Furutani S et al. (2014), GluCl a target of indole alkaloid okaramines: a...

XB-ART-49399

Sci Rep 2014 Aug 26;4:6190. doi: 10.1038/srep06190.

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GluCl a target of indole alkaloid okaramines: a 25 year enigma solved.

Furutani S , Nakatani Y , Miura Y , Ihara M , Kai K , Hayashi H , Matsuda K .

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In 1989, indole alkaloid okaramines isolated from the fermentation products of Penicillium simplicissimum were shown to be insecticidal, yet the mechanism of their toxicity to insects remains unknown. We therefore examined the action of okaramine B on silkworm larval neurons using patch-clamp electrophysiology. Okaramine B induced inward currents which reversed close to the chloride equilibrium potential and were blocked by fipronil. Thus it was tested on the silkworm RDL (resistant-to-dieldrin) γ-aminobutyric-acid-gated chloride channel (GABACl) and a silkworm L-glutamate-gated chloride channel (GluCl) expressed in Xenopus laevis oocytes. Okaramine B activated GluCl, but not RDL. GluCl activation by okaramines correlated with their insecticidal activity, offering a solution to a long-standing enigma concerning their insecticidal actions. Also, unlike ivermectin, okaramine B was inactive at 10 μM on human α1β2γ2 GABACl and α1β glycine-gated chloride channels and provides a new lead for the development of safe insect control chemicals.

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Species referenced: Xenopus laevis
Genes referenced: pdlim7

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	Figure 1. Structures of okaramines A, B, 4â²,5â²-dihydrookaramine B (okaramine B-H2), I and Q.
	Figure 2. Action of okaramine B on the membrane currents of silkworm larval neurons as measured with whole-cell patch-clamp electrophysiology (aâd) and on silkworm larval RDL Î³-aminobutyric-acid-gated chloride channel (GABACl) (e, f) and L-glutamate-gated chloride channel (GluCl) (g) expressed in Xenopus laevis oocytes as measured with two-electrode voltage-clamp electrophysiology.Okaramine B was applied via U-tube, whereas antagonists were bath-applied to the neurons. (a) Inward current induced by okaramine B at 1âÎ¼M and the effect of nicotinic receptor antagonist mecamylamine (1âÎ¼M) applied for 1âmin prior to co-application with 1âÎ¼M okaramine B. (b) Inward current induced by okaramine B at 1âÎ¼M and the effect of ligand-gated chloride channel blocker fipronil (10âÎ¼M) applied for 1âmin prior to co-application with 1âÎ¼M okaramine B. (c) Inward current induced by 1âÎ¼M okaramine B at various holding potentials. (d) Current-voltage relationship at two different extracellular chloride concentrations. Each plot indicates the mean Â± standard error of repeated experiments (n = 3). (e) Five min after recording the response to 30âÎ¼M GABA of RDL, 10âÎ¼M okaramine was bath-applied. (f) Okaramine B was bath-applied at 10âÎ¼M for 1âmin prior to co-application with 30âÎ¼M GABA. Okaramine B had a minimal impact on the GABA response RDL. (g) Five min after recording the response to 100âÎ¼M L-glutamate of GluCl, 1 and 3âÎ¼M okaramine B was bath-applied with at 5-min interval.
	Figure 3. Concentration-response relationships of okaramines A, B, 4â²,5â²-dihydrookaramine B (okaramine B-H2), I and Q for the Clâ current inducing activity on the silkworm neurons and the GluCl activating activity, and correlations of these two activities with the insecticidal activity on the silkworm larvae.(a) Concentration-response relationship for the chloride-current inducing activity on the silkworm larval neuron. (b) Concentration-response relationship for the GluCl activating activity. Each plot indicates the mean Â± standard error of the mean of repeated experiments (n = 4). (c) 3D plot for the relationship of the GluCl activating activity (X axis), and the Clâ current inducing activity on the larval neuron (Y axis) with the insecticidal activity (n = 3) (Z axis). Each sphere plot in (c) is projected to X-Y, X-Z and Y-Z planes to show its position in each plane.
	Figure 4. Actions of okaramine B on human Î±1Î²2Î³2 GABACl and Î±1Î² glycine-gated chloride channel (GlyCl) expressed in Xenopus laevis oocytes.(a) Three minutes after recording a response to 30âÎ¼M GABA, 10âÎ¼M okaramine B was bath-applied to oocytes expressing the human Î±1Î²2Î³2 GABACl. After 3âmin wash, 10âÎ¼M ivermectin was bath-applied. (b) Okaramine B (10âÎ¼M) was pre-applied for 1âmin prior to co-application with 30âÎ¼M GABA to the Î±1Î²2Î³2 GABACl. (c) Three minutes after recording a response to 100âÎ¼M glycine, 10âÎ¼M okaramine B was bath-applied to oocytes expressing the human Î±1Î² GlyCl. After 3âmin wash, 10âÎ¼M ivermectin was bath-applied. (d) Okaramine B (10âÎ¼M) was pre-applied for 1âmin prior to co-application with 100âÎ¼M glycine to oocytes expressing the Î±1Î² GlyCl. All the results were reproducible (n = 4).

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