| 2.A.37 The Monovalent Cation:Proton Antiporter-2 (CPA2) Family
The CPA2 family is a moderately large family (over 100 sequenced members) from bacteria, archaea and eukaryotes. Among the functionally well-characterized members of the family are (1) the KefB/KefC K+ efflux proteins of E. coli which may be capable of catalyzing both K+/H+ antiport and K+ uniport, depending on conditions (Bakker et al., 1987; Booth et al., 1996; Munro et al., 1991), (2) the Na+/H+ antiporter of Enterococcus hirae (Waser et al., 1992) and (3) the K+/H+ antiporter of S. cerevisiae. It has been proposed that under normal physiological conditions, these proteins may function by essentially the same mechanism (Reizer et al., 1992).
KefC and KefB of E. coli are responsible for glutathione-gated K+ efflux (Ferguson et al., 1993, 1997). Each of these proteins consists of a transmembrane hydrophobic N-terminal domain, and a less well-conserved C-terminal hydrophilic domain. Each protein interacts with a second protein encoded by genes that overlap the gene encoding the primary transporter. The KefC ancillary protein is YabF while the KefB ancillary protein is YheR. These ancillary proteins stimulate transport activity about 10-fold (Miller et al., 2000). These proteins are important for cell survival during exposure to toxic metabolites, possibly because they can release K+, allowing H+ uptake. Activation of the KefB or KefC K+ efflux system only occurs in the presence of glutathione and a reactive electrophile such as methylglyoxal or N-ethylmaleimide. Formation of the methylglyoxal-glutathione conjugate, S-lactoylglutathione, is catalyzed by glyoxalase I, and S-lactoylglutathione activates KefB and KefC (MacLean et al., 1998). H+ uptake (acidification of the cytoplasm) accompanying or following K+ efflux may serve as a further protective mechanism against electrophile toxicity (Booth et al., 1996; Ferguson et al., 1993, 1997; Stumpe et al., 1996).
The MagA protein of Magnetospirillum sp. strain AMB-1 is required for synthesis of bacterial magnetic particles. The magA gene is subject to transcriptional activation by an iron deficiency (Nakamura et al., 1995). Its transport function is not known. The GerN and GrmA proteins of Bacillus cereus and Bacillus megaterium, respectively, are spore germination proteins that can exchange Na+ for H+ and/or K+ (Southworth et al., 2001). The AmhT homologue of Bacillus pseudofirmus transports both K+ and NH4+, influences ammonium homeostasis, and is required for normal sporulation and germination. The identification of these proteins as members of the CPA2 family reveals that monovalent cation transport is required for Bacillus spore formation and germination (Tani et al., 1996).
The proteins of the CPA2 family consist of between 333 and 900 amino acyl residues. They exhibit 10-14 transmembrane α-helical spanners (TMSs). Several organisms possess multiple CPA2 paralogues. Thus, E. colihas three, Methanococcus jannaschii has four and Synechocystissp. has five paralogues. Members of the family exhibit considerable sequence divergence.
Some members of the CPA2 family show sequence similarity with certain members of the CPA1 family (TC #2.A.36), while other members of the CPA2 family show limited sequence similarity with proteins of the K+ transporter (Trk) family (TC #2.A.38). CPA1 and CPA2 proteins also are homologous to (but distantly related to) the β-subunits of Na+ transporting organic acid decarboxylases (TC #3.B.1). All four families consist of proteins in the same size range with 10 (or possibly more) putative TMSs.
The generalized transport reaction catalyzed by members of the CPA2 family is:
M+ (in) + nH+ (out)  M+ (out) + nH+ (in).
(The carrier-mediated mode)
Some members may also catalyze:
M+ (in) M+ (out).
(The channel-mediated mode)
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This family belongs to the CPA Superfamily.
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| References: |
Bakker, E.P., A. Borchard, M. Michels, K. Altendorf, and A. Siebers. (1987). High-affinity potassium uptake system in Bacillus acidocaldarius showing immunological cross-reactivity with the Kdp system from Escherichia coli. J. Bacteriol. 169: 4342-4348.
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Booth, I.R., M.A. Jones, D. McLaggan, Y. Nikolaev, L.S. Ness, C.M. Wood, S. Miller, S. Tötemeyer, and G.P. Ferguson. (1996). Bacterial ion channels. In Transport Processes in Eukaryotic and Prokaryotic Organisms, Vol. 2 (W.N. Konings, H.R. Kaback and J.S. Lolkema, eds.), Elsevier Press, New York, pp. 693-729.
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Ferguson, G.P., A.W. Munro, R.M. Douglas, D. McLaggan, and I.R. Booth. (1993). Activation of potassium channels during metabolite detoxification in Escherichia coli. Mol. Microbiol. 9: 1297-1303.
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Ferguson, G.P., S. Tötemeyer, M.J. MacLean, and I.R. Booth. (1998). Methylglyoxal production in bacteria: suicide or survival? Arch. Microbiol. 170: 209-219.
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Ferguson, G.P., Y. Nikolaev, D. McLaggan, M. MacLean, and I.R. Booth. (1997). Survival during exposure to the electrophilic reagent N-ethylmaleimide in Escherichia coli: role of KefB and KefC potassium channels. J. Bacteriol. 179: 1007-1012.
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Inaba, M., A. Sakamoto, and N. Murata. (2001). Functional expression in Escherichia coli of low-affinity and high-affinity Na+(Li+)/H+ antiporters of Synechocystis. J. Bacteriol. 183: 1376-1384.
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MacLean, M.J., L.S. Ness, G.P. Ferguson, and I.R. Booth. (1998). The role of glyoxalase I in the detoxification of methylglyoxal and in the activation of the KefB K+ efflux system in Escherichia coli. Mol. Microbiol. 27: 563-571.
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Miller, S., L.S. Ness, C.M. Wood, B.C. Fox, and I.R. Booth. (2000). Identification of an ancillary protein, YabF, required for activity of the KefC glutathione-gated potassium efflux system in Escherichia coli. J. Bacteriol. 182: 6536-6540.
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Miller, S., R.M. Douglas, P. Carter, and I.R. Booth. (1997). Mutations in the glutathione-gated KefC K+ efflux system of Escherichia coli that cause constitutive activation. J. Biol. Chem. 272: 24942-24947.
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Munro, A.W., G.Y. Ritchie, A.J. Lamb, R.M. Douglas, and I.R. Booth. (1991). The cloning and DNA sequence of the gene for the glutathione-regulated potassium-efflux system KefC of Escherichia coli. Mol. Microbiol. 5: 607-616.
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Nakamura, C., T. Kikuchi, J.G. Burgess, and T. Matsunaga. (1995). Iron-regulated expression and membrane localization of the MagA protein in Magnetospirillum sp. strain AMB-1. J. Biochem. 118: 23-27.
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Ness, L.S. and I.R. Booth. (1999). Different foci for the regulation of the activity of the KefB and KefC glutathione-gated K+ efflux systems. J. Biol. Chem. 274: 9524-9530.
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Ramírez, J., O. Ramírez, C. Saldańa, R. Coria, and A. Peńa. (1998). A Saccharomyces cerevisiae mutant lacking a K+/H+ exchanger. J. Bacteriol. 180: 5860-5865.
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Reizer, J., A. Reizer, and M.H. Saier, Jr. (1992). The putative Na+/H+ antiporter (NapA) of Enterococcus hirae is homologous to the putative K+/H+ antiporter (KefC) of Escherichia coli. FEMS Microbiol. Lett. 94: 161-164.
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Saier, M.H., Jr., B.H. Eng, S. Fard, J. Garg, D.A. Haggerty, W.J. Hutchinson, D.L. Jack, E.C. Lai, H.J. Liu, D.P. Nusinew, A.M. Omar, S.S. Pao, I.T. Paulsen, J.A. Quan, M. Sliwinski, T.-T. Tseng, S. Wachi, and G.B. Young. (1999). Phylogenetic characterization of novel transport protein families revealed by genome analyses. Biochim. Biophys. Acta 1422: 1-56.
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Southworth, T.W., A.A. Guffanti, A. Moir, and T.A. Krulwich. (2001). GerN, an endospore germination protein of Bacillus cereus, is an Na+/H+-K+ antiporter. J. Bacteriol. 183: 5896-5903.
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Stumpe, S., A. Schlösser, M. Schleyer, and E.P. Bakker. (1996). K+ circulation across the prokaryotic cell membrane: K+-uptake systems. In Transport Processes in Eukaryotic and Prokaryotic Organisms, Vol. 2 (W.N. Konings, H.R. Kaback and J.S. Lolkema, eds.), Elsevier Press, New York, pp. 473-499.
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Tani, K., T. Watanabe, H. Matsuda, M. Nasu, and M. Kondo. (1996). Cloning and sequencing of the spore germination gene of Bacillus megaterium ATCC 12872: similarities to the NaH-antiporter gene of Enterococcus hirae. Microbiol. Immunol. 40: 99-105.
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Waser, M., D. Hess-Bienz, K. Davies, and M. Solioz. (1992). Cloning and disruption of a putative NaH-antiporter gene of Enterococcus hirae. J. Biol. Chem. 267: 5396-5400.
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Wei, Y., T.W. Southworth, H. Kloster, M. Ito, A.A. Guffanti, A. Moir, and T.A. Krulwich. (2003). Mutational loss of a K+ and NH4+ transporter affects the growth and endospore formation of alkaliphilic Bacillus pseudofirmus OF4. J. Bacteriol. 185: 5133-5147.
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| Examples: |
| TC# | Name | Organismal Type | Example |
| 2.A.37.1.1 | Glutathione-regulated K+ efflux protein C, KefC | Bacteria | KefC of E. coli; ancillary protein, YabF |
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| 2.A.37.1.2 | Glutathione-regulated K+ efflux protein B, KefB | Bacteria | KefB of E. coli; ancillary protein, YheR |
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| 2.A.37.2.1 | Na+:H+ antiporter, NapA | Bacteria | NapA of Enterococcus hirae |
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| 2.A.37.2.2 | The Na+/H+-K+ antiporter, GerN (spore germination protein-N) | Gram-positive bacteria | GerN of Bacillus cereus |
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| 2.A.37.2.3 | Spore germination protein, GrmA | Gram-positive bacteria | GrmA of Bacillus megaterium |
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| 2.A.37.2.4 | The high-affinity (Km(Na+)=0.7 mM) Na+(Li+):H+ antiporter, NhaS3 | Bacteria | NhaS3 of Synechocystis sp. PCC6803 |
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| 2.A.37.3.1 | Iron-regulated MagA protein | Magnetotactic bacteria | MagA of Magnetospirillum sp. strain AMB-1 |
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| 2.A.37.4.1 | K+:H+ antiporter, Kha1 (YJL094c) | Yeast | Kha1 of Saccharomyces cerevisiae |
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| 2.A.37.5.1 | The bidirectional K+/NH4+ transporter, AmhT (ammonium homeostasis transporter) | Bacteria | AmhT of Bacillus pseudofirmus (AAB87747) |
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