Bovine Synaptic Membranes Research Articles

Possible existence of a novel receptor for uridine analogues in the central nervous system using two isomers, N3-(S)-(+)- and N3-(R)-(-)-alpha-hydroxy-beta-phenethyluridines.

Uridine analogue binding sites, the so-called uridine receptor, were observed in the experiments on specific [3H]N3-phenacyluridine binding to bovine synaptic membranes using two isomers, N3-(S)-(+)- and N3-(R)-(-)-alpha-hydroxy-beta-phenethyluridine, as ligands. The potent hypnotic, N3-(S)-(+)-alpha-hydroxy-beta-phenethyluridine, but not the (R)-isomer, strongly inhibited [3H]N3-phenacyluridine binding. The racemate had inhibitory activity intermediate between that of the two alpha-hydroxy-beta-phenethyluridines ((R)- or (S)-isomers). The inhibitory constants of these compounds were determined. The Ki values of N3-phenacyluridine, alpha-hydroxy-beta-phenethyluridine (racemate), N3-(R)-(-)-, and N3-(S)-(+)-alpha-hydroxy-beta-phenethyluridine were 0.65, 397.4, 1908, and 10.2 nM, respectively. The present results indicate the existence of uridine receptors in the central nervous system in relation to their hypnotic activities reported previously.

Characterization of two fungal-elicitor-induced rice cDNAs encoding functional homologues of the rab-specific GDP-dissociation inhibitor.

By using the mRNA differential display approach to isolate defense signaling genes active at the early stage of fungal infection two cDNA fragments with high sequence homology to rab-specific GDP-dissociation inhibitors (GDIs) were identified in rice (Oryza sativa L.) suspension cells. Using polymerase-chain-reaction products as probes, two full-length cDNA clones were isolated from a cDNA library of fungal-elicitor-treated rice, and designated as OsGDI1 and OsGDI2. The deduced amino acid sequences of the isolated cDNAs exhibited substantial homology to Arabidopsis rab-GDIs. Northern analysis revealed that transcripts detected with the 3'-gene-specific DNA probes accumulated to high levels within 30 min after treatment with a fungal elicitor derived from Magnaporthe grisea. The functionality of the OsGDIs was demonstrated by their ability to rescue the Sec19 mutant of Saccharomyces cerevisiae which is defective in vesicle transport. The proteins, expressed in Escherchia coli, cross-reacted with a polyclonal antibody prepared against bovine rab-GDI. Like bovine rab-GDI, the OsGDI proteins efficiently dissociated rab3A from bovine synaptic membranes. Using the two-hybrid system, it was shown that the OsGDIs specifically interact with the small GTP-binding proteins belonging to the rab subfamily. The specific interaction was also demonstrated in vitro by glutathione S-transferase resin pull-down assay.

Anandamide, an endogenous cannabinoid receptor ligand, also interacts with 5-hydroxytryptamine (5-HT) receptor.

Interactions of anandamide (N-arachidonylethanolamide), an endogenous compound for cannabinoid receptors, with the receptors for 5-hydroxytryptamine (5-HT), benzodiazepine, and gamma-aminobutyric acid(A) (GABA[A]) receptors in bovine synaptic membrane were examined. Anandamide decreased the 5-HT receptor bindings at concentrations of 1-100 microM, although it did not cause any change in benzodiazepine or GABA(A) receptor bindings. A high concentration of anandamide, 100 microM, significantly decrease both [3H]5-HT and [3H]ketanserin bindings. The present study revealed that the pharmacological activity of anandamide might be partially mediated through the 5-HT receptor.

Ammodytoxin A acceptor in bovine brain synaptic membranes

Ammodytoxin A, the presynaptic neurotoxin from Vipera ammodytes ammodytes venom, was found to bind specifically and with high affinity to bovine cortex synaptic membrane preparation. The detected ammodytoxin A high-affinity binding was characterized by equilibrium binding analysis which revealed a single high-affinity binding site with K d 4.13 nM and B max 6.67 pmoles/mg of membrane protein. 125I-ammodytoxin A was covalently cross-linked to its neuronal acceptor using a chemical cross-linking technique. As revealed by subsequent SDS-PAGE analysis and autoradiography, 125I-ammodytoxin A specifically attached to membrane components with apparent mol. wts 53,000–56,000. Besides by the native ammodytoxin A, the binding of radioiodinated ammodytoxin A to the neuronal acceptor was highly attenuated, also by other two iso-neurotoxins from V. a. ammodytes venom, ammodytoxins B and C, and neurotoxin crotoxin B from the venom of the South American rattlesnake ( Crotalus durissus terrificus). Vipera berus berus phospholipase A 2 was a weaker inhibitor, whereas nontoxic phospholipase A 2, ammodytoxin I 2 and myotoxic phospholipase A 2 homologue, ammodytin L, both from V. a. ammodytes venom as well, were very weak inhibitors. No inhibitory effect on 125I-ammodytoxin A specific binding at all was, however, obtained with α-dendrotoxin, β-bungarotoxin and crotoxin A, respectively. Treatment of synaptic membranes with proteinase K and Staphylococcus aureus V-8 proteinase, a combination of PNGase F and neuroaminidase, heat or acid lowered the 125I-ammodytoxin A specific binding to various extents but never completely abolished it. The ammodytoxin A binding site in bovine synaptic membranes is thus most likely a combination of membrane glycoprotein acceptor and membrane phospholipids. As ammodytoxin A reduced the second negative component of the perineural waveform, measured on mouse triangularis sterni preparation, which is very likely a result of an inhibition of a fraction of the terminal K + currents, the ammodytoxin A acceptor could well be connected with K + channels.

Cloning and expression of mamba toxins

Mamba venoms contain pharmacologically active proteins that interfere with neuromuscular transmission by binding to and altering the normal functioning of neuronal proteins involved, directly or indirectly, with regulating nerve transmission. Of the mamba toxins studied to date, many act on voltage-sensitive K + channels, nicotinic or muscarinic acetylcholine receptors, or acetylcholinesterase. In an attempt to clone, characterize, and express the genes encoding these toxins, as well as other genes specifying activities not completely elucidated as yet, a cDNA library was constructed from mRNA isolated from the glands of the black mamba. Clones from the library harboring sequences encoding 14 different mamba toxins were isolated and characterized by nucleotide sequence analysis. Genes coding for three proteins, dendrotoxins (DTX) K, I, and E, were expressed as maltose-binding (MBP) fusion proteins in the periplasmic space of Escherichia coli. The DTX K-MBP fusion protein was affinity purified, cleaved from its chaperon, and the recombinant DTX K purified from MBP. Recombinant DTX K was shown to be identical to native DTX K in its N-terminal sequence, Chromatographic behavior, convulsion-inducing activity, and binding to voltage-activated K + channels in bovine synaptic membranes. Computer modeling was employed to create three-dimensional structures of DTX K and DTX I from the X-ray crystal structure of α-DTX utilizing both structural and sequence homologies. Comparisons were made between the three toxins, providing a framework for site-directed mutagenesis.

Identification of the neuronal acceptor in bovine cortex for ammodytoxin C, a presynaptically neurotoxic phospholipase A2.

A specific, high-affinity binding site for ammodytoxin C in synaptic membranes from bovine cerebral cortex was detected and partially characterized. Equilibrium binding analysis revealed a single population of [125I]ammodytoxin C acceptors with the following binding parameters: Kd = 6.0 nM and Bmax = 5.7 pmol/mg membrane protein. Such binding was strongly inhibited by three ammodytoxins (A, B, and C) and by crotoxin B. Vipera berus berus phospholipase A2 was a weaker inhibitor; nontoxic phospholipase A2, ammodytin I2, and the myotoxic phospholipase A2 homologue, ammodytin L, both from Vipera ammodytes ammodytes venom, inhibited binding only at very high concentrations, whereas alpha-dendrotoxin, beta-bungarotoxin, and crotoxin A had no influence on the [125I]ammodytoxin C-specific binding. The ammodytoxin C neuronal binding site therefore overlaps, at least partially, with the neuronal acceptors for some of the related presynaptically neurotoxic phospholipases A2 (beta-neurotoxins). [125I]-Ammodytoxin C was covalently attached to its acceptor by chemical cross-linking. Subsequent SDS-PAGE analysis followed by autoradiography revealed saturably labeled membrane components with apparent M(r) values of 51,000 (weaker band) and 53,000-56,000 (stronger band). Pretreatment of synaptic membranes with Staphylococcus aureus V-8 proteinase and proteinase K, heat, or low pH decreased the [125I]ammodytoxin C-specific binding to various extents, but never abolished it completely. Membrane protein and certain phospholipids residing in its vicinity are therefore most likely involved in the binding of ammodytoxin C to bovine synaptic membranes.

Cloning and functional expression of dendrotoxin K from black mamba, a K+ channel blocker.

Mamba dendrotoxins, 7K M(r) polypeptides with three disulfide bonds, selectively inhibit certain fast-activating, voltage-sensitive neuronal K+ channels and have been instrumental in their identification, localization, and purification. However, derivatives with more refined specificity are essential to define the structural and functional properties of the multiple subtypes known to reside in the nervous system. Hence, utilizing a constructed cDNA library from the venom glands of the black mamba (Dendroaspis polylepis), the gene encoding dendrotoxin K was isolated, amplified, and expressed as a maltose-binding fusion protein in the periplasmic space of Escherichia coli. After cleavage of the chaperone from the affinity-purified product, a recombinant protein was isolated and shown to be identical to native dendrotoxin K in its N-terminal sequence, chromatographic behavior, convulsive-inducing activity, and binding to voltage-activated K+ channels in bovine synaptic membranes. This successful expression of refolded active toxin, in adequate yield, makes possible for the first time the preparation of mutants with specificity tailored for each K+ channel subtype, based both on the recently derived three-dimensional structure of alpha-dendrotoxin and the identified binding site on cloned K+ channels.

Dendrotoxin acceptor from bovine synaptic plasma membranes. Binding properties, purification and subunit composition of a putative constituent of certain voltage-activated K+ channels.

Dendrotoxin is a snake polypeptide that blocks selectively and potently certain voltage-sensitive, fast-activating K+ channels in the nervous system, where it binds with high affinity to membranous acceptors. Herein, the acceptor protein for dendrotoxin in bovine synaptic membranes is solubilized in active form and its complete purification achieved by affinity chromatography, involving a novel elution procedure. This putative K+-channel constituent is shown to be a large oligomeric glycoprotein containing two major subunits, with Mr values of 75,000 and 37,000.

Pipecolic acid antagonizes barbiturate-enhanced GABA binding to bovine brain membranes

l-Pipecolic acid, a brain l-lysine metabolite, is found to inhibit GABA binding to bovine synaptic membranes strongly in the presence of hexobarbital (IC 50 = 2 × 10 −10M), but only slightly (<10%) by itself. Longer dialysis increases this binding inhibition. Hill plots indicate heterogeneity of l-pipecolic acid displaceable GABA binding sites. l-Pipecolic acid may be an endogenous ligand acting as a neuromodulator on the GABA receptor ionophore complex, or it may act on its own membrane binding sites exerting an allosteric effect on the GABA receptor complex. This discovery may be useful for further defining pharmacological and biochemical differences between the GABA receptors in the brain.