needs to be transferred from the outer mitochondrial membrane to the inner membrane where cytochromeP450sccenzyme cleaves the cholesterol side chain, which is the first enzymatic step in all steroid synthesis. The aqueous phase between these two membranes cannot be crossed by the lipophilic cholesterol, unless certain proteins assist in this process. A number of proteins have historically been proposed to facilitate this transfer including: sterol carrier protein 2, steroidogenic activator polypeptide, peripheral benzodiazepine receptor, and StAR. It is now clear that this process is primarily mediated by the action of StAR. The mechanism by which StAR causes cholesterol movement remains unclear as it appears to act from the outside of the mitochondria and its entry into the mitochondria ends its function. Various hypotheses have been advanced. Some involve StAR transferring cholesterol itself like a shuttle. While StAR may bind cholesterol itself, the exorbitant number of cholesterol molecules that the protein transfers would indicate that it would have to act as a cholesterol channel instead of a shuttle. Another notion is that it causes cholesterol to be kicked out of the outer membrane to the inner. StAR may also promote the formation of contact sites between the outer and inner mitochondrial membranes to allow cholesterol influx. Another suggests that StAR acts in conjunction with PBR, causing the movement of Cl− out of the mitochondria to facilitate contact site formation. However, evidence for an interaction between StAR and PBR remains elusive.
Structure
In humans, the gene for StAR is located on chromosome 8p11.2 and the protein has 285 amino acids. The signal sequence of StAR that targets it to the mitochondria is clipped off in two steps with import into the mitochondria. Phosphorylation at the serine at position 195 increases its activity. The domain of StAR important for promoting cholesterol transfer is the StAR-related transfer domain. StAR is the prototypic member of the START domain family of proteins and is thus also known as STARD1 for "START domain-containing protein 1". It is hypothesized that the START domain forms a pocket in StAR that binds single cholesterol molecules for delivery to P450scc. The closest homolog to StAR is MLN64. Together they comprise the StarD1/D3 subfamily of START domain-containing proteins.
Production
StAR is a mitochondrial protein that is rapidly synthesized in response to stimulation of the cell to produce steroid. Hormones that stimulate its production depend on the cell type and include luteinizing hormone, ACTH and angiotensin II. At the cellular level, StAR is synthesized typically in response to activation of the cAMPsecond messenger system, although other systems can be involved even independently of cAMP. StAR has thus far been found in all tissues that can produce steroids, including the adrenal cortex, the gonads, the brain and the nonhuman placenta. One known exception is the human placenta. Substances that suppress StAR activity, like those listed below, can cause endocrine disrupting effects, including altered steroid hormone levels and fertility.
s in the gene for StAR cause lipoid congenital adrenal hyperplasia, in which patients produce little steroid and can die shortly after birth. Mutations that less severely affect the function of StAR result in nonclassic lipoid CAH or familial glucocorticoid deficiencytype 3. All known mutations disrupt StAR function by altering its START domain. In the case of StAR mutation, the phenotype does not present until birth since human placental steroidogenesis is independent of StAR. At the cellular level, the lack of StAR results in a pathologic accumulation of lipid within cells, especially noticeable in the adrenal cortex as seen in the mouse model. The testes are undescended and the resident steroidogenic Leydig cells are modestly affected. Early in life, the ovary is spared as it does not express StAR until puberty. After puberty, lipid accumulations and hallmarks of ovarian failure are noted.
StAR-Independent Steroidogenesis
While loss of functional StAR in the human and the mouse catastrophically reduces steroid production, it does not eliminate all of it, indicating the existence of StAR-independent pathways for steroid generation. Aside from the human placenta, these pathways are considered minor for endocrine production. It is unclear what factors catalyze StAR-independent steroidogenesis. Candidates include oxysterols which can be freely converted to steroid and the ubiquitous MLN64.
New Roles for StAR
Recent findings suggest that StAR may also traffic cholesterol to a second mitochondrial enzyme, sterol 27-hydroxylase. This enzyme converts cholesterol to 27-hydroxycholesterol. In this way it may be important for the first step in one of the two pathways for the production of bile acids by the liver. Evidence also shows that the presence of StAR in a type of immune cell, the macrophage, where it can stimulate the production of 27-hydroxycholesterol. In this case, 27-hydroxycholesterol may by itself be helpful against the production of inflammatory factors associated with cardiovascular disease. It is important to note that no study has yet found a link between the loss of StAR and problems in bile acid production or increased risk for cardiovascular disease. Recently StAR was found to be expressed in cardiac fibroblasts in response to ischemic injury due to myocardial infarction. In these cells it has no apparent de novo steroidogenic activity, as evidenced by the lack of the key steroidogenic enzymescytochrome P450 side chain cleavage and 3 beta hydroxysteroid dehydrogenase. StAR was found to have an anti-apoptotic effect on the fibroblasts, which may allow them to survive the initial stress of the infarct, differentiate and function in tissue repair at the infarction site.
History
The StAR protein was first identified, characterized and named by Dr. Douglas Stocco at Texas Tech University Health Sciences Center in 1994. The role of this protein in lipoid CAH was confirmed the following year in collaboration with Dr. Walter Miller at the University of California, San Francisco. All of this work follows the initial observations of the appearance of this protein and its phosphorylated form coincident with factors that caused steroid production by Dr. Nanette Orme-Johnson while at Tufts University.