Myostatin and regulation of skeletal muscle
While many of the studies demonstrate that myostatin is involved with prenatal muscle growth, we know little of its association with muscle regeneration. Muscle regeneration of injured skeletal muscle tissue is a complex system and ability for regeneration changes during an animal's lifetime. Exposure of tissues to various growth factors is altered during a lifetime. In embryos and young animals, hormones and growth factors favor muscle growth. However, many of these factors are downregulated in adults. Alteration in growth factors inside and outside of the muscle cells may diminish their capacity to maintain protein expression. Although protein mRNA may be detected within the cell, there are many sites of protein regulation beyond mRNA levels. As mentioned above, myostatin protein occurs in an unprocessed (inactive) and processed (active) form. Therefore, bioactivity of myostatin may be regulated at any point of its synthesis and secretion.
Keep in mind that nearly all regulatory systems in the body are under positive and negative control. This includes cardiac and skeletal muscle tissues. Myoblasts in developing animal embryos respond to different signals that control proliferation and cell migration. In contrast, differentiated muscle cells respond to another set of different signals. Distinct ratios of signals regulate the transition from undetermined cells to differentiated cells and ensure normal formation and differentiation in cellular tissues. However, many of the factors that regulate the various development pathways in muscle tissue are still poorly understood.
MyoD, IGF-I and myogenin (growth promoters in muscle cells) gene products are associated with muscle cell differentiation and activation of muscle-specific gene expression (14). Muscle-regulatory factor-4 (MRF-4) mRNA expression increases after birth and is the dominant factor in adult muscle. This growth factor is thought to play an important role in the maintenance of muscle cells. In addition to myostatin, there are other inhibitory gene products, such as Id (inhibitor of DNA binding). Although in vitro experiments are revealing the mechanisms of these specific proteins, we know less regarding their roles in vivo.
Although we know that lack of myostatin protein is associated with skeletal muscle hypertrophy in McPherron's gene knockout mice and in double-muscled cattle, we know little about the physiological expression of myostatin in normal skeletal muscle. Recent studies in animal and human models indicate a paradox in myostatin's role on growth of muscle tissue.
For example, evidence shows that myostatin may be fiber-type specific. Runt piglets, which have lower birth weights than their normal littermates, had lower proportions of Type I skeletal muscle fibers in specific muscles (12). Similar observations were made in rats where undetectable levels of myostatin mRNA in atrophied mice soleus (Type I fibers) (13). Transient upregulation of myostatin mRNA was detected in atrophied fast twitch muscles but not in slow twitch muscles. Thus, myostatin may modulate gene expression controlling muscle fiber type.
Studies also demonstrated lack of metabolic effects on myostatin expression in piglets and mice (12, 13). Food restriction in both piglets and mice did not affect myostatin mRNA levels in skeletal muscle. Neither dietary polyunsaturated fatty acids nor exogenous growth hormone administration in growing piglets altered myostatin expression (12). These and other studies strongly suggest that the physiological role of myostatin is mostly associated with prenatal muscle growth where myoblasts are proliferating, differentiating and fusing to form muscle fibers.
Although authors postulate that myostatin exerts its effect in an autocrine/paracrine fashion, serum myostatin has been detected demonstrating that it is also secreted into the circulation (8, 4). It is believed that the protein detected in human serum is of processed (active form) myostatin rather than the unprocessed form. High levels of this protein have been associated with muscle wasting in HIV-infected men compared to healthy normal men (4). However, this association does not necessarily verify that myostatin directly contributes to muscle wasting. We do not know if myostatin acts directly on muscle or on other regulatory systems that regulate muscle growth. Although several authors postulate that myostatin may present a larger role in muscle regeneration after injury, this has yet to be confirmed.
Myostatin and athletes
Further complicating the issue of myostatin’s role in regulation of muscle growth is the report by a team of scientists that mutations in the human myostatin gene had little impact on responses in muscle mass to strength training (15, unpublished data). Based on the report that muscle size is a heritable trait in humans (16), Ferrell and colleagues investigated the variations in the human myostatin gene sequence. They also examined the influence of myostatin variations in response of muscle mass to strength training.
Study subjects represented various ethnic groups and were classified by the degree of muscle mass increases they experienced after strength training. Included were competitive bodybuilders ranking in the top 10 world-wide and in lower ranks. Also included were football players, powerlifters and previously untrained subjects. Quadricep muscle volume of all subjects was measured by magnetic resonance imaging before and after nine weeks of heavy weight training of the knee extensors. Subjects were grouped and compared by degree of response and by ethnicity.
There were several genetic coding sequence variations detected in DNA samples from subjects. Two changes were detected in a single subject and another two were observed in two other individuals. They were heterozygous with the wild-type allele, meaning they had one allele with the mutation and the other allele was normal. The other variations were present in the general population of subjects and determined common. One of the variations was common in the group of mixed Caucasian and African-American subjects. However, the less frequent allele had a higher frequency in African-Americans. Although, as the authors comment, "these variable sites [in the gene sequence] have the potential to alter the function of the myostatin gene product and alter nutrient partitioning in individuals heterozygous for the variant allele", the data from this and other studies so far show that this may not occur. This study did not demonstrate any significant response between genotypes and response to weight training. Nor were there any significant differences between African-American responders to strength training and non-responders or between Caucasian responders and non-responders.
Further research will be necessary to determine whether myostatin has an active role in muscle growth after birth and in adult tissues. To ascertain benefit to human health, we also need to discover its role in muscle atrophy and regeneration after injury. Only extended research will reveal any such benefits.
The future of myostatin
Now that we have reviewed some of the biology of the myostatin protein, its gene, and the relevant scientific literature, what are the implications for its application?
Many authors of the myostatin studies have speculated that interfering with the activity of myostatin in humans may reverse muscle wasting disease associated with muscular dystrophy, AIDS and cancer. Some predict that manipulation of this gene could produce heavily muscled food animals. Indeed, current research is underway to investigate and develop these potentialities. Sure enough, a large pharmaceutical company has recently applied for a patent on an antibody vaccination for the myostatin protein.
A medical doctor and author of weight training articles asserts that overexpression of myostatin is to blame for weight lifters that have trouble gaining muscle mass. The spokesperson for a supplement and testing lab erroneously implied that the "rarest" form of mutation in the myostatin gene is responsible for a top competitive bodybuilder's massive muscle gains, not taking into account the performance-enhancement substances the bodybuilder may be using. The public media has, of course, predicted that "steroid-popping" athletes will take advantage of myostatin inhibitors to gain competitive edge (3).
Many of these assertions are unfounded or they misrepresent the science. Granted, the possibility exists that manipulation of the myostatin gene in humans may be a key to reversing muscle-wasting conditions. However, too little is still yet unknown regarding myostatin's role in muscle growth regulation. It is imperative that research demonstrates that the loss of myostatin activity in adults can cause muscle tissue growth. Likewise, research must also prove that overexpression or administration of myostatin causes loss of muscle mass. Also important is to know if manipulation of myostatin will interfere with other growth systems, especially in other tissues, and result in abnormal pathologies. Although McPherron's gene knockout mice did not experience any other gross abnormalities, mice are not humans.
We do not fully understand the roles of myostatin in exercise-induced muscle hypertrophy or regeneration following muscle injury. Until we do, it may be premature to blame the lack of hypertrophy in weightlifters on overexpression of myostatin. Nor does the research support the claim that a top bodybuilder's muscle mass gains are resultant of a detected mutation in the myostatin gene. The research simply does not advocate blaming genetic myostatin variations as a source of significant differences in human phenotypes.
Considering the history of the athlete's propensity, in the public eye, to abuse performance-enhancement substances, the media's prediction of myostatin-inhibitor may or may not be warranted. We all know that today's athletic arena demands gaining the competitive edge to maintain top level competition. For many athletes, that is accomplished by supplementing hard training with substances that enhance growth or performance. Whether or not myostatin inhibitors will be added to the arsenal of substances is difficult to predict. Until science reveals the full nature of this growth factor and its role in the complex regulation of muscle tissue, and researchers determine its therapeutic implications, we can only surmise. Despite attempts to tightly control any pharmaceutical uses of myostatin protein manipulation, they will likely surface at some point in the black market world of bodybuilding supplements. Let us hope that science has determined the side effects and the benefits by that point.
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