Regional and subcellular distribution of a neutral and basic amino acid transporter in forebrain neurons containing nitric oxide synthase.

The neutral and basic amino acid transporter (NBAT) facilitates sodium-independent transport of L-amino acids in renal and intestinal epithelial cells and has been postulated to play a similar role in neurons. In previous studies, NBAT has been detected within enteric and brainstem autonomic neurons in a distribution similar to that of constitutive nitric oxide synthase (cNOS). Furthermore, L-arginine, the required precursor for nitric oxide synthesis, is an excellent NBAT substrate. Together, these findings suggest that NBAT may play a role in the regulation of nitric oxide synthesis, through the control of precursor availability. To gain insight into the potential physiological role of NBAT in central neurons, we used an antipeptide antiserum to examine the light and electron microscopic immunocytochemical localization of NBAT in the rat forebrain and to compare this distribution with that of cNOS. Immunolabeling for NBAT was detected within perikarya and dendrite-like processes that were most numerous in the frontal and cingulate cortex, the ventral striatum, the central amygdala, and the bed nucleus of the stria terminalis. Labeled varicose axonal processes were distributed most densely in the agranular insular cortex and the paraventricular nuclei of the thalamus and hypothalamus (PVH). Electron microscopy showed that immunogold labeling for NBAT was distributed along plasmalemmal and vacuolar membranes within somata, dendrites, and axonal profiles. Many of the NBAT-containing somata and dendrites contained detectable cNOS. Our results suggest that expression of NBAT may provide specific populations of cNOS-containing forebrain neurons with a unique mechanism for regulating somatodendritic synthesis of nitric oxide.

Progressive C-terminal deletions of the renal cystine transporter, NBAT, reveal a novel bimodal pattern of functional expression.

Nearly identical proteins (denoted NAA-Tr, rBAT, D2, NBAT), cloned from mammalian kidneys, induce a largely sodium-independent high-affinity transport system for cystine, basic amino acids, and some neutral amino acids in Xenopus oocytes (system b0,+-like). Mutations in the human NBAT gene have been found in several type I cystinurics. In kidney, NBAT is associated with a second, smaller protein (approximately 45 kDa), and this heterodimer has been proposed to be the minimal functional unit of the renal cystine transporter (Wang, Y., and Tate, S. S. (1995) FEBS Lett. 368, 389-392). To delineate regions minimally required for functional expression in oocytes, we constructed a series of C-terminal truncated mutants of rat kidney NBAT (wild-type (WT), 683 amino acids). Expression of these mutants in oocytes yielded an unusual bimodal pattern for the induction of amino acid transport activity. Thus, initial C-terminal truncations aborted elicitation of transport activity. The next mutant in the series, Delta588-683, exhibited most of the transport-inducing potential inherent in the WT/NBAT. Further deletions again attenuated transport activity. Although both the WT/NBAT and the truncated mutant, Delta588-683, induce qualitatively similar transport systems, the two forms of the protein exhibit contrasting sensitivities toward a point mutation in which the cysteine residue at position 111 was mutated to serine. This mutation did not greatly affect induction of transport by the WT/NBAT; however, the Delta588-683 mutant was inactivated by this mutation. Our data further suggest that cysteine 111 is probably the site of disulfide linkage with an approximately 45-kDa oocyte protein producing a complex equivalent to that seen in kidney membranes.

Evidence suggesting that the minimal functional unit of a renal cystine transporter is a heterodimer and its implications in cystinuria.

Cystinuria, one of the most common genetic disorders, is characterized by excessive excretion of cystine and basic amino acids in urine. The low solubility of cystine results in formation of kidney stones which can eventually lead to renal failure. Three types of cystinurias have been described. All involve defects in a high-affinity transport system for cystine in the brush border membranes of kidney and intestinal epithelial cells. The molecular properties of proteins involved in epithelial cystine transport are incompletely understood. A protein (NBAT, neutral and basic amino acid transporter), initially cloned by us from rat kidney and shown to be localized in the renal and intestinal brush border membranes, has been implicated in this transport, and mutations in human NBAT gene have been found in several cystinurics, making it a prime candidate for a cystinuria gene. However, mutations in NBAT were found only in Type I cystinurics and not in Types II and III suggesting that defects in other, as yet uncharacterized, genes may also be involved. NBAT has an unusual (for an amino acid transporter) membrane topology. We proposed that the protein contains four membrane-spanning domains, a model disputed by other investigators. We subsequently obtained experimental data consistent with a four membrane-spanning domain model. Furthermore, recently we showed that kidney and intestinal NBAT (85kDa) is associated with another brush border membrane protein (about 50kDa) and have proposed that the heterodimer represents the minimal functional unit of the high-affinity cystine transporter in these membranes. These findings raise the tantalizing possibilities that defects in the NBAT-associated protein might account for cystinurias in individuals with normal NBAT gene (such as the Types II and III cystinurics).

Oligomeric structure of a renal cystine transporter: implications in cystinuria.

Homologous proteins (NBAT) which mediate sodium-independent transport of neutral as well as basic amino acids and cystine when expressed in Xenopus oocytes were recently cloned from mammalian kidneys. Mutations in human NBAT have been implicated in cystinuria. Here, we show that rat kidney and jejunal brush border membrane NBAT (85 kDa) is found in association with a 50 kDa protein. The association involves one or more interprotein disulfide bonds. Rabbit kidney brush border membranes and membranes of NBAT cRNA-injected Xenopus oocytes also contain such heterodimers. Our data suggest that the heterodimer is the minimal functional unit of NBAT-mediated amino acid transport and that the NBAT-associated 50 kDa protein could play a role in cystinuria.

Immunocytochemical localization of the renal neutral and basic amino acid transporter in rat adrenal gland, brainstem, and spinal cord.

A neutral and basic amino acid transporter (NBAT) cloned from rat kidney was recently localized to enteroendocrine cells and enteric neurons. We used an antibody directed against a synthetic peptide representing a putative extracellular domain of NBAT to determine whether this transporter was also present in other endocrine and neural tissues, including rat adrenal gland, brainstem, and spinal cord. Abundant, highly granular labeling for NBAT was observed in the cytoplasm of chromaffin and ganglion cells in the adrenal medulla. A small population of intensely labeled varicose processes was also seen in both the cortex and the medulla of the adrenal gland. More numerous, intensely labeled varicose processes were detected in brainstem and spinal cord nuclei, including the locus coeruleus, rostral ventrolateral medulla, nuclei of the solitary tract, dorsal motor nucleus of the vagus, and intermediolateral cell column of the thoracic spinal cord. Significant perikaryal labeling for NBAT was only detected in brainstem and spinal cord following intraventricular colchicine treatment, which increased the number, distribution, and intensity of NBAT-immunolabeled cells. These NBAT-immunoreactive perikarya were most numerous in the locus coeruleus, rostral ventrolateral medulla, nuclei of the solitary tract, and raphe nuclei. Ultrastructural examination of the nuclei of the solitary tract of normal rats showed that NBAT was localized predominantly to axon terminals. Within these labeled terminals, NBAT was associated with large dense core vesicles and discrete segments of plasma membrane. The observed localization of NBAT suggests that this renal specific amino acid transporter subserves a role as a vesicular or plasmalemmal transporter in monoamine-containing cells, including chromaffin cells and autonomic neurons.

Cloning and expression of AQP3, a water channel from the medullary collecting duct of rat kidney.

The terminal part of the inner medullary collecting duct exhibits a high degree of water permeability that is independent of increased intracellular cAMP and not accounted for by the activity of the known renal epithelial water channels CHIP28 (28-kDa channel-forming integral protein) and WCH-CD (collecting duct water channel protein). Starting with rat kidney papilla mRNA, reverse transcription PCR was performed with degenerate primers assuming that the putative channel would be a member of the major intrinsic protein (MIP) family of proteins. A cDNA fragment was identified and used to screen a rat kidney cDNA library. A 1.9-kb cDNA clone was isolated. The open reading frame of 876 bp coded for a protein of 292 amino acids (M(r), 31,431). Aquaporin 3 (AQP3; 31.4-kDa water channel protein) is a newly discovered member of the MIP family. Northern blot analysis showed a single transcript for AQP3 of approximately 1.9 kb present in the renal medulla, predominantly in the inner medulla. With in situ hybridization, abundant message was found in the cells of the medullary collecting ducts. Injection of the complementary RNA of AQP3 into Xenopus oocytes markedly increased the osmotic water permeability. This permeability had an energy of activation of 3.0 kcal/mol (1 cal = 4.184 J), it was fully blocked by 1 mM p-chloromercuriphenylsulfonate, and this inhibition was reversed by 5 mM dithiothreitol. cAMP did not increase this water permeability. AQP3 did not permit passage of monovalent ions (Na, K, Cl); however, it is slightly permeable to urea. The present study demonstrates the existence of an additional water channel, AQP3, in epithelial cells of the medullary collecting duct.

Membrane topology of the rat kidney neutral and basic amino acid transporter.

A recently cloned rat kidney protein (NBAT) mediates the sodium-independent transport of neutral as well as basic amino acids and cystine when expressed in Xenopus laevis oocytes. The human equivalent of this transporter may be the one that is defective in cystinuria. Immunocytochemical studies have indicated that NBAT is primarily localized in the brush border membranes of rat kidney and intestinal epithelial cells, a localization consistent with its proposed role in amino acid transport. Two contrasting topological models have been proposed for NBAT: a four membrane-spanning domain (MSD) Nin-Cin model and a single MSD Nin-Cout model. We have investigated the topology of this membrane protein using two different approaches. One method was an immunofluorescent labeling technique in which intact or membrane-permeabilized cells expressing NBAT were probed with antibodies directed against putative extracellular and intracellular domains of the protein. In the second method, fragments generated by limited surface proteolysis of intact brush border membrane vesicles were subjected to immunoblot analysis using several site-specific antibodies. Both approaches yielded results consistent with a four MSD Nin-Cin topological model for NBAT.

Characterization of the promoter region of the gene for the rat neutral and basic amino acid transporter and chromosomal localization of the human gene.

The promoter region of the rat kidney neutral and basic amino acid transporter (NBAT) gene has been isolated and sequenced. The major transcription initiation site was mapped by primer extension. The entire promoter region and a set of 5' deletions within it were expressed at a high level in LLC-PK1 cells using the luciferase indicator gene. Positive and negative regulatory elements in the promoter region were observed. A human genomic clone of the transporter was also obtained and was used to localize the NBAT gene at the p21 region of chromosome 2.

Primary structure and functional properties of an epithelial K channel.

Expression cloning in Xenopus oocytes was used to identify a clone for a renal K channel. The clone, named ROMK2, was obtained from a cDNA library constructed in the plasmid vector pSPORT using size-selected poly(A)+ RNA from whole rat kidney. ROMK2 consists of 1,837 nucleotides, with an open reading frame of 1,116 bases predicted to code for a 372-amino acid peptide. The clone appears to be a splice variant of a recently reported K channel (ROMK1) from rat renal outer medulla (Ho, K.H., C.G. Nichols, W.J. Lederer, J. Lytton, P.M. Vassilev, M.V. Kanazirska, and S.C. Hebert. Nature Lond. 362: 31-37, 1993). Northern blot analysis indicates that ROMK2 is expressed in renal cortex, medulla, and papilla. Expression in other tissues appears to be much lower. The functional properties of the channel as measured in Xenopus oocytes indicate its close relationship to ROMK1 and more distant relationship to the inward rectifier K channel (IRK1) (Kubo, Y, T.J. Baldwin, Y. N. Jan, and L. Y. Jan. Nature Lond. 362: 127-133, 1993). The inward conductance of the channel is a saturable function of external K, with a half-maximal conductance at <5 mM. The selectivity sequence for ion permeability based on reversal potential measurements was K > Rb > NH4 > Na, Li. The conductance to Rb was only one-half that to K. Extracellular Ba2+ and Cs+ blocked the channel in a voltage-dependent manner. The high sensitivity of Cs+ block to voltage is consistent with the channel's operating as a multi-ion pore. The channel was blocked by high concentrations (100 microM) of glibenclamide. It did not appear to be blocked by extracellular Na+ or tetraethyl-ammonium ion. Patch-clamp measurements indicated a single-channel conductance of 30 pS in the presence of 110 mM K and high open probability that was weakly dependent on voltage. This channel may be involved in maintaining the membrane potential of renal cells and/or mediating renal K secretion.

Ultrastructural localization of a neutral and basic amino acid transporter in rat kidney and intestine.

A sodium-independent neutral and basic amino acid transporter (NBAT) from rat kidney was recently cloned and its amino acid sequence deduced. We used light and electron microscopic immunoperoxidase labeling to determine the cellular localization of NBAT in rat kidney and small intestine. The localization was carried out using site-directed antisera raised against synthetic peptides within NBAT. The most prominent localization of NBAT was in microvilli of epithelial cells lining renal proximal tubules. Microvilli of small intestinal epithelia were less frequently immunoreactive. Unexpectedly, the most intense labeling in the small intestine was seen within enteroendocrine cells and submucosal neurons. The neuronal labeling was highly localized within dense core vesicles in axon terminals apposed to the basal lamina near fenestrated blood vessels. These results support the proposal that NBAT plays a role in reabsorption of amino acids in renal tubules. In addition, they suggest that NBAT (or NBAT-like proteins) may have multiple functions in the small intestine, including luminal uptake of amino acids and vesicular uptake of related substrates into enteroendocrine cells and enteric neurons.

Characterization of the rat neutral and basic amino acid transporter utilizing anti-peptide antibodies.

High-titer, site-specific antibodies have been produced against the rat kidney broad-spectrum, sodium-independent neutral and basic amino acid transporter (NBAA-Tr) whose cDNA we cloned earlier. These antibodies have allowed us to characterize the transporter protein in normal rat tissues and in various cellular and in vitro expression systems. Western analysis detected 84- to 87-kDa glycosylated species enriched in rat renal and jejunal epithelial cell brush border membranes. In vitro translation of NBAA-Tr complementary RNA in the rabbit reticulocyte lysate system yielded a 78-kDa protein, a molecular mass that was predicted by the amino acid sequence deduced from the cloned cDNA. Translation in the presence of rough microsomal membranes yielded a glycosylated 89-kDa species. Glycosylated 87- to 89-kDa species were also expressed in Xenopus oocytes microinjected with NBAA-Tr complementary RNA and in COS-7 cells transfected with NBAA-Tr cDNA. Localization of NBAA-Tr in renal and intestinal brush border membranes is consistent with its proposed role in transepithelial transport of amino acids.

Glutathione and gamma-glutamyl transpeptidase are differentially distributed in the olfactory mucosa of rats.

Components of the gamma-glutamyl cycle, including thiols, glutathione (GSH) and gamma-glutamyl transpeptidase (gamma-GT), were localized in the nasal mucosae of rats using histochemical and immunohistochemical methods. In olfactory mucosa, thiols were widely distributed, with intense staining in the mucociliary complex (MC), basal cells, acinar cells of Bowman's glands (BG), and olfactory nerve bundles, and with moderate staining in olfactory receptor neurons (ORNs). GSH was localized in MC, BG acinar cells, nerve bundles and, to a lesser extent, in ORNs. gamma-GT immunoreactivity was restricted to the MC and to basolateral and apical membranes of BG acinar and duct cells. The basolateral membrane of BG acinar cells, located in close association with blood vessels and connective tissue, showed granule-like immunoreactivity. In respiratory mucosa, all three compounds were localized in the MC and acinar cells of respiratory glands (RG). In the MC, gamma-GT immunoreactivity was associated primarily with brush borders of ciliated cells. Granular immunoreactivity was also apparent in the supranuclear region of RG acinar cells. These results demonstrate that components of the gamma-glutamyl cycle are localized in olfactory and respiratory glands, and that they are secreted into the mucus, where they may mediate perireceptor events such as detoxification and/or solubilization of air-borne xenobiotics, toxicants and odorants.

Distribution of mRNA of a Na(+)-independent neutral amino acid transporter cloned from rat kidney and its expression in mammalian tissues and Xenopus laevis oocytes.

The Na(+)-independent neutral amino acid transporter (NAA-Tr) that we had previously cloned from rat kidney has been investigated with respect to its distribution in mammalian tissues and cells. By Northern blot analysis and RNase protection assay, a 2.4-kilobase (kb) mRNA in rat intestine was found to be identical to that in rat kidney. Of the other rat tissues examined, only brain and heart were found to contain mRNAs related to kidney NAA-Tr by Northern assay. However, these were larger (approximately 5 and approximately 7 kb). Mouse and rabbit kidney also contain mRNAs of 2.4 kb that exhibited a high degree of homology with rat kidney NAA-Tr. Of the several cultured cells investigated that demonstrated considerable Na(+)-independent neutral amino acid transport activity, only human colon carcinoma (Caco) cells were positive by Northern assay. The failure to detect NAA-Tr mRNA in many cells and tissues that carry out Na(+)-independent transport indicates that unrelated transporters must also exist. Cells and tissues that were negative with respect to rat kidney NAA-Tr as well as those that were positive transported leucine and tryptophan equally well. However, when mRNA from the same cells and tissues was expressed in oocytes, in all cases tryptophan was transported far less efficiently than leucine. This defect in tryptophan transport is apparently due to aberrant expression of neutral amino acid transporters in general in Xenopus oocytes.

Expression cloning of a Na(+)-independent neutral amino acid transporter from rat kidney.

Uptake of long-chain and aromatic neutral amino acids into cells is known to be catalyzed by the Na(+)-independent system L transporter, which is ubiquitous in animal cells and tissues. We have used a Xenopus oocyte expression system to clone the cDNA of a system L transporter from a rat kidney cDNA library. The 2.3-kilobase cDNA codes for a protein of 683 amino acids. The transporter has four putative membrane-spanning domains and bears no sequence or structural homology to any known animal or bacterial transporter. When transcribed and expressed in Xenopus oocytes, the transporter exhibits many, but not all, of the characteristics of L-system transporters, suggesting that this represents one of several related L-system transporters.

Expression of renal Na(+)-Ca2+ exchange activity in Xenopus laevis oocytes.

The expression of a renal Na(+)-Ca2+ exchanger by Xenopus oocytes has been investigated. Each oocyte was injected with 50 ng of poly(A)+ RNA from either rat or rabbit kidney or with an equivalent volume of water. Na(+)-Ca2+ exchange was determined 3 days after injection, by measuring Ca2+ uptake by oocytes in the presence or absence of an outwardly directed Na+ concentration gradient. To manipulate Na+ concentration gradients, oocytes were first loaded with Na+ in Ca(2+)-free medium containing 90 mM Na+ and nystatin. They were then exposed to medium containing 45Ca and either 90 mM or 0 Na+. Na(+)-free media contained (in mM) either 90 K+, 90 choline or 85 choline plus 5 K+. Oocytes injected with rat kidney poly(A)+ RNA showed a Na+ gradient-dependent Ca2+ uptake of 6.6 +/- 0.8 (SE, n = 5) pmol.oocyte-1.30 min-1. This is significantly higher than the value of 3.4 +/- 0.5 (SE, n = 5) pmol.oocyte-1.30 min-1 obtained in water-injected oocytes (P less than 0.001). Similar results were obtained using poly(A)+ RNA from rabbit kidney cortex. Neither 10 microM nifedipine nor 0.5 mM D 600 significantly affected this Ca2+ uptake. However, 90% of the Ca2+ uptake was inhibited in the presence of 0.1 mM La3+. The poly(A)+ RNA-induced Na(+)-Ca2+ exchange activity was stimulated by the presence of 5 mM K+ in the extracellular choline solution compared with choline alone. Fractionation experiments indicate that the rat kidney Na(+)-Ca2+ exchanger was encoded by poly(A)+ RNA of 3-4 kb.

Expression of catfish amino acid taste receptors in Xenopus oocytes.

We demonstrate that poly (A+)RNA isolated from catfish barbels directs the expression of functional amino acid taste receptors in the Xenopus oocyte. The activity of these receptors is monitored in ovo by the two electrode voltage clamp technique. Specific conductance changes recorded in response to amino acid stimulation are analogous to those recorded electrophysiologically from intact catfish barbels. These responses exhibit specificity, reproducibility, rapid onset and termination, and desensitization to repetitive stimulation. A functional assay system that encompasses the full complement of transduction events from the ligand-receptor interaction to subsequent conductance changes is necessary to identify molecular components responsible for these events. Our results demonstrate that the Xenopus oocyte can be used to characterize and identify clones coding for amino acid taste receptors analogous to its use in studying receptor molecules for other neuroactive compounds.

Secreted alkaline phosphatase: an internal standard for expression of injected mRNAs in the Xenopus oocyte.

The Xenopus oocyte is widely used to study the various aspects of eukaryotic cell structure and function. It is also being used increasingly in expression cloning of cDNAs encoding proteins for which there are no structural data. One of the drawbacks of the Xenopus oocyte system is that individual oocytes taken at the same time from the same frog vary considerably in the amount of protein synthesized from the same amount of injected mRNA. In this report we describe the preparation and use of the mRNA for a secreted mutant form of human placental alkaline phosphatase as an internal, coinjected standard to monitor translation in oocytes. Secreted alkaline phosphatase can be readily determined in the medium of cultured oocytes by using a standard colorimetric assay. The amounts of alkaline phosphatase secreted into the medium were shown to parallel the level of expression of two membrane proteins. This permits rapid identification and selection of those oocytes that efficiently express injected mRNAs. The procedure yields more precise data and results in an enormous saving of time and expense, especially in investigations that involve complex measurements on individual oocytes.

Expression of the mammalian Na+-independent L system amino acid transporter in Xenopus laevis oocytes.

System L is primarily responsible for the Na+-independent transport of neutral amino acids, those with bulky chains such as leucine, isoleucine, phenylalanine, etc., into mammalian cells. mRNA from rat kidney and human lymphoid cells, when microinjected into Xenopus laevis oocytes, induced expression of this transport system. The expressed transport exhibits characteristics similar to those reported for the System L amino acid transporter from a variety of mammalian cells. Injection of size-fractionated mRNA indicates that the System L transporter in both the rat kidney and human lymphoid cells is encoded by mRNA of about 3 to 4 kb.

In vitro translation and processing of human hepatoma cell (Hep G2) gamma-glutamyl transpeptidase.

Human hepatoma cell (Hep G2) gamma-glutamyl transpeptidase (gamma-GT), a 120 ka single-chain glycoprotein, is much larger than the expected precursor of the dimeric enzyme in other human tissues. However, the Hep G2 gamma-GT mRNA encodes a 63 kDa peptide, similar to that of rat gamma-GT mRNA product and to the predicted, unglycosylated precursor of the enzyme in human tissues. Translation in presence of dog pancreas microsomes results in processing of the 63 kDa to an 80 kDa core-glycosylated species which is subsequently cleaved to 58 and 22 kDa subunits resembling those in other human tissues. The unusually large Mr of gamma-GT in Hep G2 would thus seem to be due to further glycosylation and processing in the Golgi. A deficiency of the processing protease is the most likely reason for the persistence of the single-chain form of gamma-GT in Hep G2 cells.

Renal gamma-glutamyl transpeptidases: structural and immunological studies.

Mammalian kidney gamma-glutamyl transpeptidases are compared with respect to subunit size, amino-terminal sequences of the two subunits, immunological, and some catalytic properties. The species-related variation in the apparent molecular weight of the subunits has been shown to be primarily due to the extent and nature of protein glycosylation. Using antibodies raised against the native enzymes and isolated sodium dodecyl sulfate-treated subunits, it is shown that the transpeptidases share some antigenic determinants. Some of these determinants in the highly glycosylated transpeptidase subunits can be detected by the antibodies only upon deglycosylation of the subunits. The amino-terminal sequences of the subunits exhibit considerable homology, in agreement with the immunological data. Thus, there are two segments of identity (3 and 5 residues in length, respectively) in the first 17 amino-terminal residues of the heavy subunits of rat, bovine, dog, and human kidney transpeptidases (papain-solubilized). Of particular interest is the finding of 91 to 96% identity in the first 23 amino-terminal residues of the small subunit of these transpeptidases. The small subunit contains the gamma-glutamyl binding site of the enzyme. There are three segments of identity (7, 6, and 8 residues in length, respectively) in the first 23 residues, each separated by either a Ser or an Ala residue. The first 7 amino-terminal residues of the small subunit in all four species are identical, indicating a high degree of specificity in the proteolytic processing of the common, single-chain precursor of the two subunits. Differences noted between transpeptidases in their relative acceptor specificity and in their susceptibility to inactivation by the glutamine antagonist, AT-125 (acivicin), must reflect subtle structural differences in their active center domains.