Negative regulation of the human apolipoprotein AI promoter by fibrates can be attenuated by the interaction of the peroxisome proliferator-activated receptor with its …

N Vu-Dac, K Schoonjans, B Laine, JC Fruchart… - Journal of Biological …, 1994 - Elsevier
N Vu-Dac, K Schoonjans, B Laine, JC Fruchart, J Auwerx, B Staels
Journal of Biological Chemistry, 1994Elsevier
Fibrates have been reported to modulate plasma high density lipoprotein cholesterol and
apolipoprotein (apo) AI concentrations. Therefore, the molecular mechanisms underlying the
regulation of human apoA-I gene expression by fibrates was investigated. Fenofibrate
reduced the expression of a reporter gene driven by the DNA sequences between-192 and+
91 (BC-P-chloramphenicol acetyltransferase; CAT) relative to the apoA-I gene transcription
start site approximately 3-fold. The sequences involved in the down-regulation of apoA-I …
Fibrates have been reported to modulate plasma high density lipoprotein cholesterol and apolipoprotein (apo) A-I concentrations. Therefore, the molecular mechanisms underlying the regulation of human apoA-I gene expression by fibrates was investigated. Fenofibrate reduced the expression of a reporter gene driven by the DNA sequences between -192 and +91 (BC-P-chloramphenicol acetyltransferase; CAT) relative to the apoA-I gene transcription start site approximately 3-fold. The sequences involved in the down-regulation of apoA-I gene transcription by fenofibrate were localized between -41 and +91 (P-CAT) relative to the transcription start site. The reduction of the expression of BC-P-CAT was dose-dependent and maximal at 500 microM (20 +/- 7%). Different peroxisome proliferators showed different levels of repression varying from 39 +/- 4% for fenofibrate, 43 +/- 5% for tetradecylthioacetic acid, 48 +/- 4% for bezafibrate, 54 +/- 2% for 5,8,11,14-eicotetraynoic acid, 76 +/- 2% for ciprofibrate, whereas Wy 14643 only marginally inhibited the expression of BC-P-CAT. By contrast, inclusion of sequences between -256 and -192 (ABC-P-CAT) attenuated the repression by fenofibrate. Furthermore, the apoA-IA site (-214 to -192; Awt-P-CAT) could counteract the repression of P-CAT by fenofibrate in the presence of cotransfected mPPAR alpha (peroxisome proliferator-activated receptor). In addition, the acyl-CoA oxidase-peroxisome proliferator response element (PPRE) could substitute the wild-type A-site in blocking the fenofibrate-induced reduction of the apoA-I promoter by mPPAR alpha. The protective effect of PPAR on fenofibrate induced inhibition of apoA-I expression was abolished after mutation of the direct repeat in the A site (Am-P-CAT). Consistent with these functional data only the wild-type, but not the mutated A site bound PPAR/retinoic X receptor heterodimers in gel shift assays. These data suggest that certain peroxisome proliferators can reduce the expression of the apoA-I promoter in a PPAR-independent fashion, through modulation of factors interacting with sequences localized between -41 and +91 of the apoA-I gene transcription initiation site. This inhibitory effect can be overcome when PPAR interacts with a functional PPRE, such as the apoA-I A site or the acyl-CoA oxidase-PPRE.
Elsevier