Long-distance signaling within Coleus x hybridus leaves; mediated by changes in intra-leaf CO2?

Rapid long-distance signaling in plants can occur via several mechanisms, including symplastic electric coupling and pressure waves. We show here in variegated Coleus leaves a rapid propagation of electrical signals that appears to be caused by changes in intra-leaf CO2 concentrations. Green leaf ce...

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Bibliographic Details
Published in:Planta 2001-07, Vol.213 (3), p.342-351
Main Authors: Stahlberg, R., Van Volkenburgh, E., Cleland, R. E.
Format: Article
Language:English
Subjects:
Biological and medical sciences
Carbon Dioxide - metabolism
Cell physiology
Cell Wall - metabolism
Chlorophyll - metabolism
Chlorophyll - radiation effects
Darkness
Fundamental and applied biological sciences. Psychology
Hydrogen-Ion Concentration - radiation effects
Lamiaceae - metabolism
Lamiaceae - radiation effects
Life Sciences (General)
Light
Light-Harvesting Protein Complexes
Membrane Potentials - physiology
Membrane Potentials - radiation effects
Molecular and cellular biology
Photosynthesis - radiation effects
Photosynthetic Reaction Center Complex Proteins - radiation effects
Plant Leaves - metabolism
Plant Leaves - radiation effects
Plant physiology and development
Plasma membrane and permeation
Proton-Translocating ATPases - physiology
Proton-Translocating ATPases - radiation effects
Signal Transduction
Space life sciences
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Summary:Rapid long-distance signaling in plants can occur via several mechanisms, including symplastic electric coupling and pressure waves. We show here in variegated Coleus leaves a rapid propagation of electrical signals that appears to be caused by changes in intra-leaf CO2 concentrations. Green leaf cells, when illuminated, undergo a rapid depolarization of their membrane potential (Vm) and an increase in their apoplastic pH (pHa) by a process that requires photosynthesis. This is followed by a slower hyperpolarization of Vm and apoplastic acidification, which do not require photosynthesis. White (chlorophyll-lacking) leaf cells, when in isolated white leaf segments, show only the slow response, but when in mixed (i.e. green and white) segments, the rapid Vm depolarization and increase in pHa propagate over more than 10 mm from the green to the white cells. Similarly, these responses propagate 12-20 mm from illuminated to unilluminated green cells. The fact that the propagation of these responses is eliminated when the leaf air spaces are infiltrated with solution indicates that the signal moves in the apoplast rather than the symplast. A depolarization of the mesophyll cells is induced in the dark by a decrease in apoplastic CO2 but not by an increase in pHa. These results support the hypothesis that the propagating signal for the depolarization of the white mesophyll cells is a photosynthetically induced decrease in the CO2 level of the air spaces throughout the leaf.
ISSN:0032-0935
1432-2048
DOI:10.1007/s004250000514