Choline Acetyltransferase: Regulation and Coupling with Protein Kinase and Vesicular Acetylcholine Transporter on Synaptic Vesicles

Both the membrane-bound choline acetyltransferase (MChAT) and soluble ChAT (SChAT) were found to be activated by ATP-mediated protein phosphorylation. ATP activation of MChAT but not SChAT was found to depend on the integrity of proton gradient of synaptic vesicles because conditions disrupting the proton gradient also abolished the activation of MChAT by ATP. Among the kinases studied, Ca2+/calmodulin kinase II is most effective in activation of MChAT. Transport of ACh into synaptic vesicles by vesicular acetylcholine transporter (VAChT) is also proton gradient-dependent; therefore we proposed that there is a functional coupling between ACh synthesis and its packaging into synaptic vesicles. This notion is supported by the following findings: first, the newly synthesized [3H]-ACh from [3H]-choline was taken up much more efficiently than the pre-existing ACh; second, ATP-activation of MChAT was abolished when VAChT was inhibited by the specific inhibitor vesamicol; third, the activity of ChAT was found to be markedly increased when neurons are under depolarizing conditions.     

Identification of inosine as an endogenous modulator for the benzodiazepine binding site of the GABAA receptors

Previously we have reported the presence of endogenous ligands that are involved in the regulation of the binding of muscimol to the GABA binding site of the GABA_A receptors. Here, we report the presence of multiple forms of endogenous ligands in the brain which modulate the binding of flunitrazepam (FNZP) to the benzodiazepine (BZ) binding site of the GABA_A receptor. Furthermore, one of the endogenous ligands for the BZ receptors, referred to as EBZ, has been identified as inosine based on the following observations: (1) standard inosine and the EBZ have identical NMR and UV spectra; (2) the elution profile of inosine and the EBZ from a HPLC column are indistinguishable, and (3) inosine and the EBZ show identical activity in inhibiting [³H]FNZP binding.     

Role of Ca2+ in α-Amino-3-Hydroxy-5-Methyl-4-Isoxazolepropionic Acid-Mediated Polyphosphoinositide Turnover in Primary Neuronal Cultures

Abstract: Excitatory amino acid (EAA) receptors and EAA-mediated stimulation of polyphosphoinositide (poly-PI) turnover were studied in cultured neurons at different days in vitro (DIV). Six main observations have emerged from these studies: (a) Neurons increased their sensitivity to EAAs as a function of time in culture, indicated by increasing EAA-mediated poly-PI turnover, (b) Extracellular Ca²⁺ concentration played an important role in α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)-stimulated poly-PI turnover in cells at 4 DIV, whereas poly-PI turnover mediated by l -glutamate and trans -1-amino-cyclopentane-1,3-dicarboxylic acid was not Ca²⁺-dependent. (c) A marked stimulation of poly-PI turnover by AMPA was seen in the cultured neurons at 4 DIV, but not at 17 DIV, suggesting that a distinct EAA receptor sensitive to AMPA is transiently expressed, (d) The Ca²⁺ ionophore A23187 increased poly-PI turnover in cultured neurons, suggesting that Ca²⁺ entry is involved in stimulating poly-PI turnover, (e) Stimulation of poly-PI turnover by carbachol was greater in neurons at 17 DIV as compared with −4 DIV, and appeared to be Ca²⁺-dependent across DIV. (f) 6-Cyano-7-nitroquinoxaline-2,3-dione, an antagonist for non- N -methyl- d -aspartate ionotropic EAA receptors, inhibited 100% and 35% of AMPA-and quisqualate-induced poly-PI turnover, respectively, suggesting an involvement of ionotropic AMPA/quisqualate receptors in stimulating poly-PI turnover.     

A Rat Brain cDNA Encodes Enzymatically Active GABA Transaminase and Provides a Molecular Probe for GABA-Catabolizing Cells

Abstract: cDNAs encoding γ-aminobutyric acid aminotransferase (GABA-T) were isolated from a λZAP rat hippocampal cDNA expression library by two independent cloning methods, immunological screening with an antimouse GABA-T antibody and plaque hybridization with a GABA-T cDNA probe derived by polymerase chain reaction. We have produced enzymatically active GABA-T from a rat brain cDNA containing the full-length GABA-T coding region. Our rat brain GABA-T cDNAs hybridize to mRNAs in brain and peripheral tissues, including liver, kidney, and testis. We have also detected GABA-T mRNA in GABAergic cells of rat cerebellar cortex by in situ hybridization. Our rat brain GABA-T probe hybridizes to Purkinje, basket, stellate, and Golgi II cells, the same GABAergic neurons previously shown to contain glutamate decarboxylase GAD₈₅ and GAD₈₇.     

Role of protein phosphorylation in regulation of brainL-glutamate decarboxylase activity

In the brain, the -aminobutyric acid (GABA) level is primarily controlled by the activity of its synthesizing enzyme,L-glutamate decarboxylase (GAD). At present, mechanisms responsible for regulation of GAD activity remain largely unknown. Here we report that GAD activity is inhibited by conditions favoring protein phosphorylation, and this inhibition can be reversed by phosphatase treatment. Furthermore, this inhibition appears to result from the suppression of a Ca²⁺-dependent phosphatase. Phosphorylation of GAD is demonstrated by direct incorporation of³²P into the GAD protein. These results suggest that GAD activity in the brain is inhibited by phosphorylation and activated by dephosphorylation. A model for regulation of GABA synthesis related to neuronal excitation is discussed.     

A RAPID METHOD FOR ASSAYING ENZYMES WHOSE SUBSTRATES AND PRODUCTS DIFFER BY CHARGE. APPLICATION TO BRAIN l-GLUTAMATE DECARBOXYLASE

Abstract— A simple, rapid, sensitive and economical assay technique has been developed for any enzyme whose substrate and product differ by charge. It is based on a combination of rapid vacuum filtration with an ion exchange resin. The technique has been successfully applied to brain glutamate decarboxylase.     

Identification and functional analysis of truncated human glutamic acid decarboxylase 65

Human brain glutamate decarboxylase 65 (hGAD65) was found to exist as full-length and truncated forms when the glutathione S-transferase-tagged hGAD65 fusion protein was subjected to factor Xa cleavage. The truncated form is produced by cleavage at arginine 69 based on N-terminal amino acid sequence analysis, and has a molecular weight of 58 kD. It is resistant to further factor Xa cleavage or mild trypsin treatment and is more active and more stable than the full-length form. Both the full-length and truncated forms of GAD are also observed in brain preparations in the presence of protease inhibitors. Furthermore, full-length GAD could be converted to the truncated form by endogenous proteases, suggesting that the conversion of full-length to truncated GAD mediated by endogenous protease may represent an important mechanism in the regulation of GABA biosynthesis in the brain.     

Demonstration of functional coupling between dopamine synthesis and its packaging into synaptic vesicles

We have previously shown that the membrane-associated form of the GABA-synthesizing enzyme, glutamate decarboxylase 65 (GAD₆₅), is activated by synaptic vesicle proton gradient-mediated protein phosphorylation. We now report that the rate-limiting enzyme in dopamine (DA) biosynthesis, tyrosine hydroxylase (TH), is regulated similarly to GAD₆₅. The membrane-associated form of TH (MTH) was activated by conditions favoring protein phosphorylation (e.g. ATP) and was inhibited by phosphatase (e.g. calf intestine phosphatase). Furthermore, the ATP-mediated activation of MTH was abolished by conditions that disrupted the proton gradient of synaptic vesicles, e.g. the presence of carbonyl cyanidem-chorophenylhydrazone, gramicidin, or the V-type ATPase inhibitor (bafilomycin), but not the P-type ATPase inhibitor (vanadate). Moreover, DA newly synthesized from tyrosine by MTH and membrane-associated aromatic amino acid decarboxylase was taken up preferentially rather than pre-existing DA. Therefore, the previously proposed model showing close coupling between GABA synthesis and GABA packaging into synaptic vesicles by vesicular GABA transporters is also applicable to the DA system. Hence, it is concluded that there is a general coupling mechanism between neurotransmitter synthesis and packaging of transmitter into synaptic vesicles.     

Neurotoxic effect of acamprosate, N-Acetyl-Homotaurine, in cultured neurons

Acamprosate (AC), N-acetyl-homotaurine, has recently been introduced for treating alcohol craving and reducing relapses in weaned alcoholics. AC may exert its action through the taurine system rather than the glutamatergic or GABAergic system. This conclusion is based on the observations that AC strongly inhibits the binding of taurine to taurine receptors while it has little effect on the binding of glutamate to glutamate receptors or muscimol to GABA(A) receptors. In addition, AC was found to be neurotoxic, at least in neuronal cultures, triggering neuronal damage at 1 mM. The underlying mechanism of AC-induced neuronal injury appears to be due to its action in increasing the intracellular calcium level, [Ca2+](i). Both AC-induced neurotoxicity and elevation of [Ca2+](i) can be prevented by taurine suggesting that AC may exert its effect through its antagonistic interaction with taurine receptors.     

The Role of Taurine in the Central Nervous System and the Modulation of Intracellular Calcium Homeostasis

The effects of taurine in the mammalian nervous system are numerous and varied. There has been great difficulty in determining the specific targets of taurine action. The authors present a review of accepted taurine action and highlight recent discoveries regarding taurine and calcium homeostasis in neurons. In general there is a consensus that taurine is a powerful agent in regulating and reducing the intracellular calcium levels in neurons. After prolonged L-glutamate stimulation, neurons lose the ability to effectively regulate intracellular calcium. This condition can lead to acute swelling and lysis of the cell, or culminate in apoptosis. Under these conditions, significant amounts of taurine (mM range) are released from the excited neuron. This extracellular taurine acts to slow the influx of calcium into the cytosol through both transmembrane ion transporters and intracellular storage pools. Two specific targets of taurine action are discussed: Na⁺-Ca²⁺ exchangers, and metabotropic receptors mediating phospholipase-C.