Identification of a Novel Modulator of Thyroid Hormone Receptor-Mediated Action

Thyroid hormones (THs) play critical roles in the differentiation, growth, metabolism, and physiological function of virtually all tissues. TH binds to receptors that are ligand-regulatable transcription factors belonging to the nuclear hormone receptor superfamily. Tremendous progress has been made recently in our understanding of the molecular mechanisms that underlie TH action. In this review, we present the major advances in our knowledge of the molecular mechanisms of TH action and their implications for TH action in specific tissues, resistance to thyroid hormone syndrome, and genetically engineered mouse models.

Myofibrillar proteins exist as multiple isoforms that derive from multigene (isogene) families. Additional isoforms, including products of tropomyosin, myosin light chain 1 fast, troponin T, titin, and nebulin genes, can be generated from the same gene through alternative splicing or use of alternative promoters. Myofibrillar protein isogenes are differentially expressed in various muscle types and fiber types but can be coexpressed within the same fiber. Isogenes are regulated by transcriptional and posttranscriptional mechanisms; however, specific regulatory sequences and transcriptional factors have not yet been identified. The pattern of isogene expression varies during muscle development in relation to the different origin of myogenic cells and primary/secondary fiber generations and is affected by neural and hormonal influences. The variable expression of myofibrillar protein isoforms is a major determinant of the contractile properties of skeletal muscle fibers. The diversity among isomyosins is related to the differences in the parameters of chemomechanical transduction as ATP hydrolysis rate and shortening velocity. Troponin and tropomyosin isoforms determine the variable sensitivity to calcium, whereas titin isoforms dictate the elastic properties of muscle fibers at rest. Both myosin and troponin isoforms contribute to the differences in the resistance to fatigue of muscle fibers.

It is very clear that the GH-IGF axis plays a major role in controlling the growth and differentiation of skeletal muscles, as it does virtually all of the tissues in the animal body. One aspect of this control is unquestioned: circulating GH acts on the liver to stimulate expression of the IGF-I and IGFBP3 genes, substantially increasing the levels of these proteins in the circulation. It also seems that GH stimulates expression of IGF-I genes in skeletal muscle, although there are a number of cases in which skeletal muscle IGF-I expression is elevated in the absence of GH. It is substantially less clear that GH acts directly on skeletal muscle to stimulate its growth; the presence of GH receptor mRNA in skeletal muscle is well established, but most investigators have been unsuccessful in demonstrating any specific binding of GH to skeletal muscle or to myoblasts in culture. It has been equally difficult to show direct actions of GH on cultured muscle cells; the only positive report concludes that the early insulin-like effects of GH can result from direct interactions between GH and isolated muscle cells. The effects of the IGFs on skeletal muscle are much clearer. It is well established by studies in a number of laboratories on a variety of systems that IGFs stimulate many anabolic responses in myoblasts, as they do in other cell types. IGFs have the unusual property of stimulating both proliferation and differentiation of myoblasts, responses that are generally believed to be mutually exclusive; in myoblasts, they are in fact temporally separated. The stimulation of differentiation by IGF-I is (at least in part) a result of substantially increased levels of the mRNA for myogenin, the member of the MyoD family most directly associated with terminal myogenesis. As levels of myogenin mRNA rise, those of myf-5 mRNA (the only other member of the MyoD family expressed significantly in L6 myoblasts) fall dramatically, although myf-5 expression is required for the initial elevation of myogenin. The effects of IGFs are significantly modulated by IGFBPs secreted by myoblasts in serum-free medium, inhibitory IG-FBPs-4 and -6 are expressed and secreted by L6A1 myoblasts, while expression of IGFBP-5 rises dramatically as differentiation proceeds. Other myoblasts also secrete IGFBP-2. Even if exogenous IGFs are not added to the low-serum "differentiation" medium, myoblasts express sufficient amounts of autocrine IGF-II to stimulate myogenesis after a period of time; some myogenic cell lines, (such as Sol 8) are so active in expressing the IGF-II gene that it is not possible to demonstrate effects of exogenous IGFs. This autocrine expression of IGFs is by no means unique to skeletal muscle cells; indeed, it is so widely seen in cells responding to mitogenic stimuli that we suggest that IGFs can be viewed as extracellular second messengers that mediate most, if not all, such actions of agents that stimulate cell proliferation. The component of serum that suppresses IGF-II gene expression under "growth" conditions appears to be the IGFs themselves, which exhibit a very high potency in the feedback inhibition of IGF-II expression. In addition, IGFs have effects on the expression of other genes related to differentiation. Treatment of L6A1 cell with IGFs suppresses their expression of the myogenesis-inhibiting TGF beta s with a time course consistent with an initial proliferative step followed by differentiation, i.e. expression is first increased and then very substantially decreased. It is not established that this plays a role in control of differentiation, but experiments with FGF antisense constructs suggests that this may well be the case. Until recently, IGFs were the only circulating agents known to stimulate myoblast differentiation, in contrast to the relatively large number of growth factors that inhibit the process. It is now clear that thyroid hormones and RA also stimulate myogenesis, and that IL-15 enhances the stimulatory eff