Microgenomic Analysis in Skeletal Muscle: Expression Signatures of Individual Fast and Slow Myofibers

Skeletal muscle is comprised of heterogeneous muscle fibers that differ in their physiological and metabolic parameters. It is this diversity that enables different muscle groups to provide a variety of functional properties. In response to environmental demands, skeletal muscle remodels by activating signaling pathways to reprogram gene expression to sustain muscle performance. Studies have been performed using exercise, electrical stimulation, transgenic animal models, disease states, and microgravity to show genetic alterations and transitions of muscle fibers in response to functional demands. Various components of calcium-dependent signaling pathways and multiple transcription factors, coactivators and corepressors have been shown to be involved in skeletal muscle remodeling. Understanding the mechanisms involved in modulating skeletal muscle phenotypes can potentiate the development of new therapeutic measures to ameliorate muscular diseases.

Cellular heterogeneity that arises from stochastic expression of genes, proteins and metabolites is a fundamental principle of cell biology, but single cell analysis has been beyond the capability of 'omics' technology. This is rapidly changing with the recent examples of single cell genomics, transcriptomics, proteomics and metabolomics. The rate of change is expected to accelerate owing to emerging technologies that range from micro/nanofluidics to microfabricated interfaces for mass spectrometry to third- and fourth-generation automated DNA sequencers. As described in this review, single cell analysis is the new frontier in omics, and single cell omics has the potential to transform systems biology through new discoveries derived from cellular heterogeneity.

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.