NaChBac, a six-␣-helical transmembrane-spanning protein cloned from Bacillus halodurans, is the first functionally characterized bacterial voltage-gated Na ؉ -selective channel (Ren, D., Navarro, B., Xu, H., Yue, L., Shi, Q., and Clapham, D. E. (2001) Science 294, 2372-2375). As a highly expressing ion channel protein, NaChBac is an ideal candidate for high resolution structural determination and structure-function studies. The biological role of NaChBac, however, is still unknown. In this report, another 11 structurally related bacterial proteins are described. Two of these functionally expressed as voltage-dependent Na ؉ channels (Na V PZ from Paracoccus zeaxanthinifaciens and Na V SP from Silicibacter pomeroyi). Na V PZ and Na V SP share ϳ40% amino acid sequence identity with NaChBac. When expressed in mammalian cell lines, both Na V PZ and Na V SP were Na ؉ -selective and voltage-dependent. However, their kinetics and voltage dependence differ significantly. These single six-␣-helical transmembranespanning subunits constitute a widely distributed superfamily (Na V Bac) of channels in bacteria, implying a fundamental prokaryotic function. The degree of sequence homology (22-54%) is optimal for future comparisons of Na V Bac structure and function of similarity and dissimilarity among Na V Bac proteins. Thus, the Na V Bac superfamily is fertile ground for crystallographic, electrophysiological, and microbiological studies.Mammalian voltage-gated sodium (Na V ) 1 and calcium (Ca V ) channels underlie membrane excitability, muscle contraction, and hormone secretion (1). In contrast, the function of prokaryotic voltage-gated ion-selective channels is relatively unknown. Na ϩ channels may drive Na ϩ -dependent flagellar motors in certain marine and alkaliphilic species (2-6). In marine vibrio, PomAB and MotXY have been proposed to form a functional Na ϩ channel (5, 6), but the conductance has not been directly measured. In alkaliphilic bacteria, the prokaryotic ion channel responsible has not been identified. A bacterial 6-␣-helical transmembrane (6TM) channel subunit NaChBac was expressed in CHO cells as a functional voltage-gated Na ϩ channel (7), but its role in bacteria is still being elucidated.The pore-forming subunits (␣ 1 ) of mammalian Na V and Ca V are composed of four similar repeats of 6TM domains (8, 9), probably arising by gene duplication of a single 6TM gene (1, 10). The first bacterial voltage-gated Na ϩ channel (NaChBac) functionally expressed in mammalian cells was cloned from Bacillus halodurans (7). It contains a single 6TM domain of 274 amino acids but almost certainly forms a tetramer (7). NaChBac voltagedependent activation and inactivation kinetics are 10 -100 times slower than that of Na V (7). NaChBac inactivation may result from pore inactivation (C-type inactivation), since it does not contain an obvious cytoplasmic inactivation gate (7).Because single 6TM Na ϩ -selective ion channels do not appear to be present in vertebrates, the 24 TM structure of Na V s may have arisen under evolut...
