Decrease of uptake and exchange of neurotransmitter amino acids after depletion of their synaptosomal pools

Regulation of the gamma-aminobutyric acid transporter activity by protein phosphatases in synaptic plasma membranes

The influence of the phosphorylation dephosphorylation states on the gamma-aminobutyric acid (GABA) transporter activity of synaptic plasma membranes (SPM) was studied by using either specific phosphatase inhibitors or activators. Calyculin A and okadaic acid (phosphatase 1 and phosphatase 2A inhibitors) inhibited the GABA uptake by isolated SPM vesicles, whereas cyclosporin A (phosphatase 2B inhibitor) had a stimulatory effect (approximately 10%) which was higher (approximately 38%) when all these drugs were present in the reaction medium. On the other hand, intravesicular Ca2+, up to about 10 microM, inhibited the GABA uptake (approximately 50%) in a manner which appeared to be facilitated in the presence of PP1 and PP2A inhibitors and this inhibition was relieved by the calmodulin antagonist W-7. We also observed that isolated SPM vesicles contain both Ca(2+)-independent phosphatase activity that is significantly inhibited by PP1 and PP2A inhibitors, and Ca(2+)-dependent phosphatase activity that is abolished in the presence of the PP2B inhibitor, cyclosporin A. These results indicate that regulation of the SPM GABA transporter is determined by the internally localized Ca-calmodulin-dependent phosphatase activity (calcineurin), and that other phosphorylated sites, sensitive to PP1 and PP2A inhibitors, potentiate either the positive or negative effects exerted by those internal sites when they are in their phosphorylated or dephosphorylated states, respectively.

Carrier-mediated serotonin release induced by d-fenfluramine: studies with human neuroblastoma cells transfected with a rat serotonin transporter

The NMB human neuronal cell line, transfected with a newly prepared plasmid expressing rat serotonin transporter (NMB-rSERT), shows specific [3H]5-HT uptake which is blocked by citalopram and fenfluramine (F) stereoisomers with IC50 values (1 nM. 0.5 microM (dF) and and 5 microM (IF), respectively) which are similar to those found in rat brain synaptosomes. d-Fenfluramine (0.5 and 10 microM) also stimulates tritium release from NMB-rSERT cells preloaded with [3H-]-5-HT. The d-fenfluramine-induced [3H-]5-HT release is blocked by 0.3 microM citalopram and is dependent on the density of SERT expressed per cell, but is not affected by removal of Ca++ ions from the incubation medium. Manipulation of the Na+ gradient across the plasma membrane (replacing 60 mM NaCl with an equimolar concentration of KCl or choline) also induced [3H-]5-HT release from NMB-rSERT cells, which was inhibited by 0.3 microM citalopram. These results, together with the finding that NMB-rSERT cells preloaded with 500 nM unlabelled 5-HT take up [3H-]d-fenfluramine, make NMB-rSERT cells a valuable tool for studying the transporter-mediated exchange release induced by amphetamine derivatives.

Depolarization-induced release of glycine and beta-alanine from plasma membrane vesicles derived from rat brain synaptosomes

Glycine and beta-alanine actively loaded into brain synaptic plasma membrane vesicles were released into the external medium by using the classical depolarization agents high K+ and veratridine. This release occurs via a Ca2+-independent process. Measurements of membrane depolarization using tetraphenylphosphonium uptake show a close correlation between changes in the membrane potential and stimulation of the efflux process. Results shown herein and previously reported by our group (Aragón, M.C. and Giménez, C. (1986) Biochim. Biophys. Acta 855, 257-264; Agulló, L., Jiménez, B., Aragón, M.C. and Giménez, C. (1986) Eur. J. Biochem. 159, 611-617), suggest that the glycine and beta-alanine transport systems in synaptic plasma membranes are susceptible of modulation by changes in ionic fluxes and hence in the membrane potential, similar to those occurring during depolarization and repolarization.

Compartmentation and release of exogenous GABA in sheep brain synaptosomes

Exogenous tritiated gamma-aminobutiric acid ([3H]GABA) is retained in two compartments in sheep cortex synaptosomes, corresponding to cytoplasmic and vesicular spaces, assuming that freeze-thawing the synaptosomes loaded with [3H]GABA releases the cytoplasmic [3H]GABA (81 +/- 3.9%), and that subsequent solubilization of the synaptosomes with 1% sodium cholate releases the vesicular [3H]GABA (19 +/- 3.9%). Depolarization of synaptosomes with 40 mM K+ in a Na+-medium, in the absence of Ca2+, releases 20.3 +/- 2.7% of the [3H]GABA retained in the synaptosomes. The [3H]GABA released under these conditions comes predominantly from the cytoplasm. The presence of 1 mM Ca2+ during depolarization releases an additional 13% (a total of about 33.5 +/- 9.9%) of the releasable [3H]GABA, and the [3H]GABA release which is Ca2+-dependent also comes mostly from the cytoplasmic compartment. When choline replaces external Na+, the [3H]GABA release is absolutely Ca2+-dependent, and the [3H]GABA released also comes mostly from the cytoplasmic pool. Therefore, it appears that [3H]GABA taken up by synaptosomes is accumulated mostly in the cytoplasmic compartment from which it is released upon depolarization. The technique described permits distinguishing the effect of different factors on the two pools of accumulated [3H]GABA.

Uptake of L-alanine, glycine and L-serine in the pigeon central nervous system

The uptake characteristics of L-alpha-alanine, glycine and L-serine into crude mitochondrial fractions from pigeon telencephalon, tectum and spinal cord were determined. Sodium dependent high affinity uptake systems were found for all 3 amino acids in all 3 brain regions, except for glycine in the telencephalon. The mutual inhibition of the high affinity uptake by the 3 amino acids was measured in the tectum. Alanine uptake was inhibited competitively by serine and glycine. The inhibition of serine uptake by alanine and glycine was also competitive. In contrast, glycine uptake inhibition by alanine and serine was incomplete and neither competitive, non-competitive nor uncompetitive. The effect of various chemicals on the uptake of the 3 amino acids was measured in the tectum at a substrate concentration of 10(-5) M. Four groups could be distinguished: (1) Substances with no effect on the uptake of all 3 amino acids, (2) substances which inhibited the uptake of all 3 amino acids to a similar degree, (3) substances which inhibited the uptake of alanine and serine more than glycine and (4) substances which inhibited glycine uptake more than alanine and serine uptake. From these results we conclude: Alanine and serine are probably taken up by the same transport system. This system can possibly also use glycine as substrate. Most of the glycine high affinity uptake, however, is due to a specific glycine transport system. This system was found only in tectum and spinal cord and is probably the same uptake system as known in the spinal cord of other vertebrates.