

Echocardiographic Strain Analysis for the Early Detection of Myocardial Structural Abnormality and Initiation of Drug Therapy in a Mouse Model of Dilated Cardiomyopathy

This study aimed to evaluate the role of echocardiography-based strain analysis in the early diagnosis and guidance for management of dilated cardiomyopathy (DCM). Muscular dystrophy mice (which spontaneously develop DCM) and control (C57 BL/6 J) mice were sequentially evaluated by ultrasound biomicroscopy, conventional left ventricle (LV) measurement, two-dimensional (2-D) strain analysis and myocardial histologic analysis for 12 consecutive months. Significant alternation of LV remodeling and dysfunction could be detected by conventional echocardiography after 9 mo, by strain analysis after 5 mo and by histologic analysis after 4 mo. The global longitudinal systolic peak strain (PK) was the most sensitive strain marker for early detection of myocardial structural abnormality in the subclinical stage. Moreover, losartan administration before the PK decrease was associated with significantly preserved LV function. These results suggest that myocardial strain analysis (particularly longitudinal PK) is sensitive for the early detection of LV dysfunction in mice with dilated cardiomyopathy.

Metabolic dysfunction and altered mitochondrial dynamics in the utrophin-dystrophin deficient mouse model of duchenne muscular dystrophy

The utrophin-dystrophin deficient (DKO) mouse model has been widely used to understand the progression of Duchenne muscular dystrophy (DMD). However, it is unclear as to what extent muscle pathology affects metabolism. Therefore, the present study was focused on understanding energy expenditure in the whole animal and in isolated extensor digitorum longus (EDL) muscle and to determine changes in metabolic enzymes. Our results show that the 8 week-old DKO mice consume higher oxygen relative to activity levels. Interestingly the EDL muscle from DKO mouse consumes higher oxygen per unit integral force, generates less force and performs better in the presence of pyruvate thus mimicking a slow twitch muscle. We also found that the expression of hexokinase 1 and pyruvate kinase M2 was upregulated several fold suggesting increased glycolytic flux. Additionally, there is a dramatic increase in dynamin-related protein 1 (Drp 1) and mitofusin 2 protein levels suggesting increased mitochondrial fission and fusion, a feature associated with increased energy demand and altered mitochondrial dynamics. Collectively our studies point out that the dystrophic disease has caused significant changes in muscle metabolism. To meet the increased energetic demand, upregulation of metabolic enzymes and regulators of mitochondrial fusion and fission is observed in the dystrophic muscle. A better understanding of the metabolic demands and the accompanied alterations in the dystrophic muscle can help us design improved intervention therapies along with existing drug treatments for the DMD patients.

RASA1 functions in EPHB4 signaling pathway to suppress endothelial mTORC1 activity

Vascular malformations are linked to mutations in RAS p21 protein activator 1 (RASA1, also known as p120RasGAP); however, due to the global expression of this gene, it is unclear how these mutations specifically affect the vasculature. Here, we tested the hypothesis that RASA1 performs a critical effector function downstream of the endothelial receptor EPHB4. In zebrafish models, we found that either RASA1 or EPHB4 deficiency induced strikingly similar abnormalities in blood vessel formation and function. Expression of WT EPHB4 receptor or engineered receptors with altered RASA1 binding revealed that the ability of EPHB4 to recruit RASA1 is required to restore blood flow in EPHB4-deficient animals. Analysis of EPHB4-deficient zebrafish tissue lysates revealed that mTORC1 is robustly overactivated, and pharmacological inhibition of mTORC1 in these animals rescued both vessel structure and function. Furthermore, overexpression of mTORC1 in endothelial cells exacerbated vascular phenotypes in animals with reduced EPHB4 or RASA1, suggesting a functional EPHB4/RASA1/mTORC1 signaling axis in endothelial cells. Tissue samples from patients with arteriovenous malformations displayed strong endothelial phospho-S6 staining, indicating increased mTORC1 activity. These results indicate that deregulation of EPHB4/RASA1/mTORC1 signaling in endothelial cells promotes vascular malformation and suggest that mTORC1 inhibitors, many of which are approved for the treatment of certain cancers, should be further explored as a potential strategy to treat patients with vascular malformations.

Visualizing and quantifying oxidized protein thiols in tissue sections: a comparison of dystrophic mdx and normal skeletal mouse muscles

Reactive oxygen species (ROS) are not only a cause of oxidative stress in a range of disease conditions but are also important regulators of physiological pathways in vivo. One mechanism whereby ROS can regulate cell function is by modification of proteins through the reversible oxidation of their thiol groups. An experimental challenge has been the relative lack of techniques to probe the biological significance of protein thiol oxidation in complex multicellular tissues and organs. We have developed a sensitive and quantitative fluorescence labeling technique to detect and localize protein thiol oxidation in histological tissue sections. In our technique, reduced and oxidized protein thiols are visualized and quantified on two consecutive tissue sections and the extent of protein thiol oxidation is expressed as a percentage of total protein thiols (reduced plus oxidized). We tested the application of this new technique using muscles of dystrophic (mdx) and wild-type C57Bl/10Scsn (C57) mice. In mdx myofibers, protein thiols were consistently more oxidized (19 ± 3%) compared with healthy myofibers (10 ± 1%) in C57 mice. A striking observation was the localization of intensive protein thiol oxidation (70 ± 9%) within myofibers associated with necrotic damage. Oxidative stress is an area of active investigation in many fields of research, and this technique provides a useful tool for locating and further understanding protein thiol oxidation in normal, damaged, and diseased tissues.

Peripheral nerve pathology, including aberrant Schwann cell differentiation, is ameliorated by doxycycline in a laminin-α2-deficient mouse model of congenital muscular dystrophy

The most common form of childhood congenital muscular dystrophy, Type 1A (MDC1A), is caused by mutations in the human LAMA2 gene that encodes the laminin-α2 subunit. In addition to skeletal muscle deficits, MDC1A patients typically show a loss of peripheral nerve function. To identify the mechanisms underlying this loss of nerve function, we have examined pathology and cell differentiation in sciatic nerves and ventral roots of the laminin-α2-deficient (Lama2(-/-)) mice, which are models for MDC1A. We found that, compared with wild-type, sciatic nerves of Lama2(-/-) mice had a significant increase in both proliferating (Ki67+) cells and premyelinating (Oct6+) Schwann cells, but also had a significant decrease in both immature/non-myelinating [glial fibrillary acidic protein (GFAP)(+)] and myelinating (Krox20+) Schwann cells. To extend our previous work in which we found that doxycycline, which has multiple effects on mammalian cells, improves motor behavior and more than doubles the median life-span of Lama2(-/-) mice, we also determined how nerve pathology was affected by doxycycline treatment. We found that myelinating (Krox20+) Schwann cells were significantly increased in doxycycline-treated compared with untreated sciatic nerves. In addition, doxycycline-treated peripheral nerves had significantly less pathology as measured by assays such as amount of unmyelinated or disorganized axons. This study thus identified aberrant proliferation and differentiation of Schwann cells as key components of pathogenesis in peripheral nerves and provided proof-of-concept that pharmaceutical therapy can be of potential benefit for peripheral nerve dysfunction in MDC1A.

Methods for noninvasive monitoring of muscle fiber survival with an AAV vector encoding the mSEAP reporter gene

Muscular dystrophies (MD) are a group of genetically and phenotypically heterogeneous inherited disorders characterized by the progressive degeneration of the skeletal muscle tissue. In the last decade, a tremendous amount of studies were performed to test therapeutic strategies in animal models. Evaluation of such strategies requires the use of criteria predictive of their therapeutic relevance. Here we describe a simple, noninvasive assay to monitor muscle degenerative process. An adeno-associated vector encoding a secreted form of murine embryonic alkaline phosphatase (mSEAP) reporter gene is administrated at the time of treatment. The amount of circulating mSEAP will reflect the level of myofiber survival. We tested this assay with therapeutic gene transfer. We found a strong correlation between therapeutic gene expression/muscle disease amelioration and the circulating levels of mSEAP. The assay will be very useful for monitoring muscle cell survival after therapeutic intervention.

Dystrophin expression in host muscle following transplantation of muscle precursor cells modified with the phiC31 integrase

Duchenne muscular dystrophy (DMD) is the most severe muscular dystrophy. It is caused by the absence of dystrophin in muscle fibers. The autologous transplantation of genetically corrected muscle precursor cells (MPCs) is a possible cure for DMD. A non-viral method of genetic modification was tested in this study. The co-transfection (nucleofection) of a phiC31 integrase and a transgene expressing plasmid in MPCs led to an increased stable expression in vitro. The stable expression of a small transgene (eGFP) in muscle fibers was initially demonstrated following the transplantation of the genetically modified cells. The stable expression of a truncated version of dystrophin as well as the full-length dystrophin fused with eGFP was then demonstrated in MPCs obtained from an mdx mice. The transplantation of these cells led not only to the expression of these fusion proteins in muscle fibers but also to the reconstitution of the dystrophin complex. Human MPCs were also genetically modified with a plasmid coding for the full-length human dystrophin gene fused with eGFP and transplanted in severe combined immuno deficient mice leading to the expression of eGFP dystrophin in muscle fibers. This work indicates that cell transplantation after correction of MPCs with phiC31 integrase is a possible approach to treat DMD.

Characteristics of muscle fibers reconstituted in the regeneration process of masseter muscle in an mdx mouse model of muscular dystrophy

Mdx mice, which lack dystrophin, were examined for changes in the properties of muscle fibers in the growth process of the masseter muscle at the morphological, protein and transcriptional levels. The slow-type isoform, MyHC-1, and the fast-type isoforms, MyHC-2a, MyHC-2d and MyHC-2b, were examined at the protein and the transcriptional level. Morphological examination showed that in the mdx mouse masseter muscle, degeneration, necrosis, and regeneration occurred, particularly at the age of 4 weeks, and many regenerated muscle fibers with centrally located nuclei were observed at the age of 9 weeks. The results of examination at the protein and the transcriptional level showed that in the process of muscle fiber degeneration, necrosis, and regeneration, the mdx mouse masseter muscle acquires muscle fiber characteristics entirely different from those in the normal mouse masseter muscle. In particular, MyHC-1, which is rarely found in normal mice, was very strongly expressed.

Restoration of all dystrophin protein interactions by functional domains in trans does not rescue dystrophy

Rescue of dystrophic skeletal muscle in mdx and utrophin/dystrophin-deficient (dko) mouse models by reintroduction of dystrophin has validated gene therapy as a potential therapeutic approach for Duchenne muscular dystrophy. However, the size of the dystrophin gene exceeds the capacity of adeno-associated viral (AAV) vectors. Dystrophin provides a mechanical link at the muscle membrane by direct binding of its amino-terminal and cysteine-rich domains to actin and a transmembrane protein complex, respectively. It has not been investigated whether restoration of these two tethering functions by two separate dystrophin molecules is sufficient to prevent dystrophic pathologies. We examine the effect of coexpression of the amino-terminal and cysteine-rich domains from separate dystrophin transgenes, Deltacys and Dp71, on the dystrophic phenotype. Expression of individual dystrophin domains from multiple vectors would effectively expand AAV capacity. Although both Deltacys and Dp71 colocalize at the membrane, there is no improvement of dystrophic pathology. The fiber-type and neuromuscular junction abnormalities of dko mice that are ameliorated by the Deltacys transgene are not further improved or disrupted by Dp71. Separate truncated dystrophins, which together restore all protein interactions and scaffolding for signaling molecules, are not sufficient to ameliorate the dystrophic phenotype and therefore dystrophin domains in trans cannot be used to increase the effective cloning capacity for AAV-mediated gene therapy.

Terminal antisense oligonucleotide modifications can enhance induced exon skipping

Induction of specific exon skipping during the processing of the dystrophin gene transcript is being pursued as a potential therapy for Duchenne muscular dystrophy. Antisense oligonucleotides directed at motifs involved in pre-mRNA processing can manipulate dystrophin exon incorporation in the mature gene transcript. We have compared the exon skipping ability of oligodeoxyribonucleotides with compounds of the identical sequence incorporating 2'-O-methyl modified bases. Antisense oligonucleotides composed entirely of 2'-O-methyl modified bases on a phosphorothioate backbone were consistently more efficient at inducing exon skipping than comparable oligodeoxyribonucleotides. Chimeric antisense oligonucleotides, mixtures of unmodified and 2'-O-methyl modified bases, induced intermediate levels of exon skipping. In addition, we describe terminal modifications that may be incorporated into the 2'-O-methyl antisense oligonucleotides to further enhance efficiency of exon skipping. Our findings suggest that 2'-O-methyl antisense oligonucleotides should be considered for human clinical trials involving targeted exon skipping in dystrophin gene expression in preference to oligodeoxyribonucleotides.

Determination of zinc in tissues of normal and dystrophic mice using electrothermal atomic absorption spectrometry and slurry sampling

An electrothermal atomic absorption spectrometric procedure for zinc determination in animal tissues is first optimized and then used to measure the metal content of different tissues from normal and dystrophic mice. The procedure involves minimal manipulation of the sample to overcome the severe contamination problems normally associated with the measurement of low zinc levels. The samples (recommended amount 10 mg) are slurried in 2 ml of a 10-mM tetramethylammonium hydroxide solution containing 0.1 g/100 ml silicone antifoam. After mild heating at 60 degrees C for 10 min and homogenization for 1 min, the suspensions are submitted to a 10-fold dilution and then injected into the electrothermal atomizer. Calibration is carried out using aqueous standard solutions of zinc prepared in the same suspension media. The reliability of the whole procedure is verified using three certified reference materials.

Muscular dystrophy by merosin deficiency decreases acetylcholinesterase activity in thymus of Lama2dy mice

Half of congenital muscular dystrophy cases arise from laminin alpha2 (merosin) deficiency, and merosin-deficient mice (Lama2dy) exhibit a dystrophic phenotype. The abnormal development of thymus in Lama2dy mice, the occurrence of acetylcholinesterase (AChE) in the gland and the impaired distribution of AChE molecules in skeletal muscle of the mouse mutant prompted us to compare the levels of AChE mRNAs and enzyme species in thymus of control and Lama2dy mice. AChE activity in normal thymus (mean +/- SD 1.42 +/- 0.28 micromol acetylthiocholine/h/mg protein, U/mg) was decreased by approximately 50% in dystrophic thymus (0.77 +/- 0.23 U/mg) (p = 0.007), whereas butyrylcholinesterase activity was little affected. RT-PCR assays revealed variable levels of R, H and T AChE mRNAs in thymus, bone marrow and spinal cord. Control thymus contained amphiphilic AChE dimers (G2A, 64%) and monomers (G1A, 19%), as well as hydrophilic tetramers (G4H, 9%) and monomers (G1H, 8%). The dimers consisted of glycosylphosphatidylinositol-anchored H subunits. Western blot assays with anti-AChE antibodies suggested the occurrence of inactive AChE in mouse thymus. Despite the decrease in AChE activity in Lama2dy thymus, no differences between thymuses from control and dystrophic mice were observed in the distribution of AChE forms, phosphatidylinositol-specific phospholipase C sensitivity, binding to lectins and size of AChE subunits.

Tubulyzine, a novel tri-substituted triazine, prevents the early cell death of transplanted myogenic cells and improves transplantation success

Myoblast transplantation (MT) is a potential therapeutic approach for several muscular dystrophies. A major limiting factor is that only a low percentage of the transplanted myoblasts survives the procedure. Recent advances regarding how and when the myoblasts die indicate that events preceding actual tissue implantation and during the first days after the transplantation are crucial. Myoseverin, a recently identified tri-substituted purine, was shown to induce in vitro the fission of multinucleated myotubes and affect the expression of a variety of growth factors, and immunomodulation, extracellular matrix-remodeling, and stress response genes. Since the effects of myoseverin are consistent with the activation of pathways involved in wound healing and tissue regeneration, we have investigated whether pretreatment and co-injection of myoblasts with Tubulyzine (microtubule lysing triazine), an optimized myoseverin-like molecule recently identified from a triazine library, could reduce myoblast cell death following their transplantation and consequently improves the success of myoblast transplantation. In vitro, using annexin-V labeling, we showed that Tubulyzine (5 microM) prevents normal myoblasts from apoptosis induced by staurosporine (1 microM). In vivo, the pretreatment and co-injection of immortal and normal myoblasts with Tubulyzine reduced significantly cell death (assessed by the radio-labeled thymidine of donor DNA) and increased survival of myoblasts transplanted in Tibialis anterior (TA) muscles of mdx mice, thus giving rise to more hybrid myofibers compared to transplanted untreated cells. Our results suggest that Tubulyzine can be used as an in vivo survival factor to improve the myoblast-mediated gene transfer approach.

Muscular dystrophy with laminin deficiency decreases the content of butyrylcholinesterase tetramers in sciatic nerves of Lama2dy mice

The Lama2dy mouse, a model of congenital muscular dystrophy (CMD) by merosin deficiency (MCMD), shows muscle degeneration and dysmyelination of peripheral nerves. Although it has been reported that MCMD reduces acetylcholinesterase (AChE) activity of mouse sciatic nerve, no information is available regarding its action on butyrylcholinesterase (BuChE). Amphiphilic BuChE monomers (G(1)(A), 39%), dimers (G(2)(A), 18%), and tetramers (G(4)(A), 33%), along with hydrophilic tetramers (G(4)(H), 10%), were identified in mouse sciatic nerve. It also contained abundant G(4)(A) (75%) and less G(1)(A), G(2)(A), G(4)(H) and A(12) AChE components. In dystrophic nerves, the BuChE activity increased 2-fold but the proportion of the G(4)(A) form dropped from 33% to 10%. AChE activity decreased and the composition of enzyme forms was unaffected. Lectin interaction studies showed that, in contrast to skeletal muscle, the defect of merosin did not greatly alter the glycosylation of nerve cholinesterases. The anomalous synthesis of BuChE forms in dystrophic nerve may be related with peripheral neuropathy of MCMD.

A factor implicated in the myogenic conversion of nonmuscle cells derived from the mouse dermis

Using the mdx mouse model for human Duchenne muscular dystrophy we have shown that a cell population residing in the dermis of C57B1/10ScSn mouse skin is capable of converting to a myogenic lineage when implanted into the mdx muscle environment. It was important to determine the characteristics of the converting cell. A previous in vitro study indicated that 10% of cells underwent conversion but only when the cells were grown in medium previously harvested from a myogenic culture. In the present study we cloned cells derived from the dermis to identify the converting cells. Clones grown in normal growth medium showed no conversion, but when grown in medium conditioned by muscle cells around 40% conversion was achieved in several individual clones. We investigated whether the protein beta-galactoside binding protein (betaGBP), which is secreted by myoblasts and acts as a cell growth regulator of fibroblasts. could be a candidate factor responsible for conversion. Medium harvested from COS-1 cells infected with a construct containing betaGBP has been used for this investigation. Growth of dermal fibroblasts in medium enriched with this factor showed a high rate of conversion to cells expressing muscle-specific factors.

In situ study of the sarcoplasmic reticulum function in control and mdx mouse diaphragm muscle

Sarcoplasmic reticulum (SR) calcium handling in diaphragm was compared between mdx mice (7-8 weeks old) and age-matched controls. The total SR Ca2+ load was released from the SR by rapidly cooling muscle bundles from 22 to -1 degree C. The plateau amplitude of the rapid cooling contracture (RCC) was considered as an index of the SR Ca2+ content. The steady-state RCC amplitude was significantly lower by 50% in mdx bundles mainly because of a decreased capacity of the dystrophic diaphragm to generate maximal tension. There was no significant difference between either RCC time to peak or the time to half-relaxation of the transient, spike-like, contractile response induced by muscle rewarming. The recovery process of RCC was studied by using a paired RCC protocol. In both groups, at the shortest interval (10 s) between two RCCs, the amplitude of the second RCC was decreased by 25% compared with the first RCC. Increasing the time interval led to progressive monoexponential recovery of the second RCC with similar time constants in control and mdx diaphragm. These results indicate that the dystrophic process does not significantly alter SR Ca2+ uptake nor Ca2+ redistribution within the muscular cell.

IN VITRO CULTURE OF MUSCLE TISSUE FROM NORMAL HETEROZYGOUS, AND DYSTROPHIC CHICKS

The degree of histological deterioration of the original explant and the extent of cell spreading was evaluated in cultures of pectoralis muscle from 11-day chicks. Although the frequencies of these two parameters varied with the amounts of horse serum and embryo extract added to the medium, cultures from dystrophic chicks, in comparison to those from either normal or heterozygous animals, consistently showed the largest number of explants with the most extreme forms of histological deterioration and cell spreading. At 20 per cent horse serum the cultures from heterozygous chicks showed greater frequencies of the more extensive forms of deterioration and spreading than the normal muscle explants, but at 5 per cent horse serum these two groups appeared similar. Regardless of genetic background, cultures of the pectoralis muscle from 18-day embryos and of the latissimus dorsi muscle from 11-day chicks exhibited comparable high frequencies for the maximal degrees of deterioration and spreading.

Muscle regeneration and mitochondrial calmitine increase in the dystrophic dy/dy mouse after intramuscular chlorpromazine injection

We studied the effect of chlorpromazine injection on the gastrocnemius muscles of C57BL/6J dy/dy dystrophic mice. Changes in mitochondrial calmitine concentrations and differences in microscopy studies, fibre typing and morphometry were compared in gastrocnemius muscles of dystrophic and control mice before and 2 and 21 days after injection. In both cases, calmitine reduction associated with muscle degeneration was observed 2 days after drug injection. Calmitine then increased, reaching a level at day 21 nearly identical to that of controls before injection. This increase was associated with muscle regeneration. These results clearly indicate that dystrophic mouse muscle can regenerate calmitine after drug-induced damage.

Regenerative capacity of mdx mouse muscles after repeated applications of myo-necrotic bupivacaine

We injected bupivacaine (BPVC), which produces muscle fiber necrosis, repeatedly into the soleus muscles of mdx mice, which represent a model of human Duchenne muscular dystrophy, over a 12-month period. Cytological and morphometric analysis revealed that the regenerative capacity of repeatedly BPVC-injected mdx muscles was almost equal to that of the saline-injected mdx muscles. At 9 months of age the endomysial collagen content of mdx muscles was 4.6 times that of control mice muscles, and was 7.2 times that of control mice muscle at 12 months. These results suggest that the regenerative capacity of the mdx muscle is quite large and that myo-necrosis induced by an extrinsic cause, such as BPVC, may not be an important factor in the disease progress. However, endomysial collagen, for which the mechanism of increase may be related to the defect of dystrophin, may play an important role in gradual decline of regeneration.

Pathophysiology of muscular dystrophy

The inevitable and remorseless clinical decline in a patient with Duchenne muscular dystrophy (DMD) evokes a special sense of impotent desperation, which was, until recently, exacerbated by lack of obvious progress in its treatment. However, identification of the culpable gene has provided insight into the pathogenesis of DMD and glimmerings of hope for its treatment.

Immuno-electron-microscopic localization of basic fibroblast growth factor in the dystrophic mdx mouse masseter muscle

The localization of basic fibroblast growth factor (bFGF)-like immunoreactivity in the masseter muscle of dystrophic mdx mice on postnatal day 28 was investigated by immunoblot analysis and electron microscopy. Crude homogenate of the masseter muscle, when subjected to immunoblotting with a bFGF antiserum, exhibited a main band with the same molecular weight (18 kDa) as bovine bFGF. By electron microscopy, bFGF immunoreactivity was detected in small regenerating myocytes; the smaller cells were the premature myocytes, the most intense staining was the immunoreactivity within the cytoplasm. Putative precursors of the muscle cells with a few myofilaments, which were most intensely labeled with anti-bFGF, contacted each other and possibly developed into multinucleated myocytes through cell fusion. Mature myocytes with densely packed myofilaments and peripherally located nuclei did not exhibit bFGF immunoreactivity; they formed myoneural junctions with motor nerve endings immunoreactive for bFGF. Early differentiating myocytes with intense bFGF-like immunoreactivity did not make contact with immunoreactive nerve terminals. Degenerating large myocytes with a limited number of distorted and/or disrupted myofilaments exhibited electron-dense deposits in the cristae of mitochondria; these deposits were not abolished by immunoadsorption control experiments. Thus, the cell-size-dependent decrease in bFGF immunoreactivity in regenerating but not in degenerating myocytes provides a morphological basis for an autoregulatory role of bFGF in muscle regeneration. This study suggests that neuronal bFGF is not involved in initial muscle regeneration in the dystrophic mdx mouse.

Duchenne dystrophy viewed as a disturbance of nerve-muscle interactions

The possibility that some features of Duchenne muscular dystrophy (DMD) can be explained as a disturbance of nerve-muscle interaction during development is discussed. It is argued that the initial disturbance in DMD is due to a slower rate of maturation of skeletal muscle fibers. Normally, the maturation of the motor reflexes is closely followed by maturation of the muscle fibers. The possibility is considered that if muscle fibers mature more slowly than normal, they are not able to withstand the type of activity imposed upon them by the mature motoneuron. This applies mainly to the high frequency activity imposed on the fibers of motor units that are destined to become "fast." Experimental evidence suggesting such a mechanism is presented.

Technique for measuring picomolar amounts of bound and unbound amino acids obtained from myogenic cell cultures of skeletal muscle

A procedure is described that compares the isotope dilution method of measuring picomolar amounts of amino acids obtained from cellular extracts with a direct method of analysis. Evidence is provided that shows that the direct method is at least as accurate as the isotope dilution method. In addition the direct method is as expedient an requires but a single isotope and fewer chromatograms for analysis. A procedure also is described for selecting the appropriate conditions for dansylation and for measuring the loss of dansyl amino acid due to decomposition.

IgG immunoglobulin deficiency in muscular dystrophic chickens

Plasma immunoglobulin profiles of New Hampshire strain muscular dystrophic chickens were determined by radial immunodiffusion, immunoelectrophoresis and polyacrylamide gel electrophoresis. Muscular dystrophic chickens have reduced levels of IgG but maintain normal levels of total serum proteins, IgA and IgM. The relationship and significance of the IgG deficiency to muscular dystrophy remains to be determined.

[Vitamin E and selenium in the feed of farm animals (author's transl)]

A survey is given of vitamin E and selenium deficiency syndromes in farm animals. Some syndromes can be attributed to the exclusive deficiency of one of the above-mentioned feed components. In some cases with practically complete lack of both componentspathological symptoms can be cured by the addition of one of them to the feed in sufficient amount. A synergistic effect of vitamin E and selenium is sometimes found to recur. The most important theory about the functioning of vitamin E is that it acts as an antioxidant. This theory presumes that, in case of a vitamin E deficiency, peroxidation of unsaturated lipids can occur everywhere in the body leading to oxidative chain reactions. The free radicals thus produced might participate in non-specific reactions with functional and structural compounds. Vitamin E is considered able to reduce lipid peroxides or scavenge free radicals from chain reactions. The pros' and cons' of this theory are discussed. The role of vitamin E has further been associated with thenium is part of the enzyme glutathione peroxidase. This enzyme catalyses the reaction of reduced glutathione with peroxides, whereby hydroxy-acids and oxidized glutathione are generated. Most probably the glutathione peroxidase has its antioxidative action in the cytosol, whereas vitamin E is mainly located in the membranes of the cell.

[Effect of experimental lard diet on the incidence of vitamin E deficiency signs in pigs]

In three trials pigs were fed semisynthetic diet characterized by vitamin E deficit and supplemented with lard at different degrees of oxidative rancidity. When rancid lard was used and pigs were exposed to the effects of stress factors from the 55th day of the trail, signs of affected walking and lack of appetite were observed. Pig organs were subject to histological examination on the 83rd day. Dystrophic changes of heart and skeletal muscles were revealed. The changes were accompanied by increased activities of aspartate and alanine amino transferases and lactate dehydrogenase in blood serum. The addition of 150 mg of tocopherol acetate per 1 kg of feed increased its concentration in tissues and prevented the occurrence of clinical, biochemical, and morphological signs; decreases in weight gains were also avoided. When fresh fat was used without any additional effect of stress factors, no morphological signs of vitamin E deficiency were observed. A decreased quality of lard in feed was not found to exert any influence on a higher consumption of vitamin E. The production of lipoperoxides in tissue homogenates was considerably decreased as a result of the addition of vitamin E to feed. The criteria to be used for intravital and post-mortal diagnosis of vitamin E deficiency in pigs are evaluated.

Neuromuscular disorders in childhood. Old dogmas, new concepts

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