Hinchman C A, Ballatori N
Department of Environmental Medicine, University of Rochester School of Medicine, NY 14642.
J Toxicol Environ Health. 1994 Apr;41(4):387-409. doi: 10.1080/15287399409531852.
By catalyzing the reaction of electrophilic compounds with the sulfhydryl group of glutathione, the glutathione S-transferases play physiologically important roles in the detoxication of potential alkylating agents. The glutathione S-conjugates thus formed are transported out of cells for further metabolism by gamma-glutamyltransferase and dipeptidases, ectoproteins that catalyze the sequential removal of the glutamyl and glycyl moieties, respectively. These ectoproteins are not found in all cells, but are localized predominantly to the apical surface of epithelial tissues. The resulting cysteine S-conjugates can be reabsorbed by specific cell types, and acetylated on the amino group of the cysteinyl residue by intracellular N-acetyl-transferases, to form the corresponding mercapturic acids (N-acetylcysteine S-conjugates). Mercapturic acids are then released into the circulation and delivered to the kidney for excretion in urine, or they may undergo further metabolism. Mercapturic acid biosynthesis is generally considered to be an interorgan process, with the liver serving as the major site of glutathione conjugation, and the kidney as the primary site for conversion of glutathione conjugates to cysteine conjugates. Cysteine conjugates formed in the kidney appear to be transported back to the liver for acetylation. This interorgan model of mercapturic acid synthesis is based largely on the interorgan distribution of the enzymes involved in their formation, and in particular of the enzyme gamma-glutamyltransferase. Rats have relatively low hepatic and high renal activities of gamma-glutamyltransferase, the only protein known to initiate the breakdown of glutathione S-conjugates. The low gamma-glutamyltransferase activity in rat liver limits the hepatic degradation of glutathione S-conjugates, particularly after large doses of xenobiotic. In contrast, hepatic gamma-glutamyltransferase is significantly higher in species such as rabbit, guinea pig, and dog, and as a consequence, nearly all of the glutathione and glutathione S-conjugates released by liver cells of these species is degraded within the liver. Recent studies demonstrate that glutathione S-conjugates synthesized within hepatocytes are secreted preferentially across the canalicular membrane into bile, and are broken down within biliary spaces to form cysteine S-conjugates. The latter are then reabsorbed by the liver, N-acetylated to form mercapturic acids, and reexcreted into bile, completing an intrahepatic pathway for mercapturic acid biosynthesis. The contribution of this intrahepatic pathway to overall mercapturate formation is dependent on dose of the electrophile, route of exposure, and the physicochemical properties of the glutathione S-conjugate formed, as well as the tissue distribution and activity of gamma-glutamyltransferase.(ABSTRACT TRUNCATED AT 400 WORDS)
通过催化亲电化合物与谷胱甘肽巯基的反应,谷胱甘肽S-转移酶在潜在烷基化剂的解毒过程中发挥着重要的生理作用。如此形成的谷胱甘肽S-共轭物通过γ-谷氨酰转移酶和二肽酶转运出细胞进行进一步代谢,γ-谷氨酰转移酶和二肽酶是外蛋白,分别催化依次去除谷氨酰基和甘氨酰基部分。这些外蛋白并非在所有细胞中都存在,而是主要定位于上皮组织的顶端表面。产生的半胱氨酸S-共轭物可被特定细胞类型重新吸收,并通过细胞内N-乙酰转移酶在半胱氨酰残基的氨基上进行乙酰化,形成相应的硫醚氨酸(N-乙酰半胱氨酸S-共轭物)。硫醚氨酸随后释放到循环系统中,并输送到肾脏随尿液排出,或者它们可能会经历进一步的代谢。硫醚氨酸的生物合成通常被认为是一个器官间的过程,肝脏是谷胱甘肽共轭作用的主要场所,而肾脏是将谷胱甘肽共轭物转化为半胱氨酸共轭物的主要场所。在肾脏中形成的半胱氨酸共轭物似乎会被运回肝脏进行乙酰化。这种硫醚氨酸合成的器官间模型很大程度上基于参与其形成的酶的器官间分布,特别是γ-谷氨酰转移酶。大鼠肝脏中的γ-谷氨酰转移酶活性相对较低,而肾脏中的活性较高,γ-谷氨酰转移酶是已知唯一启动谷胱甘肽S-共轭物分解的蛋白质。大鼠肝脏中低水平的γ-谷氨酰转移酶活性限制了谷胱甘肽S-共轭物的肝脏降解,尤其是在大剂量给予外源性物质之后。相比之下,在兔、豚鼠和狗等物种中,肝脏γ-谷氨酰转移酶活性显著更高,因此,这些物种的肝细胞释放的几乎所有谷胱甘肽和谷胱甘肽S-共轭物都在肝脏内被降解。最近的研究表明,在肝细胞内合成的谷胱甘肽S-共轭物优先通过胆小管膜分泌到胆汁中,并在胆管腔内分解形成半胱氨酸S-共轭物。后者随后被肝脏重新吸收,N-乙酰化形成硫醚氨酸,并重新排泄到胆汁中,从而完成了硫醚氨酸生物合成的肝内途径。这条肝内途径对整体硫醚氨酸形成的贡献取决于亲电试剂的剂量、暴露途径、所形成的谷胱甘肽S-共轭物的物理化学性质,以及γ-谷氨酰转移酶的组织分布和活性。(摘要截断于400字)
