Mammalian CNS contains a disproportionally large and remarkably stable pool of cholesterol. Despite an efficient recycling there is some requirement for elimination of brain cholesterol. Conversion of cholesterol into 24S-hydroxycholesterol by the cholesterol 24-hydroxylase (CYP46A1) is the quantitatively most important mechanism. Based on the protein expression and plasma levels of 24S-hydroxycholesterol, CYP46A1 activity appears to be highly stable in adults. Here we have made a structural and functional characterization of the promoter of the human CYP46A1 gene. No canonical TATA or CAAT boxes were found in the promoter region. Moreover this region had a high GC content, a feature often found in genes considered to have a largely housekeeping function. A broad spectrum of regulatory axes using a variety of promoter constructs did not result in a significant transcriptional regulation. Oxidative stress caused a significant increase in transcriptional activity. The possibility of a substrate-dependent transcriptional regulation was explored in vivo in a sterol-deficient mouse model (Dhcr24 null) in which almost all cholesterol had been replaced with desmosterol, which is not a substrate for CYP46A1. Compared with heterozygous littermates there was no statistically significant difference in the mRNA levels of Cyp46a1. During the first 2 weeks of life in the wild-type mouse, however, a significant increase of Cyp46a1 mRNA levels was found, in parallel with an increase in 24S-hydroxycholesterol level and a reduction of cholesterol synthesis. The failure to demonstrate a significant transcriptional regulation under most conditions is discussed in relation to the turnover of brain and neuronal cholesterol.Although the brain is the most cholesterol-rich organ in the body, relatively little is known about the mechanisms by which it maintains steady-state cholesterol levels (1, 2). This is in marked contrast to the situation in virtually every other tissue or organ. One finding that has been consistently confirmed is that, due to the efficiency of the bloodbrain barrier, the brain is unable to take up cholesterol from the circulation and relies on de novo synthesis to meet its substantial cholesterol requirements. However, the rate of cholesterol synthesis in the adult brain is very low, and the bulk of brain cholesterol has a half-life that is at least 100 times longer than that of cholesterol in most other organs (3).One consequence of this "uncoupling" of brain and whole body cholesterol homeostasis has been the evolution of specific mechanisms for maintenance of cerebral cholesterol levels. Two mechanisms for removal of brain cholesterol are currently recognized (1). The first is analogous to classic "reverse cholesterol transport" and is mediated by a flux of cholesterol present in apolipoprotein E containing lipoproteins through cerebrospinal fluid into the circulation (4, 5). In adults, this mechanism is believed to be responsible for elimination of 1-2 mg of cholesterol per 24 h. The details of this particular ...
In the absence of RTP801 expression, development of retinopathy in the mouse model of ROP was significantly attenuated, thus implying an important role of RTP801 in the pathogenesis of ROP.
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