Padan E, Venturi M, Gerchman Y, Dover N
Department of Microbial and Molecular Ecology, Institute of Life Sciences, Hebrew University of Jerusalem, Israel.
Biochim Biophys Acta. 2001 May 1;1505(1):144-57. doi: 10.1016/s0005-2728(00)00284-x.
Na(+)/H(+) antiporters are membrane proteins that play a major role in pH and Na(+) homeostasis of cells throughout the biological kingdom, from bacteria to humans and higher plants. The emerging genomic sequence projects already have started to reveal that the Na(+)/H(+) antiporters cluster in several families. Structure and function studies of a purified antiporter protein have as yet been conducted mainly with NhaA, the key Na(+)/H(+) antiporter of Escherichia coli. This antiporter has been overexpressed, purified and reconstituted in a functional form in proteoliposomes. It has recently been crystallized in both 3D as well as 2D crystals. The NhaA 2D crystals were analyzed by cryoelectron microscopy and a density map at 4 A resolution was obtained and a 3D map was reconstructed. NhaA is shown to exist in the 2D crystals as a dimer of monomers each composed of 12 transmembrane segments with an asymmetric helix packing. This is the first insight into the structure of a polytopic membrane protein. Many Na(+)/H(+) antiporters are characterized by very dramatic sensitivity to pH, a property that corroborates their role in pH homeostasis. The molecular mechanism underlying this pH sensitivity has been studied in NhaA. Amino acid residues involved in the pH response have been identified. Conformational changes transducing the pH change into a change in activity were found in loop VIII-IX and at the N-terminus by probing trypsin digestion or binding of a specific monoclonal antibody respectively. Regulation by pH of the eukaryotic Na(+)/H(+) antiporters involves an intricate signal transduction pathway (recently reviewed by Yun et al., Am. J. Physiol. 269 (1995) G1-G11). The transcription of NhaA has been shown to be regulated by a novel Na(+)-specific regulatory network. It is envisaged that interdisciplinary approaches combining structure, molecular and cell biology as well as genomics should be applied in the future to the study of this important group of transporters.
钠/氢反向转运蛋白是一类膜蛋白,在从细菌到人类及高等植物的整个生物界中,对细胞的pH值和钠稳态起着重要作用。新兴的基因组序列计划已开始揭示,钠/氢反向转运蛋白分属于几个家族。目前,对纯化的反向转运蛋白的结构和功能研究主要是针对大肠杆菌的关键钠/氢反向转运蛋白NhaA进行的。该反向转运蛋白已在蛋白脂质体中以功能形式进行了过表达、纯化和重组。最近,它已形成了三维和二维晶体。通过冷冻电子显微镜对NhaA二维晶体进行了分析,获得了分辨率为4埃的密度图,并重建了三维图。结果表明,NhaA在二维晶体中以单体二聚体形式存在,每个单体由12个跨膜片段组成,具有不对称的螺旋堆积。这是对多跨膜蛋白结构的首次深入了解。许多钠/氢反向转运蛋白的特点是对pH值非常敏感,这一特性证实了它们在pH稳态中的作用。在NhaA中研究了这种pH敏感性的分子机制。已确定了参与pH反应的氨基酸残基。分别通过探测胰蛋白酶消化或特异性单克隆抗体的结合,发现在环VIII-IX和N端存在将pH变化转化为活性变化的构象变化。真核生物钠/氢反向转运蛋白的pH调节涉及复杂的信号转导途径(最近Yun等人对此进行了综述,《美国生理学杂志》269(1995)G1-G11)。已证明NhaA的转录受一个新的钠特异性调节网络调控。预计未来应将结合结构、分子和细胞生物学以及基因组学的跨学科方法应用于这一重要转运蛋白组的研究。
