Human Acyl-CoA:Cholesterol Acyltransferase-1 (ACAT-1) Gene Organization and Evidence That the 4.3-Kilobase ACAT-1 mRNA Is Produced from Two Different Chromosomes
. The human ACAT-1 cDNA was cloned by a somatic cell and molecular genetic approach. Chinese hamster ovary (CHO) cell mutants lacking ACAT activity (including clone AC29) were isolated (8); subsequent stable transfection experiments showed that human genomic DNAs complemented the ACAT deficiency in AC29 cells (9). A 1.2-kb human genomic DNA fragment was cloned from the stable transfectants. This fragment (designated as G2 DNA) led to the eventual cloning of a full-length human ACAT cDNA K1 (4011 bp in length). Expression of this cDNA, designated as ACAT-1, in AC29 cells complemented the ACAT deficiency of the mutant (10). Additional results showed that expressing this cDNA in insect cells, which do not contain endogenous ACAT-like activity, produced high levels of ACAT activity in vitro, confirming that this cDNA encodes the catalytic component of ACAT enzyme (11). The coding region of the ACAT gene has been mapped to chromosome 1q 25 (12). Protein sequence analysis revealed the ACAT-1 protein as a hydrophobic protein containing multiple transmembrane domains and sharing several peptide regions in common with other acyltransferases (10). Recombinant human ACAT-1 protein expressed in CHO cells has been purified to homogeneity; the homogeneous ACAT-1 protein remains catalytically active and uses cholesterol as a substrate in a highly cooperative manner (13). Homologues of human ACAT-1 cDNA have also been cloned from other species (reviewed in Ref. 1), including two yeast homologues (14,15). Disruption of the ACAT-1 gene in mice has been reported (16); the ACAT-1 gene-deficient mice exhibit marked reduction in cholesteryl ester levels in only selective tissues and not in all the tissues examined. These and other results led to the molecular cloning of ACAT-2 cDNA (17-19). The predicted amino acid sequence of ACAT-2 is homologous but distinct from that of ACAT-1. The physiological roles of ACAT-1 and ACAT-2 in various tissues of different species are currently under intense investigation by several laboratories. In humans, immunodepletion experiments suggest that the ACAT-1 protein plays major catalytic roles in hepatocytes, adrenal glands, macrophages, and kidneys, but not in the intestines (20).The 4.0-kb human ACAT-1 cDNA contains a single open reading frame of 1.65 kb. It also contains an unusually long 5Ј-untranslated region (5Ј-UTR; 1396 bp) and 965 bp of 3Ј-untranslated region. Using the coding region as probe, North-
Abstract-The acyl coenzyme A:cholesterol acyltransferase (ACAT) gene was first cloned in 1993 (Chang et al, J Biol Chem. 1993;268:20747-20755; designated ACAT-1). Using affinity-purified antibodies raised against the N-terminal portion of human ACAT-1 protein, we performed immunohistochemical localization studies and showed that the ACAT-1 protein was highly expressed in atherosclerotic lesions of the human aorta. We also performed cell-specific localization studies using double immunostaining and showed that ACAT-1 was predominantly expressed in macrophages but not in smooth muscle cells. We then used a cell culture system in vitro to monitor the ACAT-1 expression in differentiating monocytes-macrophages. The ACAT-1 protein content increased by up to 10-fold when monocytes spontaneously differentiated into macrophages. This increase occurred within the first 2 days of culturing the monocytes and reached a plateau level within 4 days of culturing, indicating that the increase in ACAT-1 protein content is an early event during the monocyte differentiation process. The ACAT-1 protein expressed in the differentiating monocytes-macrophages was shown to be active by enzyme assay in vitro. The high levels of ACAT-1 present in macrophages maintained in culture can explain the high ACAT-1 contents found in atherosclerotic lesions.
Regulation of collagenase gene expression by IL–1β requires transcriptional and post-transcriptional mechanisms
Interleukin-1 beta is believed to contribute to the pathophysiology of rheumatoid arthritis by activating collagenase gene expression. We have used a cell culture model of rabbit synovial fibroblasts to examine the molecular mechanisms of IL-1 beta-mediated collagenase gene expression. Stimulation of rabbit synovial fibroblasts with 10 ng/ml recombinant human IL-1 beta resulted in a 20-fold increase in collagenase mRNA by 12 h. Transient transfection studies using collagenase promoter-CAT constructs demonstrated that proximal sequences responded poorly to IL-1 beta, possibly due to insufficient activation of AP-1 by this cytokine. More distal sequences were required for IL-1 beta responsiveness, with a 4700 bp construct showing approximately 5-fold induction above control. To examine post-transcriptional mechanisms, transcript from a human collagenase cDNA was constitutively produced by the simian virus 40 early promoter. IL-1 beta stabilized the constitutively expressed human transcript. Furthermore, mutation of the ATTTA motifs in the 3' untranslated region of the human gene also stabilized the transcript. Finally, the rabbit collagenase 3' untranslated region destabilized a constitutively transcribed chloramphenicol acetyltransferase transcript. These data indicate that in addition to activating transcription, IL-1 beta increases collagenase transcript stability by reversing the destabilizing effects of sequences in the 3' untranslated region.
cytokine that exerts many pro-atherosclerotic effects in vivo, causes up-regulation of ACAT-1 mRNA in human blood monocyte-derived macrophages and macrophage-like cells but not in other cell types. To examine the molecular nature of this observation, we identified within the ACAT-1 P1 promoter a 159-base pair core region. This region contains 4 Sp1 elements and an IFN-␥ activated sequence (GAS) that overlaps with the second Sp1 element. In the monocytic cell line THP-1 cell, the combination of IFN-␥ and all-trans-retinoic acid (a known differentiation agent) enhances the ACAT-1 P1 promoter but not the P7 promoter. Additional experiments showed that all-trans-retinoic acid causes large induction of the transcription factor STAT1, while IFN-␥ causes activation of STAT1 such that it binds to the GAS/Sp1 site in the ACAT-1 P1 promoter. Our work provides a molecular mechanism to account for the effect of IFN-␥ in causing transcriptional activation of ACAT-1 in macrophage-like cells. ACAT1 is an intracellular enzyme responsible for catalyzing the intracellular formation of cholesteryl esters from cholesterol and long-chain fatty acyl-coenzyme A (1). In mammals, two ACAT genes have been identified (2-5). In adult human tissues, ACAT-1 is the major enzyme present in various tissues, including macrophages, liver (hepatocytes and Kupffer cells), and adrenal gland (6, 7). ACAT-1 is also present in the intestine; however, the major enzyme involved in the intestinal cholesterol absorption may be ACAT-2, which is mainly located in the apical region of the intestinal villi (7). The relative tissue distributions of ACAT-1 and ACAT-2 in mice and monkeys are not entirely consistent with those found in humans (8, 9) raising the possibility that the distribution of the two ACATs in various tissues may be species dependent. In macrophages and other cell types, a dynamic cholesterol-cholesteryl ester cycle exist; the formation of intracellular cholesteryl esters is catalyzed by ACAT-1, while the hydrolysis of cholesteryl esters is catalyzed by the enzyme neutral cholesteryl ester hydrolase (10, 11). The net accumulation of intracellular cholesteryl esters is affected at the substrate level, as well as at the levels of the enzymes ACAT and neutral cholesteryl ester hydrolase (12)(13)(14). The main mode of sterol-specific regulation of ACAT-1 has been identified at the post-translational level, involving allosteric regulation by its substrate cholesterol (1, 15). On the other hand, the cellular and molecular nature of non-sterolmediated ACAT-1 regulation remains largely unknown. Recently, using mouse macrophage-derived foam cells, Panousis and Zuckerman (12) reported that IFN-␥ increased the cellular cholesteryl ester content and reduced high density lipoproteinmediated cholesterol efflux; its cellular effects were attributed to its ability to increase ACAT-1 message (12) and to induce down-regulation of the Tangier Disease gene (the ABC1 transporter) (16). In the current work, we showed that IFN-␥ increased ACAT-1 message and protein ...
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