大肠杆菌中脯氨酸和谷氨酰胺主动运输的不同能量偶联机制。

Different mechanisms of energy coupling for the active transport of proline and glutamine in Escherichia coli.

作者信息

Berger E A

出版信息

Proc Natl Acad Sci U S A. 1973 May;70(5):1514-8. doi: 10.1073/pnas.70.5.1514.

DOI:10.1073/pnas.70.5.1514

PMID:4268097

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC433532/

Abstract

The ability of either glucose or D-lactate to energize active transport of amino acids in E. coli was studied in starved cells blocked at specific sites of energy metabolism. Proline uptake could be driven by either oxidative or substrate-level processes. The oxidative pathway was sensitive to cyanide but not to arsenate, and operated normally in a mutant deficient in the Ca, Mg-dependent ATPase. The substrate-level pathway, which was active with glucose but not with D-lactate as the carbon source, was sensitive to arsenate but not to cyanide, and required a functional ATPase. Uncouplers prevented the utilization of energy for proline uptake by either pathway. Energy coupling for glutamine uptake was quite different. The oxidative pathway was sensitive to cyanide and uncouplers and, in contrast with proline, required an active ATPase. The glycolytic component was resistant to cyanide and uncouplers, and functioned normally in the ATPase mutant. Arsenate abolished glutamine transport energized by either pathway. The results suggest that proline transport is driven directly by an energy-rich membrane state, which can be generated by either electron transport or ATP hydrolysis. Glutamine uptake, on the other hand, is apparently driven directly by phosphate-bond energy formed by way of oxidative or substrate-level phosphorylations.

摘要

在能量代谢特定位点受阻的饥饿细胞中，研究了葡萄糖或D - 乳酸为大肠杆菌中氨基酸主动运输提供能量的能力。脯氨酸的摄取可以由氧化过程或底物水平过程驱动。氧化途径对氰化物敏感，但对砷酸盐不敏感，并且在缺乏钙、镁依赖性ATP酶的突变体中正常运作。底物水平途径以葡萄糖而非D - 乳酸作为碳源时具有活性，对砷酸盐敏感但对氰化物不敏感，并且需要功能性的ATP酶。解偶联剂阻止了通过任何一种途径利用能量进行脯氨酸摄取。谷氨酰胺摄取的能量偶联则大不相同。氧化途径对氰化物和解偶联剂敏感，与脯氨酸不同的是，需要有活性的ATP酶。糖酵解成分对氰化物和解偶联剂有抗性，并且在ATP酶突变体中正常发挥作用。砷酸盐消除了通过任何一种途径驱动的谷氨酰胺运输。结果表明，脯氨酸运输直接由富含能量的膜状态驱动，这种状态可以通过电子传递或ATP水解产生。另一方面，谷氨酰胺摄取显然直接由通过氧化或底物水平磷酸化形成的磷酸键能量驱动。

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本文引用的文献

Mutants of Escherichia coli requiring methionine or vitamin B12.需要甲硫氨酸或维生素B12的大肠杆菌突变体。

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