Role of damage and management in muscle hypertrophy: Different behaviors of muscle stem cells in regeneration and hypertrophy

Skeletal muscle is a dynamic tissue with two unique abilities; one is its excellent regenerative ability, due to the activity of skeletal muscle–resident stem cells named muscle satellite cells (MuSCs); and the other is the adaptation of myofiber size in response to external stimulation, intrinsic factors, or physical activity, which is known as plasticity. Low physical activity and some disease conditions lead to the reduction of myofiber size, called atrophy, whereas hypertrophy refers to the increase in myofiber size induced by high physical activity or anabolic hormones/drugs. MuSCs are essential for generating new myofibers during regeneration and the increase in new myonuclei during hypertrophy; however, there has been little investigation of the molecular mechanisms underlying MuSC activation, proliferation, and differentiation during hypertrophy compared to those of regeneration. One reason is that ‘degenerative damage’ to myofibers during muscle injury or upon hypertrophy (especially overloaded muscle) is believed to trigger similar activation/proliferation of MuSCs. However, evidence suggests that degenerative damage of myofibers is not necessary for MuSC activation/proliferation during hypertrophy. When considering MuSC-based therapy for atrophy, including sarcopenia, it will be indispensable to elucidate MuSC behaviors in muscles that exhibit non-degenerative damage, because degenerated myofibers are not present in the atrophied muscles. In this review, we summarize recent findings concerning the relationship between MuSCs and hypertrophy, and discuss what remains to be discovered to inform the development and application of relevant treatments for muscle atrophy.     

Potent myofiber hypertrophy during resistance training in humans is associated with satellite cell-mediated myonuclear addition: a cluster analysis.

A present debate in muscle biology is whether myonuclear addition is required during skeletal muscle hypertrophy. We utilized K-means cluster analysis to classify 66 humans after 16 wk of knee extensor resistance training as extreme (Xtr, n = 17), modest (Mod, n = 32), or nonresponders (Non, n = 17) based on myofiber hypertrophy, which averaged 58, 28, and 0%, respectively (Bamman MM, Petrella JK, Kim JS, Mayhew DL, Cross JM. J Appl Physiol 102: 2232-2239, 2007). We hypothesized that robust hypertrophy seen in Xtr was driven by superior satellite cell (SC) activation and myonuclear addition. Vastus lateralis biopsies were obtained at baseline and week 16. SCs were identified immunohistochemically by surface expression of neural cell adhesion molecule. At baseline, myofiber size did not differ among clusters; however, the SC population was greater in Xtr (P < 0.01) than both Mod and Non, suggesting superior basal myogenic potential. SC number increased robustly during training in Xtr only (117%; P < 0.001). Myonuclear addition occurred in Mod (9%; P < 0.05) and was most effectively accomplished in Xtr (26%; P < 0.001). After training, Xtr had more myonuclei per fiber than Non (23%; P < 0.05) and tended to have more than Mod (19%; P = 0.056). Both Xtr and Mod expanded the myonuclear domain to meet (Mod) or exceed (Xtr) 2,000 mum(2) per nucleus, possibly driving demand for myonuclear addition to support myofiber expansion. These findings strongly suggest myonuclear addition via SC recruitment may be required to achieve substantial myofiber hypertrophy in humans. Individuals with a greater basal presence of SCs demonstrated, with training, a remarkable ability to expand the SC pool, incorporate new nuclei, and achieve robust growth.     

Syndecan-3 and Notch cooperate in regulating adult myogenesis

Skeletal muscle postnatal growth and repair depend on satellite cells and are regulated by molecular signals within the satellite cell niche. We investigated the molecular and cellular events that lead to altered myogenesis upon genetic ablation of Syndecan-3, a component of the satellite cell niche. In the absence of Syndecan-3, satellite cells stall in S phase, leading to reduced proliferation, increased cell death, delayed onset of differentiation, and markedly reduced numbers of Pax7⁺ satellite cells accompanied by myofiber hypertrophy and an increased number of centrally nucleated myofibers. We show that the aberrant cell cycle and impaired self-renewal of explanted Syndecan-3–null satellite cells are rescued by ectopic expression of the constitutively active Notch intracellular domain. Furthermore, we show that Syndecan-3 interacts with Notch and is required for Notch processing by ADAM17/tumor necrosis factor-α–converting enzyme (TACE) and signal transduction. Together, our data support the conclusion that Syndecan-3 and Notch cooperate in regulating homeostasis of the satellite cell population and myofiber size.     

Estimating the Growth Rate of Slowly Growing Marine Bacteria from RNA Content

In past studies of enteric bacteria such as Escherichia coli, various measures of cellular RNA content have been shown to be strongly correlated with growth rate. We examined this correlation for four marine bacterial isolates. Isolates were grown in chemostats at four or five dilution rates, yielding growth rates that spanned the range typically determined for marine bacterial communities in nature (μ = 0.01 to 0.25 h^-1). All measures of RNA content (RNA cell^-1, RNA:biovolume ratio, RNA:DNA ratio, RNA:DNA:biovolume ratio) were significantly different among isolates. Normalizing RNA content to cell volume substantially reduced, but did not eliminate, these differences. On average, the correlation between μ and the RNA:DNA ratio accounted for 94% of variance when isolates were considered individually. For data pooled across isolates (analogous to an average measurement for a community), the ratio of RNA:DNA μm^-3 (cell volume) accounted for nearly half of variance in μ (r² = 0.47). The maximum RNA:DNA ratio for each isolate was extrapolated from regressions. The regression of (RNA:DNA)/(RNA:DNA)_max on μ was highly significant (r² = 0.76 for data pooled across four isolates) and virtually identical for three of the four isolates, perhaps reflecting an underlying common relationship between RNA content and growth rate. The dissimilar isolate was the only one derived from sediment. Cellular RNA content is likely to be a useful predictor of growth rate for slowly growing marine bacteria but in practice may be most successful when applied at the level of individual species.     

Nuclear differentiation and nucleic acid synthesis in well-fed exconjugants of Paramecium aurelia

Paramecium aurelia exconjugants contain new macronuclear anlagen and numerous fragments of the old pre-zygotic macronucleus. Macronuclear anlagen develop during the first two cell cycles after conjugation. During this time their volume increases from about 11 m³ to about 3700 m³ and more than 10 doublings of DNA content occur. The rate of DNA synthesis is between two and three times as great as in the vegetative macronucleus. — In macronuclear fragments, however, DNA synthesis is suppressed. The rate of DNA synthesis in macronuclear fragments during the extended first cell cycle after conjugation (11 1/2 hr. vs. 5 1/2 hr. for the vegetative cell cycle) is only about one-third of the rate in vegetative macronuclei and there is only a 65% increase in the mean DNA content of fragments. The rate of fragment DNA synthesis continues to decrease during each of the subsequent two cell cycles. — Unlike the rate of DNA synthesis, the rate of RNA synthesis per unit of DNA is similar in macronuclear anlagen, macronuclear fragments and fully developed macronuclei. Macronuclear fragments continue to synthesize RNA at the normal rate long after the new macronuclei are fully developed. Fragments contribute about 80% of all RNA synthesized during the first two cell cycles after conjugation. RNA synthesis begins very early in the development of macronuclear anlagen and nucleolar material appears during the first half-hour of anlage development. — Chromosome-like structures were never observed during anlage development and there was no evidence of two periods of DNA synthesis separated by a DNA poor stage as has been observed in several hypotrichous Ciliates.     

Is the myonuclear domain size fixed?

It has been suggested that the number of myonuclei in a muscle fibre changes in proportion to the change in fibre size, resulting in a constant myonuclear domain size, defined as the cytoplasmic volume per myonucleus. The myonuclear domain size varies, however, between fibre types and is inversely related with the oxidative capacity of a fibre. Overall, the observations of an increase in myonuclear domain size during both maturational growth and overload-induced hypertrophy, and the decrease in myonuclear domain size during disuse- and ageing-associated muscle atrophy suggest that the concept of a constant myonuclear domain size needs to be treated cautiously. It also suggests that only when the myonuclear domain size exceeds a certain threshold during growth or overload-induced hypertrophy acquisition of new myonuclei is required for further fibre hypertrophy.     

Satellite cell proliferation and increase in the number of myonuclei induced by testosterone in the levator ani muscle of the adult female rat

We injected adult female rats with 0.25 mg/100 g body weight of testosterone to test the sensitivity to androgens of the levator ani muscle (LAM). Testosterone induced marked hypertrophy characterized by fiber size enlargement, but did not increase the number of fibers. Morphological observations and quantitative data indicated that hypertrophy was accompanied by satellite cell proliferation between Days 1 and 3 after testosterone treatment, and by an increase in the number of myonuclei, which started between Days 2 and 3 after treatment. On Day 30, this increase reached 80% of the initial number of myonuclei. The new myonuclei seemed to result from satellite cell proliferation and from the fusion of some of them with preexistent muscle fibers. These results strongly suggest that testosterone-induced cell proliferation might have a role in developing the sexual dimorphism of the LAM. They also indicate the need to reconsider the currently accepted notion that sexual dimorphism is owing to female LAM involution.     

γ-Sarcoglycan Deficiency Leads to Muscle Membrane Defects and Apoptosis Independent of Dystrophin

γ-Sarcoglycan is a transmembrane, dystrophin-associated protein expressed in skeletal and cardiac muscle. The murine γ-sarcoglycan gene was disrupted using homologous recombination. Mice lacking γ-sarcoglycan showed pronounced dystrophic muscle changes in early life. By 20 wk of age, these mice developed cardiomyopathy and died prematurely. The loss of γ-sarcoglycan produced secondary reduction of β- and δ-sarcoglycan with partial retention of α- and ε-sarcoglycan, suggesting that β-, γ-, and δ-sarcoglycan function as a unit. Importantly, mice lacking γ-sarco- glycan showed normal dystrophin content and local- ization, demonstrating that myofiber degeneration occurred independently of dystrophin alteration. Furthermore, β-dystroglycan and laminin were left intact, implying that the dystrophin–dystroglycan–laminin mechanical link was unaffected by sarcoglycan deficiency. Apoptotic myonuclei were abundant in skeletal muscle lacking γ-sarcoglycan, suggesting that programmed cell death contributes to myofiber degeneration. Vital staining with Evans blue dye revealed that muscle lacking γ-sarcoglycan developed membrane disruptions like those seen in dystrophin-deficient muscle. Our data demonstrate that sarcoglycan loss was sufficient, and that dystrophin loss was not necessary to cause membrane defects and apoptosis. As a common molecular feature in a variety of muscular dystrophies, sarcoglycan loss is a likely mediator of pathology.     

Relationships between nucleic acid,nitrogen, and growth rate of tobacco cells in suspension culture

Summary Changes in the amount of nucleic acid and nitrogen, and the relationships between these amounts and the growth rate of tobacco cells (Nicotiana tabacum L. cv. Bright Yellow-2) at different initial nitrogen concentrations in the medium, were examined in batch cultures. During culture in basal medium, the amount of intracellular nucleic acid expressed per unit of dry biomass was 36.3 mg RNA g^–1 cell and 8.1 mg DNA g^–1 cell at the beginning of batch culture. These values increased 2.5 fold for RNA and 1.5 fold for DNA during the exponential growth phase and then gradually decreased with the decline in the growth rate. Similar changes were also observed in the medium containing less nitrogen. The specific growth rate, (day^–1), of the culture corresponded to the magnitude of the intracellular RNA content (mg RNA g^–1 cell), and the linear relationship, RNA=38+23 was obtained. In addition, there were remarkable positive correlations between the total and protein nitrogen, and during the cultures. The mononucleotide composition of total RNA (AMP+UMP)/(GMP+CMP) which was suggested to be a convenient index of metabolic activity was nearly constant (0.78 to 0.80) during tobacco cell culture in the basal medium.     

Concomitant increases in myonuclear and satellite cell content in female trapezius muscle following strength training

A skeletal muscle fibre maintains its cytoplasmic volume by means of hundreds of myonuclei distributed along its entire length. Therefore it is hypothesised that changes in fibre size would involve modifications in myonuclear number. In this study, we have examined whether 10 weeks of strength training can induce changes in the number of myonuclei and satellite cells in female trapezius muscles. Biopsies were taken pre- and posttraining from the upper part of the descending trapezius muscle of nine subjects. Muscle samples were analysed for fibre area and myonuclear and satellite cell number using immunohistochemistry. There was a 36% increase in the cross-sectional area of muscle fibres. The hypertrophy of muscle fibres was accompanied by an approximately 70% increase in myonuclear number and a 46% increase in the number of satellite cells. Myonuclei number was positively correlated to satellite cell number indicating that a muscle with an increased concentration of myonuclei will contain a correspondingly higher number of satellite cells. The acquisition of additional myonuclei appears to be required to support the enlargement of multinucleated muscle cells following 10 weeks of strength training. Increased satellite cell content suggests that mitotic divisions of satellite cells produced daughter cells that became satellite cells. Accepted: 30 November 1999     

Quantitative studies on RNA accumulation in human PHA-stimulated lymphocytes during blast transformation

The net RNA accumulation in PHA-stimulated individual lymphocytes during blast transformation was assayed. The RNA content of the cells was measured by UV microspectrophotometry and the concentration of ribosomes in the cytoplasm of non-stimulated and transforming lymphocytes was determined by counting RNP particles in electronmicrographs.The mean RNA content of non-stimulated lymphocytes was 1.9 ± 0.8 × 10⁻¹²g/cell. During transformation the RNA content increased considerably, the maximal increase being about ten-fold. This increase was proportional to the increase in cellular dry mass. In fact, the RNA concentration was constant during transformation and approximately the same in non-stimulated and transforming lymphocytes. Furthermore the ribosome concentration was approximately the same in the cytoplasm of non-stimulated and transforming lymphocytes. However, a pronounced transition of single ribosomes to ribosomal clusters occurred during transformation and was one of the earliest structural signs of stimulation observed.     

In vivo expression patterns of MyoD, p21, and Rb proteins in myonuclei and satellite cells of denervated rat skeletal muscle

MyoD, a myogenic regulatory factor, is rapidly expressed in adult skeletal muscles in response to denervation. However, the function(s) of MyoD expressed in denervated muscle has not been adequately elucidated. In vitro, it directly transactivates cyclin-dependent kinase inhibitor p21 (p21) and retinoblastoma protein (Rb), a downstream target of p21. These factors then act to regulate cell cycle withdrawal and antiapoptotic cell death. Using immunohistochemical approaches, we characterized cell types expressing MyoD, p21, and Rb and the relationship among these factors in the myonucleus of denervated muscles. In addition, we quantitatively examined the time course changes and expression patterns among distinct myofiber types of MyoD, p21, and Rb during denervation. Denervation induced MyoD expression in myonuclei and satellite cell nuclei, whereas p21 and Rb were found only in myonuclei. Furthermore, coexpression of MyoD, p21, and Rb was induced in the myonucleus, and quantitative analysis of these factors determined that there was no difference among the three myofiber types. These observations suggest that MyoD may function in myonuclei in response to denervation to protect against denervation-induced apoptosis via perhaps the activation of p21 and Rb, and function of MyoD expressed in satellite cell nuclei may be negatively regulated. The present study provides a molecular basis to further understand the function of MyoD expressed in the myonuclei and satellite cell nuclei of denervated skeletal muscle. denervation; protein expression; apoptotic cell death; immunohistochemistry     

Effect of Growth Rate and Starvation-Survival on Cellular DNA, RNA, and Protein of a Psychrophilic Marine Bacterium

DNA, RNA, and protein concentrations from starved ANT-300 cell populations grown at different growth rates fluctuated corresponding to the three stages of starvation-survival on total and viable cell bases. During stage 1 of starvation-survival, two to three peaks in the concentration levels for all three macromolecules were characteristic. During stage 2, DNA per total cell dropped to between 4.2 and 8.3% of the original amount for all of the cell populations examined, and it stabilized throughout stage 3. The decrease in DNA per cell was also observed in electron micrographs of cellular DNA in unstarved compared with starved cells. The fluctuations of RNA and protein per total cell concentrations observed during stage 2 coincided in all cases, except for the cells from dilution rate (D) = 0.015 h⁻¹. This ANT-300 cell population showed a decrease in RNA per total cell to only 29.2% and an increase in protein to 129.7% of the original amount after 98 days of starvation. During stage 3, DNA, RNA, and protein concentrations per total cell also stabilized to continuous levels. Cells from the faster-growth-rate cell populations of D = 0.170 h⁻¹ and batch culture had elevated protein per total cell concentrations, which remained primarily residual during the starvation period. Starved cells from D = 0.015 h⁻¹ had estimated nucleoid and cell volumes of 0.018 and 0.05 μm³, respectively, yielding a nucleoid volume/cell volume ratio of 0.40. We consider these data to indicate that slow-growth-rate cells are better adapted for starvation-survival than their faster-growth-rate counterparts.     

Nucleic Acid Metabolism in Germinating Onion: I. Changes in Root Tip Nucleic Acid during Germination

Nucleic acid synthesis in the G₁ cell population of the 1-millimeter apex of the Allium cepa embryo was studied during the initial 73 hours of germination. Quantitative data indicate that the total amount of RNA per cell began to increase after 18 hours of germination while the initial DNA per cell increase did not occur until some 20 hours later. Polyacrylamide gel electrophoresis patterns of ³H-uridine-labeled total nucleic acid samples indicated that synthesis of all detectable RNA fractions present in the pre-emergent 1-millimeter apex (i.e., cytoplasmic and “chloroplast-like” RNA) began at approximately the same time (18 hours). Synthesis of the various cytoplasmic RNA fractions continued throughout the germination period. Data indicating synthesis of the “chloroplast-like” RNA were obtained only for the initial 36 hours of germination. Specific radioactivity of ³H-uridine-labeled total nucleic acid increased during the first 41.5 hours of germination but then decreased while the accumulation of RNA per cell continued to increase throughout the 73-hour period. In addition, a method is described which reduced the bacterial contamination of Allium seed to a level not detectable by incorporation of radioactive precursors into bacterial ribosomal RNA.