Division of Endocrinology, Diabetes and Metabolism, Department of Medicine, University of Illinois at Chicago, Chicago, Illinois.
USF Center for Microbiome Research, University of South Florida Morsani College of Medicine, Tampa, Florida.
Am J Physiol Endocrinol Metab. 2022 Sep 1;323(3):E290-E306. doi: 10.1152/ajpendo.00016.2022. Epub 2022 Jul 20.
Free fatty acid receptor 3 (FFA3) is a recently-deorphanized G-protein-coupled receptor. Its ligands are short-chain fatty acids (SCFAs), which are key nutrients derived from the gut microbiome fermentation process that play diverse roles in the regulation of metabolic homeostasis and glycemic control. FFA3 is highly expressed within the intestine, where its role and its effects on physiology and metabolism are unclear. Previous in vivo studies involving this receptor have relied on global knockout mouse models, making it difficult to isolate intestine-specific roles of FFA3. To overcome this challenge, we generated an intestine-specific knockout mouse model for FFA3, Villin-Cre-FFA3 (Vil-FFA3). Model validation and general metabolic assessment of male mice fed a standard chow diet revealed no major congenital defects. Because dietary changes are known to alter gut microbial composition, and thereby SCFA production, an obesogenic challenge was performed on male Vil-FFA3 mice and their littermate controls to probe for a phenotype on a high-fat, high-sugar "Western diet" (WD) compared with a low-fat control diet (CD). Vil-FFA3 mice versus FFA3 controls on WD, but not CD, were protected from the development of diet-induced obesity and exhibited significantly less fat mass as well as smaller adipose depositions and adipocytes. Although overall glycemic control was unchanged in the WD-fed Vil-FFA3 group, fasted glucose levels trended lower. Intestinal inflammation was significantly reduced in the WD-fed Vil-FFA3 mice, supporting protection from obesogenic effects. Furthermore, we observed lower levels of gastric inhibitory protein (GIP) in the WD-fed Vil-FFA3 mice, which may contribute to phenotypic changes. Our findings suggest a novel role of intestinal FFA3 in promoting the metabolic consequences of a WD, including the development of obesity and inflammation. Moreover, these data support an intestine-specific role of FFA3 in whole body metabolic homeostasis and in the development of adiposity. Here, we generated a novel intestine-specific knockout mouse model for FFA3 (Vil-FFA3) and performed a comprehensive metabolic characterization of mice in response to an obesogenic challenge. We found that Vil-FFA3 mice fed with a Western diet were largely protected from obesity, exhibiting significantly lower levels of fat mass, lower intestinal inflammation, and altered expression of intestinal incretin hormones. Results support an important role of intestinal FFA3 in contributing to metabolism and in the development of diet-induced obesity.
游离脂肪酸受体 3(FFA3)是一种最近被重新定义的 G 蛋白偶联受体。其配体是短链脂肪酸(SCFAs),它们是肠道微生物组发酵过程中的关键营养物质,在调节代谢稳态和血糖控制方面发挥着多样化的作用。FFA3 在肠道中高度表达,但其作用及其对生理和代谢的影响尚不清楚。以前涉及该受体的体内研究依赖于全局敲除小鼠模型,这使得难以分离 FFA3 的肠道特异性作用。为了克服这一挑战,我们生成了一种 FFA3 的肠道特异性敲除小鼠模型,即 Villin-Cre-FFA3(Vil-FFA3)。对雄性小鼠进行标准饮食喂养的模型验证和一般代谢评估显示,没有发现重大先天性缺陷。由于饮食变化已知会改变肠道微生物组成,从而改变 SCFA 的产生,因此对雄性 Vil-FFA3 小鼠及其同窝对照进行了肥胖挑战,以在高脂肪、高糖的“西方饮食”(WD)与低脂肪对照饮食(CD)上探究表型。与 CD 相比,WD 喂养的 Vil-FFA3 小鼠与 FFA3 对照相比,可防止饮食诱导的肥胖发生,并表现出明显更少的脂肪量以及更小的脂肪沉积和脂肪细胞。尽管 WD 喂养的 Vil-FFA3 组的整体血糖控制没有改变,但空腹血糖水平呈下降趋势。在 WD 喂养的 Vil-FFA3 小鼠中,肠道炎症明显减轻,这表明其对肥胖的影响有保护作用。此外,我们观察到 WD 喂养的 Vil-FFA3 小鼠中胃抑制素蛋白(GIP)水平降低,这可能有助于表型变化。我们的研究结果表明,肠道 FFA3 在促进 WD 的代谢后果方面具有新的作用,包括肥胖和炎症的发展。此外,这些数据支持 FFA3 在全身代谢稳态和肥胖发展中的肠道特异性作用。在这里,我们为 FFA3 生成了一种新的肠道特异性敲除小鼠模型(Vil-FFA3),并对小鼠在肥胖挑战下的综合代谢特征进行了描述。我们发现,用西方饮食喂养的 Vil-FFA3 小鼠在很大程度上可以防止肥胖,其脂肪量显著降低,肠道炎症降低,肠道肠促胰岛素激素表达改变。结果支持肠道 FFA3 在促进代谢和饮食诱导肥胖发展方面的重要作用。
