Reynafarje B, Lehninger A L
Proc Natl Acad Sci U S A. 1978 Oct;75(10):4788-92. doi: 10.1073/pnas.75.10.4788.
This paper describes the properties and a possible biological role of a transport process across the inner membrane of rat liver mitochondria resulting in the exchange of ATP(4-) (out) for ADP(3-) (in) + 0.5 phosphate(2-) (in). This transmembrane exchange reaction, designated as the ATP-ADP-phosphate exchange, is specific for the ligands shown, electroneutral, insensitive to N-ethylmaleimide or mersalyl, inhibited by atractyloside, and appears to occur only in the direction as written. It is thus distinct from the well-known phosphate-hydroxide and phosphate-dicarboxylate exchange systems, which are inhibited by mersalyl, and from the ATP-ADP exchanger, which does not transport phosphate. During ATP hydrolysis by mitochondria, half of the phosphate formed from ATP passes from the matrix to the medium by the mersalyl-insensitive ATP-ADP-phosphate exchange and the other half by the well-known mersalyl-sensitive phosphate-hydroxide exchange. These and other considerations have led to a hypothesis for the pathway and stoichiometry of ATP-dependent reverse electron transport, characterized by a requirement of 1.33 molecules of ATP per pair of electrons reversed and by the utilization of a different membrane transport pathway for phosphate and adenine nucleotides than is taken in forward electron flow and oxidative phosphorylation. The possible occurrence of independent pathways for ATP-forming forward electron flow and ATP-consuming reverse electron flow is consonant with the fact that the opposing degradative and synthetic pathways in the central routes of cell metabolism generally have different pathways that are independently regulated.
本文描述了大鼠肝脏线粒体内膜上一种转运过程的特性及其可能的生物学作用,该转运过程导致ATP(4-)(向外)与ADP(3-)(向内)+0.5磷酸(2-)(向内)进行交换。这种跨膜交换反应,称为ATP-ADP-磷酸交换,对所示配体具有特异性,呈电中性,对N-乙基马来酰胺或汞撒利不敏感,受苍术苷抑制,且似乎仅按所写方向发生。因此,它不同于众所周知的受汞撒利抑制的磷酸-氢氧根和磷酸-二羧酸交换系统,也不同于不转运磷酸的ATP-ADP交换体。在由线粒体进行的ATP水解过程中,由ATP形成的磷酸的一半通过对汞撒利不敏感的ATP-ADP-磷酸交换从基质转移到介质中,另一半则通过众所周知的对汞撒利敏感的磷酸-氢氧根交换。这些以及其他因素导致了一个关于ATP依赖性逆向电子传递途径和化学计量的假说,其特征是每对逆向电子需要1.33个ATP分子,并且对于磷酸和腺嘌呤核苷酸利用了与正向电子流和氧化磷酸化不同的膜转运途径。ATP形成的正向电子流和ATP消耗的逆向电子流可能存在独立途径,这与细胞代谢中心途径中相反的降解和合成途径通常具有独立调节的不同途径这一事实是一致的。