Molecular cloning and characterization of a murine hemicholinium-3-sensitive choline transporter.

In cholinergic neurons, a specific requirement for precursor choline in the biosynthesis of acetylcholine (ACh) is thought to be sustained by a presynaptic, hemicholinium-3 (HC-3)-sensitive choline transporter (CHT). This transporter exhibits micromolar affinity for choline and transport activity is Na(+)- and Cl(-)-dependent. Based on the sequence information available with the recent cloning of rat and human CHTs [Okuda, Haga, Kanai, Endou, Ishihara and Katsura (2000) Nat. Neurosci. 3, 120-125; Apparsundaram, Ferguson, George Jr and Blakely (2000) Biochem. Biophys. Res. Commun. 276, 862-867; Okuda and Haga (2000) FEBS Lett. 484, 92-97], we have identified a murine CHT orthologue (mCHT) by reverse transcriptase-PCR of spinal cord mRNA and confirmed this sequence using assembled mouse genomic DNA. Inferred splice junctions for mCHT exons are conserved with those of hCHT. The mCHT cDNA encodes a protein of 580 amino acids with 93% and 98% amino acid identity to human CHT and rat CHT1, respectively. Hydropathy analysis of the predicted amino acid sequence of mCHT indicates a protein containing 13 transmembrane domains (TMDs), with the N-terminus oriented extracellularly and the C-terminus oriented intracellularly. Northern blot analysis of mouse tissues reveals the expression of mCHT as a single transcript of approximately 5 kb with highest expression in regions that are rich in cholinergic cell bodies, e.g. the spinal cord, brainstem, mid-brain and striatum, whereas hybridization signals are absent in regions lacking cholinergic soma, e.g. the cerebellum and kidney. Expression of mCHT in COS-7 cells results in high-affinity [(3)H]HC-3-binding sites (K(d)=5 nM), and Na(+)- and Cl(-)-dependent HC-3-sensitive choline uptake (K(m)=2 microM), assessed in resealed membrane vesicles. The availability of cloned, functional mCHT and its cognate genomic DNA should prove useful for studies of mCHT regulation and should open possibilities for evaluation of CHT dysfunction in murine models.

Transient developmental expression of monoamine transporters in the rodent forebrain.

Neurons in first-order sensory thalamic nuclei have been shown to express functional plasma membrane serotonin (SERT) and vesicular monoamine (VMAT2) transporters during early postnatal development. In the present study, we provide an extensive description of the spatial and the temporal patterns of VMAT2 and SERT expression, during early embryonic development and postnatal life, by using in situ hybridization and immunocytochemistry. VMAT2 and SERT genes are transiently expressed in a wide population of non-monoaminergic neurons in the central and peripheral nervous system with a large overlap in the temporal and spatial pattern of expression of both genes. A selective pattern of expression of both genes was observed in the thalamus with expression limited to the dorsal thalamus and more particularly to primary sensory relay nuclei that convey point to point projection maps. Transient expression of the transporters was also observed in sensory cranial nerves, in the hippocampus, cerebral cortex, septum, and amygdala. VMAT2 and SERT gene expression was not necessarily linked, as some neural populations expressed only VMAT2, while others only contained SERT. Since VMAT2 serves to transport catecholamines besides serotonin, we examined the developmental expression of the plasma membrane dopamine and norepinephrine transporters but found no transient expression of these genes. Despite minor temporal disparities, VMAT2 and SERT extinguished almost simultaneously during the second and third weeks of post-natal life. These expressions did not seem to be dependent on peripheral neural inputs, since monocular enucleations and infraorbital nerve cuts effected on the day of birth, did not modify the period of transporter expression or of extinction.

Identification of a single amino acid, phenylalanine 586, that is responsible for high affinity interactions of tricyclic antidepressants with the human serotonin transporter.

When assayed in parallel using transfected mammalian cells, human and rat serotonin transporters (SERTs) exhibit consistent differences in potency for tricyclic antidepressants but not for 5-hydroxytryptamine, cocaine, or nontricyclic serotonin transporter-selective reuptake inhibitors. Previously, using chimeric proteins, we determined that domains or residues distal to transmembrane domain 11 (amino acid 531) dictate the increased sensitivity of human SERT to imipramine. Using an additional chimera and site-directed mutagenesis, we have determined that a single amino acid, F586, is responsible for increased sensitivity to imipramine, desipramine, and nortriptyline. Thus, mutation of wild-type rat SERT (V586) to the human SERT identity F586, but no other divergent amino acids between human and rat SERTs, selectively increased tricyclic antidepressant potency. A reciprocal reduction in potency was observed when human SERT F586 was converted to the cognate rat SERT residue (V586). Interactions with other SERT antagonists, including paroxetine and cocaine, as well as the SERT substrates 5-hydroxytryptamine and d-amphetamine were unaffected by interconversion of this residue. Phenylalanine conversion in the human norepinephrine transporter at the homologous position failed to alter tricyclic inhibition of catecholamine uptake, revealing a SERT-specific context for use of the aromatic side chain at this position. Additional constraints on aromaticity at rat SERT position 586 were revealed by conversion of rat SERT V586 to Y586, which failed to repllcate the effect of the F586 mutation. In addition, conversion to V586D, but not V586R, increased tricyclic potency to that of human SERT and additionally increased potency for cocaine but not paroxetine. These results implicate distal domains and a single residue in TMD 12 in the formation of high affinity SERT antagonist binding sites.

Functional characterization and chromosomal localization of a cloned taurine transporter from human placenta.

A cDNA clone highly related to the rat brain taurine transporter has been isolated from a human placental cDNA library. Transfection of this cDNA into HeLa cells results in a marked elevation of taurine transport activity. The activity of the cDNA-induced transporter is dependent on the presence of Na+ as well as Cl-. The Na+/Cl-/taurine stoichiometry for the cloned transporter is 2:1:1. The transporter is specific for taurine and other beta-amino acids, including beta-alanine, and exhibits high affinity for taurine (Michaelis-Menten constant approximately 6 microM). The clone consists of a coding region 1863 bp long (including the termination codon), flanked by a 376 bp-long 5' non-coding region and a 625 bp-long 3' non-coding region. The nucleotide sequence of the coding region predicts a 620-amino acid protein with a calculated M(r) of 69,853. Northern-blot analysis of poly(A)+ RNA from several human tissues indicates a complex expression pattern differing across tissues. The principal transcript, 6.9 kb in size, is expressed abundantly in placenta and skeletal muscle, at intermediate levels in heart, brain, lung, kidney and pancreas and at low levels in liver. Cultured human cell lines derived from placenta (JAR and BeWo), intestine (HT-29), cervix (HeLa) and retinal pigment epithelium (HRPE), which are known to possess Na(+)- and Cl(-)-coupled taurine transport activity, also contain the 6.9 kb transcript. Somatic cell hybrid and in situ hybridization studies indicate that the cloned taurine transporter is localized to human chromosome 3 p24-->p26.