Adrenocortical lipid depletion gene (ald) in AKR mice is associated with an acyl-CoA:cholesterol acyltransferase (ACAT) mutation.

ald, a recessive allele in AKR inbred mice, is responsible for complete adrenocortical lipid depletion in postpubertal males, which appears to be androgen dependent. Two recent observations (adrenocortical lipid depletion in acyl-CoA:cholesterol acyltransferase-deficient (Acact-/-) mice and the mapping of Acact to a region of chromosome 1 containing the ald locus) prompted us to ask whether adrenocortical lipid depletion in AKR mice results from an Acact mutation. Refined genetic mapping of Acact and ald was consistent with colocalization of these loci. Crossing Acact-/- with AKR (ald/ald) mice yielded postpubertal male offspring characterized by adrenocortical lipid depletion, indicating that these loci are not complementational and are therefore allelic. Immunoblotting of preputial gland homogenates demonstrated that AKR mice had an ACAT protein with a lower molecular mass than other mouse strains. Analysis of Acact cDNA from AKR mice revealed a deletion of the first coding exon and two missense mutations. Despite these coding sequence differences, the ACAT protein from the ald allele catalyzed cholesterol esterification activity at levels similar to that of wild-type protein. We speculate that the adrenocortical lipid depletion resulting from the ald mutation is caused by an altered susceptibility of the mutant protein to modifying factors, such as androgen production at puberty, in an as yet undetermined manner.

Disruption of the acyl-CoA:cholesterol acyltransferase gene in mice: evidence suggesting multiple cholesterol esterification enzymes in mammals.

The microsomal enzyme acyl-CoA:cholesterol acyltransferase (ACAT; EC 2.3.1.26) catalyzes the esterification of cellular cholesterol with fatty acids to form cholesterol esters. ACAT activity is found in many tissues, including macrophages, the adrenal glands, and the liver. In macrophages, ACAT is thought to participate in foam cell formation and thereby to contribute to atherosclerotic lesion development. Disruption of the gene for ACAT (Acact) in mice resulted in decreased cholesterol esterification in ACAT-deficient fibroblasts and adrenal membranes, and markedly reduced cholesterol ester levels in adrenal glands and peritoneal macrophages; the latter finding will be useful in testing the role of ACAT and macrophage foam cell formation in atherosclerosis. In contrast, the livers of ACAT-deficient mice contained substantial amounts of cholesterol esters and exhibited no reduction in cholesterol esterification activity. These tissue-specific reductions in cholesterol esterification provide evidence that in mammals this process involves more than one form of esterification enzyme.