Androgen Receptor in Human Skeletal Muscle and Cultured Muscle Satellite Cells: Up-Regulation by Androgen Treatment

doi:10.1210/jc.2004-0084

Androgen Receptor in Human Skeletal Muscle and Cultured Muscle Satellite Cells: Up-Regulation by Androgen Treatment

Indrani Sinha-Hikim, Wayne E. Taylor, Nestor F. Gonzalez-Cadavid, Wei Zheng and Shalender Bhasin

Division of Endocrinology, Metabolism, and Molecular Medicine, Charles R. Drew University of Medicine and Science, Los Angeles, California 90059

Address all correspondence and requests for reprints to: Shalender Bhasin, M.D., Charles R. Drew University of Medicine and Science, 1731 East 120th Street, Los Angeles, California 90059. E-mail: sbhasin{at}ucla.edu.

Androgens stimulate myogenesis, but we do not know what celltypes within human skeletal muscle express the androgen receptor(AR) protein and are the target of androgen action. Becausetestosterone promotes the commitment of pluripotent, mesenchymalcells into myogenic lineage, we hypothesized that AR would beexpressed in mesenchymal precursor cells in the skeletal muscle.AR expression was evaluated by immunohistochemical staining,confocal immunofluorescence, and immunoelectron microscopy insections of vastus lateralis from healthy men before and aftertreatment with a supraphysiological dose of testosterone enanthate.Satellite cell cultures from human skeletal muscle were alsotested for AR expression. AR protein was expressed predominantlyin satellite cells, identified by their location outside sarcolemmaand inside basal lamina, and by CD34 and C-met staining. Manymyonuclei in muscle fibers also demonstrated AR immunostaining.Additionally, CD34+ stem cells in the interstitium, fibroblasts,and mast cells expressed AR immunoreactivity. AR expressionwas also observed in vascular endothelial and smooth musclecells. Immunoelectron microscopy revealed aggregation of immunogoldparticles in nucleoli of satellite cells and myonuclei; testosteronetreatment increased nucleolar AR density. In enriched culturesof human satellite cells, more than 95% of cells stained forCD34 and C-met, confirming their identity as satellite cells,and expressed AR protein. AR mRNA and protein expression insatellite cell cultures was confirmed by RT-PCR, reverse transcriptionand real-time PCR, sequencing of RT-PCR product, and Westernblot analysis. Incubation of satellite cell cultures with supraphysiologicaltestosterone and dihydrotestosterone concentrations (100 nMtestosterone and 30 nM dihydrotestosterone) modestly increasedAR protein levels. We conclude that AR is expressed in severalcell types in human skeletal muscle, including satellite cells,fibroblasts, CD34+ precursor cells, vascular endothelial, smoothmuscle cells, and mast cells. Satellite cells are the predominantsite of AR expression. These observations support the hypothesisthat androgens increase muscle mass in part by acting on severalcell types to regulate the differentiation of mesenchymal precursorcells in the skeletal muscle.

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