Protein kinase C signaling controls skeletal muscle fiber types

Slow myosin heavy chain 2 (MyHC2) gene expression in fetal avian skeletal muscle fibers is regulated by innervation and protein kinase C (PKC) activity. Fetal chick muscle fibers derived from the slow twitch medial adductor (MA) muscle express slow MyHC2 when innervated in vitro. The same pattern of slow MyHC2 regulation occurs in MA muscle fibers in which PKC activity is inhibited by staurosporine. To further test the function of PKC activity in the regulation of slow MyHC2 expression, wild-type and dominant-negative mutations of PKCalpha and PKCtheta were overexpressed in MA muscle fibers in vitro. Overexpression of wild-type PKCalpha and PKCtheta cDNAs resulted in increased PKC activities in muscle fibers and concomitant repression of slow MyHC2 expression under conditions that normally induced gene expression. Point mutations leading to single amino acid substitutions were generated in the ATP binding domains of PKCalpha and PKCtheta. Overexpression of CMVPKCalphaR368 and CMVPKCthetaR409 resulted in decreased PKC activities in transfected MA muscle fibers. Furthermore, transfection of CMVPKCalphaR368 and CMVPKCthetaR409 mutant constructs into MA muscle fibers did not repress the capacity of these fibers to express slow MyHC2 when cultured in medium containing staurosporine or when innervated. These results indicate that PKC activity represses slow MyHC2 expression and that PKC down-regulation, possibly in response to innervation, is required but not sufficient for slow MyHC2 expression.     

Diversity of myosin heavy chain expression in satellite cells from mouse soleus and EDL muscles.

Postnatal myoblasts, the satellite cells, originating from slow and fast skeletal muscle fibres differentiate and fuse into myotubes expressing different phenotype of myosin heavy chain (MyHC) isoforms. Little is known, however, of factors which establish and maintain this phenotypic diversity. We used immunofluorescent labelling and Western blotting to examine the expression of slow and fast MyHC isoforms in myotubes formed in vitro from satellite cells isolated from mouse fast twitch extensor digitorum longus (EDL) and slow twitch soleus muscles. Satellite cells were cultured in serum-rich growth medium promoting myoblast proliferation until cross-striated and self-contracting myotubes were formed. We report that in both cultures myotubes expressed slow as well as fast MyHC isoforms, but the level of slow MyHC was higher in soleus culture than in EDL culture. Hence, the pattern of expression of slow and fast MyHC was characteristic of the muscle fibre type from which these cells derive. These results support the concept of phenotypic diversity among satellite cells in mature skeletal muscles and suggest that this diversity is generated in vitro irrespectively of serum mitogens.     

Expression of patched, prdm1 and engrailed in the lamprey somite reveals conserved responses to Hedgehog signaling

SUMMARY In the zebrafish embryo, expression of the prdm1 and patched1 genes in adaxial cells is indicative of their specification to give rise to slow twitch muscle fibers in response to Hedgehog (Hh) signaling. Subsets of these slow twitch muscle progenitors activate engrailed ( eng ) strongly in response to high-level Hh signaling, and differentiate into muscle pioneer cells, which are important for subsequent development of the horizontal myoseptum. In addition, eng is expressed more weakly in medial fast fibers in response to lower Hh levels. Somite morphology in the lamprey, an agnathan (jawless) vertebrate, differs significantly from that of teleosts. In particular, the lamprey does not have clear epaxial/hypaxial domains, lacks a horizontal myoseptum, and does not appear to possess distinct populations of fast and slow fibers in the embryonic somite. Nevertheless, Hh is expressed in the midline of the lamprey embryo, and we report here that, as in zebrafish, homologues of patched and prdm1 are expressed in adaxial regions of the lamprey somite, and an eng homologue is also expressed in the somite. However, the lamprey adaxial region does not exhibit the same distinct adaxial cell morphology as in the zebrafish. In addition, the expression of follistatin is not excluded from the adaxial region, and eng is not detected in discrete muscle pioneer-like cells. These data suggest the presence of conserved responses to Hh signaling in lamprey somites, although the full range of effects elicited by Hh in the zebrafish somite is not recapitulated.     

Hedgehog can drive terminal differentiation of amniote slow skeletal muscle

Background

Secreted Hedgehog (Hh) signalling molecules have profound influences on many developing and regenerating tissues. Yet in most vertebrate tissues it is unclear which Hh-responses are the direct result of Hh action on a particular cell type because Hhs frequently elicit secondary signals. In developing skeletal muscle, Hhs promote slow myogenesis in zebrafish and are involved in specification of medial muscle cells in amniote somites. However, the extent to which non-myogenic cells, myoblasts or differentiating myocytes are direct or indirect targets of Hh signalling is not known.

Results

We show that Sonic hedgehog (Shh) can act directly on cultured C2 myoblasts, driving Gli1 expression, myogenin up-regulation and terminal differentiation, even in the presence of growth factors that normally prevent differentiation. Distinct myoblasts respond differently to Shh: in some slow myosin expression is increased, whereas in others Shh simply enhances terminal differentiation. Exposure of chick wing bud cells to Shh in culture increases numbers of both muscle and non-muscle cells, yet simultaneously enhances differentiation of myoblasts. The small proportion of differentiated muscle cells expressing definitive slow myosin can be doubled by Shh. Shh over-expression in chick limb bud reduces muscle mass at early developmental stages while inducing ectopic slow muscle fibre formation. Abundant later-differentiating fibres, however, do not express extra slow myosin. Conversely, Hh loss of function in the limb bud, caused by implanting hybridoma cells expressing a functionally blocking anti-Hh antibody, reduces early slow muscle formation and differentiation, but does not prevent later slow myogenesis. Analysis of Hh knockout mice indicates that Shh promotes early somitic slow myogenesis.

Conclusions

Taken together, the data show that Hh can have direct pro-differentiative effects on myoblasts and that early-developing muscle requires Hh for normal differentiation and slow myosin expression. We propose a simple model of how direct and indirect effects of Hh regulate early limb myogenesis.

     

Hedgehog regulation of superficial slow muscle fibres in Xenopus and the evolution of tetrapod trunk myogenesis

In tetrapod phylogeny, the dramatic modifications of the trunk have received less attention than the more obvious evolution of limbs. In somites, several waves of muscle precursors are induced by signals from nearby tissues. In both amniotes and fish, the earliest myogenesis requires secreted signals from the ventral midline carried by Hedgehog (Hh) proteins. To determine if this similarity represents evolutionary homology, we have examined myogenesis in Xenopus laevis, the major species from which insight into vertebrate mesoderm patterning has been derived. Xenopus embryos form two distinct kinds of muscle cells analogous to the superficial slow and medial fast muscle fibres of zebrafish. As in zebrafish, Hh signalling is required for XMyf5 expression and generation of a first wave of early superficial slow muscle fibres in tail somites. Thus, Hh-dependent adaxial myogenesis is the likely ancestral condition of teleosts, amphibia and amniotes. Our evidence suggests that midline-derived cells migrate to the lateral somite surface and generate superficial slow muscle. This cell re-orientation contributes to the apparent rotation of Xenopus somites. Xenopus myogenesis in the trunk differs from that in the tail. In the trunk, the first wave of superficial slow fibres is missing, suggesting that significant adaptation of the ancestral myogenic programme occurred during tetrapod trunk evolution. Although notochord is required for early medial XMyf5 expression, Hh signalling fails to drive these cells to slow myogenesis. Later, both trunk and tail somites develop a second wave of Hh-independent slow fibres. These fibres probably derive from an outer cell layer expressing the myogenic determination genes XMyf5, XMyoD and Pax3 in a pattern reminiscent of amniote dermomyotome. Thus, Xenopus somites have characteristics in common with both fish and amniotes that shed light on the evolution of somite differentiation. We propose a model for the evolutionary adaptation of myogenesis in the transition from fish to tetrapod trunk.     

Evidence for myoblast-extrinsic regulation of slow myosin heavy chain expression during muscle fiber formation in embryonic development

Vertebrate muscles are composed of an array of diverse fast and slow fiber types with different contractile properties. Differences among fibers in fast and slow MyHC expression could be due to extrinsic factors that act on the differentiated myofibers. Alternatively, the mononucleate myoblasts that fuse to form multinucleated muscle fibers could differ intrinsically due to lineage. To distinguish between these possibilities, we determined whether the changes in proportion of slow fibers were attributable to inherent differences in myoblasts. The proportion of fibers expressing slow myosin heavy chain (MyHC) was found to change markedly with time during embryonic and fetal human limb development. During the first trimester, a maximum of 75% of fibers expressed slow MyHC. Thereafter, new fibers formed which did not express this MyHC, so that the proportion of fibers expressing slow MyHC dropped to approximately 3% of the total by midgestation. Several weeks later, a subset of the new fibers began to express slow MyHC and from week 30 of gestation through adulthood, approximately 50% of fibers were slow. However, each myoblast clone (n = 2,119) derived from muscle tissues at six stages of human development (weeks 7, 9, 16, and 22 of gestation, 2 mo after birth and adult) expressed slow MyHC upon differentiation. We conclude from these results that the control of slow MyHC expression in vivo during muscle fiber formation in embryonic development is largely extrinsic to the myoblast. By contrast, human myoblast clones from the same samples differed in their expression of embryonic and neonatal MyHCs, in agreement with studies in other species, and this difference was shown to be stably heritable. Even after 25 population doublings in tissue culture, embryonic stage myoblasts did not give rise to myoblasts capable of expressing MyHCs typical of neonatal stages, indicating that stage-specific differences are not under the control of a division dependent mechanism, or intrinsic "clock." Taken together, these results suggest that, unlike embryonic and neonatal MyHCs, the expression of slow MyHC in vivo at different developmental stages during gestation is not the result of commitment to a distinct myoblast lineage, but is largely determined by the environment.     

The development of fibre types in grafts of a slow tonic avian muscle, the dorsocutaneous latissimus dorsi

The dorsocutaneous (DLD) and anterior (ALD) latissimus dorsii are both homogeneous slow tonic muscles. Autografts of mature DLD were attached onto the ALD of chickens to study regeneration of slow tonic muscle fibres innervated exclusively by slow tonic nerves. Fifty-three grafts were examined from 3 to 231 days after implantation for myosin ATPase, and for heavy chains of fast myosin. New muscle fibres in grafts were initially type 1 (slow) or type 2 (fast twitch). Tonic type 3 fibres were slow to differentiate and were not seen within 59 days. From 105 days many fibres were type 3A and type 1 were no longer apparent. However, type 2 fibres persisted and appeared to be present instead of type 3B fibres even after 8 months.     

Effects of hypothyroidism on myosin heavy chain composition and fibre types of fast skeletal muscles in a small marsupial, Antechinus flavipes

Effects of drug-induced hypothyroidism on myosin heavy chain (MyHC) content and fibre types of fast skeletal muscles were studied in a small marsupial, Antechinus flavipes. SDS-PAGE of MyHCs from the tibialis anterior and gastrocnemius revealed four isoforms, 2B, 2X, 2A and slow, in that order of decreasing abundance. After 5 weeks treatment with methimazole, the functionally fastest 2B MyHC significantly decreased, while 2X, 2A and slow MyHCs increased. Immunohistochemistry using monospecific antibodies to each of the four MyHCs revealed decreased 2b and 2x fibres, and increased 2a and hybrid fibres co-expressing two or three MyHCs. In the normally homogeneously fast superficial regions of these muscles, evenly distributed slow-staining fibres appeared, resembling the distribution of slow primary myotubes in fast muscles during development. Hybrid fibres containing 2A and slow MyHCs were virtually absent. These results are more detailed but broadly similar to the earlier studies on eutherians. We hypothesize that hypothyroidism essentially reverses the effects of thyroid hormone on MyHC gene expression of muscle fibres during myogenesis, which differ according to the developmental origin of the fibre: it induces slow MyHC expression in 2b fibres derived from fast primary myotubes, and shifts fast MyHC expression in fibres of secondary origin towards 2A, but not slow, MyHC.     

Grape seed proanthocyanidin extract promotes skeletal muscle fiber type transformation via AMPK signaling pathway

Transformation of skeletal muscle fiber type from fast twitch to slow twitch has significances for sustained contractile and stretchable events, energy homeostasis and antifatigue ability. However, the regulation of skeletal muscle fiber type transformation through nutritional intervention is still not fully spelled out. Grape seed proanthocyanidin extract (GSPE) has been widely reported to play a broader role in many aspects of diseases with its various pharmacological and health-promoting effects. In this study, we found that GSPE significantly improved the fatigue resistance in mice. GSPE up-regulated slow myosin heavy chain (MyHC) and down-regulated fast MyHC, accompanied by increases in activities of succinic dehydrogenase and malate dehydrogenase and by decreased lactate dehydrogenase activity in muscle of mice and in C2C12 myotubes. The AMP-activated protein kinase (AMPK) signaling can be activated by GSPE. Several upstream and downstream factors of AMPK signaling such as liver kinase B1, nuclear respiratory factor 1, calcium calmodulin-dependent protein kinase kinase β, sirtuin1 and peroxisome proliferator activated receptor-γ coactivator-1α (PGC-1α) were also up-regulated by GSPE. Specific inhibition of AMPK signaling by AMPK inhibitor compound C or by AMPKα1 siRNA significantly abolished the GSPE-induced the activation of AMPK and the increase of PGC-1α, and attenuated the GSPE-induced increase of slow MyHC and decrease of fast MyHC in C2C12 myotubes. Taken together, we revealed that GSPE promotes skeletal muscle fiber type transformation from fast twitch to slow twitch through AMPK signaling pathway, and this GSPE-induced fiber type transformation may contribute to increased fatigue resistance.     

Influence of neurons on the occurrence of fibre types and myosin light chains in cultured presumptive slow and fast myoblasts

Myoblasts from 9-day-old quail embryo slow anterior latissimus dorsi (ALD) and fast posterior and latissimus dorsi (PLD) muscles were co-cultured with neurons. The presence of neurons allowed ALD-derived muscle fibres to express characteristic features of a slow muscle (occurrence of alpha' and of beta' fibres and predominance of slow myosin light chains). On the contrary, PLD-derived fibres did not differentiate into normal fast fibres (occurrence of alpha'-like fibres and absence of LC3f). These results are compared with the differentiation of ALD and PLD myoblasts in aneural condition. It is suggested that neurons can modify some phenotypic expression of presumptive slow or fast myoblasts.     

Local signals in the chick limb bud can override myoblast lineage commitment: induction of slow myosin heavy chain in fast myoblasts.

Patterning of fast and slow muscle fibres in limbs is regulated by signals from non-muscle cells. Myoblast lineage has, however, also been implicated in fibre type patterning. Here we test a founder cell hypothesis for the role of myoblast lineage, by implanting characterized fast and slow mouse myoblast clones into chick limb buds. In culture, late foetal mouse myoblast clones are committed to a probability (range 0-0.92) of slow myosin heavy chain (MyHC) expression. In contrast, when implanted into chick limbs, fast mouse myoblast clones express myosin characteristic of their new environment, without fusion to chick muscle cells and in the absence of innervation. Therefore, local signals exist within the chick limb bud during primary myogenesis that can override intrinsic commitment of at least some myoblasts, and induce slow MyHC.     

Sexually differentiated,androgen-regulated,larynx-specific myosin heavy-chain isoforms in <Emphasis Type="Italic">Xenopus tropicalis</Emphasis>; comparison to <Emphasis Type="Italic">Xenopus laevis</Emphasis>

We have shown that the sarcoplasmic myosin heavy-chain (MyHC) isoform xtMyHC-101d is highly and specifically expressed in the larynx of the aquatic anuran, Xenopus tropicalis. In male larynges, the predominant MyHC isoform is xtMyHC-101d, while in females, another isoform, xtMyHC-270c, predominates. The X. tropicalis genome has been sequenced in its entirety, and xtMyHC-101d is part of a specific array of xtMyHC genes expressed otherwise in embryonic muscles (Nasipak and Kelley, Dev Genes Evol, in press, 2008). The administration of the androgen dihydrotestosterone increases the expression of xtMyHC-101d in juvenile larynges of both sexes. Using ATPase histochemistry, we found that in adults, X. tropicalis male laryngeal muscle contains only fast-twitch fibers, while the female laryngeal muscle contains a mix of fast- and slow-twitch fibers. Juvenile larynges are female-like in fiber type composition (44% slow twitch, 56% fast twitch); androgen treatment increases the percentage of fast-twitch fibers to 86%. xtMyHC-101d predominates in larynges of dihydrotestosterone-treated juveniles but not in larynges of untreated juveniles. We compared the larynx-specific expression of xtMyHC genes in X. tropicalis to the MyHC gene expressed in X. laevis larynx (xlMyHC-LM) by sequencing the entire xlMyHC-LM gene. The androgen-regulated xtMyHC that predominates in the male larynx of X. tropicalis is not the gene phylogenetically most similar to xlMyHC-LM at the nucleotide level but is instead a similar isoform found in the same MyHC array and expressed in the embryonic muscle.     

Sarco(endo)plasmic reticulum calcium pump isoforms in paralyzed rat slow muscle

To assess the influence of paralysis on the expression of phenotypic protein isoforms related to muscle relaxation, the effects of spinal cord transection (ST) on sarco(endo)plasmic reticulum calcium ATPase (SERCA) pump isoform protein levels in the slow rat soleus were measured. Western blotting using SERCA isoform specific antibodies demonstrated a rapid up-regulation (7 days post ST) of the fast fiber type-specific isoform (SERCA1). In contrast, the slow fiber type-specific isoform, SERCA2, was decreased with a slower time-course. The up-regulation of SERCA1 protein preceded the up-regulation of fast myosin heavy chain (MyHC) (i.e., MyHC-II). Immunohistochemical analyses of single muscle fibers showed that 15 days after ST there was a pronounced increase in the proportion of slow MyHC fibers with SERCA1 confirming that SERCA1 was up-regulated in the slow fibers of the soleus prior to MyHC-II. These data suggest that the expression of the SERCA isoforms (particularly SERCA1) may serve as more sensitive markers of phenotypic adaptation in response to altered levels of contractile activity than the MyHC isoforms. In addition, since the expression of SERCA isoforms was dissociated from MyHC isoforms, regulation of gene expression for these two different protein systems must involve different signaling events and/or synthetic processes.