Nath K A, Croatt A J, Hostetter T H
Department of Medicine, University of Minnesota, Minneapolis 55455.
Am J Physiol. 1990 May;258(5 Pt 2):F1354-62. doi: 10.1152/ajprenal.1990.258.5.F1354.
We investigated the effects of reduction of renal mass on rates of oxygen consumption, sodium transport, and indexes of oxidant stress in surviving nephrons. Rates of oxygen consumption in surviving nephrons were elevated by more than twofold compared with nephrons in intact kidneys in rats on standard protein intakes. Absolute rates of sodium reabsorption (TNa) in the surviving nephrons were increased with a lower ratio of TNa to oxygen consumption. To determine oxidant stress, we measured malondialdehyde (MDA) in the kidney and urine and the glutathione redox ratio in kidney tissue. MDA per nephron was increased in the subtotally nephrectomized model and was accompanied by increased absolute and fractional urinary excretion of MDA but not by an increase in kidney MDA per milligram protein. The glutathione redox ratios were similar. Since increased dietary protein intake worsens renal injury, we studied the effects of dietary protein manipulation (30 vs. 6%) on oxygen consumption, MDA levels, and the glutathione redox ratio. The kidneys of subtotally nephrectomized animals maintained on 30% protein diets exhibited increased rates of oxygen consumption. Increased dietary protein intake led to increased MDA per nephron, increased urinary excretion of MDA, and increased MDA per milligram protein in subtotally nephrectomized animals, and markedly increased the glutathione redox ratio. We conclude that, despite increased oxygen consumption, surviving nephrons compared with intact nephrons in rats on standard protein intake demonstrate no evidence of oxidant stress. Increased urinary clearance of MDA may provide a mechanism that prevents the buildup of lipid peroxidation. Subjecting the remnant nephron to increased protein increases oxygen consumption and imposes oxidant stress.(ABSTRACT TRUNCATED AT 250 WORDS)
我们研究了肾单位减少对存活肾单位的氧消耗率、钠转运以及氧化应激指标的影响。与标准蛋白摄入量的大鼠完整肾脏中的肾单位相比,存活肾单位的氧消耗率提高了两倍多。存活肾单位中钠重吸收的绝对速率(TNa)增加,而TNa与氧消耗的比率降低。为了确定氧化应激,我们测量了肾脏和尿液中的丙二醛(MDA)以及肾组织中的谷胱甘肽氧化还原比。在次全肾切除模型中,每个肾单位的MDA增加,同时MDA的绝对和分数尿排泄增加,但每毫克蛋白质的肾脏MDA没有增加。谷胱甘肽氧化还原比相似。由于增加饮食蛋白摄入量会加重肾损伤,我们研究了饮食蛋白控制(30%与6%)对氧消耗、MDA水平和谷胱甘肽氧化还原比的影响。维持30%蛋白质饮食的次全肾切除动物的肾脏表现出氧消耗率增加。增加饮食蛋白摄入量导致次全肾切除动物每个肾单位的MDA增加、MDA尿排泄增加以及每毫克蛋白质的肾脏MDA增加,并显著提高了谷胱甘肽氧化还原比。我们得出结论,尽管氧消耗增加,但与标准蛋白摄入量的大鼠完整肾单位相比,存活肾单位没有氧化应激的证据。MDA尿清除率增加可能提供了一种防止脂质过氧化积累的机制。使残余肾单位暴露于增加的蛋白质中会增加氧消耗并施加氧化应激。(摘要截断于250字)
