碳水化合物代谢中的肝细胞异质性。

Enzyme Pub Date : 1992-01-01 DOI:10.1159/000468777
K Jungermann, R G Thurman
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引用次数: 117

摘要

门静脉周围和门静脉周围的肝细胞具有不同数量和活性的碳水化合物和氧化能代谢速率酶,因此不同的代谢能力。这是代谢分区模型的基础,根据该模型,门静脉周围细胞主要催化脂肪和氨基酸的氧化分解代谢,以及葡萄糖释放和糖原形成,通过糖异生,静脉周围细胞优先进行葡萄糖摄取,用于糖原合成和糖酵解,并结合脂肪生成。体液和神经信号输入门静脉周围区和门静脉周围区是不同的;氧、底物和产物、激素和介质以及神经密度的梯度不仅对碳水化合物代谢的短期调控重要,而且对区域性基因表达的长期调控也很重要。门静脉周围和门静脉周围肝细胞在碳水化合物代谢中的特化已被很好地表征。体内证据由称为“葡萄糖悖论”的复杂代谢情况和基于酶和代谢物分布计算的区域通量差异提供。通过经典侵入性技术测定的不同通量率提供了体外证据,例如在细胞培养中的门静脉样和静脉周围样肝细胞中,在门静脉周围和静脉周围富集的肝细胞群中,在正流式和逆行血流期间灌注的肝脏中,以及使用微型氧电极的非侵入性技术,例如在任何方向灌注的肝脏中。讨论了作者在解释有创和无创技术研究中的不同意见。氧浓度梯度的下降、胰高血糖素/胰岛素比值的降低和神经支配的不同可能是糖代谢酶基因纬向表达的重要因素。虽然很明显,肝细胞通过各自的激素受体感知胰高血糖素/胰岛素梯度,但尚不清楚它们如何感知不同的氧张力;O2传感器可能是一种氧结合血红素蛋白。葡萄糖释放和摄取的区域分离似乎对肝脏作为“葡萄糖抑制素”的运作很重要。因此,碳水化合物代谢的区带在出生后的最初几周逐渐形成,部分是在断奶前,部分是在断奶后,此时(在大鼠和小鼠中)通过牛奶获得的富含脂肪和蛋白质但碳水化合物含量低的营养被富含碳水化合物的食物所取代。类似地,碳水化合物代谢的分区适应于需要“葡萄糖抑制素”的更持久的变化,如饥饿、糖尿病、门静脉吻合或部分肝切除术。
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Hepatocyte heterogeneity in the metabolism of carbohydrates.

Periportal and perivenous hepatocytes possess different amounts and activities of the rate-generating enzymes of carbohydrate and oxidative energy metabolism and thus different metabolic capacities. This is the basis of the model of metabolic zonation, according to which periportal cells catalyze predominantly the oxidative catabolism of fatty and amino acids as well as glucose release and glycogen formation via gluconeogenesis, and perivenous cells carry out preferentially glucose uptake for glycogen synthesis and glycolysis coupled to liponeogenesis. The input of humoral and nervous signals into the periportal and perivenous zones is different; gradients of oxygen, substrates and products, hormones and mediators and nerve densities exist which are important not only for the short-term regulation of carbohydrate metabolism but also for the long-term regulation of zonal gene expression. The specialization of periportal and perivenous hepatocytes in carbohydrate metabolism has been well characterized. In vivo evidence is provided by the complex metabolic situation termed the 'glucose paradox' and by zonal flux differences calculated on the basis of the distribution of enzymes and metabolites. In vitro evidence is given by the different flux rates determined with classical invasive techniques, e.g. in periportal-like and perivenous-like hepatocytes in cell culture, in periportal- and perivenous-enriched hepatocyte populations and in perfused livers during orthograde and retrograde flow, as well as with noninvasive techniques using miniature oxygen electrodes, e.g. in livers perfused in either direction. Differences of opinion in the interpretation of studies with invasive and noninvasive techniques by the authors are discussed. The declining gradient in oxygen concentrations, the decreasing glucagon/insulin ratio and the different innervation could be important factors in the zonal expression of the genes of carbohydrate-metabolizing enzymes. While it is clear that the hepatocytes sense the glucagon/insulin gradients via the respective hormone receptors, it is not known how they sense different oxygen tensions; the O2 sensor may be an oxygen-binding heme protein. The zonal separation of glucose release and uptake appears to be important for the liver to operate as a 'glucostat'. Thus, zonation of carbohydrate metabolism develops gradually during the first weeks of life, in part before and in part with weaning, when (in rat and mouse) the fat- and protein-rich but carbohydrate-poor nutrition via milk is replaced by carbohydrate-rich food. Similarly, zonation of carbohydrate metabolism adapts to longer lasting alterations in the need of a 'glucostat', such as starvation, diabetes, portocaval anastomoses or partial hepatectomy.

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Functional hepatocellular heterogeneity for the production of plasma proteins. Liver cell heterogeneity: functions of non-parenchymal cells. Hepatocyte heterogeneity in the metabolism of carbohydrates. Zonal liver cell heterogeneity. Hepatocyte heterogeneity in the metabolism of amino acids and ammonia.
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