Kispal G, Melegh B, Alkonyi I, Sandor A
Biochim Biophys Acta. 1987 Jan 9;896(1):96-102. doi: 10.1016/0005-2736(87)90360-9.
Previously, the release of carnitine from the perfused rat liver was found to be protein-mediated, dependent on the nutritional state but not on metabolic energy. Further, it was shown to exceed the physiological demand by about 10-fold (Sandor et al. (1985) Biochim. Biophys. Acta 835, 83-91). In the present study the uptake of carnitine by perfused rat liver has been investigated. The liver tissue and the perfusate were in equilibrium when the carnitine concentration in the perfusate was close to 45 microM, physiological in the rat plasma. Under this condition, when no net carnitine transport occurred, an unidirectional uptake of L-[3H]carnitine was observed. Quantitatively, the uptake rate was 355 +/- 60 (S.D.) nmol/h per 100 g body weight at 45-50 microM perfusate concentration. This uptake capacity balances the previously reported excessive release (Sandor et al., op. cit.). On this basis we propose that a futile release/uptake cycle operates in carnitine transport across the liver cell membrane. Liverse of 24-h starved rats took up L-[3H]carnitine at 56% higher rate from the perfusate (75 microM) than livers of fed rats. Kinetic analysis revealed that fasting caused a decrease in Km value from 4.22 mM to 2.59 mM, whereas Vmax remained practically unchanged, average 0.95 mumol/min per 100 g body weight. D-[3H]Carnitine was transported at the same rate as L-carnitine and underwent the effect of fasting as well. The uptake was partially inhibited by 1 mM 2,4-dinitrophenol and 5 mM KCN, showing its dependency on metabolic energy. If Li+ replaced Na+ a strong inhibitory effect (to 20% of control) was observed, which suggests a co-transport of carnitine with Na+. Mersalyl, an SH reagent, had no effect on the uptake, whereas it practically abolished the release of carnitine from the perfused livers. This observation suggests that the inward and outward transport of carnitine are mediated by two different proteins.
先前发现,从灌注的大鼠肝脏中释放肉碱是由蛋白质介导的,取决于营养状态而非代谢能量。此外,已表明其释放量超过生理需求量约10倍(桑多尔等人(1985年)《生物化学与生物物理学报》835卷,83 - 91页)。在本研究中,对灌注大鼠肝脏摄取肉碱的情况进行了研究。当灌注液中的肉碱浓度接近45微摩尔时,肝脏组织与灌注液达到平衡,该浓度在大鼠血浆中为生理浓度。在此条件下,当没有净肉碱转运发生时,观察到L - [³H]肉碱的单向摄取。定量分析表明,在灌注液浓度为45 - 50微摩尔时,摄取速率为每100克体重355±60(标准差)纳摩尔/小时。这种摄取能力与先前报道的过量释放相平衡(桑多尔等人,同前)。在此基础上,我们提出在肉碱跨肝细胞膜的转运过程中存在一个无效的释放/摄取循环。24小时饥饿大鼠的肝脏从灌注液(75微摩尔)中摄取L - [³H]肉碱的速率比喂食大鼠的肝脏高56%。动力学分析表明,禁食使米氏常数(Km)值从4.22毫摩尔降至2.59毫摩尔,而最大反应速度(Vmax)实际上保持不变,平均为每100克体重0.95微摩尔/分钟。D - [³H]肉碱的转运速率与L - 肉碱相同,并且也受到禁食的影响。摄取部分受到1毫摩尔2,4 - 二硝基苯酚和5毫摩尔氰化钾的抑制,表明其对代谢能量的依赖性。如果用锂离子取代钠离子,会观察到强烈的抑制作用(降至对照的20%),这表明肉碱与钠离子协同转运。汞撒利,一种巯基试剂,对摄取没有影响,而它实际上消除了灌注肝脏中肉碱的释放。这一观察结果表明,肉碱的内向和外向转运是由两种不同的蛋白质介导的。
