Diversity of fast myosin heavy chain expression during development of gastrocnemius, bicep brachii, and posterior latissimus dorsi muscles in normal and dystrophic chickens

The expression of fast myosin heavy chain (MHC) isoforms was examined in developing bicep brachii, lateral gastrocnemius, and posterior latissimus dorsi (PLD) muscles of inbred normal White Leghorn chickens (Line 03) and genetically related inbred dystrophic White Leghorn chickens (Line 433). Utilizing a highly characterized monoclonal antibody library we employed ELISA, Western blot, immunocytochemical, and MHC epitope mapping techniques to determine which MHCs were present in the fibers of these muscles at different stages of development. The developmental pattern of MHC expression in the normal bicep brachii was uniform with all fibers initially accumulating embryonic MHC similar to that of the pectoralis muscle. At hatching the neonatal isoform was expressed in all fibers; however, unlike in the pectoralis muscle the embryonic MHC isoform did not disappear. With increasing age the neonatal MHC was repressed leaving the embryonic MHC as the only detectable isoform present in the adult bicep brachii muscle. While initially expressing embryonic MHC in ovo, the post-hatch normal gastrocnemius expressed both embryonic and neonatal MHCs. However, unlike the bicep brachii muscle, this pattern of expression continued in the adult muscle. The adult normal gastrocnemius stained heterogeneously with anti-embryonic and anti-neonatal antibodies indicating that mature fibers could contain either isoform or both. Neither the bicep brachii muscle nor the lateral gastrocnemius muscle reacted with the adult specific antibody at any stage of development. In the developing posterior latissimus dorsi muscle (PLD), embryonic, neonatal, and adult isoforms sequentially appeared; however, expression of the embryonic isoform continued throughout development. In the adult PLD, both embryonic and adult MHCs were expressed, with most fibers expressing both isoforms. In dystrophic neonates and adults virtually all fibers of the bicep brachii, gastrocnemius, and PLD muscles were identical and contained embryonic and neonatal MHCs. These results corroborate previous observations that there are alternative programs of fast MHC expression to that found in the pectoralis muscle of the chicken (M.T. Crow and F.E. Stockdale, 1986, Dev. Biol. 118, 333-342), and that diversification into fibers containing specific MHCs fails to occur in the fast muscle fibers of the dystrophic chicken. These results are consistent with the hypothesis that avian muscular dystrophy is a developmental disorder that is associated with alterations in isoform switching during muscle maturation.     

The developmental program of fast myosin heavy chain expression in avian skeletal muscles

We have examined the types of fast myosin heavy chains (MHCs) expressed in a number of different developing chicken skeletal muscles by combining peptide mapping and immunoblotting to identify fast MHC-specific peptides among the total mixture of MHC digestion products. Using this technique, we have identified three different fast MHC patterns among the different fast and mixed (i.e., fast and slow) fiber type muscles of the adult. While the different muscles all underwent sequential changes in fast MHC isoform expression during their development, the exact sequence of these changes and the isoform patterns expressed varied from muscle to muscle. During late embryonic or fetal development, all muscles expressed a similar fast MHC pattern (designated here as the fetal pattern) which was replaced shortly after hatching with a different fast MHC pattern (the neonatal pattern). During the transition from the neonatal to the adult state that occurred sometime in the first year after hatching, many of the muscles underwent additional changes in fast MHC isoform expression. In muscles such as the pectoralis major and pectoralis minor, a new fast MHC isoform pattern was seen in the adult so that the developmental program of isoform switching in these muscles involved the sequential appearance of distinct fetal, neonatal, and adult fast MHCs. Other muscles, such as the sartorius and posterior latissimus dorsi, underwent a qualitatively different program of isoform switching and expressed as an adult a fast MHC pattern that was indistinguishable from that expressed during fetal development. Finally, in some muscles, such as the superficial biceps, no change in isoform pattern was detected during the neonatal to adult transition--in these muscles, expression of the neonatal MHC isoform pattern apparently persisted into the adult state. These data indicate that no single scheme or program of fast MHC isoform switching can describe all the developmental changes that occur in fast MHC isoform expression in the chicken and that at least three different programs of isoform switching and expression can be identified.     

Developmentally regulated expression of three slow isoforms of myosin heavy chain: diversity among the first fibers to form in avian muscle.

At least three slow myosin heavy chain (MHC) isoforms were expressed in skeletal muscles of the developing chicken hindlimb, and differential expression of these slow MHC isoforms produced distinct fiber types from the outset of skeletal muscle myogenesis. Immunohistochemistry with isoform-specific monoclonal antibodies demonstrated differences in MHC content among the fibers of the dorsal and ventral premuscle masses and distinctions among fibers before splitting of the premuscle masses into individual muscles (Hamburger and Hamilton Stage 25). Immunoblot analyses by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of myosin extracted from the hindlimb demonstrated the presence throughout development of different mobility classes of MHCs with epitopes associated with slow MHC isoforms. Immunopeptide mapping showed that one of the MHCs expressed in the embryonic limb was the same slow MHC isoform, slow MHC1 (SMHC1), that is expressed in adult slow muscles. SMHC1 was expressed in the dorsal and ventral premuscle masses, embryonic, fetal, and some neonatal and adult hindlimb muscles. In the embryo and fetus SMHC1 was expressed in future fast, as well as future slow muscles, whereas in the adult only the slow muscles retained expression of SMHC1. Those embryonic muscles destined in the adult to contain slow fibers or mixed fast/slow fibers not only expressed SMHC1, but also an additional slow MHC not previously described, designated as slow MHC3 (SMHC3). Slow MHC3 was shown by immunopeptide mapping to contain a slow MHC epitope (reactive with mAb S58) and to be structurally similar to a MHC expressed in the atria of the adult chicken heart. SMHC3 was designated as a slow MHC isoform because (i) it was expressed only in those muscles destined to be of the slow type in the adult, (ii) it was expressed only in primary fibers of muscles that subsequently are of the slow type, and (iii) it had an epitope demonstrated to be present on other slow, but not fast, isoforms of avian MHC. This study demonstrates that a difference in phenotype between fibers is established very early in the chicken embryo and is based on the fiber type-specific expression of three slow MHC isoforms.     

Effect of hypothyroidism on myosin heavy chain expression in rat pharyngeal dilator muscles.

Although the association between hypothyroidism and obstructive sleep apnea is well established, the effect of thyroid hormone deficiency on contractile proteins in pharyngeal dilator muscles responsible for maintaining upper airway patency is unknown. In the present study, the effects of hypothyroidism on myosin heavy chain (MHC) expression were examined in the sternohyoid, geniohyoid, and genioglossus muscles of adult rats (n = 20). The relative proportions of MHC isoforms present were determined using MHC-specific monoclonal antibodies and oligonucleotide probes. All control muscles showed a paucity of type I MHC fibers, with greater than 90% of fibers containing fast-twitch type II MHCs. In the genioglossus muscle, a population of non-IIa non-IIb fast-twitch type II fibers (putatively identified as type IIx MHC fibers) were detected. Hypothyroidism induced significant changes in MHC expression in all muscles studied. In the sternohyoid, type I fibers increased from 6.2 to 16.9%, whereas type IIa fibers increased from 25.9 to 30.7%. Type I fibers in the geniohyoid increased from 1.2 to 12.8%, whereas type IIa fibers increased from 34.1 to 42.7%. The genioglossus showed the smallest relative increase in type I expression but the greatest induction of type IIa MHC. None of the muscles examined demonstrated reinduction of embryonic or neonatal MHC in response to thyroid hormone deficiency. In summary, hypothyroidism alters the MHC profile of pharyngeal dilators in a muscle-specific manner. These changes may play a role in the pathogenesis of obstructive apnea in hypothyroid patients.     

Interaction of hyperthyroidism and hindlimb suspension on skeletal myosin heavy chain expression

We examined the novel interaction ofhyperthyroidism and hindlimb suspension on the pattern of myosin heavychain (MHC) expression (mRNA and protein) in skeletal muscles. FemaleSprague-Dawley rats were assigned to four groups:1) normal control (Con);2) thyroid hormone treated[150 µg 3,5,3'-triiodothyronine(T₃) · kg¹ · day¹](T₃);3) hindlimb suspension (HS); or4)T₃-treated and HS(T₃ + HS). Results show for thefirst time the novel observation that the combinationT₃ + HS induces a rapid andsustained, marked (80-90%) downregulation of type I MHC geneexpression that is mirrored temporally by concomitant markedupregulation of type IIb MHC gene expression, as evidenced by the denovo synthesis of type IIb MHC protein in the soleus. The fast type IIxMHC isoform showed a differential response among the experimentalgroups, generally increasing with the separate and combined treatments in both the soleus and vastus intermedius muscles while decreasing inthe plantaris muscles. The fast type IIa MHC was the least responsiveto suspension of the MHCs and reflected its greatest responsiveness toT₃ treatment while also undergoingdifferential adaptations in slow vs. fast muscle (increases vs.decreases, respectively). These results confirm previous findings thatall four adult MHC genes are sensitive toT₃ and suspension in amuscle-specific manner. In addition, we show thatT₃ + HS can interactsynergistically to create novel adaptations in MHC expression thatcould not be observed when each factor was imposed separately.

     

Neural control of the sequence of expression of myosin heavy chain isoforms in foetal mammalian muscles

The expression of myosin isoforms was studied during development of calf muscles in foetal and neonatal rats, using monoclonal antibodies against slow, embryonic and neonatal isoforms of myosin heavy chain (MHC). Primary myotubes had appeared in all prospective rat calf muscles by embryonic day 16 (E16). On both E16 and E17, primary myotubes in all muscles with the exception of soleus stained for slow, embryonic and neonatal MHC isoforms; soleus did not express neonatal MHC. In earlier stages of muscle formation staining for the neonatal isoform was absent or faint. Secondary myotubes were present in all muscles by E18, and these stained for both embryonic and neonatal MHCs, but not slow. In mixed muscles, primary myotubes destined to differentiate into fast muscle fibres began to lose expression of slow MHC, and primary myotubes destined to become slow muscle fibres began to lose expression of neonatal MHC. This pattern was further accentuated by E19, when many primary myotubes stained for only one of these two isoforms. Chronic paralysis or denervation from E15 or earlier did not disrupt the normal sequence of maturation of primary myotubes up until E18, but secondary myotubes did not form. By E19, however, most primary myotubes in aneural or paralyzed tibialis anterior muscles had lost expression of slow MHC and expressed only embryonic and neonatal MHCs. Similar changes occurred in other muscles, except for soleus which never expressed neonatal MHC, as in controls. Paralysis or denervation commencing later than E15 did not have these effects, even though it was initiated well before the period of change in expression of MHC isoforms. In this case, some secondary myotubes appeared in treated muscles. Paralysis initiated on E15, followed by recovery 2 days later so that animals were motile during the period of change in expression of MHC isoforms, was as effective as full paralysis. These experiments define a critical period (E15-17) during which foetuses must be active if slow muscle fibres are to differentiate during E19-20. We suggest that changes in expression of MHC isoforms in primary myotubes depend on different populations of myoblasts fusing with the myotubes, and that the normal sequence of appearance of these myoblasts has a stage-dependent reliance on active innervation of foetal muscles. A critical period of nerve-dependence for these myoblasts occurs several days before their action can be noted.     

Skeletal muscle adaptations to microgravity exposure in the mouse.

To investigate the effects of microgravity on murine skeletal muscle fiber size, muscle contractile protein, and enzymatic activity, female C57BL/6J mice, aged 64 days, were divided into animal enclosure module (AEM) ground control and spaceflight (SF) treatment groups. SF animals were flown on the space shuttle Endeavour (STS-108/UF-1) and subjected to approximately 11 days and 19 h of microgravity. Immunohistochemical analysis of muscle fiber cross-sectional area revealed that, in each of the muscles analyzed, mean muscle fiber cross-sectional area was significantly reduced (P < 0.0001) for all fiber types for SF vs. AEM control. In the soleus, immunohistochemical analysis of myosin heavy chain (MHC) isoform expression revealed a significant increase in the percentage of muscle fibers expressing MHC IIx and MHC IIb (P < 0.05). For the gastrocnemius and plantaris, no significant changes in MHC isoform expression were observed. For the muscles analyzed, no alterations in MHC I or MHC IIa protein expression were observed. Enzymatic analysis of the gastrocnemius revealed a significant decrease in citrate synthase activity in SF vs. AEM control.     

Developmental modulation of myosin expression by thyroid hormone in avian skeletal muscle.

It is well established that a rise in circulating thyroid hormone during the second half of chick embryo development significantly influences muscle weight gain and bone growth. We studied thyroid influence on differentiation in slow anterior latissimus dorsi (ALD) and fast posterior latissimus dorsi (PLD) muscles of embryos rendered hypothyroid by hypophysectomy or administration of an anti-thyroid drug. The expression of native myosins and myosin light chains (MLCs) was studied by electrophoretic analysis, and the myosin heavy chain (MHC) was characterized by immunohistochemistry. The first effects of hypothyroid status were observed at day 21 of embryonic development (stage 46 according to Hamburger and Hamilton). Analysis of myosin isoform expression in PLD muscles of hypothyroid embryos showed persistence of slow migrating native myosins and slow MLCs as well as inhibition of neonatal fast MHC expression, indicating retarded differentiation of this muscle. In ALD muscle, hypothyroidism maintained fast embryonic MHC and induced noticeable amounts of fast MLCs, thus delaying slow muscle differentiation. Our results suggest that thyroid hormones play a role in modulating the appearance of neonatal fast MHC and the disappearance of isomyosins transiently present during embryogenesis. However, T3 supplemental treatment would seem to compensate in part for the effects of hypothyroidism induced by hypophysectomy, suggesting that thyroid hormone might interfere with other factors also accounting for the observed effects.     

Skeletal muscle calcineurin: influence of phenotype adaptation and atrophy

Calcineurin (CaN) has been implicated as a signaling molecule that can transduce physiological stimuli (e.g., contractile activity) into molecular signals that initiate slow-fiber phenotypic gene expression and muscle growth. To determine the influence of muscle phenotype and atrophy on CaN levels in muscle, the levels of soluble CaN in rat muscles of varying phenotype, as assessed by myosin heavy chain (MHC)-isoform proportions, were determined by Western blotting. CaN levels were significantly greater in the plantaris muscle containing predominantly fast (IIx and IIb) MHC isoforms, compared with the soleus (predominantly type I MHC) or vastus intermedius (VI, contains all 4 adult MHC isoforms). Three months after a complete spinal cord transection (ST), the CaN levels in the VI muscle were significantly reduced, despite a significant increase in fast MHC isoforms. Surprisingly, the levels of CaN in the VI were highly correlated with muscle mass but not MHC isoform proportions in ST and control rats. These data demonstrate that CaN levels in skeletal muscle are highly correlated to muscle mass and that the normal relationship with phenotype is lost after ST.     

Co-expression of multiple myosin heavy chain genes, in addition to a tissue-specific one, in extraocular musculature

We have investigated the developmental transitions of myosin heavy chain (MHC) gene expression in the rat extraocular musculature (EOM) at the mRNA level using S1-nuclease mapping techniques and at the protein level by polypeptide mapping and immunochemistry. We have isolated a genomic clone, designated lambda 10B3, corresponding to an MHC gene which is expressed in the EOM fibers (recti and oblique muscles) of the adult rat but not in hind limb muscles. Using cDNA and genomic probes for MHC genes expressed in skeletal (embryonic, neonatal, fast oxidative, fast glycolytic, and slow/cardiac beta-MHC), cardiac (alpha-MHC), and EOM (lambda 10B3) muscles, we demonstrate the concomitant expression at the mRNA level of at least six different MHC genes in adult EOM. Protein and immunochemical analyses confirm the presence of at least four different MHC types in EOM. Immunocytochemistry demonstrates that different myosin isozymes tend to segregate into individual myofibers, although some fibers seem to contain more than one MHC type. The results also show that the EOM fibers exhibit multiple patterns of MHC gene regulation. One set of fibers undergoes a sequence of isoform transitions similar to the one described for limb skeletal muscles, whereas other EOM myofiber populations arrest the MHC transition at the embryonic, neonatal/adult, or adult EOM-specific stage. Thus, the MHC gene family is not under the control of a strict developmental clock, but the individual genes can modify their expression by tissue-specific and/or environmental factors.     

Emergence of the mature myosin phenotype in the rat diaphragm muscle

Immunohistochemical analysis of myosin heavy chain (MHC) isoform expression in perinatal and adult rat diaphragm muscles was performed with antibodies which permitted the identification of all known MHC isoforms found in typical rat muscles. Isoform switching, leading to the emergence of the adult phenotype, was more complex than had been previously described. As many as four isoforms could be coexpressed in a single myofiber. Elimination of developmental isoforms did not usually result in the myofiber immediately achieving its adult phenotype. Activation of genes for specific adult isoforms might be delayed to puberty. For example, two of the three fast MHCs, MHC2X and MHC2A appeared perinatally, while MHC2B did not appear until 30 days postnatal. By Day 60 this isoform was present in approximately 27% of the myofibers, but in most myofibers expression of this isoform was transient (i.e., at Day greater than or equal to 115, less than 4% of the myofibers expressed MHC2B). Fibers which contained MHC beta/slow during the late fetal and early neonatal period coexpressed MHCemb. A marked increase in the frequency of fibers containing MHC beta/slow occurred between 4 and 21 days postnatal. These slow fibers arose from a population of myofibers which expressed MHCemb and MHCneo during their development, and they accounted for the majority of slow fibers found in the adult diaphragm. The adult myosin phenotype of the diaphragm myofibers (as determined with immunocytochemistry, and 5% SDS-PAGE) was not achieved until the rat was greater than or equal to 115 days old.     

Dystonia musculorum mutation and myosin heavy chain expression in skeletal and cardiac muscles.

This study evaluated the influence of dystonia musculorum (dt) mutation, characterized by spinocerebellar fibers degeneration, on cardiac and skeletal muscles: one respiratory (diaphragm, Dia), three masticatory (anterior temporalis, AT; masseter superficialis, MS; and anterior digastric, AD), one hindlimb (soleus, S), tongue (T), and one cardiac (ventricle, V). Body and muscle weight, muscle protein content, and myosin heavy chain (MHC) isoforms relative expression were then compared in dt mutant mice and in normal mice, according to sex. Male body and muscle weight was always greater than that of females, but there was no specific muscle difference in females. dt mutant mice showed a reduced whole body growth but no specific muscle atrophy, as well as a global decrease in muscle protein content that made muscles more fragile. dt mutation induced a global reduction of muscle protein concentration, whereas a general influence of sex could not be disclosed. Concerning MHC relative composition, all the muscles were fast-twitch: Dia, AT, MS, AD, S, and T expressed predominantly the fast type 2 MHC isoforms, whereas V contained only MHC alpha, also a fast MHC. Female muscles were slower than male muscles, except for S, which was faster. However, classification of muscles in terms of shortening velocity was very different in normal males and females. In other respects, dt mutant muscles were slower and consequently more fatigue resistant than normal, except for S, which became faster and less fatigue resistant. dt mutation exhibits then a specific effect on this continually active postural muscle. In the other muscles, global increased fatigue resistance could constitute an adaptive response to work requirements modifications linked to the muscle damage. It should be noted that a developmental MHC (neonatal) was present in female dt AD. Innervation, which influences muscle structure, is altered in dt mutant and could be another causal factor of the fast-to-slow MHC switches. It appears that dystonin, the dt gene product, is very important in maintaining the structural integrity of both cardiac and skeletal muscle and in its absence, the muscle becomes more fragile and is damaged by modified activity.     

Gene conversions within the skeletal myosin multigene family.

Comparisons of the nucleotide sequences of the light meromyosin (LMM) region of developmentally regulated fast chicken myosin heavy chain (MHC) isoforms indicates that chicken MHC isoforms are more similar to each other than to MHC isoforms in other species. The sequence data provide evidence that gene conversion events have occurred recently among the isoforms. An embryonic (Cemb1) isoform and neonatal isoform have the most extensive regions of sequence identity. Similar gene conversion events are present in the rat alpha- and beta-cardiac MHCs, but were not obvious in the LMM of developmentally regulated fast human MHC isoforms. The data suggest that gene conversion events can play a significant role in the evolution of the MHC multigene families and that concerted evolution of the chicken multigene family occurred after the divergence of mammals and avians.     

Effects of spaceflight and thyroid deficiency on hindlimb development. I. Muscle mass and IGF-I expression.

Thyroid deficiency (TD) in neonatal rats causes reduced growth of skeletal muscle that is disproportionately greater than that for other tissues (G. R. Adams, S. A. McCue, M. Zeng, and K. M. Baldwin. Am. J. Physiol. Regulatory Integrative Comp. Physiol. 276: R954-R961, 1999). TD depresses plasma insulin-like growth factor I (IGF-I) levels, suggesting a mechanism for this effect. We hypothesized that TD and exposure to spaceflight (SF) would interact to reduce skeletal muscle growth via a reduction in IGF-I levels. Neonatal rats were flown in space for 16 days. There was a similar, nonadditive reduction in the growth of the body ( approximately 50%) and muscle weight (fast muscles, approximately 60%) with either TD or SF. In the soleus muscle, either SF or TD alone resulted in growth reductions that were augmented by SF-TD interactions. There were strong correlations between 1) muscle mass and muscle IGF-I levels and 2) circulating IGF-I and body weight. These results indicate that either hypothyroidism or exposure to SF will limit the somatic and muscle-specific growth of neonatal rats. The impact of these perturbations on skeletal muscle growth is relatively greater than the effect on somatic growth. The mechanisms by which either TD or SF impact growth appear to have a common pathway involving the control of plasma and muscle IGF-I concentrations.     

Postnatal expression of myosin isoforms in an expiratory muscle--external abdominal oblique.

We studied the postnatal expression of heavy-chain (MHC) and native myosin isoforms in an expiratory abdominal muscle of the rat, the external abdominal oblique (EO). Moreover, we contrasted EO myosin expression with that of the costal diaphragm (DIA) to draw inspiratory vs. expiratory muscle comparisons during development. Examination of MHC gels demonstrated a mature phenotype of slow and adult fast myosin isoforms at an earlier age in the EO (day 60) than in the DIA [day > 115 (adult)]. The mature MHC phenotype of the EO was characterized by a preponderance of MHC 2B, whereas the DIA was characterized by approximately equal portions of MHC slow, MHC 2A, and MHC 2X. During early postnatal development, there was a delay in the expression of MHC 2A in the EO compared with the DIA. However, MHC 2B, expressed later in development in both muscles, was noted in the EO before the DIA. We conclude that 1) the EO mature myosin phenotype is characterized by a preponderance of fast myosin isoforms and 2) the EO and DIA muscles are subject to different temporal patterns of isoform expression during postnatal development.     

Work overload induced changes in fast and slow skeletal muscle myosin heavy chain gene expression

Work induced hypertrophy of the slow postural soleus and the fast phasic plantaris muscles was produced by tenotomy of the synergistic gastrocnemius muscle. Increases in weight of both muscles were associated with proportionately even larger increases in total RNA and mRNA levels. Alterations in levels of specific myosin heavy chain (MHC) isoform mRNAs were measured using the slot blot procedure with radioactively labelled oligonucleotides as probes. Type 1 MHC gene expression was unaffected in both muscles by work overload, whereas type 2a was deinduced in the soleus and type 2b was deinduced in the plantaris. The neonatal MHC gene was transiently reinduced in the plantaris.