Altered membrane association of glycogen phosphorylase in the dystrophic chicken

The subcellular distribution of glycogen phosphorylase in pectoralis muscle from normal and dystrophic chickens was determined as a function of age. A substantially larger proportion of the total activity was associated with membranes cellular organelles, both mitochondria and sarcoplasmic reticulum, in preparations from dystrophic birds. The difference could be detected as early as 2 weeks ex ovo. Interaction of phosphorylase with cellular membranes may provide a probe for the underlying membrane defect in this dystrophyl model.     

Myosin heavy chain in avian muscular dystrophy corresponds to the neonatal isozyme

We have previously demonstrated, based on comparison of homologous amino acid sequences and of two-dimensional CNBr peptide gel patterns, that the myosin heavy chain in pectoralis muscles of Storrs, Connecticut dystrophic chickens is different from that of their normal controls (Huszar, G., Vigue, L., De-Lucia, J. Elzinga, M., and Haines, J. (1985) J. Biol. Chem. 260, 7429-7434). Others have shown, however, that genomic banks and mRNA complements of the control and dystrophic birds are not different. In the present studies, we have examined the hypothesis that the "dystrophic" myosin heavy chain is not a novel gene product, but is a developmental isozyme which is expressed in pectoralis muscles of adult chickens due to the dystrophic process. Two-dimensional maps of myosin heavy chain CNBr peptides were prepared from breast muscles of 17-day in ovo (embryonic), 25-day posthatch (neonatal), and adult birds of the Storrs dystrophic and of two control strains. Also, myosin and actomyosin ATPase enzymatic activities of the various preparations were determined in the pH range of 5.5 to 9.0. Analysis of the peptide maps demonstrates that the embyronic, neonatal, and control adult myosin heavy chain isozymes are distinctly different gene products with only minute variations between the respective developmental isozymes in dystrophic and control muscles. However, the pectoralis myosin heavy chain of adult dystrophic birds, which is a homogeneous isozyme population by amino acid sequences and gel patterns, corresponds to that of the neonatal-type myosin heavy chain. The ATPase properties of the embryonic, neonatal, or adult pectoralis myosins and actomyosins were not different, whether the level of specific activity or the pattern of pH activation is considered. Since the mobility of neonatal chicks (primarily neonatal-type isozymes) is not restricted, the differences in myosin heavy chain structures are part of the syndrome, but not the cause of avian muscular dystrophy.     

Detection and isolation of a 30 kDa abnormal protein in avian dystrophic muscle

We have studied the protein composition of the pectoralis superficialis muscle of genetically dystrophic (New Hampshire line 413) and normal control (line 412) chickens by one- and two-dimensional gel electrophoresis. A protein, referred to hereafter as the 30 kDa abnormal protein, was specifically detected in the affected muscle. It was purified to homogeneity, and its molecular properties were studied. It is a monomer with a molecular mass of approximately 30 kDa and an isoelectric point of about pI 8.4. We have screened by Western blotting a variety of muscles from line 412 and line 413 chickens for the presence of the 30 kDa protein. While the pattern of total protein is very similar in all cases, the 30 kDa protein was not detected in the pectoralis superficialis muscle of line 412 chickens. However, the immunoreactive bands were detected in the sartorius muscle and the tensor fasciae latae muscle from dystrophic and normal chickens. Interestingly, the immunoreactive bands of normal skeletal muscles are smaller in molecular weight than those of dystrophic skeletal muscles. To determine the early time sequence of the appearance of the abnormal protein, we studied muscles from embryos and post-hatched chickens at various ages. The abnormal protein was detected in dystrophic muscles as early as 15 days ex ovo and occurred throughout development up to six months ex ovo. Although the implication of the dystrophy-associated appearance of the 30 kDa protein in the affected muscle is not clear at present, it would be of particular interest to elucidate the biochemical functions of the 30 kDa protein in the affected muscle (pectoralis superficialis muscle) of genetically dystrophic chicken.     

The involvement of sarcotubular membranes in genetic muscular dystrophy.

Microsomal preparations from breast muscle of normal and dystrophic chickens are characterized with regard to ultrastructural features, protein composition, Ca2+ transport and ATPase activity. Dystrophic muscle yields a greater microsomal dry weight, with a reduced protein to lipid ratio. This is related to the presence of a considerable number of low density microsomes, in addition to seemingly normal microsomes. The low density microsomes display a reduced number of protein particles on freeze fracture faces. Electrophoretic analysis reveals nearly identical patterns in normal and dystrophic microsomes. Furthermore, normal and dystrophic microsomes sustain equal rates of Ca2+ transport and ATPase, demonstrating an identical protein specific activity. However, the dystrophic microsomes have a lower capacity to retain transported Ca2+. The high yield of low density microsomes with reduced capacity for Ca2+ uptake is attributed to the presence of membranes proliferated in the junctional and tubular sarcomere regions of the dystrophic muscle. It is suggested that proliferation of such membranes accounts for the altered excitation-contraction coupling and cable properties of genetically dystrophic muscle.     

Early abnormal development of calmodulin gene expression and calmodulin-resistant Ca2+-ATPase activity in avian dystrophic muscle

We have reported previously that the pectoralis muscle from three month-old dystrophic chickens with signs of myopathy exhibits increased calmodulin content, elevated calmodulin-specific mRNA (Biochem. Biophys. Res. Commun. 137:507-512, 1986), and reduced sarcoplasmic reticulum (SR) Ca2+-ATPase activity in response to calmodulin exposure in vitro (Clin. Res. 34: 725A, 1986). To determine the early time sequence for development of these abnormalities, we have studied muscle from embryos and post-hatched chickens at various ages. Quantitated by dot blot analysis, there was an approximate two-fold increase in calmodulin-specific mRNA in dystrophic muscle as early as 13 days ex ovo which was maintained throughout development up to three months ex ovo. Similarly, Ca2+-ATPase activity measured in SR membranes from chickens as early as 13 days post-hatch was also found to be resistant to stimulation in vitro by exogenous calmodulin, whereas the enzyme from normal muscle was calmodulin-stimulable. These findings suggest that the genetic lesion expressed in the avian dystrophic animal model involves the loss of normal control of intracellular calcium metabolism early in the maturation of the affected musculature and prior to appearance of disease signs.     

The involvement of sarcotubular membranes in genetic muscular dystrophy

Microsomal preparations from breast muscle of normal and dystrophic chickens are characterized with regard to ultrastructural features, protein composition, Ca²⁺ transport and ATPase activity.Dystrophic muscle yields a greater microsomal dry weight, with a reduced protein to lipid ratio. This is related to the presence of a considerable number of low density microsomes, in addition to seemingly normal microsomes. The low density microsomes display a reduced number of protein particles on freeze fracture faces.Electrophoretic analysis reveals nearly identical patterns in normal and dystrophic microsomes. Furthermore, normal and dystrophic microsomes sustain equal rates of Ca²⁺ transport and ATPase, demonstrating an identical protein specific activity. However, the dystrophic microsomes have a lower capacity to retain transported Ca²⁺.The high yield of low density microsomes with reduced capacity for Ca²⁺ uptake is attributed to the presence of membranes proliferated in the junctional and tubular sarcomere regions of the dystrophic muscle. It is suggested that proliferation of such membranes accounts for the altered excitation-contraction coupling and cable properties of genetically dystrophic muscle.     

Altered contents of tocopherols in chickens with inherited muscular dystrophy

Oxidative damage has been hypothesized as the basis for some of the changes in enzymatic functions and physical properties of membranes in inherited muscular dystrophy. The contents of alpha- and gamma-tocopherol (vitamin E) and their oxidation products, the tocopheryl quinones, were measured at 1 to 4 weeks after hatching in the muscle and other tissues of chickens with inherited muscular dystrophy. Analyses at these early ages minimized the potential influence of pathological changes on the measured parameters. The affected muscle (pectoralis major) of dystrophic birds contained significantly higher levels of alpha-tocopheryl quinone and a decreased ratio of alpha- to gamma-tocopherol. Consistent changes in these parameters were not observed in other tissues. Although their basis remains unclear, these changes in the tocopherols are suggestive of oxidative stress in dystrophic muscle membranes. Lipid extracts of tissues of normal and dystrophic birds exhibited no significant differences in the content of conjugated dienes or lipofuscins, two other indices of oxidative stress. These data do not consistently support the hypothesis that oxidative stress plays a causal role in damage to dystrophic muscle, although it remains possible that free-radical damage is involved in the secondary alterations associated with muscular dystrophy.     

Multiple acid phosphatases in avian pectoral muscle--the postmicrosomal supernatant acid phosphatase is elevated in avian dystrophic muscle

There are at least three forms of acid phosphatase in avian pectoralis muscle differing in molecular weight, subcellular location, and response to various substrates and inhibitors. These enzymes are separated by differential sedimentation into postmicrosomal supernatant, lysosomal, and microsomal activities with apparent molecular weights in Triton X-100 of 68,000, 198,000, and 365,000, respectively. All of the enzymes show acid pH optima (pH approximately 5), but the postmicrosomal supernatant form is distinctly different from the other two forms in its resistance to most common phosphatase inhibitors and in its reduced activity against several organic phosphates. Quantitation of these three forms of acid phosphatase in normal and dystrophic avian pectoralis muscle shows that the postmicrosomal supernatant form is significantly elevated in dystrophic muscle; at 33 days ex ovo, 84% of the increased acid phosphatase activity in dystrophic muscle can be attributed to the postmicrosomal supernatant form. The microsomal form is only slightly elevated; the level of the lysosomal form is not altered.     

Changes in the Levels and Forms of Cholinesterases in the Blood Plasma of Normal and Dystrophic Chickens

Abstract: Acetylcholinesterase (AChE) and pseudocholinesterase (°ChE) were analysed in the blood plasma of developing chickens, both normal and those with inherited muscular dystrophy. The amounts and the molecular forms of each were examined. °ChE concentration rises in the plasma of normal and dystrophic chicks at the end of embryonic development and is maintained after hatching at a constant, relatively high level, accounting for 90-95% of total cholinesterase activity in normal plasma. This level is maintained in normal and dystrophic chickens. In embryonic plasma of both normal and dystrophic chicks, on the other hand, the levels of AChE are higher than those of °ChE. Immediately after hatching the AChE level decreases rapidly in normal plasma, reaching a very low level by 2-3 weeks ex ovo. The AChE level in plasma from dystrophic birds, although less than normal from day 19 in ovo to 2 weeks ex ovo, subsequently increases to peak around 4 months at levels 15-20-fold of those in normal birds. There is virtually no enzyme of either type in the erythrocytes of normal or dystrophic chickens. The changes of AChE in plasma were correlated with the alterations of AChE in dystrophic fast-twitch muscles, suggesting that the latter pool is a precursor of the plasma AChE. Both the AChE and the °ChE in plasma exist in multiple molecular forms, which are similar to certain of those found previously in the muscles of these birds. The major form (60-80%) of both enzymes in the plasma is the M form (sedimentation coefficient ≥11 S) in all cases, but it is accompanied by certain other forms. In no case is there any of the heaviest form (H₂, 19-20 S) of AChE or of °ChE found in normal and dystrophic muscle, which is attached at the synapses in normal muscle. The pattern of forms of plasma °ChE is constant at all ages, and in normal and dystrophic chickens. The pattern of forms of AChE in the plasma, in contrast, varies with age and with dystrophy in a characteristic manner. The sedimentation coefficients and the amounts of the enzymes in fast-twitch muscle of dystrophic animals are compared with those of the plasma forms, and an interpretation is given of the characteristic patterns of AChE and of χE in their blood.     

Microsomal T system: a stereological analysis of purified microsomes derived from normal and dystrophic skeletal muscle

Heterogeneous populations of microsomes obtained from normal and dystrophic chicken pectoralis muscle were separated into two subfractions by an iterative loading technique. The buoyant density of the sarcoplasmic reticulum (SR) microsomes was increased after loading them with calcium oxalate. Several incubations in the transport medium were necessary to load all of the SR. The fraction that did not form a pellet contained microsomes which displayed freeze-fracture faces that had a low density of particles. A stereological analysis was used on membrane fracture faces of intact muscle to generate reference particle density distributions, which were compared with the distributions measured on the microsomal fracture faces. The concave microsomal fracture faces of purified microsomes which did not load calcium oxalate had particle distributions nearly identical to the distributions of intact P-face T tubules. The morphological data suggest that this subfraction is microsomal T system. Biochemical measurements show negligible amounts of specific Na+, K+-ATPase activity, suggesting that there was little contamination from the surface membrane in this subfraction. Furthermore, an active Ca2+-ATPase is demonstrated in both normal and dystrophic T-tubular membranes.     

Avian muscular dystrophy: Thyroidal influence on pectoralis muscle growth and glucose-6-phosphate dehydrogenase activity

The pectoralis muscles of dystrophic chickens (line 413) were hypertrophic on the basis of fresh weight and fat-free dry weight. They also had greater DNA content and greater glucose-6-phosphate dehydrogenase (G6PD) and 6-phosphogluconate dehydrogenase (6PGD) activities. Of the parameters measured, the largest differences between pectoralis muscles from dystrophic and normal (line 412) chickens were for DNA content and G6PD activity. These parameters were 4.3- and 6.7-fold, respectively, the values for control pectoralis at 5 wk of age. The average number of nuclei per unit length of isolated muscle fiber was also greater (approximately 3-fold) for the dystrophic pectoralis. Body weight and pectoralis fresh weight, fat-free dry weight, DNA content, G6PD activity and 6PGD activity were reduced significantly in propylthiouracil (PTU)-treated normal and dystrophic chickens. Moreover, the effects of PTU were more pronounced in the dystrophic strain. Thyroid deprivation significantly improved the righting ability of the dystrophic chickens, in addition to its influence on muscle hypertrophy and body growth. Thyroxine (T₄) replacement reversed the PTU effects in both strains. Of all the variables measured, total G6PD activity was the most affected by PTU treatment of dystrophic chickens and was only 16% of the control dystrophic value.In addition to the effects of thyroid deprivation on the expression of avian muscular dystrophy, we observed significant differences in thyroid-related variables in the two strains. The average thyroid weight at 4 wk and serum triiodothyronine level at 5 wk for dystrophic chickens were 65 and 76%, respectively, of the normal values. The results that we report here indicate that altered thyroid function affects the expression of avian muscular dystrophy.     

Structure of myosin heavy chain in avian muscular dystrophy

We have studied the structure of myosin heavy chain (MHC) in the pectoralis muscle of genetically dystrophic (Connecticut Strain) and White Leghorn chicks. MHC was alkylated with N-ethylmaleimide, purified by Sepharose-4B chromatography, and cleaved with cyanogen bromide. The MHC CNBr peptides were analyzed by one-dimensional and two-dimensional isoelectric focusing/sodium dodecyl sulfate gradient gels and by amino acid sequencing. Specific changes were detected in the gel patterns which could be correlated with the loss of muscle function as measured by the exhaustion score (the ability of chicks to rise from a reclining position) in three experimental groups (exhaustion scores: less than 3, 10-20, greater than 30). We have also examined the amino acid sequence of a 3-methyl-histidine-containing peptide which originates from the 20-kDa fragment of pectoralis muscle MHC in dystrophic chicks: Val-Leu-Asn-Ala-Ser-Ala-Ile-Pro-Glu-Gly-*Gln-Phe-*Ile-Asp-Ser-Lys-Lys- Ala-Ser-Leu-Gln-Lys-Leu-Gly-Ser-Ile-Asp-Val-(Asp, 3-methylhistidine, Gln). Comparison of the homologous MHC sequences shows two positions at which MHC from dystrophic chicks differs from that of the White Leghorn chicks *(Glu----Gln and Met----Ile). Thus, both the peptide map and sequence analyses demonstrate that in avian muscular dystrophy an abnormal pectoralis MHC is synthesized. It is not yet clear whether the "dystrophic" MHC is a variant MHC or if it arises from the abnormal expression of an earlier developmental form (embryonic or neonatal) of pectoralis muscle MHC.     

Oxidation state of tissue thiol groups and content of protein carbonyl groups in chickens with inherited muscular dystrophy.

Indirect evidence suggests that oxidative stress may play a role in the pathogenesis of inherited muscular dystrophy, but the significance and precise extent of this contribution is poorly understood. Compared with normal muscle, significantly higher contents of glutathione, glutathione disulphide, protein-glutathione mixed disulphides and protein carbonyl groups, and significantly lower contents of free protein thiol groups, were found in pectoralis major muscle of genetically dystrophic chickens (the muscle affected by this disease) at 4 weeks of age. Other tissues did not show such marked disease-related differences. Interestingly, the protein pool in normal, but not dystrophic, pectoralis major muscle was relatively less oxidized in relation to the glutathione pool as compared with other tissues studied. The mechanisms by which this unique relationship between the thiol pools is maintained remain unknown. Although the physiological consequences of the increased content of protein carbonyl groups and the altered thiol pools in dystrophic muscle are not clear, the changes evident at such a young age are consistent with the occurrence of oxidative stress and may reflect significant damage to cellular proteins in this disease.     

Elevation of calmodulin in avian muscular dystrophy

In an attempt to understand the mechanism of calcium accumulation in myopathies, changes in the major calcium-binding protein, calmodulin, was studied in genetically dystrophic chickens. Measurements by radioimmunoassay revealed an increase in the calmodulin concentration of dystrophic chicken muscles. Poly A-containing RNA(s) of fast and slow muscles from the normal and dystrophic chicks were hybridized with [32P]-labeled calmodulin cDNA probe by the dot-hybridization technique. Densitometric scan of the autoradiogram showed that the calmodulin mRNA levels of dystrophic fast muscles (pectoralis and posterior latissimus dorsi) were approximately two-fold higher than those of the corresponding normal muscles. No significant change in calmodulin and calmodulin messenger RNA of slow muscle (ALD) was found in dystrophic chickens. Our results suggest that increased calcium flux within the dystrophic muscle may be modulated by calmodulin.     

Rapid kinetics of calcium ion transport and ATPase activity in the sarcoplasmic reticulum of dystrophic muscle.

Vesicular fragments of sarcoplasmic reticulum were isolated from pectoralis muscle of normal and dystrophic chicken. Purification of both preparations was equally satisfactory, as shown by a prominent ATPase band in electrophoresis gels. Measurements of ATPase phosphorylation, Ca2+ transport and Pi cleavage by rapid quench methods revealed a lower specific activity of the dystrophic vesicles with respect to all of these functions. On the other hand, Ca2+-independent ATPase activity was found to be increased in dystrophic vesicles. It is suggested that a fraction of ATPase units of dystrophic sarcoplasmic reticulum is not activated by Ca2+, owing to an altered protein assembly within the membrane bilayer. In fact, when the membrane structure is perturbed by detergents normal and dystropic preparations acquire an equally high Ca2+-dependent ATPase.     

Effects of the sex-linked dwarf gene (dw) on the expression of the muscular dystrophy gene (am) in chicken.

The sex-linked dwarf gene (dw) was introduced into companion muscular dystrophic (am) and nondystrophic (Am+) New Hampshire chicken lines to investigate influences of the dwarf gene on breast muscle weights, muscle fiber area, and the histological expression of muscular dystrophy. Dystrophic and nondystrophic chickens within dwarf or nondwarf genotypes were similar in body and carcass weights. Pectoralis and supracoracoideus muscle weights (as a percentage of adjusted carcass weight) were similar in nondystrophic dwarf and nondwarf males and females. In addition, pectoralis weight was similar in dystrophic dwarf males and dystrophic nondwarf males and females. However, pectoralis weight was significantly smaller in dystrophic dwarf females than in dystrophic nondwarf females, whereas supracoracoideus weight was significantly larger in dystrophic dwarf males than in dystrophic nondwarf males. Supracoracoideus weight was similar in dystrophic dwarf males and females and dystrophic nondwarf females. Pectoralis muscle fiber area was influenced by sex and by dwarf and dystrophy genotype. Muscle fiber area was larger in females than in males, smaller in dwarfs than in nondwarfs, and smaller in dystrophic than in nondystrophic muscles. Muscle fiber degeneration and adipose infiltration was more extensive in dystrophic than in nondystrophic females and males, and it was more advanced in dwarfs than in nondwarfs. Excessive acetylcholinesterase staining patterns were characteristic of dystrophic muscle in both dwarf and nondwarf genotypes. Nondystrophic and dystrophic dwarf male and female chickens are comparable substitutes for nondwarfs as biomedical models with respect to pectoralis histology, acetylcholinesterase staining pattern, and pectoralis muscle hypertrophy.     

Ca2+ binding,ATP-dependent Ca2+ transport,and total tissue Ca2+ in embryonic and adult avian dystrophic pectoralis

Summary Avian muscular dystrophy is an autosomal recessive genetic disease characterized by early hypertrophy and loss of function of the pectoralis major. The disease is progressive, ultimately resulting in atrophy and heavy lipid deposition.Previous investigators have noted a decrease in the ability of the dystrophic sarcoplasmic reticulum to concentrate Ca²⁺. More recently, other investigators have shown an abnormal calcium uptake in avian dystrophic sarcoplasmic reticulum. They indicated, using freeze-fracture techniques, that a 90 Å particle of the vesicle membrane exhibited a decreased population and suggested that they might be the ATPase involved in calcium transport.Our studies confirm the earlier observations of a decreased rate of Ca²⁺ uptake and Ca²⁺ binding capacity of dystrophic fragmented sarcoplasmic reticulum vesicles which are isolated from both embryonic and adult pectoralis. These observations correlate in turn with a 75% drop in the Ca: ATP transport efficiency of the dystrophic sarcoplasmic reticulum determined by measuring the rate of³²P_i liberation from -ATP³² during active calcium transport by the isolated sarcoplasmic reticulum SR.In addition, we have found a quantitative deficiency in a 65,000 dalton component of the dystrophic fragmented SR at the time of myoblast fusion by measuring³⁵S-Methionine incorporation into the SR, coupled to high resolution polyacrylamide gel electrophoresis and radioautography. Analysis of total tissue calcium by atomic absorption spectroscopy revealed a decrease in the total calcium content of dystrophic muscle.     

Thyroidal involvement in the expression of avian muscular dystrophy

We showed previously that propylthiouracil (PTU), a thyroid inhibitor, could alleviate several major signs of hereditary muscular dystrophy in chickens. The goals of the present investigation were to: (1) determine whether a nearly athyroid condition (achieved within two days after hatching by surgical thyroidectomy plus PTU) during an 11-day period beneficially affects the dystrophic condition when followed by triiodothyronine (T3) replacement to 33 days of age; (2) determine the beneficial effects on the expression of avian dystrophy when the thyroidectomized-PTU-treated chickens received a wide range of moderate to low T3 replacement doses beginning by two days after thyroidectomy; and (3) examine the thyroid hormone receptor system in dystrophic muscle for a possible abnormality. Thyroid deprivation increased muscle function (righting ability) and reduced plasma creatine kinase activity in dystrophic chickens. The major thyroid-related abnormality in dystrophic pectoralis muscles was an increased maximum binding capacity of solubilized nuclear T3 receptors.     

Myogenic defect in muscular dystrophy of the chicken.

Inherited muscular dystrophy of the chicken is thought to arise from abnormal development of trophic regulation of skeletal muscles by their innervating nerves. To determine whether expression of muscular dystrophy in the chicken is a property of the nerves or of the muscles, wing limb buds were transplanted between normal and dystrophic chick embryos at $\text{3}\text{1}\text{2}$ days of incubation (stage 19–20). Muscles of donor limbs innervated by nerves of the hosts were compared to contralateral unoperated host limb muscles in chicks from 6 to 25 weeks after hatching. Expression of normal or dystrophic phenotype was determined by examination of five different properties which are altered in dystrophic chick muscle: electromyographic evidence of myotonia; fiber diameter; acetylcholinesterase activity, localization, and isozymes; lactic dehydrogenase activity; and succinic dehydrogenase activity. Genetically normal muscle innervated by nerves of normal or dystrophic hosts was phenotypically normal while genetically dystrophic muscle innervated by normal nerves was phenotypically dystrophic. The results suggest that inherited muscular dystrophy of the chicken arises from a defect of muscle rather than from a lesion in the nerves themselves.     

Abnormal expression of the calmodulin gene in muscle from the dystrophic chicken

Compared to that of genetically-related normal chickens, pectoralis muscle from the dystrophic chicken contained increased calmodulin measured by radioimmunoassay. Determined by the dot blot procedure, expression of the calmodulin gene was enhanced in muscle from affected animals. The bioactivity of the gene product was normal. Together with previous studies reporting increased cell Ca2+ content in dystrophic muscle, the current findings of increased sarcoplasmic calmodulin suggest the latter is a cellular response to defective Ca2+ transport at the level of cell efflux or intracellular organelle (sarcoplasmic reticulum) uptake.