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Development and Growth Regulation

Regulation of Electrogenic Proton Pumping by Auxin and Fusicoccin as Related to the Growth of Avena Coleoptiles ¹

Department of Biology, Kline Biology Tower, Yale University, P.O. Box 6666, New Haven, Connecticut 06511

The temporal relations between early responses to indoleacetic acid (IAA), proton secretion, hyperpolarization of the membrane potential, and growth change during the incubation of segments of oat (Avena sativa L.) coleoptiles in a low salt medium. When IAA is added after pretreatment of several hours, proton secretion increases after a latency of 7 minutes and reaches its maximum 10 to 15 minutes later. This timing coincides with both the increase in growth of the segments and the hyperpolarization of the membrane potential of parenchyma cells, consistent with the hypothesis that the change in membrane voltage reflects the activity of an electrogenic proton pump. The extent of IAA-induced hyperpolarization is substantially reduced by elevating [KCl]₀, most likely because this increases the passive conductance of the membrane. Neither growth nor proton secretion is affected by high [KCl]₀ (30 millimolar), indicating that neither process is limited by the magnitude of the membrane potential. These results are consistent with the acid growth hypothesis. Following short incubation times, however, IAA-induced hyperpolarization and growth are detected within 10 minutes, while acidification of the medium is delayed for more than 40 minutes. This result is seemingly in conflict with the acid growth hypothesis, but in freshly cut tissue, the pH of the external medium may not reflect the pH of the epidermal cell walls. The temporal coincidence of auxin-induced growth and hyperpolarization suggests that in freshly isolated segments the hyperpolarization is a more sensitive indication of proton secretion than is acidification of the external aqueous environment.

¹ Supported by National Science Foundation grant DMB-8419759. The senior author was supported by a John Simon Guggenheim Fellowship while writing this paper.

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