In monoaminergic cells, the neurotransmitter is accumulated into secretory or synaptic vesicles by a tetrabenazine-and reserpine-sensitive transporter, catalyzing an H+/monoamine antiport. The major vesicular monoamine transporter from bovine chromaffin cells was cloned, using sequences common to adrenal medulla and brain rat vesicular monoamine transporters. Its identity was confirmed by peptide sequences, determined from the purified protein. Surprisingly, the bovine adrenal medulla sequence, bVMAT,, is more related to the transporter from human and rat brain than to that from rat adrenal medulla. PCR amplifi~tion showed that bVMAT, is expressed in both adrenal medulla and brain, in contrast with the situation reported in rats, where distinct genes appear to be expressed in brain (SVAT or MAT, now renamed rVMAT& and in the adrenal medulla (CGAT, now renamed rVMA'I',). In bovine ~hromaffin cells, long-term depolarization by KCI resulted in an increase in the level of bVMAT, mRNA, in agreement with the previously observed increase in the transporter binding sites, suggesting that a coupiing between stimulation, secretion and synthesis changes the composition of the secretory granule membrane.
The monoamine transporter of the chromaffin granule membranes can be specifically labeled by the photoaffinity reagent 7-azido-8-[125I]iodoketanserin. The characteristics of the labeled protein have been investigated. Two-dimensional gel electrophoresis of the labeled membranes indicated a MW of about 70,000 and an isoelectric point ranging from 3.8 to 4.6. No clear protein spot was associated with the radioactive material, which migrated between glycoproteins GPII and GPIV. The diffuse aspect of the radioactive material indicated a heterogeneity, which was not modified after a second electrophoresis. This heterogeneity was, at least partially, due to glycosylation of the transporter; neuraminidase treatment increased the protein pI up to 6.3, whereas digestion with N-glycopeptidase markedly decreased the apparent MW, from 70,000 to 50,000. SDS-polyacrylamide gel electrophoresis showed that, at low acrylamide concentrations, the labeled material migrated more rapidly than predicted from the mobility of the markers of molecular weight, a behavior which indicated a marked hydrophobicity of the transporter. The labeled protein was purified to homogeneity by a combination of chromatography on DEAE-cellulose at pH 4.5, on immobilized wheat germ agglutinin, and on hydroxylapatite in the presence of SDS. During this purification, the specific radioactivity was increased by a factor of 300-500, with a yield of 10-20%.
The long-term effects of a unique injection of reserpine (5 mg/kg s.c.) on the vesicular monoamine transporter and dopamine uptake complex have been investigated, in parallel with behavioral and neurochemical effects. Early after treatment, a dramatic decrease in locomotor activity, as well as a marked depletion in striatal dopamine (DA), associated with a prominent enhancement in dopaminergic turnover were observed in reserpine-treated rats. From 2 to 60 days after reserpine injection, a recovery in locomotor activity occurred, in parallel with an increased DA content in the striatum, reaching about 50% of controls at day 60. At this time, the dopamine turnover was quite normal. The density of the dopamine uptake sites in the striatum, studied with 3H GBR12783, was unchanged after reserpine treatment at any time studied up to 60 days. By contrast, the density of binding sites for 3H dihydrotetrabenazine (3H TBZOH), a marker for the vesicular monoamine transporter, remained dramatically decreased in the striatum all over the time of the study (> -90% of controls at day 2 and -80% at day 30 and 60). A lesser decrease (-60%) was observed in the substantia nigra pars compacta (SNc), 2 and 30 days after reserpine treatment. This suggests that at least 60% of the vesicular monoamine transporter is sensitive to reserpine in this cell bodies region, indicating that this proportion of the transporter is integrated in functional vesicles, a prerequisite for reserpine binding.(ABSTRACT TRUNCATED AT 250 WORDS)
Prior to secretion, monoamines (catecholamines, serotonin, histamine) are concentrated from the cytoplasm into vesicles by vesicular monoamine transporters (VMAT). These transporters also carry non-physiological compounds, e.g. the neurotoxin methyl-4-phenylpyridinium. VMAT acts as an electrogenic antiporter (exchanger) of protons and monoamines, using a proton electrochemical gradient. Vesicular transport is inhibited by specific ligands, including tetrabenazine, ketanserin and reserpine. The mechanism of transport and the biochemistry of VMAT have been analyzed with the help of these tools, using mainly the chromaffin granules from bovine adrenal glands as a source of transporter. Although biochemical studies did not suggest a multiplicity of VMATs, two homologous but distinct VMAT genes have recently been cloned from rat, bovine and human adrenal glands. The VMAT proteins are predicted to possess 12 transmembrane segments, with both extremities lying on the cytoplasmic side. They possess N-glycosylation sites in a putative luminal loop and phosphorylation sites in cytoplasmic domains. In rat, VMAT1 is expressed in the adrenal gland whereas VMAT2 is expressed in the brain. In contrast, we found that the bovine adrenal gland expressed both VMAT1 and VMAT2. VMAT2 corresponds to the major transporter of chromaffin granules, as shown by partial peptidic sequences of the purified protein and by a pharmacological analysis of the transport obtained in transfected COS cells (COS cells are monkey kidney cells possessing the ability to replicate SV-40-origin-containing plasmids). We discuss the possibility that VMAT1 may be specifically addressed to large secretory granules vesicles, whereas VMAT2 may also be addressed to small synaptic vesicles; species differences would then reflect the distinct physiological roles of the small synaptic vesicles in the adrenal gland.
Catecholamines are accumulated in vesicles by a proton gradient-dependent transport, which has mostly been studied in bovine chromaffin granules. The full sequence of a cDNA encoding a vesicular transporter from bovine chromaffi cells, bVMAT*, was recently reported. We now present an analysis of bVMAT,, expressed in transfected COS cells. Comparing the binding of a labelled ligand, ['HITBZOH, and the rate of uptake, we find a much lower molecular turnover number than in chromaffin granules, probably indicating that a majority of expressed transporters are correctly folded and possess the ligand binding site but cannot actively transport monoamines because they are located in compartments which do not possess a proton gradient. The substrate specificity of uptake and its pharmacological sensitivity to various inhibitors closely resemble those previously observed in chromaffin granules. These results suggest that VMAT, is the major transporter in bovine adrenal glands, and raise the question of the significance of the second related transporter, VMAT,, which is also expressed in this tissue.
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