Plaat1l1 控制摄食诱导的 NAPE 生物合成,有助于斑马鱼的能量平衡调节。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-07-06 DOI:10.1016/j.prostaglandins.2024.106869
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引用次数: 0

摘要

能量平衡失调导致肥胖是糖尿病、非酒精性脂肪肝和动脉粥样硬化等心脏代谢疾病的重要风险因素。在啮齿动物和其他几种脊椎动物中,喂食已被证明会引起肠道中 N-酰乙醇胺(NAEs)水平的快速上升,而长期食用高脂肪饮食则会消除这种上升。给摄入高脂肪饮食的啮齿动物喂食NAEs可降低其脂肪含量,部分原因是减少了食物摄入量并促进了脂肪氧化,因此喂食诱导的肠道NAE生物合成似乎对适当调节能量平衡至关重要。然而,人们对进食诱导的肠道非乙酰胆碱生物合成对适当能量平衡的贡献仍然知之甚少,部分原因是有多种酶可促进非乙酰胆碱生物合成,而负责进食诱导的肠道非乙酰胆碱生物合成的特定酶尚未确定。NAE 在肠道生物合成过程中的限速步骤是由磷脂酰乙醇胺 N-酰基转移酶(NAT)形成其直接前体--N-酰基磷脂酰乙醇胺(NAPE)。人类体内至少有六种 NATs,大多数脊椎动物体内都有这些 NATs 的多个同源物。近年来,斑马鱼(Danio rerio)繁殖力强、体型小,而且在摄食行为和能量平衡调节方面与哺乳动物相似,因此被用来模拟心脏代谢疾病的主要特征。因此,我们搜索了斑马鱼基因组以确定所有的NAT同源物,并发现除了之前报道的plaat1、larres3和larres3l之外,还有两个NAT同源物,并使用CRISPR/cas9删除了这两个NAT同源物(plaat1l1和plaat1l2)。野生型鱼类在空腹进餐后,肠道中的NAPE水平会明显增加,而plaat1l1-/-鱼类的这种反应则完全消失。此外,与野生型鱼类相比,喂食标准片状食物的 plaat1l1-/- 鱼类体重增加和葡萄糖不耐受性增加。这些结果证明了摄食诱导的 NAPE 和 NAE 生物合成在调节能量平衡中的关键作用,并表明恢复肥胖动物的这种反应有可能用于治疗肥胖症和心脏代谢疾病。
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Plaat1l1 controls feeding induced NAPE biosynthesis and contributes to energy balance regulation in zebrafish

Dysregulation of energy balance leading to obesity is a significant risk factor for cardiometabolic diseases such as diabetes, non-alcoholic fatty liver disease and atherosclerosis. In rodents and several other vertebrates, feeding has been shown to induce a rapid rise in the intestinal levels of N-acyl-ethanolamines (NAEs) and the chronic consumption of a high fat diet abolishes this rise. Administering NAEs to rodents consuming a high fat diet reduces their adiposity, in part by reducing food intake and enhancing fat oxidation, so that feeding-induced intestinal NAE biosynthesis appears to be critical to appropriate regulation of energy balance. However, the contribution of feeding-induced intestinal NAE biosynthesis to appropriate energy balance remains poorly understood in part because there are multiple enzymes that can contribute to NAE biosynthesis and the specific enzyme(s) that are responsible for feeding-induced intestinal NAE biosynthesis have not been identified. The rate-limiting step in the intestinal biosynthesis of NAEs is formation of their immediate precursors, the N-acyl-phosphatidylethanolamines (NAPEs), by phosphatidylethanolamine N-acyltransferases (NATs). At least six NATs are found in humans and multiple homologs of these NATs are found in most vertebrate species. In recent years, the fecundity and small size of zebrafish (Danio rerio), as well as their similarities in feeding behavior and energy balance regulation with mammals, have led to their use to model key features of cardiometabolic disease. We therefore searched the Danio rerio genome to identify all NAT homologs and found two additional NAT homologs besides the previously reported plaat1, rarres3, and rarres3l, and used CRISPR/cas9 to delete these two NAT homologs (plaat1l1 and plaat1l2). While wild-type fish markedly increased their intestinal NAPE levels in response to a meal after fasting, this response was completely ablated in plaat1l1-/- fish. Furthermore, plaat1l1-/- fish fed a standard flake diet had increased weight gain and glucose intolerance compared to wild-type fish. The results support a critical role for feeding-induced NAPE and NAE biosynthesis in regulating energy balance and suggest that restoring this response in obese animals could potentially be used to treat obesity and cardiometabolic disease.

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ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
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464
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