肠内分泌细胞与上皮细胞和神经元的相互作用。

Interactions of Gut Endocrine Cells with Epithelium and Neurons.

机构信息

Department of Medicine, Duke University and Durham VA Healthcare System, Durham, North Carolina, USA.

出版信息

Compr Physiol. 2018 Jun 18;8(3):1019-1030. doi: 10.1002/cphy.c170044.

DOI:10.1002/cphy.c170044

PMID:29978902

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6487668/

Abstract

Even the simplest animals possess sophisticated systems for sensing and securing nutrients. After all, ensuring adequate nutrition is essential for sustaining life. Once multicellular animals grew too large to be nourished by simple diffusion of nutrients from their environment, they required a digestive system for the absorption and digestion of food. The majority of cells in the digestive tract are enterocytes that are designed to absorb nutrients. However, the digestive tracts of animals ranging from worms to humans contain specialized cells that discriminate between nutrients and nondigestible ingestants. These cells "sense" both the environment within the gut lumen and nutrients as they cross the gut epithelium. This dual sensing is then translated into local signals that regulate the gut epithelium or distant signals through hormones or nerves. This review will discuss how sensors of the gut interact with cells of the epithelium and neurons to regulate epithelial integrity and initiate neural transmission from the gut lumen. © 2017 American Physiological Society. Compr Physiol 8:1019-1030, 2018.

摘要

即使是最简单的动物也拥有复杂的系统来感知和获取营养。毕竟，确保充足的营养对于维持生命是至关重要的。一旦多细胞动物变得太大，无法通过简单的营养物质从环境中的扩散来获取营养，它们就需要一个消化系统来吸收和消化食物。消化道中的大多数细胞是吸收营养物质的肠细胞。然而，从蠕虫到人类的动物的消化道中都含有专门的细胞，可以区分营养物质和不可消化的摄入物。这些细胞“感知”肠道腔内部的环境以及穿过肠道上皮的营养物质。这种双重感知随后被转化为局部信号，调节肠道上皮细胞，或通过激素或神经传递到远处的信号。这篇综述将讨论肠道传感器如何与上皮细胞和神经元相互作用，以调节上皮细胞的完整性，并从肠道腔启动神经传递。美国生理学会 2017 年版。《生理学综合》8:1019-1030，2018 年。

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