| 2.A.21 The Solute:Sodium Symporter (SSS) Family
Members of the SSS family catalyze solute:Na+ symport. The solutes transported may be sugars, amino acids, organo cations such as choline, nucleosides, inositols, vitamins, urea or anions, depending on the system. Members of the SSS family have been identified in bacteria, archaea and animals, and all functionally well-characterized members normally catalyze solute uptake via Na+ symport. The human placental multivitamin symporter cotransports an anionic vitamin with two Na+. In the rabbit Na+:D-glucose cotransporter, SGLT1, the glucose translocation pathway probably involves TMSs 10-13, and the binding site for the inhibitor, phlorizin, involves loop 13 (residues 604-610). Cation binding in the N-terminal domain may induce transport-related conformational changes.
In the human homologue (hSGLT1), H+ can replace Na+, but the apparent affinity for glucose reduces 20x from 0.3 mM to 6 mM. The apparent affinity for H+ is 6 μM, 1000x higher than for Na+ (6 mM). The transport stoichiometry is 1 glucose:2 Na+ or H+. If Asp204 is replaced by glutamate (D204E), the apparent affinity for H+ increases >20x with no change in apparent Na+ affinity. The D204N or D204C mutation promotes phlorizin-sensitive H+ currents that are 10x greater than Na+ currents, and the glucose:H+ stoichiometry is then as great as 1:145. The mutant system thus behaves as a glucose-gated H+ channel.
Proteins of the SSS vary in size from about 400 residues to about 700 residues and probably possess thirteen to fifteen putative transmembrane helical spanners (TMSs). They generally share a core of 13 TMSs, but different members of the family may have different numbers of TMSs. A 13 TMS topology with a periplasmic N-terminus and a cytoplasmic C-terminus has been experimentally determined for the proline:Na+ symporter, PutP, of E. coli. Residues important for substrate and Na+ binding in PutP are found in TMSs 2, 7 and 9 as well as adjacent loops (Jung, 2002). A 14 TMS topology with periplasmic N- and C-termini has been established for the V. parahaemolyticus SglT carrier. SglT transports sugar:Na with a 1:1 stoichiometry. However, MctP of Rhizobium leguminosarum may take up monocarboxylates via an H+ symport mechanism as a dependency on Na+ could not be demonstrated and uptake was strongly inhibited by 10 μM CCCP.
Some bacterial sensor kinases (2.A.21.9.1 and 2.A.22.9.2) have N-terminal, 12 TMS, sensor domains that regulate the C-terminal kinase domains. The latter are homologous to the kinase domain of NtrB (Pao and Saier, 1995). The N-terminal sensor domains are homologous, but distantly related to members of the SSS. The closest homologues are PutP of E. coli (2.A.21.2.1) and PanF of E. coli (2.A.21.1.1). Homologous regulatory domains are found in Agrobacterium, Mesorhizobium, Sinorhizobium, Vibrio cholera and Bacillus species. While it is clear that these domains function as sensors, it is not known if they also transport the small molecules they sense.
The generalized transport reaction catalyzed by the members of this family is:
solute (out) + nNa+ (out) → solute (in) + nNa+ (in).
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| References: |
Coady, M.J., B. Wallendorff, D.G. Gagnon, and J.-Y. Lapointe. (2002). Identification of a novel Na+/myo-inositol cotransporter. J. Biol. Chem. 277: 35219-35224.
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Eskandari, S., D.D.F. Loo, G. Dai, O. Levy, E.M. Wright, and N. Carrasco. (1997). Thyroid Na+/I- symporter: mechanism, stoichiometry, and specificity. J. Biol. Chem. 272: 27230-27238.
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Gimenez, R., M.F. Nuñez, J. Badia, J. Aguilar, and L. Baldoma. (2003). The gene yjcG, cotranscribed with the gene acs, encodes an acetate permease in Escherichia coli. J. Bacteriol. 185: 6448-6455.
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Hosie, A.H.F., D. Allaway, and P.S. Poole. (2002). A monocarboxylate permease of Rhizobium leguminosarum is the first member of a new subfamily of transporters. J. Bacteriol. 184: 5436-5448.
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Jung, H. (2002). The sodium/substrate symporter family: structural and functional features. FEBS Lett. 529: 73-77.
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Jung, H., R. Rübenhagen, S. Tebbe, K. Leifker, N. Tholema, M. Quick, and R. Schmid. (1998). Topology of the Na+/proline transporter of Escherichia coli. J. Biol. Chem. 273: 26400-26407.
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Miyauchi, S., E. Gopal, Y.-J. Fei, and V. Ganapathy. (2004). Functional identification of SLC5A8, a tumor suppressor down-regulated in colon cancer, as a Na+-coupled transporter for short-chain fatty acids. J. Biol. Chem. 279: 13293-13296.
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Nishijyo, T., D. Haas, and Y. Itoh. (2001). The CbrA-CbrB two-component regulatory system controls the utilization of multiple carbon and nitrogen sources in Pseudomonas aeruginosa. Mol. Microbiol. 40: 917-931.
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Okuda, T. and T. Haga. (2000). Functional characterization of the human high-affinity choline transporter. FEBS Lett. 484: 92-97.
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Okuda, T., T. Haga, Y. Kanai, H. Endou, T. Ishihara, and I. Katsura. (2000). Identification and characterization of the high-affinity choline transporter. Nature Neurosci. 3: 120-125.
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Pao, G.M. and M.H. Saier, Jr. (1995). Response regulators of bacterial signal transduction systems: selective domain shuffling during evolution. J. Molec. Evol. 40: 136-154.
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Prasad, P.D., H. Wang, R. Kekuda, T. Fujita, Y.-J. Fei, L.D. Devoe, F.H. Leibach, and V. Ganapathy. (1998). Cloning and functional expression of a cDNA encoding a mammalian sodium-dependent vitamin transporter mediating the uptake of pantothenate, biotin, and lipoate. J. Biol. Chem. 273: 7501-7506.
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Quick, M., D.D.F. Loo, and E.M. Wright. (2001). Neutralization of a conserved amino acid residue in the human Na+/glucose transporter (hSGLT1) generates a glucose-gated H+ channel. J. Biol. Chem. 276: 1728-1734.
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Reizer, J., A. Reizer, and M.H. Saier, Jr. (1994). A functional superfamily of sodium/solute symporters. Biochim. Biophys. Acta 1197: 133-166.
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Sarker, R.I., W. Ogawa, T. Shimamoto, T. Shimamoto, and T. Tsuchiya. (1997). Primary structure and properties of the Na+/glucose symporter (SglS) of Vibrio parahaemolyticus. J. Bacteriol. 179: 1805-1808.
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Turk, E. and E.M. Wright. (1997). Membrane topology motifs in the SGLT cotransporter family. J. Membr. Biol. 159: 1-20.
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Turk, E., O. Kim, J. le Coutre, J.P. Whitelegge, S. Eskandari, J.T. Lam, M. Kreman, G. Zampighi, K.F. Faull, and E.M. Wright. (2000). Molecular characterization of Vibrio parahaemolyticus vSGLT: a model for sodium-coupled sugar cotransporters. J. Biol. Chem. 275: 25711-25716.
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Wang, H., W. Huang, Y.-J. Fei, H. Xia, T.L. Yang-Feng, F.H. Leibach, L.D. Devoe, V. Ganapathy, and P.D. Prasad. (1999). Human placental Na+-dependent multivitamin transporter. J. Biol. Chem. 274: 14875-14883.
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Xie, Z., E. Turk, and E.M. Wright. (2000). Characterization of the Vibrio parahaemolyticus Na+/glucose cotransporter: a bacterial member of the sodium/glucose transporter (SGLT) family. J. Biol Chem. 275: 25959-25964.
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| Examples: |
| TC# | Name | Organismal Type | Example |
| 2.A.21.1.1 | Pantothenate:Na+ symporter | Bacteria | PanF of E. coli |
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| 2.A.21.2.1 | Proline:Na+ symporter | Bacteria | PutP of E. coli |
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| 2.A.21.3.1 | Glucose or galactose:Na+ symporter (galactose > glucose > fucose) | Animals | SGLT of Homo sapiens |
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| 2.A.21.3.2 | Glucose or galactose:Na+ symporter | Bacteria | SglS of Vibrio parahaemolyticus |
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| 2.A.21.3.3 | Nucleoside or glucose(?):Na+ symporter | Animals | SNST of Oryctologus cuniculus |
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| 2.A.21.3.4 | Glucose:Na+ symporter 3 (low affinity) | Animals | SAAT1 of Sus scrofa |
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| 2.A.21.3.5 | Myoinositol:Na+ symporter | Animals | SMIT of Canis familaris |
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| 2.A.21.3.6 | Myoinositol:Na+ symporter, SMIT2 (also transports D-chiro-inositol, D-glucose and D-xylose) (Coady et al., 2002) | Animals | SMIT2 of Homo sapiens |
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| 2.A.21.4.1 | The monocarboxylate uptake (H+ symport?) permease, MctP (transports lactate, pyruvate, propionate, butyrate, α-hydroxybutylate, L- and D-alanine, and possibly cysteine and histidine) | Bacteria | MctP of Rhizobium leguminosarum |
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| 2.A.21.5.1 | Sodium iodide symporter (also transports other monovalent anions including: ClO3-, SCN-, SeCN-, NO3-, Br-, BF4-, IO4- and BrO3-) | Animals | Na+I- symporter of Homo sapiens |
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| 2.A.21.5.2 | Na+-dependent multivitamin (pantothenate, biotin, lipoate) transporter | Animals | SMVT of Rattus norvegicus |
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| 2.A.21.5.3 | Na+-dependent short chain fatty acid transporter SLC5A8 (tumor suppressor gene product, down-regulated in colon cancer) (substrates: lactate, pyruvate, acetate, propionate, butyrate (Km ≈1 mM)) [propionate:Na+ = 1:3] (Miyauchi et al., 2004) | Animals | Short chain organic acid:Na+ symporter, SLC5A8 (AAS49159) |
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| 2.A.21.6.1 | Urea active transporter | Animals | DUR3 of Saccharomyces cerevisiae |
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| 2.A.21.7.1 | Phenylacetate permease, Ppa | Bacteria | Phenylacetate permease Ppa of Pseudomonas putida |
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| 2.A.21.7.2 | Acetate/glyoxalate permease, ActP (Gimenez et al., 2003) | Bacteria | ActP (YjcG) of E. coli (NP_418491) |
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| 2.A.21.8.1 | High affinity neuronal choline: Na+ symporter, CHT1 (chloride-dependent) | Animals | CHT1 of Rattus norvegicus |
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| 2.A.21.9.1 | The nitrogen sensor-receptor domain of the CbrA sensor kinase | Bacteria | CbrA sensor domain of Pseudomonas aeruginosa |
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| 2.A.21.9.2 | The proline sensor-receptor domain of the PrlS sensor kinase | Bacteria | PrlS of Aeromonas hydrophila |
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