Department of Botany, Bharathidasan University, 620023, Tiruchirappalli, India.
Photosynth Res. 1987 Jan;14(2):113-24. doi: 10.1007/BF00032316.
NADP-malate dehydrogenase extracted from darkened leaves of the C3 plants pea, barley, wheat and spinach was activated by reduced glutathione, a monothiol, as well as by dithiothreitol (DTT). However, in the C4 plants maize and Flaveria trinervia, only dithiothreitol could effectively activate the enzyme. There was no activation of the maize enzyme and little or no activation of the F. trinervia enzyme by glutathione. The failure of glutathione to activate NADP-MDH in leaf extracts of maize and F. trinervia may indicate there is some difference in disulfide groups of the protein compared to the C3 plant enzyme. Both DTT and glutathione could activate NADP-malate dehydrogenase in a partially purified enzyme preparation from pea leaves with or without addition of partially purified thioredoxin. However, the required concentration of reductant was lower with addition of thioredoxin than in its absence. In extracts of C3 species and the partially purified pea enzyme the level of activation after 40 to 60 min under aerobic conditions was higher (up to twofold) with DTT than with glutathione. Under anaerobic conditions, the initial rate of activation was about twice as high with DTT as with glutathione, but the total activation after 40 to 60 min was similar. Ascorbate was totally ineffective as a reducing agent in activating NADP-MDH from C3 or C4 plants, possibly due to its more positive redox potential.
从 C3 植物豌豆、大麦、小麦和菠菜的黑暗叶片中提取的 NADP-苹果酸脱氢酶被还原型谷胱甘肽(一种单硫醇)和二硫苏糖醇(DTT)激活。然而,在 C4 植物玉米和 Flaveria trinervia 中,只有 DTT 能够有效地激活该酶。谷胱甘肽不能激活玉米酶,对 F. trinervia 酶的激活作用很小或没有。谷胱甘肽不能激活玉米和 F. trinervia 叶片提取物中的 NADP-MDH,这可能表明与 C3 植物酶相比,该蛋白的二硫键存在一些差异。DTT 和谷胱甘肽均可在添加或不添加部分纯化的硫氧还蛋白的情况下,激活来自豌豆叶片的部分纯化酶制剂中的 NADP-苹果酸脱氢酶。然而,添加硫氧还蛋白时所需的还原剂浓度低于不添加时的浓度。在 C3 物种和部分纯化的豌豆酶的提取物中,在有氧条件下 40 至 60 分钟后,DTT 比谷胱甘肽的激活水平更高(高达两倍)。在厌氧条件下,DTT 作为还原剂激活 NADP-MDH 的初始速率比谷胱甘肽高约两倍,但 40 至 60 分钟后的总激活程度相似。抗坏血酸作为还原剂完全不能激活 C3 或 C4 植物的 NADP-MDH,可能是因为其氧化还原电位更正。
