Hepatocyte heterogeneity in the metabolism of amino acids and ammonia.

Enzyme Pub Date : 1992-01-01 DOI:10.1159/000468779
D Häussinger, W H Lamers, A F Moorman
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引用次数: 217

Abstract

With respect to hepatocyte heterogeneity in ammonia and amino acid metabolism, two different patterns of sublobular gene expression are distinguished: 'gradient-type' and 'strict- or compartment-type' zonation. An example for strict-type zonation is the reciprocal distribution of carbamoylphosphate synthase and glutamine synthase in the liver lobule. The mechanisms underlying the different sublobular gene expressions are not yet settled but may involve the development of hepatic architecture, innervation, blood-borne hormonal and metabolic factors. The periportal zone is characterized by a high capacity for uptake and catabolism of amino acids (except glutamate and aspartate) as well as for urea synthesis and gluconeogenesis. On the other hand, glutamine synthesis, ornithine transamination and the uptake of vascular glutamate, aspartate, malate and alpha-ketoglutarate are restricted to a small perivenous hepatocyte population. Accordingly, in the intact liver lobule the major pathways for ammonia detoxication, urea and glutamine synthesis, are anatomically switched behind each other and represent in functional terms the sequence of the periportal low affinity system (urea synthesis) and a previous high affinity system (glutamine synthesis) for ammonia detoxication. Perivenous glutamine synthase-containing hepatocytes ('scavenger cells') act as a high affinity scavenger for the ammonia, which escapes the more upstream urea-synthesizing compartment. Periportal glutaminase acts as a pH- and hormone-modulated ammonia-amplifying system in the mitochondria of periportal hepatocytes. The activity of this amplifying system is one crucial determinant for flux through the urea cycle in view of the high Km (ammonia) of carbamoylphosphate synthase, the rate-controlling enzyme of the urea cycle. The structural and functional organization of glutamine and ammonia-metabolizing pathways in the liver lobule provides one basis for the understanding of a hepatic role in systemic acid base homeostasis. Urea synthesis is a major pathway for irreversible removal of metabolically generated bicarbonate. The lobular organization enables the adjustment of the urea cycle flux and accordingly the rate of irreversible hepatic bicarbonate elimination to the needs of the systemic acid base situation, without the threat of hyperammonemia.

氨基酸和氨代谢中的肝细胞异质性。
关于肝细胞氨和氨基酸代谢的异质性,区分了两种不同的小叶下基因表达模式:“梯度型”和“严格或室型”分区。严格型分区的一个例子是氨甲酰磷酸合成酶和谷氨酰胺合成酶在肝小叶中的互反分布。不同小叶下基因表达的机制尚未确定,但可能涉及肝脏结构、神经支配、血源性激素和代谢因素的发展。门静脉周围区具有吸收和分解氨基酸(谷氨酸和天冬氨酸除外)以及尿素合成和糖异生的高能力。另一方面,谷氨酰胺合成、鸟氨酸转氨化和血管谷氨酸、天冬氨酸、苹果酸和α -酮戊二酸的摄取仅限于小的静脉周围肝细胞群。因此,在完整的肝小叶中,氨解毒的主要途径,尿素和谷氨酰胺合成,在解剖学上是相互转换的,并在功能上代表了门静脉周围低亲和力系统(尿素合成)和先前高亲和力系统(谷氨酰胺合成)的氨解毒顺序。静脉周围含谷氨酰胺合成酶的肝细胞(“清道夫细胞”)作为氨的高亲和力清道夫,氨从上游的尿素合成区逃逸。门静脉周围谷氨酰胺酶是门静脉周围肝细胞线粒体中pH和激素调节的氨扩增系统。考虑到尿素循环的速率控制酶氨甲酰磷酸合成酶的高Km(氨),该扩增系统的活性是尿素循环通量的一个关键决定因素。肝小叶中谷氨酰胺和氨代谢途径的结构和功能组织为理解肝脏在全身酸碱稳态中的作用提供了一个基础。尿素合成是不可逆去除代谢生成的碳酸氢盐的主要途径。小叶组织能够调节尿素循环通量和相应的不可逆肝脏碳酸氢盐消除速率,以满足全身酸碱情况的需要,而不会产生高氨血症的威胁。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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