大肠杆菌ATP合酶的γ亚基。羧基末端区域的突变可恢复与氨基末端突变体γ Met-23→Lys的能量偶联。

The gamma subunit of the Escherichia coli ATP synthase. Mutations in the carboxyl-terminal region restore energy coupling to the amino-terminal mutant gamma Met-23-->Lys.

作者信息

Nakamoto R K, Maeda M, Futai M

机构信息

Department of Organic Chemistry and Biochemistry, Osaka University, Japan.

出版信息

J Biol Chem. 1993 Jan 15;268(2):867-72.

PMID:8419364

Abstract

The gamma subunit mutations, gamma Met-23-->Lys or Arg, in the Escherichia coli ATP synthase were previously reported to cause dramatically inefficient energy coupling between ATPase catalysis and H+ translocation (Shin, K., Nakamoto, R.K., Maeda, M., and Futai, M. (1992) J. Biol. Chem. 267, 20835-20839). In this paper, we report that second-site mutations in the gamma subunit can suppress the effects of gamma Met-23-->Lys. By screening randomly mutagenized uncG (gamma Met-23-->Lys), eight mutations in the carboxyl-terminal region were identified; strains carrying gamma Arg-242-->Cys, gamma Gln-269-->Arg, gamma Ala-270-->Val, gamma Ile-272-->Thr, gamma Thr-273-->Ser, gamma Glu-278-->Gly, gamma Ile-279-->Thr, or gamma Val-280-->Ala in combination with gamma Met-23-->Lys were able to grow by oxidative phosphorylation. H+ pumping assayed in membranes prepared from double mutation strains demonstrated that efficient ATP-dependent H+ transport was restored. Interestingly, the single mutations, gamma Gln-269-->Arg or gamma Thr-273-->Ser, caused reduced growth by oxidative phosphorylation; however, when these mutations were in combination with gamma Met-23-->Lys, growth was substantially increased. Furthermore, strains carrying gamma Met-23-->Lys, gamma Gln-269-->Arg, or gamma Thr-273-->Ser as single mutations were temperature sensitive, whereas, strains with the double mutations, gamma Met-23-->Lys/gamma Gln-269-->Arg or gamma Met-23-->Lys/gamma Thr-273-->Ser, were thermally stable. Taken together, these results strongly suggest that gamma Met-23, gamma Arg-242, and the region between gamma Gln-269 to gamma Val-280 are close to each other and interact to mediate efficient energy coupling.

摘要

先前有报道称，大肠杆菌ATP合酶中的γ亚基突变，即γ Met-23→Lys或Arg，会导致ATP酶催化与H⁺转运之间的能量偶联效率显著降低（Shin, K., Nakamoto, R.K., Maeda, M., and Futai, M. (1992) J. Biol. Chem. 267, 20835 - 20839）。在本文中，我们报道γ亚基中的第二位点突变可以抑制γ Met-23→Lys的影响。通过筛选随机诱变的uncG（γ Met-23→Lys），在羧基末端区域鉴定出8个突变；携带γ Arg-242→Cys、γ Gln-269→Arg、γ Ala-270→Val、γ Ile-272→Thr、γ Thr-273→Ser、γ Glu-278→Gly、γ Ile-279→Thr或γ Val-280→Ala并与γ Met-23→Lys组合的菌株能够通过氧化磷酸化生长。对双突变菌株制备的膜进行的H⁺泵送分析表明，依赖ATP的高效H⁺转运得以恢复。有趣的是，单一突变γ Gln-269→Arg或γ Thr-273→Ser会导致氧化磷酸化生长减少；然而，当这些突变与γ Met-23→Lys组合时，生长显著增加。此外，携带γ Met-23→Lys、γ Gln-269→Arg或γ Thr-273→Ser作为单一突变的菌株对温度敏感，而具有双突变γ Met-23→Lys/γ Gln-269→Arg或γ Met-23→Lys/γ Thr-273→Ser的菌株则具有热稳定性。综上所述，这些结果强烈表明γ Met-23、γ Arg-242以及γ Gln-269至γ Val-280之间的区域彼此靠近并相互作用，以介导高效的能量偶联。

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大肠杆菌ATP合酶的γ亚基。羧基末端区域的突变可恢复与氨基末端突变体γ Met-23→Lys的能量偶联。

The gamma subunit of the Escherichia coli ATP synthase. Mutations in the carboxyl-terminal region restore energy coupling to the amino-terminal mutant gamma Met-23-->Lys.

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