Characterization of Zinc Finger Protein 593 (Zfp593) in Skeletal Muscle

Skeletal muscle atrophy is a debilitating medical condition which can arise due to aging, cancer, corticosteroid use, and denervation. In order to better characterize the molecular genetic events of neurogenic atrophy, the gastrocnemius muscle was isolated from mice following 3 days and 14 days of sciatic nerve denervation. The gene expression profile in the denervated muscle tissue was then analyzed by microarray and compared to control muscle tissue in order to identify novel neurogenic atrophy‐induced genes. The microarray data revealed for the first time that zinc finger protein 593 (Zfp593) is expressed in skeletal muscle and is significantly induced in response to denervation. Furthermore, Western blot analysis confirmed that Zfp593 is expressed at the protein level in C 2 C 12 mouse muscle cells. In order to characterize the transcriptional regulation of Zfp593, fragments of the proximal promoter located immediately upstream from the start of transcription were cloned and fused to a reporter gene. The reporter plasmids were then transfected into C 2 C 12 mouse muscle cells alone or in combination with MyoD1 or myogenin expression plasmids, resulting in a differential effect on reporter activity. Furthermore, analysis of the promoter region of Zfp593 has revealed four conserved E‐box elements, which are known myogenic regulatory factor (MRF) binding sites. Zfp593 is predicted to possess a zinc finger domain and is believed to function as a transcription factor. Furthermore, two predicted putative nuclear localization signal sequences have been identified in the Zfp593 protein sequence, further suggesting that this protein is localized to the nucleus. Therefore, in order to determine the sub‐cellular localization of Zfp593 in muscle cells, the Zfp593 cDNA was isolated from C 2 C 12 cells, cloned into a green fluorescent protein (GFP) expression plasmid and transfected into proliferating C 2 C 12 cells. Transfected cells were visualized by confocal microscopy revealing that Zfp593 is localized to the nucleus of proliferating myoblasts. The discovery that Zfp593 is expressed in skeletal muscle combined with the observation that this gene, a potential modulator of gene expression itself, is induced in response to neurogenic atrophy helps further our understanding of the molecular genetic events of skeletal muscle wasting. Support or Funding Information The work was supported by University of North Florida Transformational Learning grants to D.W.