Department of Physiology, University of Tennessee Health Science Center, 894 Union Avenue, Memphis, TN, 38163, USA,
Amino Acids. 2014 Mar;46(3):565-73. doi: 10.1007/s00726-013-1565-2. Epub 2013 Aug 1.
Amino acids, especially glutamine (GLN) have been known for many years to stimulate the growth of small intestinal mucosa. Polyamines are also required for optimal mucosal growth, and the inhibition of ornithine decarboxylase (ODC), the first rate-limiting enzyme in polyamine synthesis, blocks growth. Certain amino acids, primarily asparagine (ASN) and GLN stimulate ODC activity in a solution of physiological salts. More importantly, their presence is also required before growth factors and hormones such as epidermal growth factor and insulin are able to increase ODC activity. ODC activity is inhibited by antizyme-1 (AZ) whose synthesis is stimulated by polyamines, thus, providing a negative feedback regulation of the enzyme. In the absence of amino acids mammalian target of rapamycin complex 1 (mTORC1) is inhibited, whereas, mTORC2 is stimulated leading to the inhibition of global protein synthesis but increasing the synthesis of AZ via a cap-independent mechanism. These data, therefore, explain why ASN or GLN is essential for the activation of ODC. Interestingly, in a number of papers, AZ has been shown to inhibit cell proliferation, stimulate apoptosis, or increase autophagy. Each of these activities results in decreased cellular growth. AZ binds to and accelerates the degradation of ODC and other proteins shown to regulate proliferation and cell death, such as Aurora-A, Cyclin D1, and Smad1. The correlation between the stimulation of ODC activity and the absence of AZ as influenced by amino acids is high. Not only do amino acids such as ASN and GLN stimulate ODC while inhibiting AZ synthesis, but also amino acids such as lysine, valine, and ornithine, which inhibit ODC activity, increase the synthesis of AZ. The question remaining to be answered is whether AZ inhibits growth directly or whether it acts by decreasing the availability of polyamines to the dividing cells. In either case, evidence strongly suggests that the regulation of AZ synthesis is the mechanism through which amino acids influence the growth of intestinal mucosa. This brief article reviews the experiments leading to the information presented above. We also present evidence from the literature that AZ acts directly to inhibit cell proliferation and increase the rate of apoptosis. Finally, we discuss future experiments that will determine the role of AZ in the regulation of intestinal mucosal growth by amino acids.
多年来,人们一直知道氨基酸,尤其是谷氨酰胺(GLN)可以刺激小肠黏膜的生长。多胺也是促进黏膜最佳生长所必需的物质,而抑制鸟氨酸脱羧酶(ODC)——多胺合成的限速酶,会阻止生长。某些氨基酸,主要是天冬酰胺(ASN)和 GLN,在生理盐溶液中刺激 ODC 活性。更重要的是,在生长因子和激素(如表皮生长因子和胰岛素)能够增加 ODC 活性之前,它们的存在也是必需的。ODC 活性受到抗霉素-1(AZ)的抑制,而 AZ 的合成受到多胺的刺激,从而对酶进行负反馈调节。在没有氨基酸的情况下,哺乳动物雷帕霉素靶蛋白复合物 1(mTORC1)受到抑制,而 mTORC2 受到刺激,导致全局蛋白质合成减少,但通过一种非帽依赖机制增加 AZ 的合成。因此,这些数据解释了为什么 ASN 或 GLN 对 ODC 的激活是必需的。有趣的是,在许多论文中,AZ 已被证明可以抑制细胞增殖、刺激细胞凋亡或增加自噬。这些活动中的每一种都会导致细胞生长减少。AZ 与 ODC 和其他被证明可调节增殖和细胞死亡的蛋白质(如 Aurora-A、Cyclin D1 和 Smad1)结合并加速其降解。受氨基酸影响的 ODC 活性的刺激和 AZ 缺乏之间的相关性很高。不仅 ASN 和 GLN 等氨基酸刺激 ODC,同时抑制 AZ 合成,而且赖氨酸、缬氨酸和鸟氨酸等抑制 ODC 活性的氨基酸也会增加 AZ 的合成。有待回答的问题是,AZ 是否直接抑制生长,还是通过减少多胺向分裂细胞的供应来发挥作用。在任何一种情况下,都有强有力的证据表明 AZ 合成的调节是氨基酸影响肠黏膜生长的机制。这篇简短的文章回顾了导致上述信息的实验。我们还从文献中提供了证据,表明 AZ 直接抑制细胞增殖并增加细胞凋亡率。最后,我们讨论了未来的实验,这些实验将确定 AZ 在氨基酸调节肠黏膜生长中的作用。
