An autoradiographic study of binding of iodinated spider toxin to lobster muscle

Small molecules from spiders used as chemical probes

Spiders are important species in ecological systems and as major predators of insects they are endowed with a plethora of low-molecular-weight natural products having intriguing biological activities. The isolation and biological characterization of these entities are well established, however, only very recently have these compounds been used as templates for the design, synthesis, and biological evaluation of synthetic analogues. In contrast, the investigation of compounds responsible for chemical communication between spiders is far less developed, but recently new light has been shed onto the area of pheromones and allomones from spiders. Herein, we recapitulate these recent results, put them into perspective with previous findings, and provide an outlook for future studies of these chemotypes.

Purification of AMPA type glutamate receptor by a spider toxin

A glutamate receptor was purified from Triton X-100-solubilized bovine cerebellum membranes. The purification was carried out in two steps: affinity chromatography using a spider toxin (Joro spider toxin; JSTX) immobilized on a lysine-agarose column, and a Mono Q anion exchange column. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of the purified active fraction showed a single band with Coomassie Blue staining, which migrated with a M(r) = 130,000. The specific [3H]amino-3-hydroxy-5-methyl-isoxazole propionate ([3H]AMPA) binding activity of the affinity-purified fraction was 2095-fold higher than that of the crude soluble fraction. Lineweaver-Burk plot analysis showed a Kd of 12.7 nM [3H]AMPA in the purified fraction. The purified fraction was examined with patch-clamp recording methods in reconstituted liposomes. A glutamate-activated channel was observed and was inhibited with JSTX. The rank order of potency of agonists inducing channel currents was AMPA = glutamate greater than quisqualate much greater than kainate greater than NMDA. Thus, there is strong evidence that the 130 kDa protein is a purified component of the native AMPA type glutamate channel of bovine cerebellum.

Spider toxin and pertussis toxin differentiate post- and presynaptic glutamate receptors

A specific blocker of the postsynaptic glutamate receptors was found in the venom of the spider Nephila clavata. The toxin (JSTX) preferentially blocks quisqualate-type glutamate receptors in the crustacean neuromuscular synapse, squid giant synapse and hippocampal neurons in slice preparations. Following determination of the structure of JSTXs, a main component JSTX-3 with its analogs was chemically synthesized and used for the study of structure-activity relationships. 125I-labeled JSTX-3 and biotinylated JSTX-3 were synthesized for histochemical and biochemical studies of the glutamate receptors. The labeled JSTXs enabled visualization of the glutamate receptors in lobster muscle, rat cerebellum and hippocampus. By use of JSTX and pertussis toxin, a novel type of glutamate receptor (GluB receptor) was found in the crustacean neuromuscular synapse. While the postsynaptic glutamate receptor was blocked by JSTX, GluB receptor was insensitive to JSTX, but it was blocked by pertussis toxin, indicating involvement of inhibitory GTP-binding protein. Injection of GTP gamma S in the presynaptic axon mimicked the presynaptic glutamate potentials and caused presynaptic inhibitory action. Thus two types of biological toxins clearly separate the pre- and postsynaptic glutamate receptors.

Structure-activity relationship of philanthotoxins--I. Pre- and postsynaptic inhibition of the locust neuromuscular transmission

1. Like the natural toxin, synthetic delta-philanthotoxin, now called PTX-4.3.3 acts as a reversible postsynaptic open ion-channel blocker of the glutamatergic neuromuscular system of the locust. 2. It also inhibits the high-affinity re-uptake of glutamate in the nerve endings and glial cells. 3. To study the structure-activity relationship, three parts of the PTX-4.3.3 molecule were changed. 4. One of these PTX-analogues, trifluoromethyl-PTX-4.3.3, proved to be a more potent postsynaptic blocker. 5. Moreover, compared with PTX-4.3.3 a delayed recovery period is seen with trifluoromethyl-PTX-4.3.3. 6. A number of PTX-analogues were equipotent to PTX-4.3.3 regarding the inhibition of iontophoretically evoked, postsynaptic glutamate potentials. 7. However, complete inactivation was achieved by reducing the length of the polyamine chain, moreover dideaza-PTX-12 was nearly completely inactive and a reduced activity was seen with dephenol-PTX-4.3.3. 8. A decrease of the decay time constant of glutamate potentials, normally seen by open ion-channel blockers in Con A pretreated preparations, was unaffected during application of the latter two analogues. 9. Possibly these two toxins act as weak receptor antagonists. 10. The presynaptic inhibition of the glutamate re-uptake, seemed to be a very specific property of PTX-4.3.3. Only one of the tested analogues (dehydroxy-PTX-4.3.3) exhibited this capacity.

A histochemical study of glutamate receptor in rat brain using biotinyl spider toxin

Joro spider toxin (JSTX), a specific blocker of glutamate receptors, was conjugated with biotin. Using the avidin-biotin complex method, specific binding sites of biotinylated JSTX were demonstrated in the cerebellum and hippocampus of the rat. In the cerebellum, strong binding of biotinyl JSTX was observed on perikarya and dendrites of the Purkinje cells with much less binding in the granular cell layer. In the hippocampus, a dense staining was observed in the pyramidal cell layer, with more heavy binding in CA3 than in other sectors of Ammon's horn. The area of distribution of biotinyl JSTX binding sites corresponded well with that of receptors preferentially activated by quisqualate.

Characterization of binding sites for spider toxin, [3H]NSTX-3, in the rat brain

A group of spider toxins (JSTX, NSTX, argiopin, argiotoxin etc.) share a basic common structure and have been reported to block strongly quisqualate- and kainate-sensitive glutamate responses in vertebrate and invertebrate nervous systems. They are presumed to be potent antagonists of both quisqualate and kainate receptors and may serve as useful tools for characterizing these receptors. We report here the synthesis of tritium-labeled NSTX-3 and the characterization of its binding sites in the rat brain. We found that high- and low-affinity binding sites exist in the cerebellum (Kd = 7.75 and 202 nM, Bmax = 0.37 and 5.54 pmol/mg protein, respectively). Synthetic NSTX analogs strongly inhibited [3H]NSTX-3 binding in the cerebellum (IC50 = 10(-7)-10(-6) M), whereas competitive agonists of glutamate receptors (AMPA, quisqualate, NMDA, kainate, glutamate and aspartate) exhibited weak or no inhibitory effects.

Zinc ion enhances the blocking potency of synthetic analogs of spider toxin (JSTX) on the glutamate receptor

The effect of synthetic spider toxin analogs containing aza-crown in combination with zinc and copper was studied on the lobster neuromuscular synapse. The suppressive action of N4-type spider toxin analog (N4) on excitatory postsynaptic potentials (EPSPs) was markedly enhanced in the presence of 10(-5)-10(-4) M Zn2+. Cu2+ (10(-4) M) also had a potentiating effect on the suppression of EPSPs by N4 but to a lesser degree than Zn2+. While N6-type spider toxin analog (N6) suppressed EPSPs more effectively than N4, additional suppression was not pronounced in the presence of Zn2+ or Cu2+. The results suggest that chelatable divalent metal ions play an important role in the blocking mechanism of glutamate receptor by the spider toxin.

Effects of a spider toxin (JSTX) on hippocampal CA1 neurons in vitro

The effect of a toxin (JSTX) obtained from Nephila clavata (Joro spider) on the CA1 pyramidal neurons of the hippocampus was studied using slice preparations. JSTX blocked the excitatory postsynaptic potentials (EPSPs) in the pyramidal neuron evoked by Schaffer collateral stimulation but was without effect on the antidromic action potentials or on the resting conductance. Depolarization induced by ionophoretic application of glutamate was readily suppressed by JSTX but aspartate-induced depolarization was much less sensitive to the toxin. Among preferential agonists activating 3 receptor subtypes for excitatory amino acids, quisqualate responses were most effectively suppressed by JSTX. Kainate responses were similarly suppressed but in some cells higher concentration of the toxin was needed to block the responses. N-methyl-D-aspartate (NMDA) responses were the least sensitive to JSTX but they were suppressed by +/- 2-amino-5-phosphonovaleric acid (APV). Long term potentiation (LTP) once it had taken place was not completely inhibited by APV. In the presence of JSTX, however, LTP was blocked and tetanic stimuli produced only a short-lived potentiation. In Mg2+ free solution, an orthodromic stimulation evoked repetitive spike responses which were superimposed on the depolarization following the initial spike. APV suppressed the depolarization and associated spikes leaving an orthodromic response which was sensitive to JSTX. The results suggest that JSTX blocks EPSPs in CA1 pyramidal neurons which are mediated by non-NMDA type receptors.