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Key Event Title
Decrease, Steroidogenic acute regulatory protein (STAR)
|Level of Biological Organization|
|steroid hormone secreting cell|
Key Event Components
Key Event Overview
AOPs Including This Key Event
Key Event Description
Steroidogenic acute regulatory protein (StAR) functions as a cholesterol transfer protein and acts directly on lipids of the outer mitochondrial membrane to promote cholesterol translocation (Stocco 2001). Reduction of the protein impacts on the amount of substrate available for steroidogenesis.
StAR is expressed principally in steroidogenic tissues (Bauer et al. 2000).
General role in biology
StAR is required for cholesterol shuttling across the mitochondrial membrane and appears to regulate acute steroid production (Clark and Stocco, 1997). Transcriptional or translational inhibition of StAR expression results in a dramatic decrease in steroid biosynthesis, whereas ~10–15% of steroid synthesis appears to be mediated through StAR-independent mechanisms (Manna et al. 2001) (Clark and Stocco, 1997). In contrast, chronically regulated steroid production appears to be largely mediated by increased transcription of steroidogenic enzymes (Hum and Miller 1993).
How It Is Measured or Detected
The StAR expression can be measured by RT-PCR (mRNA) and on the protein level (western blot). The StAR expression as well as other steroidogenic proteins can be measured in vitro cultured Leydig cells. The methods for culturing Leydig cells can be found in the Database Service on Alternative Methods to animal experimentation (DB-ALM): Leydig Cell-enriched Cultures  Testicular Organ and Tissue Culture Systems .
Domain of Applicability
StAR has been cloned from many species, and is highly conserved among mammals, birds, amphibians and fish (Bauer et al. 2000).
Bauer, M P, J T Bridgham, D M Langenau, A L Johnson, and F W Goetz. 2000. “Conservation of Steroidogenic Acute Regulatory (StAR) Protein Structure and Expression in Vertebrates.” Molecular and Cellular Endocrinology 168 (1-2) (October 25): 119–25.
Hum, D W, and W L Miller. 1993. “Transcriptional Regulation of Human Genes for Steroidogenic Enzymes.” Clinical Chemistry 39 (2) (February): 333–40.
Manna, P R, J Kero, M Tena-Sempere, P Pakarinen, D M Stocco, and I T Huhtaniemi. 2001. “Assessment of Mechanisms of Thyroid Hormone Action in Mouse Leydig Cells: Regulation of the Steroidogenic Acute Regulatory Protein, Steroidogenesis, and Luteinizing Hormone Receptor Function.” Endocrinology 142 (1) (January): 319–31. doi:10.1210/endo.142.1.7900.
Stocco, D M. 2001. “StAR Protein and the Regulation of Steroid Hormone Biosynthesis.” Annual Review of Physiology 63 (January): 193–213. doi:10.1146/annurev.physiol.63.1.193.