New perspectives on PPAR, VDR and FXRα as new actors in testicular pathophysiology.

The incidence of reproductive disorders is constantly increasing and affects 15% of couples, with male's abnormalities diagnosed in almost half of the cases. The male gonads exert two major functions of the testis with the productions of gametes (exocrine function) and of sexual hormones (endocrine function). In the last decades, next to steroid receptors such as estrogen and androgen receptors, the involvement of other members of the nuclear receptor superfamily have been described such as Steroidogenic factor-1 (SF-1), Nerve growth factor IB (NGFIB), Liver-X-Receptorα (LXRα) and Dosage-sensitive sex reversal, adrenal hypoplasia critical region, on chromosome X, gene 1 (DAX-1). The purpose of this review is to highlight the emerging roles of some members of the nuclear receptor superfamily among which the vitamin-D Receptor (VDR), Peroxisome Proliferator-Activated Receptor (PPAR), Farnesoid-X-Receptor-α (FXRα). We discuss how these receptors could participate to explain male fertility disorders; and their potential to be use as biomarkers or therapeutic targets for management of fertility disorders.

Nuclear oxysterol receptors, LXRs, are involved in the maintenance of mouse caput epididymidis structure and functions.

In this study we looked at the epididymides and spermatozoa of mice knocked-out for nuclear oxysterol receptors (LXR). We have shown that LXR-deficient mice exhibited upon ageing a severe disruption of their caput epididymides associated with abnormal accumulation of neutral lipids. The epididymis defaults were correlated with sperm head fragility and infertility. In agreement with the observed caput defect in transgenic animals in which both LXRalpha and LXRbeta isoforms were disrupted, we have shown here that both receptors are expressed in caput and cauda epididymides regions. LXRbeta was predominantly expressed throughout the mouse epididymis while the expression of LXRalpha was weaker. In addition, the expression of selected genes that can be considered as markers of adult epididymis function was monitored via Northern blots in the different single and double LXR-deficient backgrounds. Altogether, the data presented here suggest that LXR receptors are important actors in epididymis function.

[Regulation of lipid metabolism by the orphan nuclear receptors]. / Régulation du métabolisme des lipides par les récepteurs nucléaires orphelins.

Lipids (cholesterol and fatty acids) are essential nutriments and have a major impact on gene expression. Hence cholesterol intracellular concentration is precisely controlled by some complex mechanisms involving transcriptional regulations. The excess of cholesterol in cells is converted into oxysterols. These cholesterol metabolites are important signalisation molecules that modulate several transcription factors involved in cholesterol homeostasis. Schematically, regulation of cholesterol homeostasis is achieved by three different but complementary pathways: 1) endogeneous biosynthesis, which corresponds to the de novo synthesis of cholesterol and is controlled by sterol response element binding proteins (SREBPs); 2) the transport, intracellular absorption and esterification of the cholesterol; 3) the metabolic conversion into bile acids and steroid hormones. These three pathways are closely linked, however we will schematically detail the role of the orphan nuclear receptors on the modulation of these three levels of regulation. Phenotype analyses of knock-out or transgenic mice pointed out the respective role of the "enterohepatic" orphan nuclear receptors LXRalpha, LXRB, FXR, LRH-1, the nuclear receptor PPARalpha, and their heterodimeric partner RXR, as well as the peculiar receptor SHP. Complex feed-backs have thus been demonstrated. These transciptional regulations have several targets: the P450 cytochromes involved in the bile acid synthesis Cyp7a1 and Cyp8b1; the intestinal bile acid binding protein IBABP; the cholesteryl ester transfert protein CETP and phospholipid transfert protein PLTP, both involved in the HDL catabolism; the ABC cholesterol transporters ABCG1/ABC8 and ABCAI/ABCI. At last it seems that polyunsaturated fatty acids could activate LXRalpha transcription through its activation by PPARalpha. In the near future, the identification and study of new target genes by transcriptomic or proteomic analyses will allow a better understanding of lipid homeostasis in physiological as well as pathophysiological conditions.