Proliferation Of Muscle Stem Cells Research Articles

Insulin-dependent Non-canonical Activation of Notch in Drosophila: A Story of Notch-Induced Muscle Stem Cell Proliferation.

Notch plays multiple roles both in development and in adult tissue homeostasis. Notch was first identified in Drosophila in which it has then been extensively studied. Among the flag-ship Notch functions we could mention its capacity to keep precursor and stem cells in a nondifferentiated state but also its ability to activate cell proliferation that in some contexts could led to cancer. In general, both these functions involve, canonical, ligand-dependent Notch activation. However, a ligand-independent Notch activation has also been described in a few cellular contexts. Here, we focus on one of such contexts, Drosophila muscle stem cells, called AMPs, and discuss how insulin-dependent noncanonical activation of Notch pushes quiescent AMPs to proliferation.

The Microenvironment Is a Critical Regulator of Muscle Stem Cell Activation and Proliferation

Skeletal muscle has a remarkable capacity to regenerate following injury, a property conferred by a resident population of muscle stem cells (MuSCs). In response to injury, MuSCs must double their cellular content to divide, a process requiring significant new biomass in the form of nucleotides, phospholipids, and amino acids. This new biomass is derived from a series of intracellular metabolic cycles and alternative routing of carbon. In this review, we examine the link between metabolism and skeletal muscle regeneration with particular emphasis on the role of the cellular microenvironment in supporting the production of new biomass and MuSC proliferation.

P.137ETS1 facilitates muscle satellite cell proliferation and stemness perpetuation

Muscle stem cells (MuSCs) possess remarkable regenerative capacity which is controlled by various molecules. Understanding these regulatory pathways is a promising therapeutic approach to many muscle diseases. Here, we reported ETS1 as an important transcription factor which regulates MuSCs proliferation and stemness perpetuation. ETS1 is known to associate in various biological processes, especially in immune system. Aberrant expression of ETS1 has been described in many types of cancer. However, its function in musculoskeletal system remains unclear. Using transcriptomic analysis, we identified ETS1 which is highly expressed in proliferating MuSCs compared to differentiating cells. qRT-PCR showed significant reduction of ETS1 expression during the course of differentiation which was confirmed by immunostaining and western blot. We constructed ETS1-retroviral vector and performed forced overexpression of ETS1. Despite being cultured in differentiation media, ETS1-overexpressing MuSCs could maintain Pax7 expression and proliferation potential. In addition, most of the cells remained unfused and myotube formation was obviously scarce. On the contrary, with RNA interference, we observed decreased EdU and KI67 incorporation in ETS1 knocked-down MuSCs. Taken together, our findings suggest that ETS1 is one of the essential regulators of MuSCs proliferation and stem cell property. Functionally knockdown of ETS1 significantly affects proliferation of MuSCs.

Sustained expression of HeyL is critical for the proliferation of muscle stem cells in overloaded muscle.

In overloaded and regenerating muscle, the generation of new myonuclei depends on muscle satellite cells (MuSCs). Because MuSC behaviors in these two environments have not been considered separately, MuSC behaviors in overloaded muscle remain unexamined. Here, we show that most MuSCs in overloaded muscle, unlike MuSCs in regenerating muscle, proliferate in the absence of MyoD expression. Mechanistically, MuSCs in overloaded muscle sustain the expression of Heyl, a Notch effector gene, to suppress MyoD expression, which allows effective MuSC proliferation on myofibers and beneath the basal lamina. Although Heyl-knockout mice show no impairment in an injury model, in a hypertrophy model, their muscles harbor fewer new MuSC-derived myonuclei due to increased MyoD expression and diminished proliferation, which ultimately causes blunted hypertrophy. Our results show that sustained HeyL expression is critical for MuSC proliferation specifically in overloaded muscle, and thus indicate that the MuSC-proliferation mechanism differs in overloaded and regenerating muscle.

Mechanism of Action and the Effect of Beta-Hydroxy-Beta-Methylbutyrate (HMB) Supplementation on Different Types of Physical Performance - A Systematic Review.

Beta-hydroxy-beta-methylbutyrate (HMB) has been used extensively as a dietary supplement for athletes and physically active people. HMB is a leucine metabolite, which is one of three branched chain amino acids. HMB plays multiple roles in the human body of which most important ones include protein metabolism, insulin activity and skeletal muscle hypertrophy. The ergogenic effects of HMB supplementation are related to the enhancement of sarcolemma integrity, inhibition of protein degradation (ubiquitin pathway), decreased cell apoptosis, increased protein synthesis (mTOR pathway), stimulation of the growth hormone/insulin-like growth factor-1 (GH/IGF-1) axis and enhancement of muscle stem cells proliferation and differentiation. HMB supplementation has been carried out with various groups of athletes. In endurance and martial arts athletes, HMB supplementation revealed positive effects on specific aerobic capacity variables. Positive results were also disclosed in resistance trained athletes, where changes in strength, body fat and muscle mass as well as anaerobic performance and power output were observed. The purpose of this review was to present the main mechanisms of HMB action, especially related to muscle protein synthesis and degradation, and ergogenic effects on different types of sports and physical activities.

Muscle development and regeneration controlled by AUF1-mediated stage-specific degradation of fate-determining checkpoint mRNAs

AUF1 promotes rapid decay of mRNAs containing 3' untranslated region (3'UTR) AU-rich elements (AREs). AUF1 depletion in mice accelerates muscle loss and causes limb girdle muscular dystrophy. Here, we demonstrate that the selective, targeted degradation by AUF1 of key muscle stem cell fate-determining checkpoint mRNAs regulates each stage of muscle development and regeneration by reprogramming each myogenic stage. Skeletal muscle stem (satellite) cell explants show that Auf1 transcription is activated with satellite cell activation by stem cell regulatory factor CTCF. AUF1 then targets checkpoint ARE-mRNAs for degradation, progressively reprogramming the transcriptome through each stage of myogenesis. Transition steps in myogenesis, from stem cell proliferation to differentiation to muscle fiber development, are each controlled by fate-determining checkpoint mRNAs, which, surprisingly, were found to be controlled in their expression by AUF1-targeted mRNA decay. Checkpoint mRNAs targeted by AUF1 include Twist1, decay of which promotes myoblast development; CyclinD1, decay of which blocks myoblast proliferation and initiates differentiation; and RGS5, decay of which activates Sonic Hedgehog (SHH) pathway-mediated differentiation of mature myotubes. AUF1 therefore orchestrates muscle stem cell proliferation, self-renewal, myoblast differentiation, and ultimately formation of muscle fibers through targeted, staged mRNA decay.

Small molecule nicotinamide N-methyltransferase inhibitor activates senescent muscle stem cells and improves regenerative capacity of aged skeletal muscle

Aging is accompanied by progressive declines in skeletal muscle mass and strength and impaired regenerative capacity, predisposing older adults to debilitating age-related muscle deteriorations and severe morbidity. Muscle stem cells (muSCs) that proliferate, differentiate to fusion-competent myoblasts, and facilitate muscle regeneration are increasingly dysfunctional upon aging, impairing muscle recovery after injury. While regulators of muSC activity can offer novel therapeutics to improve recovery and reduce morbidity among aged adults, there are no known muSC regenerative small molecule therapeutics. We recently developed small molecule inhibitors of nicotinamide N-methyltransferase (NNMT), an enzyme overexpressed with aging in skeletal muscles and linked to impairment of the NAD+ salvage pathway, dysregulated sirtuin 1 activity, and increased muSC senescence. We hypothesized that NNMT inhibitor (NNMTi) treatment will rescue age-related deficits in muSC activity to promote superior regeneration post-injury in aging muscle. 24-month old mice were treated with saline (control), and low and high dose NNMTi (5 and 10 mg/kg) for 1-week post-injury, or control and high dose NNMTi for 3-weeks post-injury. All mice underwent an acute muscle injury (barium chloride injection) locally to the tibialis anterior (TA) muscle, and received 5-ethynyl-2′-deoxyuridine systemically to analyze muSC activity. In vivo contractile function measurements were conducted on the injured TA muscle and tissues collected for ex-vivo analyses, including myofiber cross-sectional area (CSA) measurements to assess muscle recovery. Results revealed that muscle stem cell proliferation and subsequent fusion were elevated in NNMTi-treated mice, supporting nearly 2-fold greater CSA and shifts in fiber size distribution to greater proportions of larger sized myofibers and fewer smaller sized fibers in NNMTi-treated mice compared to controls. Prolonged NNMTi treatment post-injury further augmented myofiber regeneration evinced by increasingly larger fiber CSA. Importantly, improved muSC activity translated not only to larger myofibers after injury but also to greater contractile function, with the peak torque of the TA increased by ∼70% in NNMTi-treated mice compared to controls. Similar results were recapitulated in vitro with C2C12 myoblasts, where NNMTi treatment promoted and enhanced myoblast differentiation with supporting changes in the cellular NAD+/NADH redox states. Taken together, these results provide the first clear evidence that NNMT inhibitors constitute a viable pharmacological approach to enhance aged muscle regeneration by rescuing muSC function, supporting the development of NNMTi as novel mechanism-of-action therapeutic to improve skeletal muscle regenerative capacity and functional recovery after musculoskeletal injury in older adults.

Platelet releasate promotes skeletal myogenesis by increasing muscle stem cell commitment to differentiation and accelerates muscle regeneration following acute injury

The use of platelets as biomaterials has gained intense research interest. However, the mechanisms regarding platelet-mediated skeletal myogenesis remain to be established. The aim of this study was to determine the role of platelet releasate in skeletal myogenesis and muscle stem cell fate in vitro and ex vivo respectively. We analysed the effect of platelet releasate on proliferation and differentiation of C2C12 myoblasts by means of cell proliferation assays, immunohistochemistry, gene expression and cell bioenergetics. We expanded in vitro findings on single muscle fibres by determining the effect of platelet releasate on murine skeletal muscle stem cells using protein expression profiles for key myogenic regulatory factors. TRAP6 and collagen used for releasate preparation had a more pronounced effect on myoblast proliferation vs thrombin and sonicated platelets (P<0.05). In addition, platelet concentration positively correlated with myoblast proliferation. Platelet releasate increased myoblast and muscle stem cell proliferation in a dose-dependent manner, which was mitigated by VEGFR and PDGFR inhibition. Inhibition of VEGFR and PDGFR ablated MyoD expression on proliferating muscle stem cells, compromising their commitment to differentiation in muscle fibres (P<0.001). Platelet releasate was detrimental to myoblast fusion and affected differentiation of myoblasts in a temporal manner. Most importantly, we show that platelet releasate promotes skeletal myogenesis through the PDGF/VEGF-Cyclin D1-MyoD-Scrib-Myogenin axis and accelerates skeletal muscle regeneration after acute injury. This study provides novel mechanistic insights on the role of platelet releasate in skeletal myogenesis and set the physiological basis for exploiting platelets as biomaterials in regenerative medicine.

Beneficial effects of whey protein supplementation on muscle metabolism in a mouse model of sepsis

Rationale: Among sepsis survivors, development of an ICU acquired muscle weakness (ICUAMW) is often associated with long-term disability. In healthy subjects, whey protein is known to stimulate the proliferation of muscle stem cells (satellite cells (SC)) and muscle development [1]. The anabolic properties of whey may limit the functional consequences of ICUAMW. The aim of this study is to determine if oral whey supplementation can improve muscle regeneration in a mouse model of sepsis-induced inflammatory response.

Muscle stem cell intramuscular delivery within hyaluronan methylcellulose improves engraftment efficiency and dispersion

Adult skeletal muscle tissue harbors the capacity for self-repair due to the presence of tissue resident muscle stem cells (MuSCs). Advances in the area of prospective MuSC isolation demonstrated the potential of cell transplantation therapy as a regenerative medicine strategy to restore strength and long-term regenerative capacity to aged, injured, or diseased skeletal muscle tissue. However, cell loss during ejection, limits to post-injection proliferation, and poor donor cell dispersion distal to the injection site are amongst hurdles to overcome to maximize MuSC transplant impact. Here, we assess a physical blend of hyaluronan and methylcellulose (HAMC) as a bioactive, shear thinning hydrogel cell delivery system to improve MuSC transplantation efficiency. Using in vivo transplantation studies, we found that the HAMC delivery system results in a >45% increase in the number of donor-derived fibers as compared to saline delivery. We demonstrate that increases in donor-derived fibers when using HAMC are attributed to increased MuSC proliferation via a CD44-independent mechanism, preventing injected cell active clearance, and supporting in vivo expansion by delaying differentiation. Furthermore, we observed a significant improvement in donor fiber dispersion when MuSCs were delivered in HAMC. Our study results suggest that HAMC is a promising muscle stem cell delivery vehicle.

Recovery from impaired muscle growth arises from prolonged postnatal accretion of myonuclei in Atrx mutant mice.

Reduced muscle mass due to pathological development can occur through several mechanisms, including the loss or reduced proliferation of muscle stem cells. Muscle-specific ablation of the α-thalassemia mental retardation syndrome mutant protein, Atrx, in transgenic mice results in animals with a severely reduced muscle mass at three weeks of age; yet this muscle mass reduction resolves by adult age. Here, we explore the cellular mechanism underlying this effect. Analysis of Atrx mutant mice included testing for grip strength and rotorod performance. Muscle fiber length, fiber volume and numbers of myofiber-associated nuclei were determined from individual EDL or soleus myofibers isolated at three, five, or eight weeks. Myofibers from three week old Atrx mutant mice are smaller with fewer myofiber-associated nuclei and reduced volume compared to control animals, despite similar fiber numbers. Nonetheless, the grip strength of Atrx mutant mice was comparable to control mice when adjusted for body weight. Myofiber volume remained smaller at five weeks, becoming comparable to controls by 8 weeks of age. Concomitantly, increased numbers of myofiber-associated nuclei and Ki67+ myoblasts indicated that the recovery of muscle mass likely arises from the prolonged accretion of new myonuclei. This suggests that under disease conditions the muscle satellite stem cell niche can remain in a prolonged active state, allowing for the addition of a minimum number of myonuclei required to achieve a normal muscle size.

APC is required for muscle stem cell proliferation and skeletal muscle tissue repair.

The tumor suppressor adenomatous polyposis coli (APC) is a crucial regulator of many stem cell types. In constantly cycling stem cells of fast turnover tissues, APC loss results in the constitutive activation of a Wnt target gene program that massively increases proliferation and leads to malignant transformation. However, APC function in skeletal muscle, a tissue with a low turnover rate, has never been investigated. Here we show that conditional genetic disruption of APC in adult muscle stem cells results in the abrogation of adult muscle regenerative potential. We demonstrate that APC removal in adult muscle stem cells abolishes cell cycle entry and leads to cell death. By using double knockout strategies, we further prove that this phenotype is attributable to overactivation of β-catenin signaling. Our results demonstrate that in muscle stem cells, APC dampens canonical Wnt signaling to allow cell cycle progression and radically diverge from previous observations concerning stem cells in actively self-renewing tissues.

Abstract 4030: Interactions between co-cultured myoblasts and prostate cancer cells kill myoblasts but promote cancer cell proliferation and fusion: implications for cachexia and metastasis to skeletal muscle

Abstract Severe muscle loss (cachexia) is the major cause for the cancer related death and 70% prostate cancer patients suffer from cachexia. Multinucleated cells of skeletal muscles are generated and regenerated by cell-to-cell fusion. It has been suggested that cell-to-cell fusion also takes place during carcinogenesis and promotes tumor cell diversity, drug resistance and the ability to metastasize. However fusion between cancer cells has remained elusive due to a very low efficiency of this process in earlier studies. Here we explored interactions between cancer cells and muscle environment in vitro. Co-culturing cells of human prostate cancer line (PC3) with primary murine proliferating myoblasts (muscle stem cells) resulted in differentiation and then apoptosis in muscle stem cells. Conditioned medium from PC3 cells also caused 50% decrease in proliferation of muscle stem cells. On the other hand, fusion-committed myoblasts co-cultured with PC3 cells lost their characteristic shapes and went through apoptosis. In addition to these effects of PC3 cells on murine myoblasts, we observed striking effects of myoblasts on PC3 cells. Co-culturing of PC3 cells with either proliferating myoblasts or fusion-committed myoblasts resulted in a robust fusion between cancer cells that yielded PC3 syncytia with up to 5 nuclei. Fusion promotion between PC3 cells was accompanied by a 1.5-fold increase in expression of Annexin A5, a protein recently implicated in myoblast fusion. In contrast, the expression of Annexin A5 in myoblasts was halved. Both co-culturing and using conditioned medium from fusion-committed myoblasts also resulted in a 2-fold increase in cancer cells proliferation and a 3-fold increase in the expression of the phosphorylated protein kinase AKT (pAKT). pAKT activity is associated with proliferation, drug resistance and cancer stem cell phenotype generation. Therefore we examined cancer stem cell marker, CD133 expression in PC3 cells. Treatment with conditioned medium from either proliferating or fusion-committed myoblasts doubled a percentage of CD133-expressing cells. Our results suggest an intriguing interplay between prostate cancer and muscle cells that may contribute to the progression of cancer and potentially explain cachexia. Citation Format: Berna Uygur, Evgenia Leikina, Leonid V. Chernomordik. Interactions between co-cultured myoblasts and prostate cancer cells kill myoblasts but promote cancer cell proliferation and fusion: implications for cachexia and metastasis to skeletal muscle. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 4030. doi:10.1158/1538-7445.AM2015-4030

RNA-Seq analysis of isolated satellite cells in Prmt5 deficient mice.

Satellite cells (SCs) represent a distinct population of stem cells, essential for maintenance, growth and regeneration of adult skeletal muscle. SCs are mononuclear and are located between the basal lamina and the plasma membrane of myofibers. They are typically characterized by presence of the transcription factor paired-box 7 (PAX7) that is widely used as a satellite cell marker. Under normal physiological conditions SCs are quiescent but are activated by insults such as injury, disease or exercise. Once activated, satellite cells proliferate and subsequently differentiate into myoblasts to finally fuse to form new myofibers or with preexisting myofibers to repair or rebuild the skeletal muscle. A minority of SCs retains stem cell characteristics and self-renews to assure future bouts of regeneration throughout most of adult life. While a comprehensive picture of the regulatory events controlling SC fate has not yet been achieved, several factors were recently identified playing important roles in functional processes. One example is the arginine methyltransferase Prmt5 that is known to have multiple roles in germ cells and is involved in the maintenance of ES cell pluripotency. We have previously shown that Prmt5 is required for muscle stem cell proliferation and regenerative myogenesis due to direct epigenetic regulation of the cell cycle inhibitor p21. Here we provide a dataset that investigates the loss of Prmt5 in isolated Pax7+ primary SCs using the Pax7CreERT2/Prmt5loxP/loxP knockout mouse model.RNA-Seq raw and analyzed data have been deposited in GEO under accession code GSE66822.

Intracellular Inactivation of Thyroid Hormone Is a Survival Mechanism for Muscle Stem Cell Proliferation and Lineage Progression

SummaryPrecise control of the thyroid hormone (T3)-dependent transcriptional program is required by multiple cell systems, including muscle stem cells. Deciphering how this is achieved and how the T3 signal is controlled in stem cell niches is essentially unknown. We report that in response to proliferative stimuli such as acute skeletal muscle injury, type 3 deiodinase (D3), the thyroid hormone-inactivating enzyme, is induced in satellite cells where it reduces intracellular thyroid signaling. Satellite cell-specific genetic ablation of dio3 severely impairs skeletal muscle regeneration. This impairment is due to massive satellite cell apoptosis caused by exposure of activated satellite cells to the circulating TH. The execution of this proapoptotic program requires an intact FoxO3/MyoD axis, both genes positively regulated by intracellular TH. Thus, D3 is dynamically exploited in vivo to chronically attenuate TH signaling under basal conditions while also being available to acutely increase gene programs required for satellite cell lineage progression.

Abstract A14: Canonical WNT/β-catenin pathway activation suppresses embryonal rhabdomyosarcoma growth and self-renewal

Abstract Embryonal rhabdomyosarcoma (ERMS) is a common pediatric malignancy of muscle with relapse being the major clinical challenge. Self-renewing tumor-propagating cells (TPCs) drive cancer relapse and are confined to a molecularly definable subset of ERMS cells. To identify drugs that suppress TPC function, a large-scale chemical screen comprising of ~40,000 compounds including 47% FDA-approved drugs was completed, identifying GSK3-inhibitors as potent suppressors of ERMS growth through inducing terminal differentiation of TPCs into myosin-expressing cells. In support of GSK3 inhibitors functioning through activation of the canonical WNT pathway, recombinant WNT3A and a stabilized β-catenin enhanced differentiation and reduced self-renewal in human ERMS cell lines. Moreover, treatment of tumor-bearing zebrafish with a GSK3 inhibitor activated the WNT/β-catenin pathway, resulting in suppressed ERMS growth, depleted TPCs, and diminished self-renewal capacity in vivo. As canonical WNT signaling is essential for transition from muscle stem cell proliferation to myogenic differentiation during regeneration, our findings suggest that the same developmental pathways that regulate muscle stem cell self-renewal also contribute to tumorigenesis in ERMS. GSK3 inhibitors are being assessed for their efficacy in inhibiting growth as well as inducing differentiation of human ERMS in xenograft mouse models. Our work has identified the vital role of canonical WNT pathway in regulating differentiation and self-renewal of ERMS and demonstrated the effective application of small molecule inhibitors to target differentiation of TPCs in ERMS. Citation Format: Eleanor Chen, Michael DeRan, Katherine Brooke Grandinetti, Myron Ignatius, Ryan Clagg, Karin McCarthy, Riadh Lobbardi, Xu Wu, David Langenau. Canonical WNT/β-catenin pathway activation suppresses embryonal rhabdomyosarcoma growth and self-renewal. [abstract]. In: Proceedings of the AACR Special Conference: The Translational Impact of Model Organisms in Cancer; Nov 5-8, 2013; San Diego, CA. Philadelphia (PA): AACR; Mol Cancer Res 2014;12(11 Suppl):Abstract nr A14.

Abstract A67: Canonical WNT/β;-catenin pathway activation suppresses embryonal rhabdomyosarcoma growth and self-renewal

Abstract Embryonal rhabdomyosarcoma (ERMS) is a common pediatric malignancy of muscle with relapse being the major clinical challenge. Self-renewing tumor-propagating cells (TPCs) drive cancer relapse and are confined to a molecularly definable subset of ERMS cells. To identify drugs that suppress TPC function, a large-scale chemical screen comprising of ∼40,000 compounds including 47% FDA-approved drugs was completed, identifying GSK3-inhibitors as potent suppressors of ERMS growth through inducing terminal differentiation of TPCs into myosin-expressing cells. In support of GSK3 inhibitors functioning through activation of the canonical WNT pathway, recombinant WNT3A and a stabilized β-catenin enhanced differentiation and reduced self-renewal in human ERMS cell lines. Moreover, treatment of tumor-bearing zebrafish with a GSK3 inhibitor activated the WNT/β-catenin pathway, resulting in suppressed ERMS growth, depleted TPCs, and diminished self-renewal capacity in vivo. As canonical WNT signaling is essential for transition from muscle stem cell proliferation to myogenic differentiation during regeneration, our findings suggest that the same developmental pathways that regulate muscle stem cell self-renewal also contribute to tumorigenesis in ERMS. GSK3 inhibitors are being assessed for their efficacy in inhibiting growth as well as inducing differentiation of human ERMS in xenograft mouse models. Our work has identified the vital role of canonical WNT pathway in regulating differentiation and self-renewal of ERMS and demonstrated the effective application of small molecule inhibitors to target differentiation of TPCs in ERMS. Citation Format: Eleanor Chen, Michael DeRan, Katherine Brooke Grandinetti, Myron Ignatius, Ryan Clagg, Karin McCarthy, Riadh Lobbardi, Xu Wu, David Langenau. Canonical WNT/β;-catenin pathway activation suppresses embryonal rhabdomyosarcoma growth and self-renewal. [abstract]. In: Proceedings of the AACR Special Conference on Pediatric Cancer at the Crossroads: Translating Discovery into Improved Outcomes; Nov 3-6, 2013; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2013;74(20 Suppl):Abstract nr A67.

The aging muscle stem cell niche as a therapeutic target (79.2)

Impaired muscle strength and regeneration are major problems of aging. We found that skeletal muscle stem cells (MuSCs) from aged mice are two‐thirds less effective in regenerating muscle than young MuSCs, even in a young microenvironment. Culture of aged MuSCs in hydrogel niches in conjunction with a pharmacological inhibitor of p38 mitogen‐activated protein kinase, enhanced MuSC proliferation and decreased the proportion expressing p16Ink4a. The capacity of this population to regenerate damaged muscles was similar to young MuSCs following transplantation into mice, evaluated by non‐invasive imaging, stem‐cell repopulation, and serial transplantation assays. The rejuvenation of the aged muscle stem cell population was attributable to expansion of a functional subpopulation, as revealed by time‐lapse microscopy. Molecular analyses identified a mechanism whereby substrate mechanics contributes to the modulation of MuSC stemness. Notably, strength was restored when the rejuvenated population was delivered to damaged muscles of aged mice. These findings suggest that a localized autologous muscle stem cell therapy post‐injury could benefit aged individuals.

Editorial: The Fall of Mechanogrowth Factor?

Scientists want to learn about the inner workings of the natural world; as biomedical research scientists, our goals are to understand the mechanisms that regulate normal human physiology, to discern how things may go awry in disease, and to devise effective and specific treatments. When a potential new discovery is made that may facilitate achieving these objectives, it is an admittedly natural tendency to favor the supporting information and dismiss confounding or contradictory data. This psychological phenomenon is termed confirmation bias (1) and is implicit in attempts to prove rather than test hypotheses. The saga of the mechanogrowth factor (MGF) is instructive because it illustrates the dangers of confirmation bias. Many hormones and growth factors play critical roles in skeletal muscle growth, maintenance, and repair and in mediating responses to mechanical and other stresses (2–4). For example, IGF-1 functions as an endocrine hormone in promoting overall somatic growth, including skeletal muscle (5), and also acts as a paracrine/autocrine factor in muscle tissue, particularly in response to injury and mechanical strain (6, 7). As befits an agent with multiple distinct physiological actions, IGF-1 is under multifactorial regulation. The two IGF-1 precursor proteins [there are three in humans (8)] represent the translation products of distinct mRNAs that arise from alternative RNA splicing (9). Each contains the same 70-residue mature IGF-1 molecule, which is located at the NH2 terminus and is released by posttranslational proteolytic processing, but differs in the predicted amino acid sequence at the COOH terminus (9). More than 15 years ago, it was noted that soon after muscle injury, the fold increase of one of the minor classes of IGF-1 transcripts was greater than the major mRNA species (absolute transcript levels were not measured) (10, 11). This result and subsequent observations led to formulation of the MGF hypothesis, in which it was postulated that a segment of the COOH-terminal extension peptide encoded by the mRNA that increased most exuberantly and most quickly in injured muscle enhanced repair by promoting proliferation of muscle stem cells (termed satellite cells) (for review, see reference 12). Despite skepticism about the correlative nature of the studies (8), the MGF hypothesis has gained traction in the regenerative medicine field (13, 14). Against this background, a recent report by Fornaro et al (15) stands as a strongly negative challenge to the MGF concept. The authors, representing muscle research groups from three pharmaceutical companies, used synthetic versions of MGF and compared their actions with effects of equimolar concentrations of 70-amino acid mature IGF-1 in human and mouse muscle cells. In key experiments they showed that added IGF-1 was able to promote proliferation of the C2C12 muscle cell line and human myoblasts and mouse satellite cells in primary culture but that human or mouse MGF was not (15). The latter two cell types also were able to proliferate after exposure to a 110-amino acid human IGF-I precursor protein that contained the 24-residue MGF peptide (15). The authors' interpretation of their results was that IGF-I was biologically active but that MGF on its own, even when modified to enhance its half-life (16), was inert. What can we learn from these admittedly negative data and from the entire MGF story? First, as scientists we must fight against confirmation bias. In the case of MGF, it appears that confirmation bias was evident in the initial idea that correlation (increase in mRNA levels after muscle injury) was equivalent to causation (biological effects of endogenous MGF peptide on satellite cell proliferation) when this had not been established. Second, independently performed follow-up studies are critically needed to confirm or refute novel observations and the resultant hypotheses, and the scientific literature needs to provide a forum for publication of such studies. And third, as acknowledged by the title of this editorial, the last word about MGF has not been written yet. We should maintain an open mind and a healthy skepticism about the possibility that a peptide exists with the postulated biological properties of MGF and as a scientific community demand experiments that critically and objectively test the MGF hypothesis.

β-Hydroxy-β-methylbutyrate (HMB) enhances the proliferation of satellite cells in fast muscles of aged rats during recovery from disuse atrophy

Loss of myonuclei by apoptosis is thought to contribute to sarcopenia. We have previously shown, that the leucine metabolite, β-hydroxy-β-methylbutyrate (HMB) suppresses apoptotic signaling and the apoptotic index (the ratio of apoptotic positive to apoptotic negative myonuclei) during muscle disuse and during reloading periods after disuse in aged rats. However, it was not clear if the apoptotic signaling indexes were due only to preservation of myonuclei or if perhaps the total myogenic pool increased as a result of HMB-mediated satellite cell proliferation as this would have also reduced the apoptotic index. In this study, we tested the hypothesis that HMB would augment myogenic cells (satellite cells) proliferation during muscle recovery (growth) after a period of disuse in senescent animals. The hindlimb muscles of 34month old Fisher 344×Brown Norway rats were unloaded for 14days by hindlimb suspension (HLS), and then reloaded for 14days. The rats received either Ca-HMB (340mg/kg body weight; n=16), or the vehicle (n=10) by gavage throughout the experimental period. HMB prevented the functional decline in maximal plantar flexion isometric force production during the reloading period, but not during HLS. HMB-treatment enhanced the proliferation of muscle stem cells as shown by a greater percentage of satellite cells that had proliferated (more BrdU positive, Pax-7 positive, and more Pax7/Ki67 positive nuclei) and as a result, more differentiated stem cells were present (more MyoD/myogenin positive myonuclei), relative to total myonuclei, in reloaded plantaris muscles as compared to reloaded muscles from vehicle-treated animals. Furthermore HMB increased the nuclear protein abundance of proliferation markers, inhibitor of differentiation-2 and cyclin A, as compared to vehicle treatment in reloaded muscles. Although HMB increased phosphorylated Akt during reloading, other mTOR related proteins were not altered by HMB treatment. These data show that HMB improved the proliferation of muscle stem cells in fast twitch plantaris muscles. Enhanced satellite cell proliferation leading to increased differentiated myonuclei should increase the transcriptional potential to support muscle hypertrophic changes and functional changes in sarcopenic muscles, and this could partly explain the reduced apoptotic index in HMB treated muscles. Indeed, muscle mass and fiber cross-sectional area were significantly greater in plantaris muscles from HMB-treated animal muscles after reloading as compared to vehicle-treated animals.