A brain-to-gut signal controls intestinal fat absorption.
Qianqian LyuWenzhi XueRuixin LiuQinyun MaVikram Babu KasaragodShan SunQian LiYanru ChenMingyang YuanYu-Ying YangBing ZhangAifang NieSheng JiaChongrong ShenPo GaoWeifang RongChenxi YuYufang BiChun-Lei ZhangFajun NanGuang NingZihe RaoXiu-Na YangJiqiu WangWei-Qing WangPublished in: Nature (2024)
Although fat is a crucial source of energy in diets, excessive intake leads to obesity. Fat absorption in the gut is prevailingly thought to occur organ-autonomously by diffusion 1-3 . Whether the process is controlled by the brain-to-gut axis, however, remains largely unknown. Here we demonstrate that the dorsal motor nucleus of vagus (DMV) plays a key part in this process. Inactivation of DMV neurons reduces intestinal fat absorption and consequently causes weight loss, whereas activation of the DMV increases fat absorption and weight gain. Notably, the inactivation of a subpopulation of DMV neurons that project to the jejunum shortens the length of microvilli, thereby reducing fat absorption. Moreover, we identify a natural compound, puerarin, that mimics the suppression of the DMV-vagus pathway, which in turn leads to reduced fat absorption. Photoaffinity chemical methods and cryogenic electron microscopy of the structure of a GABA A receptor-puerarin complex reveal that puerarin binds to an allosteric modulatory site. Notably, conditional Gabra1 knockout in the DMV largely abolishes puerarin-induced intestinal fat loss. In summary, we discover that suppression of the DMV-vagus-jejunum axis controls intestinal fat absorption by shortening the length of microvilli and illustrate the therapeutic potential of puerarin binding to GABRA1 in fat loss.
Keyphrases
- adipose tissue
- weight gain
- weight loss
- fatty acid
- type diabetes
- bariatric surgery
- body mass index
- small molecule
- metabolic syndrome
- multiple sclerosis
- insulin resistance
- gene expression
- skeletal muscle
- white matter
- resting state
- brain injury
- functional connectivity
- birth weight
- electron microscopy
- single cell
- quality improvement
- blood brain barrier
- subarachnoid hemorrhage
- cerebral ischemia
- gestational age