Hyperpolarization-activated calcium channels at the tip of Arabidopsis root hairs

AUTOR(ES)
FONTE

The National Academy of Sciences

RESUMO

The root hair elongative growth phase (“tip growth”), like that of other tip-growing systems such as pollen tubes, algal rhizoids, and fungal hyphae, is associated with an apex-high cytosolic free calcium ([Ca2+]c) gradient generated by a local Ca2+ influx at the tip. This gradient has been shown to be a fundamental regulator of tip growth. Here, we have performed patch-clamp experiments at root hair apices of Arabidopsis thaliana (after localized cell wall laser ablation) to characterize the plasma membrane Ca2+ channels implicated in the tip Ca2+ influx. We have identified a hyperpolarization-activated Ca2+ conductance. This conductance is selective for Ca2+ over K+ and Cl− (PCa/PK = 15; PCa/PCl = 25) and is fully blocked by <100-μM trivalent cations (La3+, Al3+, Gd3+). The selectivity sequence among divalent cations (determined by comparisons of the channel unitary conductance) is Ba2+ > Ca2+ (22 pS in 10 mM) ≈ Mg2+ > Mn2+. This conductance was operative at typical growing hair apical resting membrane potentials. Moreover, it was seen to be down-regulated in growing hair subapical regions, as well as at the tip of mature hairs (known not to exhibit Ca2+ influx). We therefore propose that this inward-rectifying Ca2+ conductance is inherently involved in the apical Ca2+ influx of growing hairs. The observed enhancement of the conductance by increased [Ca2+]c may form part of a positive feedback system for continued apical Ca2+ influx during tip growth.

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