Dependence of brown adipose tissue function on CD36-mediated coenzyme Q uptake.

Brown adipose tissue (BAT) possesses the inherent ability to dissipate metabolic energy as heat through uncoupled mitochondrial respiration. An essential component of the mitochondrial electron transport chain is coenzyme Q (CoQ). While cells synthesize CoQ mostly endogenously, exogenous supplementation with CoQ has been successful as a therapy for patients with CoQ deficiency. However, which tissues depend on exogenous CoQ uptake as well as the mechanism by which CoQ is taken up by cells and the role of this process in BAT function are not well understood. Here, we report that the scavenger receptor CD36 drives the uptake of CoQ by BAT and is required for normal BAT function. BAT from mice lacking CD36 displays CoQ deficiency, impaired CoQ uptake, hypertrophy, altered lipid metabolism, mitochondrial dysfunction, and defective nonshivering thermogenesis. Together, these data reveal an important new role for the systemic transport of CoQ to BAT and its function in thermogenesis.

EP 80317, a selective CD36 ligand, shows cardioprotective effects against post-ischaemic myocardial damage in mice.

AIMS: The CD36 receptor plays an important role in facilitating fatty acid transport to the heart. The present study aimed to assess whether EP 80317, a selective synthetic peptide ligand of CD36, is cardioprotective in a murine model of myocardial ischaemia and reperfusion (MI/R) injury. METHODS AND RESULTS: Mice were pretreated with daily subcutaneous injections of EP 80317 for 14 days before being subjected to a 30 min ligation of the left anterior descending coronary artery. The treatment reduced the infarct area and improved myocardial haemodynamics and function, as shown by an increase in cardiac output, ejection fraction and stroke work, and a reduced total peripheral resistance. In contrast, administration of EP 51389, a tripeptide analogue devoid of binding affinity to CD36, did not protect against myocardial injury. Six hours after myocardial reperfusion, EP 80317-treated mice showed reduced myocardial fatty acid uptake, as assessed by micro-positron emission tomography, in agreement with reduced levels of circulating non-esterified fatty acids. Studies using [(14)C]-palmitate infusion revealed reduced lipolysis, although no significant change in insulin or catecholamine plasma levels were observed. Increased expression levels of adipogenic and anti-lipolytic genes further supported an effect of EP 80317 in preventing fatty acid mobilization from adipose tissue. No effect of the treatment was observed in CD36(-/-) mice. CONCLUSION: Our results show that pretreatment with EP 80317 protected the heart against damage and dysfunction elicited by MI/R, along with a transient reduction in peripheral lipolysis. Our findings support CD36 as a novel target for the treatment of ischaemic cardiopathy.

CD36 involvement in orosensory detection of dietary lipids, spontaneous fat preference, and digestive secretions.

Rats and mice exhibit a spontaneous attraction for lipids. Such a behavior raises the possibility that an orosensory system is responsible for the detection of dietary lipids. The fatty acid transporter CD36 appears to be a plausible candidate for this function since it has a high affinity for long-chain fatty acids (LCFAs) and is found in lingual papillae in the rat. To explore this hypothesis further, experiments were conducted in rats and in wild-type and CD36-null mice. In mice, RT-PCR experiments with primers specific for candidate lipid-binding proteins revealed that only CD36 expression was restricted to lingual papillae although absent from the palatal papillae. Immunostaining studies showed a distribution of CD36 along the apical side of circumvallate taste bud cells. CD36 gene inactivation fully abolished the preference for LCFA-enriched solutions and solid diet observed in wild-type mice. Furthermore, in rats and wild-type mice with an esophageal ligation, deposition of unsaturated LCFAs onto the tongue led to a rapid and sustained rise in flux and protein content of pancreatobiliary secretions. These findings demonstrate that CD36 is involved in oral LCFA detection and raise the possibility that an alteration in the lingual fat perception may be linked to feeding dysregulation.