Parce J W, Spach P I, Cunningham C C
Biochem J. 1980 Jun 15;188(3):817-22. doi: 10.1042/bj1880817.
In a previous study [Parce, Cunningham & Waite (1978) Biochemistry 17, 1634-1639] changes in mitochondrial phospholipid metabolism and energy-linked functions were monitored as coupled mitochondria were aged in iso-osmotic sucrose solution at 18 degrees C. The sequence of events that occur in mitochondrial deterioration under the above conditions have been established more completely. Total adenine nucleotides are depleted early in the aging process, and their loss parallels the decline in respiratory control. Related to the loss of total adenine nucleotides is a dramatic decrease in ADP and ATP translocation (uptake). The decline of respiratory control is due primarily to a decrease in State-3 respiration; loss of this respiratory activity can be related to the decline in ADP translocation. Mitochondrial ATPase activity does not increase significantly until State-4 respiration has increased appreciably. At the time of loss of respiratory control the ATPase activity increases to equal the uncoupler-stimulated activity. The H+/O ratio and P/O ratios do not decrease appreciably until respiratory control is lost. Similarly, permeability of the membrane to the passive diffusion of protons increases only after respiratory control is lost. There observations reinforce our earlier conclusion that there are two main phases in mitochondrial aging. The first phase is characterized by loss of the ability to translocate adenine nucleotides. The second phase is characterized by a decline in the ability of the mitochondrion to conserve energy (i.e. maintain a respiration-driven proton gradient) and to synthesize ATP.
在之前的一项研究中[帕尔塞、坎宁安和韦特(1978年),《生物化学》17卷,第1634 - 1639页],当偶联的线粒体在18℃的等渗蔗糖溶液中老化时,监测了线粒体磷脂代谢和能量相关功能的变化。在上述条件下线粒体退化过程中发生的一系列事件已得到更全面的确立。在老化过程早期,总腺嘌呤核苷酸就会耗尽,其损失与呼吸控制的下降平行。与总腺嘌呤核苷酸的损失相关的是ADP和ATP转运(摄取)的显著下降。呼吸控制的下降主要是由于状态3呼吸的减少;这种呼吸活性的丧失可能与ADP转运的下降有关。直到状态4呼吸明显增加,线粒体ATP酶活性才会显著增加。在呼吸控制丧失时,ATP酶活性增加到与解偶联剂刺激的活性相等。直到呼吸控制丧失,H⁺/O比值和P/O比值才会明显下降。同样,膜对质子被动扩散的通透性只有在呼吸控制丧失后才会增加。这些观察结果强化了我们早期的结论,即线粒体老化有两个主要阶段。第一阶段的特征是腺嘌呤核苷酸转运能力的丧失。第二阶段的特征是线粒体保存能量(即维持呼吸驱动的质子梯度)和合成ATP的能力下降。