Acute molecular response of mouse hindlimb muscles to chronic stimulation.

Stimulation of the mouse hindlimb via the sciatic nerve was performed for a 4-h period to investigate acute muscle gene activation in a model of muscle phenotype conversion. Initial force production (1.6 +/- 0.1 g/g body wt) declined 45% within 10 min and was maintained for the remainder of the experiment. Force returned to initial levels upon study completion. An immediate-early growth response was present in the extensor digitorum longus (EDL) muscle (FOS, JUN, activating transcription factor 3, and musculoaponeurotic fibrosarcoma oncogene) with a similar but attenuated pattern in the soleus muscle. Transcript profiles showed decreased fast fiber-specific mRNA (myosin heavy chains 2A and 2B, fast troponins T(3) and I, alpha-tropomyosin, muscle creatine kinase, and parvalbumin) and increased slow transcripts (myosin heavy chain-1beta/slow, troponin C slow, and tropomyosin 3y) in the EDL versus soleus muscles. Histological analysis of the EDL revealed glycogen depletion without inflammatory cell infiltration in stimulated versus control muscles, whereas ultrastructural analysis showed no evidence of myofiber damage after stimulation. Multiple fiber type-specific transcription factors (tea domain family member 1, nuclear factor of activated T cells 1, peroxisome proliferator-activated receptor-gamma coactivator-1alpha and -beta, circadian locomotor output cycles kaput, and hypoxia-inducible factor-1alpha) increased in the EDL along with transcription factors characteristic of embryogenesis (Kruppel-like factor 4; SRY box containing 17; transcription factor 15; PBX/knotted 1 homeobox 1; and embryonic lethal, abnormal vision). No established in vivo satellite cell markers or genes activated in our parallel experiments of satellite cell proliferation in vitro (cyclins A(2), B(2), C, and E(1) and MyoD) were differentially increased in the stimulated muscles. These results indicated that the molecular onset of fast to slow phenotype conversion occurred in the EDL within 4 h of stimulation without injury or satellite cell recruitment. This conversion was associated with the expression of phenotype-specific transcription factors from resident fiber myonuclei, including the activation of nascent developmental transcriptional programs.

Molecular dynamics of the compensatory response to myocardial infarct.

Myocardial infarct via occlusion of the left anterior descending coronary in rats caused overriding depression in transcription, signal transduction, inflammation and extracellular matrix pathways in the infarct zone within 24 h. In contrast, remote zone gene expression was reciprocally activated during the immediate post-infarct period. Infarct zone signal transduction occurred primarily through TGFbeta1 induction while the remote zone exhibited elevated WNT, NOTCH, GPCR and transmembrane signaling. A minimal day 1 acute phase, inflammatory response was detected in the infarct zone while interleukins (IL1alpha, IL1beta, IL6, IL12alpha, IL18) and the TNFalpha superfamily were activated in the remote zone. Different cytochrome subsets were activated in each left ventricular region on day 1 while anti-oxidant genes were elevated only in the remote zone. The infarct zone exhibited mixed early transcription factor activation across all binding domains with a balance favoring constitutive gene activation and differentiation pathways as opposed to cell proliferation. In contrast, the remote zone exhibited activation of extensive developmental transcription factors involved in specification of cell phenotype, tissue-specific interactions and position-specific cell proliferation on day 1. The day 28 infarct zone response mirrored the day 1 remote zone response including activation of genes associated with matrix remodeling (metallothionein and metalloproteinase 9, 12, 23), as well as genes associated with cell proliferation and phenotype specification (MYC, EGR2, ATF3, HOXA1) recapitulating developmental histogenesis programs.

Effect of muscle origin and phenotype on satellite cell muscle-specific gene expression.

Satellite cells from adult mouse tongue, diaphragm, vastus lateralis, rectus femoris, tibialis anterior, soleus, and extensor digitorum longus muscles were isolated, expanded, and differentiated under identical culture conditions. Proliferating myoblasts and differentiated myofiber cultures were analyzed via SDS-PAGE, immunochemical, and PCR methods for expression of myosin heavy chains (MyHC) and muscle creatine kinase (MCK) as indices of muscle fiber type. Contralateral muscles were harvested for simultaneous, parallel analysis utilizing these assays. The MyHC profile of differentiated primary satellite cells was equivalent across all cultures with MyHC(2A) and MyHC(1/slow) co-expressed in all myotube and myofiber structures. Trace amounts of MyHC(2B) and MyHC(neo) were detected in a few myofibers. MCK was expressed at a uniform, similar level among these cultures. In contrast, contralateral muscles expressed each muscle-specific indicator at levels correlated with the fiber-type distribution within each muscle. MM14 and C2C12 cells, mouse satellite cell lines, were expanded and compared to primary cell cultures. MM14 cells had a high differentiation index (>95%) and co-expressed MyHC(2A) and MyHC(1/slow) along with trace amounts of MyHC(neo) throughout myotube cultures. Myofibers obtained from C2C12 cells exhibited less differentiation (~75%) with MyHC(2A) as the dominant isoform. These data indicate that primary satellite cells from adult muscle form a uniform differentiated cell type regardless of the fiber-type, anatomic location, and embryonic origin of the donor muscles. MM14 cells expressed an adult MyHC isoform profile similar to primary satellite cells. The results suggest that satellite cells provide a uniform cell source for use in autologous transplantation studies and do not acquire a heritable fiber-type-specific phenotype from their host muscle.