PLANT PHYSIOLOGY , Vol 114, Issue 4 1313-1325, Copyright © 1997 by American Society of Plant Biologists
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WHOLE PLANT, ENVIRONMENTAL, AND STRESS PHYSIOLOGY |
The Effect of Cu2+ on Ion Transport Systems of the Plant Cell Plasmalemma
V. Demidchik, A. Sokolik and V. Yurin
Department of Physiology and Biochemistry of Plants, Biological Faculty, Belarus State University, Skaryna Avenue 4, 220050, Minsk, Republic of Belarus
Changes in plasmalemma permeability caused by excessive Cu2+ levels were
examined in cells of a freshwater alga (Nitella flexilis) using a
conventional microelectrode voltage-clamp technique. A rapid Cu2+-induced
increase of plasmalemma conductance starting from 5 [mu]M Cu2+ was shown.
Cu2+-induced plasmalemma conductance (ClGm) was nonselective and
potential-independent, resembling the conductance of nonselective ionic
leakage of the plasmalemma. The K+ channel conductance was shown to be
unaltered by Cu2+, and a decrease in plasmalemma Cl- channel conductance at
Cu2+ concentrations above 5 [mu]M was found. The depression of Cl- channels
and ClGm were time-, dosage-, and Ca2+-dependent processes, revealing a
great similarity in all parameters, with Ca2+ causing the preventive effect
by shifting the effective Cu2+ concentrations to higher levels. This
phenomenon may be explained by the same Cu2+-modified target on the
plasmalemma both for ClGm and Cl- channel depression. In addition, a
reversible, inhibitory effect of Cu2+ (>10 [mu]M) on the
light-stimulated H+-ATPase electrogenic pump in the plasmalemma was
demonstrated. This effect was Ca2+- independent, which made it possible to
distinguish it from ClGm. Therefore, the Cu2+-induced dramatic alterations
in plant cell plasmalemma permeability are caused mainly by nonselective
conductance increases and electrogenic pump inhibition.
