Wh. Zhang et al., Malate-permeable channels and cation channels activated by aluminum in theapical cells of wheat roots, PLANT PHYSL, 125(3), 2001, pp. 1459-1472
Aluminum (Al3+)-dependent efflux of malate from root apices is a mechanism
for Al3+ tolerance in wheat (Triticum aestivum). The malate anions protect
the sensitive root tips by chelating the toxic Al3+ cations in the rhizosph
ere to form non-toxic complexes. Activation of malate-permeable channels in
the plasma membrane could be critical in regulating this malate efflux, We
examined this by investigating Al3+-activated channels in protoplasts from
root apices of near-isogenic wheat differing in Al3+ tolerance at a single
locus. Using whole-cell patch clamp we found that Al3+ stimulated an elect
rical current carried by anion efflux across the plasma membrane in the Al3
+-tolerant (ET8) and Al3+-sensitive (ES8) genotypes. This current occurred
more frequently, had a greater current density, and remained active for lon
ger in ET8 protoplasts than for ES8 protoplasts. The Al3+-activated current
exhibited higher permeability to malate(2-) than to Cl- (P-mal/P-C1 greate
r than or equal to 2.6) and was inhibited by anion channel antagonists, nif
lumate and diphenylamine-2-carboxylic acid. In ET8, but not ESS, protoplast
s an outward-rectifying K+ current was activated in the presence of Al3+ wh
en cAMP was included in the pipette solution. These findings provide eviden
ce that the difference in Al3+-induced malate efflux between Al3+-tolerant
and Al3+-sensitive genotypes lies in the differing capacity for Al3+ to act
ivate malate permeable channels and cation channels for sustained malate re
lease.