Tiansheng Shen

Signaling pathways in activity-dependent fiber type plasticity in adult skeletal muscle

Adult fast- and slow-twitch skeletal muscle fibers exhibit characteristic differences in functional properties due to differences in the isoforms and quantities of expression of most muscle proteins. However, these differences may be reversed by chronic electrical stimulation of denervated muscle with the pattern typical of the other fiber type. Here, we review three possible signaling pathways that may contribute to fast to slow fiber type transformation. The first pathway involves cytosolic activation of the Ca2+ sensitive posphatase calcineurin (CaN) due to elevated cytosolic [Ca2+], resulting in dephosphorylation of cytoplasmic NFATc, translocation of dephosphorylated NFATc from cytoplasm into the nucleus and activation of slow fiber gene expression by NFATc in the nucleus. The second pathway involves elevated intranuclear [Ca2+] causing the activation of nuclear calmodulin dependent protein kinase, which phosphorylates HDAC within the nucleus and thereby permits nuclear efflux of HDAC, thus decreasing the HDAC suppression of MEF2 activation of slow fiber gene expression. The third possible pathway involves nuclear entry of CaN, dephosphorylation of intranuclear MEF2 and consequent increased activation of slow fiber type gene expression by dephosphorylated MEF2. Evidence for the first two pathways from our studies on adult fast twitch skeletal muscle fibers is briefly reviewed.

Regulation of the nuclear export of the transcription factor NFATc1 by protein kinases after slow fibre type electrical stimulation of adult mouse skeletal muscle fibres

The transcription factor nuclear factor of activated T cells (NFAT)c1 has been shown to be involved in turning on slow skeletal muscle fibre gene expression. Previous studies from our laboratory have characterized the stimulation pattern‐dependent nuclear import and resting shuttling of NFATc1–green fluorescent protein (GFP) in flexor digitorum brevis (FDB) muscle fibres from adult mouse. In this study, we use viral expression of the transcription factor NFATc1–GFP fusion protein to investigate the mechanisms underlying the nuclear export of the NFATc1–GFP that accumulated in the nuclei of cultured dissociated adult mouse FDB muscle fibres during slow‐twitch fibre type electrical stimulation. In these studies, we found that inhibition of either glycogen synthase kinase 3β (GSK3β) or casein kinase 1 or 2 (CK1/2) markedly slowed the decay of nuclear NFATc1–GFP after cessation of muscle fibre electrical stimulation, whereas inhibition of casein kinase 1δ, p38 mitogen‐activated protein kinase, c‐Jun N‐terminal kinase and protein kinase A had little effect. Simultaneous inhibition of GSK3β and CK1/2 completely blocked the nuclear export of NFATc1–GFP after muscle activity. We also developed a simplified model of NFATc1 phosphorylation/dephosphorylation and nuclear fluxes, and used this model to simulate the observed time courses of nuclear NFATc1–GFP with and without NFATc1 kinase inhibition. Our results suggest that GSK3β and CK1/2 are the major protein kinases that contribute to the removal of NFATc1 that accumulates in muscle fibre nuclei during muscle activity, and that GSK3β and CK1/2 are responsible for phosphorylating NFATc1 in muscle nuclei in a complementary or synergistic fashion.

Parallel mechanisms for resting nucleo-cytoplasmic shuttling and activity dependent translocation provide dual control of transcriptional regulators HDAC and NFAT in skeletal muscle fiber type plasticity.

Skeletal muscle fibers exhibit plasticity of their physiological and biochemical properties in response to the firing pattern from the innervating motor neuron. In particular, the gene expression pattern generally characteristic of a slow twitch fiber can be induced in a fast twitch fiber by chronic slow fiber type electrical stimulation. We have studied the nucleo-cytoplasmic distribution of two transcriptional regulators of slow fiber type genes, HDAC4 and NFATc1, both in response to slow fiber type stimulation and in resting conditions using cultured fast twitch skeletal muscle fibers. HDAC4 is present in both cytoplasm and nuclei of resting fibers, and moves out of the nuclei in response to slow fiber type stimulation. The stimulation-dependent nuclear efflux of HDAC4 requires activation of nuclear CaMKII, which phosphorylates nuclear HDAC4 and thus allows its exit of the nucleus. In unstimulated resting fibers, a balance of nuclear efflux and influx of HDAC4 establishes the resting level of nuclear HDAC4. However, the nuclear efflux of HDAC4 in resting fibers does not involve CaMKII. Slow fiber type stimulation also causes NFATc1 translocation from the cytoplasm into muscle fiber nuclei following dephosphorylation by calcineurin (CaN) activated by the elevated cytosolic Ca2+ accompanying fiber stimulation. In resting fibers, NFATc1 exhibits balanced shuttling between cytoplasm and nucleus, but during this shuttling NFATc1 influx does not require CaN and NFATc1 efflux does not require the kinases involved in removing nuclear NFATc1 following prior activity. Thus different enzymes are responsible for HDAC4 nuclear efflux in resting and active fibers, and different pathways mediate NFATc1 nuclear influx and efflux in resting and active fibers. Such dual mechanisms for resting shuttling and active movements provide the potential for the resting level and the rate of translocation during fiber stimulation to be controlled independently for both of the transcriptional regulators HDAC4 and NFATc1.

Kinetics of nuclear-cytoplasmic translocation of Foxo1 and Foxo3A in adult skeletal muscle fibers

In skeletal muscle, the transcription factors Foxo1 and Foxo3A control expression of proteins that mediate muscle atrophy, making the nuclear concentration and nuclear-cytoplasmic movements of Foxo1 and Foxo3A of therapeutic interest in conditions of muscle wasting. Here, we use Foxo-GFP fusion proteins adenovirally expressed in cultured adult mouse skeletal muscle fibers to characterize the time course of nuclear efflux of Foxo1-GFP in response to activation of the insulin-like growth factor-1 (IGF-1)/phosphatidylinositol-3-kinase (PI3K)/Akt pathway to determine the time course of nuclear influx of Foxo1-GFP during inhibition of this pathway and to show that Akt mediates the efflux of nuclear Foxo1-GFP induced by IGF-1. Localization of endogenous Foxo1 in muscle fibers, as determined via immunocytochemistry, is consistent with that of Foxo1-GFP. Inhibition of the nuclear export carrier chromosome region maintenance 1 by leptomycin B (LMB) traps Foxo1 in the nucleus and results in a relatively rapid rate of Foxo1 nuclear accumulation, consistent with a high rate of nuclear-cytoplasmic shuttling of Foxo1 under control conditions before LMB application, with near balance of unidirectional influx and efflux. Expressed Foxo3A-GFP shuttles ∼20-fold more slowly than Foxo1-GFP. Our approach allows quantitative kinetic characterization of Foxo1 and Foxo3A nuclear-cytoplasmic movements in living muscle fibers under various experimental conditions.

Smyd1b_tv1, a Key Regulator of Sarcomere Assembly, Is Localized on the M-Line of Skeletal Muscle Fibers

Background Smyd1b is a member of the Smyd family that plays a key role in sarcomere assembly during myofibrillogenesis. Smyd1b encodes two alternatively spliced isoforms, smyd1b_tv1 and smyd1b_tv2, that are expressed in skeletal and cardiac muscles and play a vital role in myofibrillogenesis in skeletal muscles of zebrafish embryos. Methodology/Principal Findings To better understand Smyd1b function in myofibrillogenesis, we analyzed the subcellular localization of Smyd1b_tv1 and Smyd1b_tv2 in transgenic zebrafish expressing a myc-tagged Smyd1b_tv1 or Smyd1b_tv2. The results showed a dynamic change of their subcellular localization during muscle cell differentiation. Smyd1b_tv1 and Smyd1b_tv2 were primarily localized in the cytosol of myoblasts and myotubes at early stage zebrafish embryos. However, in mature myofibers, Smyd1b_tv1, and to a small degree of Smyd1b_tv2, exhibited a sarcomeric localization. Double staining with sarcomeric markers revealed that Smyd1b_tv1was localized on the M-lines. The sarcomeric localization was confirmed in zebrafish embryos expressing the Smyd1b_tv1-GFP or Smyd1b_tv2-GFP fusion proteins. Compared with Smyd1b_tv1, Smyd1b_tv2, however, showed a weak sarcomeric localization. Smyd1b_tv1 differs from Smyd1b_tv2 by a 13 amino acid insertion encoded by exon 5, suggesting that some residues within the 13 aa insertion may be critical for the strong sarcomeric localization of Smyd1b_tv1. Sequence comparison with Smyd1b_tv1 orthologs from other vertebrates revealed several highly conserved residues (Phe223, His224 and Gln226) and two potential phosphorylation sites (Thr221 and Ser225) within the 13 aa insertion. To determine whether these residues are involved in the increased sarcomeric localization of Smyd1b_tv1, we mutated these residues into alanine. Substitution of Phe223 or Ser225 with alanine significantly reduced the sarcomeric localization of Smyd1b_tv1. In contrast, other substitutions had no effect. Moreover, replacing Ser225 with threonine (S225T) retained the strong sarcomeric localization of Smyd1b_tv1. Conclusion/Significance Together, these data indicate that Phe223 and Ser225 are required for the M-line localization of Smyd1b_tv1.

α-Adrenergic signalling activates protein kinase D and causes nuclear efflux of the transcriptional repressor HDAC5 in cultured adult mouse soleus skeletal muscle fibres

The protein kinase PKD1 has recently been linked to slow fibre‐type gene expression in fast skeletal muscle through phosphorylation of class II histone deacetylase (HDAC) molecules, resulting in nuclear efflux of HDAC and consequent activation of the transcription factor MEF2. However, possible upstream activators of PKD, and the time course and signalling pathway of downstream effectors have not been determined in skeletal muscle. Using fluorescent fusion proteins HDAC5–green fluorescent protein (GFP) and PKD1–mPlum expressed in fibres isolated from predominantly slow soleus muscle and maintained for 4 days in culture, we now show that α‐adrenergic receptor activation by phenylephrine causes a transient, PKD‐dependent HDAC5–GFP nuclear efflux. Concurrent to this response, PKD1–mPlum transiently redistributes from cytoplasm to plasma membrane and nuclei, and back, during 2 h exposure to phenylephrine. The recovery may reflect α‐receptor desensitization. In contrast, the phorbol ester PMA (phorbol‐12‐myristate‐13‐acetate, a pharmacological mimic of the downstream mediator diacylglycerol in α‐adrenergic signalling), caused continuous PKD‐dependent HDAC5–GFP nuclear efflux and maintained PKD1–mPlum redistribution. In the absence of expressed HDAC, PMA increased histone H3 acetylation and increased MEF2 reporter activity in a PKD‐dependent manner, consistent with PKD phosphorylation of endogenous HDAC(s) and reduced nuclear HDAC activity due to HDAC nuclear efflux. HDAC5–GFP did not respond to PMA in fibres from predominantly fast flexor digitorum brevis (FDB) muscle, but did in FDB fibres expressing exogenous PKD1. Our results demonstrate that a PKD‐mediated signalling pathway for HDAC nuclear efflux is activated in slow skeletal muscle through adrenergic input, which is typically active in parallel with motor neurone input during muscular activity.

Elevated extracellular glucose and uncontrolled type 1 diabetes enhance NFAT5 signaling and disrupt the transverse tubular network in mouse skeletal muscle

The transcription factor nuclear factor of activated T-cells 5 (NFAT5) is a key protector from hypertonic stress in the kidney, but its role in skeletal muscle is unexamined. Here, we evaluate the effects of glucose hypertonicity and hyperglycemia on endogenous NFAT5 activity, transverse tubular system morphology and Ca2+ signaling in adult murine skeletal muscle fibers. We found that exposure to elevated glucose (25–50 mmol/L) increased NFAT5 expression and nuclear translocation, and NFAT-driven transcriptional activity. These effects were insensitive to the inhibition of calcineurin A, but sensitive to both p38α mitogen-activated protein kinases and phosphoinositide 3-kinase-related kinase inhibition. Fibers exposed to elevated glucose exhibited disrupted transverse tubular morphology, characterized by swollen transverse tubules and an increase in longitudinal connections between adjacent transverse tubules. Ca2+ transients elicited by a single, brief electric field stimuli were increased in amplitude in fibers challenged by elevated glucose. Muscle fibers from type 1 diabetic mice exhibited increased NFAT5 expression and transverse tubule disruptions, but no differences in electrically evoked Ca2+ transients. Our results suggest the hypothesis that these changes in skeletal muscle could play a role in the pathophysiology of acute and severe hyperglycemic episodes commonly observed in uncontrolled diabetes.

Localization and Regulation of the N Terminal Splice Variant of PGC-1α in Adult Skeletal Muscle Fibers

The transcriptional coactivator peroxisome proliferator-activated receptor γ coactivator 1α (PGC-1α) regulates expression of genes for metabolism and muscle fiber type. Recently, a novel splice variant of PGC-1α (NT-PGC-1α, amino acids 1–270) was cloned and found to be expressed in muscle. Here we use Flag-tagged NT-PGC-1α to examine the subcellular localization and regulation of NT-PGC-1α in skeletal muscle fibers. Flag-NT-PGC-1α is located predominantly in the myoplasm. Nuclear NT-PGC-1α can be increased by activation of protein kinase A. Activation of p38 MAPK by muscle activity or of AMPK had no effect on the subcellular distribution of NT-PGC-1α. Inhibition of CRM1-mediated export only caused relatively slow nuclear accumulation of NT-PGC-1α, indicating that nuclear export of NT-PGC-1α may be mediated by both CRM1-dependent and -independent pathways. Together these results suggest that the regulation of NT-PGC-1α in muscle fibers may be very different from that of the full-length PGC-1α, which is exclusively nuclear.