SummaryDepolarization-activated plasma membrane calcium channels have been suggested to play prominent roles in signal perception and transduction processes during growth and development of higher plants. The existence of such channels has recently been established in higher plant cells. However, patch-clamp experiments have shown that their activity is very low and decreases very rapidly after the establishment of the whole-cell configuration, due most probably to protein-protein interactions involving microtubules. The present study takes advantage of the existence of Arabidopsis thaliana mutants referred to as ton 2 mutants reported to be affected in their microtubule organization, to address the physiological relevance of such a hypothesis based on a pharmacological approach. Patch-clamp studies showed that depolarization-activated calcium channel activities in ton 2 protoplasts were 10-fold higher and their relative half-life threetimes longer than in wild-type protoplasts. In addition, oryzalin and colchicine, which disrupt the microtubule organization, stimulated and stabilized calcium channel activities in wild-type but remained ineffective on ton 2 protoplasts. However, although the microtubules appeared important in the regulation of calcium channels
Plasma membrane-bound voltage-dependent calcium channels may couple the perception of an initial stimulus to a regulated pathway for calcium influx. The activities of these channels have been shown to be very low and highly unstable but may be recruited by large-predepolarizing pulses, according to a process referred to as recruitment. By combining pharmacological and electrophysiological approaches, we demonstrate in the present paper that the cytoskeleton plays an important role in the regulation of the activity and stability of voltage-dependent calcium channels during whole-cell patch-clamp experiments on carrot protoplasts. Whereas drugs affecting the organization of the microfilament network have no measurable effect, the manipulation of the microtubule network elicits important changes. Thus, the addition of colchicine or oryzalin, which are known to disrupt microtubule organization, leads to a 6-10-fold increase in calcium channel activities and half-life. In contrast, stabilization of the microtubules by taxol has no effect on any of these parameters. The data obtained suggest that interactions of microtubules and voltage-dependent calcium channels by either direct or indirect mechanisms inhibit channel activities and decrease their half-life. In contrast, the disruption of the network overcomes such an inhibitory effect and allows the activation of calcium channels. It is speculated that under normal physiological conditions these protein-protein interactions may work in a reversible manner and contribute to signal transduction in higher plants.
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