Summary
The cDNAs of mammalian amino acid transporters already identified could be grouped into four families. One of these protein families is composed of the protein rBAT and the heavy chain of the cell surface antigen 4F2 (4F2hc). The cRNAs of rBAT and 4F2hc induce amino acid transport activity via systems b0,+ -like and y+L -like inXenopus oocytes respectively. Surprisingly, neither rBAT nor 4F2hc is very hydrophobic, and they seem to be unable to form a pore in the plasma membrane. This prompted the hypothesis that rBAT and 4F2hc are subunits or modulators of the corresponding amino acid transporters. The association of rBAT with a light subunit of ~40kDa has been suggested, and such an association has been demonstrated for 4F2hc.
The b0,+-like system expressed in oocytes by rBAT cRNA transports L-cystine, L-dibasic and L-neutral amino acids with high-affinity. This transport system shows exchange of amino acids through the plasma membrane ofXenopus oocytes, suggesting a tertiary active transport mechanism. The rBAT gene is mainly expressed in the outer stripe of the outer medulla of the kidney and in the mucosa of the small intestine. The protein localizes to the microvilli of the proximal straight tubules (S3 segment) of the nephron and the mucosa of the small intestine. All this suggested the participation of rBAT in a high-affinity reabsorption system of cystine and dibasic amino acids in kidney and intestine, and indicated rBAT (named SLC3A1 in Gene Data Bank) as a good candidate gene for cystinuria. This is an inherited aminoaciduria due to defective renal and intestinal reabsorption of cystine and dibasic amino acids. The poor solubility of cystine causes the formation of renal cystine calculi. Mutational analysis of the rBAT gene of patients with cystinuria is revealing a growing number (~20) of cystinuria-specific mutations, including missense, nonsense, deletions and insertions. Mutations M467T (substitution of methionine 467 residue for threonine) and R270X (stop codon at arginine residue 270) represent approximately half of the cystinuric chromosomes where mutations have been found. Mutation M467T reduces transport activity of rBAT in oocytes. All this demonstrates that mutations in the rBAT gene cause cystinuria.
Three types of cystinuria (types, I, II and III) have been described on the basis of the genetic, biochemical and clinical manifestations of the disease. Type I cystinuria has a complete recessive inheritance; type I heterozygotes are totally silent. In contrast, type II and III heterozygotes show, respectively, high or moderate hyperaminoaciduria of cystine and dibasic amino acids. Type III homozygotes show moderate, if any, alteration of intestinal absorption of cystine and dibasic amino acids; type II homozygotes clearly show defective intestinal absorption of these amino acids. To date, all the rBAT cystinuria-specific mutations we have found are associated with type I cystinuria (~70% of the chromosomes studied) but not to types II or III. This strongly suggests genetic heterogeneity for cystinuria. Genetic linkage analysis with markers of the genomic region of rBAT in chromosome 2 (G band 2p16.3) and intragenic markers of rBAT have demonstrated genetic heterogeneity for cystinuria; the rBAT gene is linked to type I cystinuria, but not to type III. Biochemical, genetic and clinical studies are needed to identify the additional cystinuria genes; a low-affinity cystine reabsortion system and the putative light subunit of rBAT are additional candidate genes for cystinuria.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Ahmed A, Peter GJ, Taylor PM, Harper AA, Rennie MJ (1995) Sodium-independent currents of opposite polarity evoked by neutral and cationic amino acids in neutral and basic amino acid transporter cRNA-injected oocytes. J Biol Chem 270: 8482–8486
Bertran J, Werner A, Stange G, Markovich D, Biber J, Testar X, Zorzano A, Palacín M, Murer H (1992a) Expression of Na+ independent amino acid transport in Xenopus laevis oocytes by injection of rabbit kidney cortex mRNA. Biochem J 281: 717–723
Bertran J, Werner A, Moore ML, Stange G, Markovich D, Biber J, Testar X, Zorzano A, Palacín M, Murer H (1992b) Expression cloning of a cDNA from rabbit kidney cortex that induces a single transport system for cystine and dibasic and neutral amino acids. Proc Natl Acad Sci USA 89: 5601–5605
Bertran J, Magagnin S, Werner A, Markovich D, Biber J, Testar X, Zorzano A, Kühn LC, Palacín M, Murer H (1992c) Stimulation of system y+-like amino acid transport by the heavy chain of human 4F2 surface antigen in Xenopus laevis oocytes. Proc Natl Acad Sci USA 89: 5606–5610
Bertran J, Werner A, Chillarón J, Nunes V, Biber J, Testar X, Zorzano A, Estivill X, Murer H, Palacín M (1993) Expression cloning of a human renal cDNA that induces high affinity transport of L-cystine shared with dibasic amino acids in Xenopus oocytes. J Biol Chem 268: 14842–14849
Bertran J, Testar X, Zorzano A, Palacín M (1994) A new age for mammalian plasma membrane amino acid transporters. Cell Physiol Biochem 4: 217–241
Busch A, Herzer T, Waldegger S, Schmidt F, Palacín M, Biber J, Markovich D, Murer H, Lang F (1994) Opposite directed currents induced by the transport of dibasic and neutral amino acids in Xenopus oocytes expressing the protein rBAT. J Biol Chem 269: 25581–25586
Calonge MJ, Gasparini P, Chillarón J, Chillón M, Gallucci M, Rousaud F, Zelante L, Testar X, Dallapiccola B, Di Silverio F, Barceló P, Estivill X, Zorzano A, Nunes V, Palacín M (1994) Cystinuria caused by mutations in rBAT, a gene involved in the transport of cystine. Nature Genetics 6: 420–425
Calonge MJ, Nadal M, Calvano S, Testar X, Zelante L, Zorzano A, Estivill X, Gasparini P, Palacín M, Nunes V (1995a) Assignement of the gene responsible for cystinuria (rBAT) and of markers D2S119 and D2S177 to 2p16 by fluorescence in situ hybridization. Human Genet 95: 633–636
Calonge MJ, Volpini V, Bisceglia L, Rousaud F, DeSantis L, Brescia E, Zelante L, Testar X, Zorzano A, Estivill X, Gasparini P, Nunes V, Palacín M (1995b) Genetic heterogeneity in cystinuria: the rBAT gene is linked to type I but not to type III cystinuria. Proc Natl Acad Sci USA 92: 9667–9671
Chillarón J, Estévez R, Mora C, Lang F, Testar X, Busch AE, Zorzano A, Palacín M (1996) Amino acid exchange via systems b0,+-like (associated to rBAT) and y+L-like (associated to 4F2hc). A mechanisms for vectorial reabsorption of amino acids. Biol Chem 271: 17761–17770
Coady MJ, Jalal F, Chen X, Lemay G, Berteloot A, Lapoint J-Y (1994) Electrogenic amino acid exchange via the rBAT transporter. FEBS Lett. 356: 174–178
Coicadan L, Heyman M, Grasset E, Desjeux JF (1980) Cystinuria: reduced lysine permeability at the brush border of intestinal membrane cells. Pediatr Res 14: 109–112
Chelly J, Concordet JP, Kaplan JC, Khan A (1989) Illegitimate transcription: transcription of any gene in any cell type. Proc Natl Acad Sci USA 86: 2617–2621
Dent CE, Rose GA (1951) Amino acid metabolism in cystinuria. Q J Med 20: 205
Devés R, Chavez P, Boyd CAR (1992) Identification of a new transport system (y+L) in human erythocytes that recognizes lysine and leucine with high affinity. J Physiol 454: 491–501
Fei Y- J, Prasad PD, Leibach FH, Ganapathy V (1995) The amino acid transport system y+L induced in Xenopus laevis oocytes by human choriocarcinoma cell (JAR) mRNA is functionally related to the heavy chain of the 4F2 cell surface antigen. Biochemistry 34: 8744–8751
Foreman JW, Hwang SM, Segal S (1980) Transport interactions of cystine and dibasic amino acids in isolated rat renal tubules. Metabolism 29: 53–61
Furlong TJ, Posen S (1990) D-penicillamine and the transport of L-cystine by rat and human renal cortical brush-border membrane vesicles. Am J Physiol 258: F321-F327
Furriols M, Chillarón J, Mora C, Castelló A, Bertran J, Camps M, Testar X, Vilaró S, Zorzano A, Palacín M (1993) rBAT, related to L-cystine transport is localized to the microvilli of proximal straight tubules and its expression is regulated in kidney by development. J Biol Chem 268: 27060–27068
Garrod AE (1908) Inborn errors of metabolism. Lancet ii: 1–7
Gasparini P, Calonge MJ, Bisceglia L, Purroy J, Dianzani I, Notarangelo A, Rousaud F, Gallucci M, Testar X, Ponzone A, Estivill X, Zorzano A, Palacín M, Nunes V, Zelante L (1995) Molecular genetics of cystinuria: identification of 4 new mutations and 7 polymorphismes and evidence for genetic heterogeneity. Am J Hum Genet 57: 781–788
Geering K, Theulaz I, Verrey F, Häuptle MT, Rossier BC (1989) A role for the b-subunit in the expression of functional Na+, K+ -ATPase in Xenopus oocytes. Am J Physiol 257: C851-C858
Goodyer PR, Clow C, Reade T, Girardin C (1993) Prospective analysis and classification of patients wth cystinuria indentified in a newborn screening program. J Pediatr 122: 568–572
Haynes BF, Hemler ME, Mann DL, Eisenbarth GS, Shelhamer JH, Mostowski HS, Thomas CA, Strominger JL, Fauci AS (1981) Characterization of a monoclonal antibody (4F2) that binds to human monocytes and to a subset of activated lymphocytes. J Immunol 126: 1409–1414
Hemler ME, Strominger JL (1982) Characterization of the antigen recognized by the monoclonal antibody (4F2): different molecular forms on human T and B lymphoblastoid cell lines. J Immunol 129: 623–628
Horsford J, Raelson J, Saadi I, Hediger M, Goodyer P, Rozen R (1995) Analysis of the D2H gene (SLC3A1) in cystinuria patients from Quebec reveals 3 novel mutations and 2 polymorphisms. Am J Hum Genet 57: A215 (poster ner 1239)
Kanai Y, Stelzner MG, Lee W-S, Wells RG, Brown D, Hediger MA (1992) Expression of mRNA (D2) encoding a protein involved in amino acid transport in S3 proximal tubule. Am J Physiol 263: F1087-F1093
Kanai Y, Smith CP, Hediger MA (1994) A new family of neurotransmitter transporters: the high-affinity glutamate transporters. FASEB J 8: 1450–1459
Kanner BI, Kleinberger-Doron N (1994) Structure and function of sodium-coupled neurotransmitter transporters. Cell Physiol Biochem 4: 174–184
Lee W-S, Wells RG, Sabbag RV, Mohandas TK, Hediger MA (1993) Cloning and chromosomal localization of a human kidney cDNA involved in cystine, dibasic, and neutral amino acid transport. J Clin Invest 91: 1959–1963
Levy HL (1973) Genetic screening. In: Harris H, Hirschhorn K (eds) Advances in human genetics, vol 4. Plenum, New York, p1
MacLeod CL, Finley KD, Kakuda DK (1994) y+-type cationic amino acid transport: expression and regulation of the mCAT genes. J Exp Biol 196: 109–122
Magagnin S, Bertran J, Werner A, Markovich D, Biber J, Palacín M, Murer H (1992) Poly(A)+ RNA from rabbit intestinal mucosa induces b0,+ and y+ amino acid transport activities inXenopus laevis oocytes. J Biol Chem 267: 15384–15390
Markovich D, Stange G, Bertran J, Palacín M, Werner A, Biber J, Murer H (1993) Two mRNA transcripts (rBAT-1 and rBAT-2) are involved in system b0,+-related amino acid transport. J Biol Chem 268: 1362–1367
McGivan JD, Pastor-Anglada M (1994) Regulatory and molecular aspects of mammalian amino acid transport. Biochem J 299: 321–334
McKusick VA (1990) Cystinuria. In: Mendelian inheritance in man. Catalogs of autosomal dominant, autosomal recessive, and X-linked phenotypes, 9th edn. The Johns Hopkins University Press, Baltimore London, pp 1128–1129
McNamara PD, Pepe LM, Segal S (1981) Cystine uptake by renal brush border vesicles. Biochem J 194: 443–449
McNamara PD, Rea CT, Segal S (1991) Expression of rat jejunal cystine carrier inXenopus oocytes. J Biol Chem 266: 986–989
McNamara PD, Rea CT, Segal S (1992) Ion dependence of cystine and lysine uptake by rat renal brush-border membrane vesicles. Biochim Biophys Acta 1103: 101–108
Milne MD, Asatoor AM, Edwards KDG, Loughridge LW (1961) The intestinal absorption defect in cystinuria. Gut 2: 323
Miyamoto K, Katai K, Tatsumi S, Sone K, Segawa H, Yamamoto H, Taketani Y, Takada K, Morita K, Kanayama H, Kagawa S, Takeda E (1995) Mutations in the basic amino acid transporter gene associated with cystinuria. Biochem J 310: 951–955
Mora C, Chillarón J, Calonge MJ, Forgo J, Testar X, Estivill X, Nunes V, Murer H, Zorzano A, Palacín M (1996) The rBAT gene is responsible for L-cystine uptake via the b0,+-like amino acid transport system in a “renal proximal tubular” cell line (OK-cells) J Biol Chem 271: 10569–10576
Mosckovitz R, Yan N, Heimer E, Felix A, Tate SS, Udenfriend S (1993) Characterization of the rat neutral and basic amino acid transporter utilizing antipeptide antibodies. Proc Natl Acad Sci 90: 4022–4026
Mosckovitz R, Udenfriend S, Felix A, Heimer E, Tate SS (1994) Membrane topology of the rat kidney neutral and basic amino acid transporter. FASEB J 8: 1069–1074
Ozegovic B, McNamara PD, Segal S (1982) Cystine uptake by rat jejunal brush border membrane vesicles. Biosci Rep 2: 913–920
Palacín M (1994) A new family of proteins (rBAT and 4F2hc) involved in cationic and zwitterionic amino acid transport: a tale of two proteins in search of a transport function. J Exp Biol 196: 123–137
Parmacek MS, Karpinski BA, Gottesdiener KM, Thompson CB, Leiden JM (1989) Structure, expression and regulation of the murine 4F2 heavy chain. Nucleic Acids Res 17: 1915–1931
Pickel VM, Nirenberg MJ, Chan J, Mosckovitz R, Udenfriend S, Tate SS (1993) Ultrastructural localization of a neutral and basic amino acid transporter in rat kidney and intestine. Proc Natl Acad Sci USA 90: 7779–7783
Pras E, Arber N, Aksentijevich I, Katz G, Schapiro JM, Prosen L, Gruberg L, Harel D, Liberman U, Weissenbach J, Pras M, Kastner DL (1994) Localization of a gene causing cystinuria to chromosome 2p. Nature Genetics 6: 415–419
Pras E, Raben N, Golomb E, Arber N, Aksentijevich I, Schapiro JM, Harel D, Katz G, Liberman U, Pras M, Kastner DL (1995) Mutations in the SLC3A1 transporter gene in cystinuria. Am J Hum Genet 56: 1297–1303
Quackenbush E, Clabby M, Gottesdiener KM, Barbosa J, Jones NH, Strominger JL, Speck S, Leiden JM (1987) Molecular cloning of complementray DNAs encoding the heavy chain of the human 4F2 cell-surface antigen: a type II membrane glycoprotein involved in normal and neoplastic cell growth. Proc Natl Acad Sci USA 84: 6526–6530
Rosenberg LE, Durant JL, Holland IM (1965) Intestinal absorption and renal extraction of cystine and cysteine in cystinuria. N Engl J Med 273: 1239–1345
Rosenberg LE, Downing S, Durant JL, Segal S (1966a) Cystinuria: biochemical evidence of three genetically distinct diseases. J Clin Invest 45: 365–371
Rosenberg LE, Durant JL, Albrecht I (1966b) Genetic heterogeneity in cystinuria: evidence for allelism. Trans Assoc Am Physicians 79: 284–296
Schafer JA, Watkins ML (1984) Transport of L-cystine in isolated perfused proximal straight tubules. Pfluegers Arch 401: 143–151
Scriver CR, Clow CL, Terry M, Reade TM, Goodyer P, Auray-Blais C, Giguère R, Lemieux B (1985) Ontogeny modifies manifestations of cystinuria genes: implications for counseling. J Pediatr 106: 411–416
Segal S, Thier SO (1995) Cystinuria. In: Scriver CH, Beaudet AL, Valle WS, Sly y D (eds) The metabolic and molecular bases of inherited diseases. McGraw-Hill, New York, pp 3581–3601
Segal S, McNamara PD, Pepe LM (1977) Transport interaction of cystine and dibasic amino acids in renal brush border vesicles. Science 197: 169–171
Silbernagl S (1988) The renal handling of amino acids and oligopeptides. Physiol Rev 68: 911–1007
Tate SS, Yan N, Udenfriend S (1992) Expression cloning of a Na+ -independent neutral amino acid transporter from rat kidney. Proc Natl Acad Sci USA 89: 1–5
Taylor MA, Smith DL (1987) Accumulation of free amino acids in growingXenopus laevis oocytes. Dev Biol 124: 287–290
Teixeira S, Di Grandi S, Kühn LC (1987) Primary structure of the human 4F2 antigen heavy chain predicts a transmembrane protein with a cytoplasmic NH2 terminus. J Biol Chem 262: 9574–9580
Thier S, Fox M, Segal S, Rosenberg LE (1964) Cystinuria: in vitro demonstration of a intestinal transport defect. Science 143: 482–484
Van Winkle LJ, Campione AL, Gorman MJ (1988) Na+-independent transport of basic and zwitterionic amino acids in mouse blastocysts by a shared system and by processes which distinguish between these substrates. J Biol Chem 263: 3150–3163
Wang Y, Tate SS (1995) Oligomeric structure of a renal cystine transporter: implications in cystinuria. FEBS Lett 368: 389–392
Wells RG, Hediger MA (1992) Cloning of a rat kidney cDNA that stimulates dibasic and neutral amino acid transport and has sequence similarity to glucosidases. Proc Natl Acad Sci USA 89: 5596–5600
Wells RG, Lee W, Kanai Y, Leiden JM, Hediger MA (1992) The 4F2 antigen heavy chain induces uptake of neutral and dibasic amino acids inXenopus oocytes. J Biol Chem 267: 15285–15288
Wollaston WH (1810) On cystic oxide: a new species of urinary calculus. Trans R Soc London 100: 223
Wright EM (1994) Cystinuria defect expresses itself. Nature Genetics 6: 328–329
Yan N, Mosckovitz R, Udenfriend S, Tate S (1992) Distribution of mRNA of a Na+-independent neutral amino acid transporter cloned from rat kidney and its expression in mammalian tissues andXenopus laevis oocytes. Proc Natl Acad Sci USA 89: 9982–9985
Yan N, Mosckovitz R, Gerber ID, Mathew S, Murthy VVVS, Tate SS, Udenfriend S (1994) Characterization of the promoter region of the gene for the rat neutral and basic amino acid transporter and chromosomal localization of the human gene. Proc Natl Acad Sci USA 91: 7548–7552
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Palacín, M., Mora, C., Chillarón, J. et al. The molecular basis of cystinuria: the role of the rBAT gene. Amino Acids 11, 225–246 (1996). https://doi.org/10.1007/BF00813862
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00813862