Tarshis M A, Demikova N S, Migushina V L
Biokhimiia. 1978 Mar;43(3):498-503.
Possible energy supply pathways of active transport of non-metabolized 3-O-methylglucose (3-O-mG) into Acholeplasma laidlawii cells are studied. 3-O-MG transport is sensitive to arsenate, inhibitors of glucolysis and membrane Mg-dependent ATPase (dicyclohexylcarbodiimide) and to uncoupling agents. It is suggested that glycolysis is the main energy source, which main enzymes are found in cell-free extracts. A. laidlawii cells are capable to glycolytic ATP synthesis using glucose as a substrate but not fructose, arginine and ethanol. ATP synthesis is also sensitive to arsenate and glycolytic inhibitors and is resistant to uncoupling agents, dicyclohexylcarbodiimide, valinomycin and nigericin. Probably, hydrolysis of glycolytic ATP by membrane-bound ATPase results in the formation on a membrane of both components of proton-motive force, which supply energy for the active 3-O-MG transport. It is supported with the data on the inhibitor analysis of transport using ionic-selecive antibiotics and lipid-soluble ions.
对非代谢性3 - O - 甲基葡萄糖(3 - O - mG)主动转运至莱氏无胆甾原体细胞的可能能量供应途径进行了研究。3 - O - mG转运对砷酸盐、糖酵解抑制剂和膜镁依赖性ATP酶(二环己基碳二亚胺)以及解偶联剂敏感。研究表明糖酵解是主要能量来源,其主要酶存在于无细胞提取物中。莱氏无胆甾原体细胞能够以葡萄糖为底物进行糖酵解ATP合成,但不能利用果糖、精氨酸和乙醇。ATP合成也对砷酸盐和糖酵解抑制剂敏感,且对解偶联剂、二环己基碳二亚胺、缬氨霉素和尼日利亚菌素具有抗性。可能是膜结合ATP酶对糖酵解ATP的水解导致质子动力势的两个组分在膜上形成,为3 - O - mG的主动转运提供能量。这一观点得到了使用离子选择性抗生素和脂溶性离子对转运进行抑制剂分析的数据支持。