| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
|
|
|
|||||||
|
|||||||||
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
CELLULAR |
1 Epithelial Research Group, Institute for Cell & Molecular Biosciences, Faculty of Medical Sciences, University of Newcastle upon Tyne, Newcastle upon Tyne NE2 4HH, UK
2
Department of Biochemistry and Molecular Biology, Medical College of Georgia, Augusta, Georgia, 30912, USA
 |
Abstract |
|---|
 Top Abstract MethodsResultsDiscussionReferences |
|---|
-amino acids such as β-alanine with low affinity, and has a higher affinity for dipolar and cationic amino acids such as leucine and lysine. N-methylation of its substrates reduces the affinity for transport. These observations confirm the hypothesis that the SLC6A14 gene encodes the transport protein known as the β-alanine carrier which, due to its broad substrate specificity, is likely to play an important role in absorption of essential nutrients and drugs in the distal regions of the human gastrointestinal tract.
(Received 26 March 2008;
accepted after revision 1 July 2008;
first published online 3 July 2008)
Corresponding author D. T. Thwaites: Institute for Cell & Molecular Biosciences, Faculty of Medical Sciences, University of Newcastle upon Tyne, Newcastle upon Tyne NE2 4HH, UK. Email: d.t.thwaites{at}ncl.ac.uk
Amino acids are required for many fundamental biological functions such as protein synthesis, neurotransmission, nitrogen metabolism, and cell growth. In humans and mammals the requirements for most amino acids are met by assimilation from diet. Transepithelial amino acid absorption across the intestinal wall is mediated by a number of amino acid transporters arranged in series and parallel at the luminal and serosal membranes of the intestinal epithelium (Ganapathy et al. 2006). Although amino acid transporters vary in substrate selectivity, ion dependency and substrate affinity, the attribution of function to any particular transport system in intact tissues is often hampered by overlapping substrate specificity. One such amino acid transport system was described at the mucosal surface of rabbit ileum and named the β-alanine carrier (Munck & Schultz, 1969; Paterson et al. 1981; Munck, 1985; Anderson & Munck, 1987). This carrier system transports a range of both essential and non-essential amino acids and accepts non--amino acids such as β-alanine but has a higher affinity for dipolar (e.g. leucine) and cationic (e.g. lysine) amino acids; is Na+ and Cl– dependent; is only moderately stereospecific; and has a much lower affinity for the N-methylated derivatives of its dipolar amino acid substrates (Munck, 1985; Munck & Munck, 1990, 1992a,b, 1995). The β-alanine carrier is unusual in that, under normal circumstances, its small intestinal expression is limited to the ileum (Munck & Munck, 1992a,b).
The cloning of transporter related genes over recent years has allowed molecular identification of most of the ‘classical’ amino acid transport systems characterized functionally in specific cells and tissues during the 1960s to 1980s. The purpose of this investigation was to establish the molecular identity of the β-alanine carrier. The solute carrier SLC6A14 has been cloned from human mammary gland, mouse colon and rat lung (Sloan & Mager, 1999; Hatanaka et al. 2001; Nakanishi et al. 2001; Ugawa et al. 2001; Umapathy et al. 2004). SLC6A14 is the 14th member of solute carrier family 6, a family of Na+- and Cl–-dependent solute transport systems many of which are involved in transmembrane movement of neurotransmitters (Chen et al. 2004). SLC6A14 (also named ATB0,+) functions as a dipolar and cationic amino acid transporter with characteristics similar to system B0,+ (identified originally in mouse blastocysts; Van Winkle et al. 1985). Thus far, β-alanine carrier-like function has not been demonstrated by any solute carrier transport system identified at the molecular level. In this investigation, a series of experiments were designed to determine whether SLC6A14 is the molecular correlate of the intestinal β-alanine carrier, perhaps the last of the classical intestinal amino acid transport systems to be identified at the molecular level.
|
Methods |
|---|
|
TopAbstractMethodsResultsDiscussionReferences |
|---|
[3H]β-Alanine (50 Ci mmol–1) was from American Radiolabelled Chemicals. [3H]Lysine (99 Ci mmol–1), [3H]leucine (115 Ci mmol–1) and [14C]MeAIB (-(methylamino)isobutyric acid) (51 mCi mmol–1) were from PerkinElmer.
Functional expression in Xenopus laevis oocytes
Human SLC6A14 cRNA was produced by in vitro transcription (using mMessage mMachine T7 Ultra kit (Ambion)) of pSPORT1 plasmid containing the SLC6A14 sequence isolated originally from MCF-7 cells (Nakanishi et al. 2001). Female Xenopus laevis were killed humanely by cervical dislocation following Schedule 1 procedures. Oocytes were prepared and injected with 50 nl cRNA (1 mg ml–1) or water, as previously described (Kennedy et al. 2002, 2005), and incubated at 18°C in Barth's solution until required.
Uptake of radiolabelled amino acids
Uptake of radiolabelled amino acids (2–5 µCi ml–1) was measured in oocytes 2–5 days after injection, as previously described (Kennedy et al. 2002). Oocytes were washed in a NaCl-containing pH 7.4 solution (100 mM NaCl, 2 mM KCl, 1 mM CaCl2, 1 mM MgCl2, 10 mM Hepes adjusted to pH 7.4 with Tris base) and uptake measured at 22°C for 40 min. Uptake measurements were performed in this NaCl-containing pH 7.4 solution or using a solution adjusted as follows: for the Na+-free solution, NaCl was replaced with choline chloride; for the Cl–-free solution, NaCl, KCl, CaCl2 and MgCl2 were replaced with sodium gluconate, potassium gluconate, calcium gluconate and MgSO4, respectively; for the pH 5.5 solution, Hepes was replaced by Mes. After uptake, oocytes were washed three times in ice-cold buffer and lysed in 10% SDS. Radioactivity was measured by scintillation counting.
Two-electrode voltage clamp
Oocytes (2–8 days post-injection) were superfused in an open chamber with a NaCl-containing pH 7.4 solution (see above). Oocytes were clamped at –60 mV and exposed to various concentrations of β-alanine (0.2–20 mM, 2min) or different amino acids (all at 20 mM, 2min) to allow amino acid-induced currents to be measured using a Geneclamp 500 amplifier, Digidata 1200 (Axon Instruments) and Clampex software (Kennedy et al. 2005). Currents were analysed using Clampfit 8.2. To determine the current evoked by a 2 min exposure to an amino acid, the current measured over the last 15 s of the 2 min exposure was averaged. The baseline current (taken as the average current over the 15 s before exposure to the amino acid) was then subtracted to determine SLC6A14-specific current.
Statistics
Data are means ± S.E.M. Statistical comparisons were made using ANOVA and Tukey's post hoc test using GraphPad Prism 4 (GraphPad Software Inc., San Diego, CA, USA). Curves were fitted with GraphPad Prism 4.
|
Results |
|---|
|
TopAbstractMethodsResultsDiscussionReferences |
|---|
|
|
|
|
|
|
|
Discussion |
|---|
|
TopAbstractMethodsResultsDiscussionReferences |
|---|
-amino acids such as β-alanine with low affinity, and has a higher affinity for dipolar and cationic amino acids such as leucine and lysine (Figs 1–5). N-methylation of the substrates leucine, glycine, alanine and AIB reduces the affinity for transport (Fig. 6). In addition, the characteristic of weak stereoselectivity has been demonstrated previously with the identification of D-serine transport via SLC6A14 (Hatanaka et al. 2002). These observations confirm the hypothesis that the SLC6A14 gene encodes the transport protein known as the β-alanine carrier (Munck, 1985; Anderson & Munck, 1987). The β-alanine carrier is considered to be the Na+-dependent transporter of leucine, lysine and alanine observed originally in rabbit ileum by Munck & Schultz (1969) and Paterson et al. (1981). Importantly, these observations also indicate that the studies of the β-alanine carrier in the 1960s to 1980s can now be considered to represent in situ measurements of SLC6A14 function in the intestine. The tissue distribution of the β-alanine carrier is unusual as the only intestinal location where function has been described is at the luminal surface of the ileum (Munck, 1985; Anderson & Munck, 1987; Munck & Munck, 1990, 1992a,b, 1995). This predominantly distal intestinal expression pattern is supported by observations using mouse gastrointestinal tract that demonstrate greater expression of SLC6A14 mRNA in the ileum and colon compared to duodenum and jejunum (Hatanaka et al. 2001, 2002; Ugawa et al. 2001; Sloan et al. 2003). In the rabbit, the physiological role of the β-alanine carrier seems certain to lie in nutrient absorption from the diet as the ileum is the site of maximal amino acid absorption in rabbit small intestine (Munck & Munck, 1992b). The physiological role in the human intestine is not known but the broad substrate specificity of SLC6A14 means that this distal intestinal site of absorption could be important in both nutrient and drug absorption. β-Alanine is a non-proteinogenic amino acid and is a component of the dipeptide carnosine (β-alanine–L-histidine), found at high concentrations in both vertebrate and non-vertebrate skeletal muscle. In humans, dietary supplementation with β-alanine (at concentrations relevant to diet) leads to an increase in skeletal muscle carnosine (Harris et al. 2006) which is associated with an improvement in performance during exercise, proposed to be due to the enhanced pH buffering effect of carnosine (Harris et al. 2006; Stout et al. 2007; Zoeller et al. 2007). In addition to cationic and dipolar amino acids, SLC6A14 transports carnitine, a range of nitric oxide synthase inhibitors, and the antiviral prodrugs valacyclovir and valganciclovir (Hatanaka et al. 2001, 2004; Nakanishi et al. 2001; Umapathy et al. 2004). Thus, SLC6A14 has great potential as a target for drug delivery programmes using slow release formulations or rectal suppositories. In addition, the colonic expression may have relevance for the absorption of bacterially derived D-amino acids as D-serine is transported by SLC6A14 (Hatanaka et al. 2002). Interestingly, the distribution pattern of SLC6A14 parallels the regions of the gastrointestinal tract that are generally colonized by bacteria. The hypothesis that SLC6A14 expression might be up-regulated following bacterial colonization is consistent with the recent demonstration of selective up-regulation of SLC6A14 mRNA and protein expression in acute cholera patients compared to convalescence such that SLC6A14 protein has been immunolocalized to the luminal surface of the human duodenum during acute infection (Flach et al. 2007). After induction, e.g. following infection with cholera, SLC6A14 could provide a highly concentrating mechanism (due to its Na+ and Cl– dependence) for absorption of essential amino acids such as lysine and leucine that could otherwise be lost during excess intestinal fluid and electrolyte secretion. The SLC6A14 gene seems highly regulated being associated with obesity (Suviolahti et al. 2003; Durand et al. 2004), and being up-regulated in colorectal cancer (Gupta et al. 2005), cervical cancer (Gupta et al. 2006), and ulcerative colitis (Flach et al. 2006).
In summary, this study describes the first demonstration of β-alanine carrier-like function by any cloned transporter. The functional characteristics described here, which are identical to those determined by measurement of amino acid uptake across the luminal surface of flat sheets of rabbit ileal mucosa (Munck, 1985; Munck & Munck, 1990, 1992a,b, 1994, 1995), can account for all β-alanine carrier-like function and emphasize the added value of in situ measurements of physiological function over theoretical predictions of transport protein function based solely upon measurements of mRNA distribution.
SLC6A14 was isolated originally from human mammary gland (Sloan & Mager, 1999) and named ATB0,+ due to its similarity in function to the amino acid transport system B0,+, described in mouse blastocysts (Van Winkle et al. 1985). The observations reported in this study demonstrate that SLC6A14 is the β-alanine carrier and that the blastocyst ATB0,+ and intestinal β-alanine carrier are one and the same transport system (Munck & Munck, 1995). The term β-alanine carrier is somewhat inappropriate as a means of identification of this intestinal transport system as it has a low affinity for β-alanine, and the intestinal tract contains another transport system for β-alanine namely the H+-coupled amino acid transporter SLC36A1 which is also known variously as system PAT, PAT1 or the imino acid carrier (Thwaites et al. 1993; Chen et al. 2003; Anderson et al. 2004; Thwaites & Anderson, 2007). To reduce confusion in the literature, the term β-alanine carrier should be avoided and the names SLC6A14 and ATB°,+ adopted to be consistent with descriptions in other tissues (Van Winkle et al. 1985; Munck & Munck, 1994, 1995; Sloan & Mager, 1999; Sloan et al. 2003).
|
References |
|---|
|
TopAbstractMethodsResultsDiscussionReferences |
|---|
-amino-mono-carboxylic acid L-alanine by the β-alanine carrier of the rabbit ileum. Biochim Biophys Acta 902, 145–148.[Medline]Anderson CMH, Grenade DS, Boll M, Foltz M, Wake KA, Kennedy DJ, Munck LK, Miyauchi S, Taylor PM, Campbell FC, Munck BG, Daniel H, Ganapathy V & Thwaites DT (2004). H+/amino acid transporter 1 (PAT1) is the imino acid carrier: an intestinal nutrient/drug transporter in human and rat. Gastroenterology 127, 1410–1422.[CrossRef][Medline]
Chen Z, Fei YJ, Anderson CMH, Wake KA, Miyauchi S, Huang W, Thwaites DT & Ganapathy V (2003). Structure, function and immunolocalization of a proton-coupled amino acid transporter (hPAT1) in the human intestinal cell line Caco-2. J Physiol 546, 349–361.
Chen NH, Reith ME & Quick MW (2004). Synaptic uptake and beyond: the sodium- and chloride-dependent neurotransmitter transporter family SLC6. Pflugers Arch 447, 519–531.[CrossRef][Medline]
Durand E, Boutin P, Meyre D, Charles MA, Clement K, Dina C & Froguel P (2004). Polymorphisms in the amino acid transporter solute carrier family 6 (neurotransmitter transporter) member 14 gene contribute to polygenic obesity in French Caucasians. Diabetes 53, 2483–2486.
Flach CF, Eriksson A, Jennische E, Lange S, Gunnerek C & Lönnroth I (2006). Detection of elafin as a candidate biomarker for ulcerative colitis by whole-genome microarray screening. Inflamm Bowel Dis 12, 837–842.[CrossRef][Medline]
Flach CF, Qadri F, Bhuiyan TR, Alam NH, Jennische E, Holmgran J & Lönnroth I (2007). Differential expression of intestinal membrane transporters in cholera patients. FEBS Lett 581, 3183–3188.[CrossRef][Medline]
Ganapathy V, Gupta N & Martindale RG (2006). Protein digestion and absorption. In Physiology of the Gastrointestinal Tract, 4th edn, ed. Johnson LR, pp. 1667–1692. Elsevier, San Diego.
Gupta N, Miyauchi S, Martindale RG, Herdman AV, Podolsky R, Miyake K, Mager S, Prasad PD, Ganapathy ME & Ganapathy V (2005). Upregulation of the amino acid transporter ATB0,+ (SLC6A14) in colorectal cancer and metastasis in humans. Biochim Biophys Acta 1741, 215–223.[Medline]
Gupta N, Prasad PD, Ghamande S, Moore-Martin P, Herdman AV, Martindale RG, Podolsky R, Mager S, Ganapathy ME & Ganapathy V (2006). Up-regulation of the amino acid transporter ATB0,+ (SLC6A14) in carcinoma of the cervix. Gynecol Oncol 100, 8–13.[CrossRef][Medline]
Harris RC, Tallon MJ, Dunnett M, Boobis L, Coakley J, Kim HJ, Fallowfield JL, Hill CA, Sale C & Wise JA (2006). The absorption of orally supplied β-alanine and its effect on muscle carnosine synthesis in human vastus lateralis. Amino Acids 30, 279–289.[CrossRef][Medline]
Hatanaka T, Haramura M, Fei YJ, Miyauchi S, Bridges CC, Ganapathy PS, Smith SB, Ganapathy V & Ganapathy ME (2004). Transport of amino acid-based prodrugs by the Na+- and Cl–-coupled amino acid transporter ATB0,+ and expression of the transporter in tissues amenable for drug delivery. J Pharmacol Exp Ther 308, 1138–1147.
Hatanaka T, Huang W, Nakanishi T, Bridges CC, Smith SB, Prasad PD, Ganapathy ME & Ganapathy V (2002). Transport of D-serine via the amino acid transporter ATB0,+ expressed in the colon. Biochem Biophys Res Commun 291, 291–295.[CrossRef][Medline]
Hatanaka T, Nakanishi T, Huang W, Leibach FH, Prasad PD, Ganapathy V & Ganapathy ME (2001). Na+- and Cl–-coupled active transport of nitric oxide synthase inhibitors via amino acid transport system B0,+. J Clin Invest 107, 1035–1043.[Medline]
Kennedy DJ, Gatfield KM, Winpenny JP, Ganapathy V & Thwaites DT (2005). Substrate specificity and functional characterisation of the H+/amino acid transporter rat PAT2 (Slc36a2). Br J Pharmacol 144, 28–41.[CrossRef][Medline]
Kennedy DJ, Leibach FH, Ganapathy V & Thwaites DT (2002). Optimal absorptive transport of the dipeptide glycylsarcosine is dependent on functional Na+/H+ exchange activity. Pflugers Arch 445, 139–146.[CrossRef][Medline]
Munck BG (1985). Transport of imino acids and non--amino acids across the brush-border membrane of the rabbit ileum. J Membr Biol 83, 15–24.[CrossRef][Medline]
Munck LK & Munck BG (1990). Chloride-dependence of amino acid transport in rabbit ileum. Biochim Biophys Acta 1027, 17–20.[Medline]
Munck LK & Munck BG (1992a). Distinction between chloride-dependent transport systems for taurine and β-alanine in rabbit ileum. Am J Physiol Gastrointest Liver Physiol 262, G609–G615.
Munck LK & Munck BG (1992b). Variation in amino acid transport along the rabbit small intestine. Mutual jejunal carriers of leucine and lysine. Biochim Biophys Acta 1116, 83–90.[Medline]
Munck LK & Munck BG (1994). Amino acid transport in the small intestine. Physiol Res 43, 335–346.[Medline]
Munck LK & Munck BG (1995). Transport of glycine and lysine on the chloride-dependent β-alanine (B0,+) carrier in rabbit small intestine. Biochim Biophys Acta 1235, 93–99.[Medline]
Munck BG & Schultz SG (1969). Interactions between leucine and lysine transport in rabbit ileum. Biochim Biophys Acta 183, 182–193.[Medline]
Nakanishi T, Hatanaka T, Huang W, Prasad PD, Leibach FH, Ganapathy ME & Ganapathy V (2001). Na+- and Cl–-coupled active transport of carnitine by the amino acid transporter ATB0,+ from mouse colon expressed in HRPE cells and Xenopus oocytes. J Physiol 532, 297–304.
Paterson JYF, Sepúlveda FV & Smith MW (1981). Distinguishing transport systems having overlapping specificities for neutral and basic amino acids in the rabbit ileum. J Physiol 319, 345–354.
Sloan JL, Grubb BR & Mager S (2003). Expression of the amino acid transporter ATB0+ in lung: possible role in luminal protein removal. Am J Physiol Lung Cell Mol Physiol 284, L39–L49.
Sloan JL & Mager S (1999). Cloning and functional expression of a human Na+ and Cl–-dependent neutral and cationic amino acid transporter B0+. J Biol Chem 274, 23740–23745.
Stout JR, Cramer JT, Zoeller RF, Torok D, Costa P, Hoffman JR, Harris RC & O'Kroy J (2007). Effects of β-alanine supplementation on the onset of neuromuscular fatigue and ventilatory threshold in women. Amino Acids 32, 381–386.[CrossRef][Medline]
Suviolahti E, Oksanen LJ, Ohman M, Cantor RM, Ridderstrale M, Tuomi T, Kaprio J, Rissanen A, Mustajoki P, Jousilahti P, Vartiainen E, Silander K, Kilpikari R, Salomaa V, Groop L, Kontula K, Peltonen L & Pajukanta P (2003). The SLC6A14 gene shows evidence of association with obesity. J Clin Invest 112, 1762–1772.[CrossRef][Medline]
Thwaites DT & Anderson CMH (2007). Deciphering the mechanisms of intestinal imino (and amino) acid transport: the redemption of SLC36A1. Biochim Biophys Acta 1768, 179–197.[Medline]
Thwaites DT, McEwan GTA, Brown CDA, Hirst BH & Simmons NL (1993). Na+-independent, H+-coupled transepithelial β-alanine absorption by human intestinal Caco-2 cell monolayers. J Biol Chem 268, 18438–18441.
Ugawa S, Sunouchi Y, Ueda T, Takahashi E, Saishin Y & Shimada S (2001). Characterization of a mouse colonic system B0+ amino acid transporter related to amino acid absorption in colon. Am J Physiol Gastrointest Liver Physiol 281, G365–G370.
Umapathy NS, Ganapathy V & Ganapathy ME (2004). Transport of amino acid esters and the amino-acid-based prodrug valganciclovir by the amino acid transporter ATB0,+. Pharm Res 21, 1303–1310.[CrossRef][Medline]
Van Winkle LJ, Christensen HN & Campione AL (1985). Na+-dependent transport of basic, zwitterionic, and bicyclic amino acids by a broad-scope system in mouse blastocysts. J Biol Chem 260, 12118–12123.
Zoeller RF, Stout JR, O'Kroy JA, Torok DJ & Mielke M (2007). Effects of 28 days of β-alanine and creatine monohydrate supplementation on aerobic power, ventilatory and lactate thresholds, and time to exhaustion. Amino Acids 33, 505–510.[CrossRef][Medline]
|
Acknowledgements |
|---|
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
