碳酸氢盐对大鼠肝脏分离实质细胞内区室间还原当量转运的影响。
Effects of bicarbonate on intercompartmental reducing-equivalent translocation in isolated parenchymal cells from rat liver.
作者信息
Berry M N, Werner H V, Kun E
出版信息
Biochem J. 1974 Jun;140(3):355-61. doi: 10.1042/bj1400355.
Abstract
- Incubation of isolated liver cells in a medium containing bicarbonate raises malate concentrations almost sixfold compared with values obtained in a bicarbonate-free phosphate medium. The malate concentration of about 0.3mm in bicarbonate medium is of the same order as the K(m) for malate dehydrogenase. 2. The utilization of ethanol, glyercol and sorbitol was increased by 20-35% in bicarbonate medium. 3. Fluoromalate, a specific inhibitor of malate dehydrogenase and the malate carrier, inhibited or ethanol oxidation by 23%, glycerol uptake by 20% and sorbitol uptake by 42% in bicarbonate medium, but had a much smaller inhibitory action in phosphate medium. In consequence fluoromalate almost abolished the stimulatory effects of bicarbonate on substrate utilization. 4. Difluoro-oxaloacetate, a specific inhibitor of aspartate aminotransferase, had about one-half the inhibitory activity of fluoromalate. The two inhibitors in combination were less effective than fluoromalate by itself. 5. It is concluded that bicarbonate stimulates the utilization of reduced substrates, which are oxidized in the cytoplasmic compartment of the liver cell, by increasing the activity of rate-limiting malate dehydrogenase-dependent intercompartmental hydrogen shuttles. Both malate-oxaloacetate and malate-aspartate systems are involved in these hydrogen-translocation processes.
摘要
- 与在不含碳酸氢盐的磷酸盐培养基中所获值相比,将分离的肝细胞置于含碳酸氢盐的培养基中孵育会使苹果酸浓度提高近六倍。在碳酸氢盐培养基中约0.3mmol/L的苹果酸浓度与苹果酸脱氢酶的米氏常数处于同一数量级。2. 在碳酸氢盐培养基中,乙醇、甘油和山梨醇的利用率提高了20% - 35%。3. 氟代苹果酸是苹果酸脱氢酶和苹果酸载体的特异性抑制剂,在碳酸氢盐培养基中,它使乙醇氧化受到23%的抑制,甘油摄取受到20%的抑制,山梨醇摄取受到42%的抑制,但在磷酸盐培养基中的抑制作用要小得多。因此,氟代苹果酸几乎消除了碳酸氢盐对底物利用的刺激作用。4. 二氟草酰乙酸是天冬氨酸氨基转移酶的特异性抑制剂,其抑制活性约为氟代苹果酸的一半。这两种抑制剂联合使用的效果不如单独使用氟代苹果酸。5. 得出的结论是,碳酸氢盐通过提高限速的依赖苹果酸脱氢酶的细胞间氢穿梭的活性,刺激肝细胞胞质区室中被氧化的还原型底物的利用。苹果酸 - 草酰乙酸和苹果酸 - 天冬氨酸系统都参与了这些氢转运过程。
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