SIRT1 regulates nuclear number and domain size in skeletal muscle fibers

Skeletal muscle fibers are giant multinucleated cells wherein individual nuclei govern the protein synthesis in a finite volume of cytoplasm; this is termed the myonuclear domain (MND). The factors that control MND size remain to be defined. In the present study, we studied the contribution of the NAD⁺‐dependent deacetylase, sirtuin 1 (SIRT1), to the regulation of nuclear number and MND size. For this, we isolated myofibers from mice with tissue‐specific inactivation (mKO) or inducible overexpression (imOX) of SIRT1 and analyzed the 3D organisation of myonuclei. In imOX mice, the number of nuclei was increased whilst the average MND size was decreased as compared to littermate controls. Our findings were the opposite in mKO mice. Muscle stem cell (satellite cell) numbers were reduced in mKO muscles, a possible explanation for the lower density of myonuclei in these mice; however, no change was observed in imOX mice, suggesting that other factors might also be involved, such as the functional regulation of stem cells/muscle precursors. Interestingly, however, the changes in the MND volume did not impact the force‐generating capacity of muscle fibers. Taken together, our results demonstrate that SIRT1 is a key regulator of MND sizes, although the underlying molecular mechanisms and the cause‐effect relationship between MND and muscle function remain to be fully defined.     

Pax7 reveals a greater frequency and concentration of satellite cells at the ends of growing skeletal muscle fibers.

The main sites of longitudinal growth in skeletal muscle are the ends of the fibers. This study tests the hypothesis that satellite cells (SCs) are at a greater frequency (#SC nuclei/all nuclei within basal laminae) and concentration (closer together) within growing fiber ends of posthatch chicken pectoralis. SCs were localized by their Pax7 expression, and fiber ends were identified by their retention of neonatal myosin heavy chains and small cross-sectional profiles. Whereas SC frequency decreased from about 20% at 9 days posthatch to <5% at 115 days, fiber ends retained a frequency of approximately 16%. Calculated mean area of sarcolemma per SC revealed higher concentrations of SCs at fiber ends. There was also a strong inverse correlation between SC frequency and fiber profile cross-sectional size throughout development. This study suggests that SCs at fiber ends play a key role in the longitudinal growth of muscle fibers, and that fiber profile size may impact SC distribution.     

Biochemical isolation of myonuclei employed to define changes to the myonuclear proteome that occur with aging

Skeletal muscle aging is accompanied by loss of muscle mass and strength. Examining changes in myonuclear proteins with age would provide insight into molecular processes which regulate these profound changes in muscle physiology. However, muscle tissue is highly adapted for contraction and thus comprised largely of contractile proteins making the nuclear proteins difficult to identify from whole muscle samples. By developing a method to purify myonuclei from whole skeletal muscle, we were able to collect myonuclei for analysis by flow cytometry, biochemistry, and mass spectrometry. Nuclear purification dramatically increased the number and intensity of nuclear proteins detected by mass spectrometry compared to whole tissue. We exploited this increased proteomic depth to investigate age‐related changes to the myonuclear proteome. Nuclear levels of 54 of 779 identified proteins (7%) changed significantly with age; these proteins were primarily involved in chromatin maintenance and RNA processing. To determine whether the changes we detected were specific to myonuclei or were common to nuclei of excitatory tissues, we compared aging in myonuclei to aging in brain nuclei. Although several of the same processes were affected by aging in both brain and muscle nuclei, the specific proteins involved in these alterations differed between the two tissues. Isolating myonuclei allowed a deeper view into the myonuclear proteome than previously possible facilitating identification of novel age‐related changes in skeletal muscle. Our technique will enable future studies into a heretofore underrepresented compartment of skeletal muscle.     

Steroid control of muscle remodeling during metamorphosis in Manduca sexta

During metamorphosis in the tobacco hornworm, Manduca sexta, the abdominal body-wall muscle DEO1 is remodeled to form the adult muscle DE5. The degeneration of muscle DEO1 involves the dismantling of its contractile apparatus followed by the degeneration of muscle nuclei. As some nuclei are degenerating, others begin to incorporate 5-bromodeoxyuridine (BrdU), indicating the onset of nuclear proliferation. This proliferation is initially most evident at the site where the motoneuron contacts the muscle remnant. The developmental events involved in muscle remodeling are under the control of the steroid hormones, the ecdysteroids. The loss of the contractile elements of the larval muscle requires the rise and fall of the prepupal peak of ecdysteroids, whereas the subsequent loss of muscle nuclei is influenced by the slight rise in ecdysteroids seen after pupal ecdysis. Incorporation of BrdU by muscle nuclei depends on both the adult peak of the ecdysteroids and contact with the motoneuron. Unilateral axotomy blocks proliferation within the rudiment, but it does not block its subsequent differentiation into a very thin muscle in the adult. © 1996 John Wiley & Sons, Inc.     

Xestospongin B, a competitive inhibitor of IP3-mediated Ca2+ signalling in cultured rat myotubes, isolated myonuclei, and neuroblastoma (NG108-15) cells

Xestospongin B, a macrocyclic bis-1-oxaquinolizidine alkaloid extracted from the marine sponge Xestospongia exigua, was highly purified and tested for its ability to block inositol 1,4,5-trisphosphate (IP(3))-induced Ca(2+) release. In a concentration-dependent manner xestospongin B displaced [(3)H]IP(3) from both rat cerebellar membranes and rat skeletal myotube homogenates with an EC(50) of 44.6 +/- 1.1 microM and 27.4 +/- 1.1 microM, respectively. Xestospongin B, depending on the dose, suppressed bradykinin-induced Ca(2+) signals in neuroblastoma (NG108-15) cells, and also selectively blocked the slow intracellular Ca(2+) signal induced by membrane depolarization with high external K(+) (47 mM) in rat skeletal myotubes. This slow Ca(2+) signal is unrelated to muscle contraction, and involves IP(3) receptors. In highly purified isolated nuclei from rat skeletal myotubes, Xestospongin B reduced, or suppressed IP(3)-induced Ca(2+) oscillations with an EC(50) = 18.9 +/- 1.35 microM. In rat myotubes exposed to a Ca(2+)-free medium, Xestospongin B neither depleted sarcoplasmic reticulum Ca(2+) stores, nor modified thapsigargin action and did not affect capacitative Ca(2+) entry after thapsigargin-induced depletion of Ca(2+) stores. Ca(2+)-ATPase activity measured in skeletal myotube homogenates remained unaffected by Xestospongin B. It is concluded that xestospongin B is an effective cell-permeant, competitive inhibitor of IP(3) receptors in cultured rat myotubes, isolated myonuclei, and neuroblastoma (NG108-15) cells.     

Cellular effects of functional unloading and passive strain of soleus muscle in dystrophin-deficient mice

There is a suggestion that dystrophin, a subsarcolemmal protein communicating fiber cytoskeleton to extracellular matrix, participates in signal transduction reflecting the mechanical state of skeletal muscle (mechanotransduction). Recent works indicate the possible signaling role of this protein in the prevention of the activation of proteolytic processes accompanying development of muscle fiber atrophy and in realization of anabolic effects of muscle passive stretching. To assess the role of dystrophin in these processes, the experiment was carried out on two-month old C57 black and mdx (dystrophin-deficient) mice subjected to hind-limb suspension with stretching and without it. Passive stretching results in the partial prevention of atrophy in two muscle fiber types of both C57 black and mdx mice; at the same time, in mdx mice, the slow-to-fast transformation of the soleus muscle fiber type was not observed. Proliferative activity in soleus muscle decreased as a result of hind-limb suspension, but markedly increased during muscle passive stretching. We have found no correlation between the altered dystrophin synthesis and proliferative activity of satellite cells during hind-limb suspension and hind-limb suspension with stretching. Hence, the disturbed dystrophin synthesis retards the atrophy of slow muscle fibers and practically does not affect the stretching preventive action.     

Growth of carp (Cyprinus carpio) white axial muscle; hyperplasia and hypertrophy in relation to the myonucleus/sarcoplasm ratio and the occurrence of different subclasses of myogenic cells

In white axial muscle of carp addition of new fibres to the muscle mass (hyperplasia) decreased with increasing length of the fish. This was deducted from the decrease in the amount of small fibres. In carp larger than about 40 cm standard length (s.l.) hyperplasia no longer occurred (small fibres were absent) and muscle growth only occurred by means of hypertrophy (growth of existing fibres). The stage of growth in which many new fibres were added showed a relatively fast increase in trunk weight, as calculated from growth curves. During the stage of fast growth with a high occurrence of hyperplasia, the DNA/protein ratio decreased. The high percentage of postmitotic myosatellite cells isolated from carp of 5 cm s.l. suggests that in hyperplasia a subpopulation of already differentiated myosatellite cells formed in an earlier stage of development is incorporated in new muscle fibres. The increase of the relative importance of hypertrophy appears to be correlated to an increase in the percentage of proliferating myosatellite cells 17 h after isolation in vitro . This suggests that in hyperplasia and in hypertrophy different subpopulations of myosatellite cells are involved.