Both cell skirt loosening and the uptake of various solutes appears to depend on the acidification of the surround immediately surrounding the cells via the activity of enzyme driven pumps located on the plasma tissue layer, specifically H+ - ATPase. H+ - ATPase influences acidification and solute uptake via cation:H+ exchange and via anion:H+ cotransport mechanisms. The enzyme's activity is inhibited by the pharmacologic agents vanadate and diethylstilbestrol, it is stimulated by metallic cations and forms a covalent phosphoenzyme negotiate during the transport cycle (Brayman and Miller "60-Hz electric car" 24). The key call into question in understanding the impact of electric fields on plant growth is the relationship between plasma membrane potential (Vm) and the activity of H+ - ATPase.
The majority of experimental studies on the impact of electric fields on growth throw used plant roots as model systems. root represent tissues which grow rapidly and well in simple, inorganic, chemically defined, aqueous media. The small radial diameter of roots allows electric field make to be isolated from their associated heating effects by regulating the temperature of the growth medium (Miller et al. 109).
When roots be placed in an extremely low frequency electric field, root growth is inhibited in a panelling dependent manor (Robertson and Miller 329-340). The cells inside the roots atomic number 18 exposed to fields similar to those o
In a parallel study (Brayman and Miller "60-Hz electric automobile" 22-31), acidification and H+ -ATPase activity in Zea mays root results fuck off also been investigated. At field intensivenesss of greater than 225 V.m-1, acidification due to H+ efflux decreases proportionally with increasing field strength. The field strength sceptre for this inhibition is about 220 V.m-1 which is nominally greater than that of the threshold for growth inhibition in Zea (170 V.m-1). As in the previous study, inhibition of acidification correlates positively with increasing cell size and distance from the root tip, and further indicates that the cellular orientation to the electrical field is an additional factor to be considerated (Brayman and Miller "60-Hz Electric" 29).
Within the elongation zone of a root, cell dimensions join on with increasing distance from the root tip, thus at a given field exposure, cells with opposite dimensions will exhibit different Vim such that growth rate inhibition place will increase with increasing distance from the root tip (Brayman, Brulfert, and Miller 151-157).
Johnson, Gregory J., Dennis T. Poznaniak, and Guy W. McKee. "Prediction of Damage Severity on Plants due to 60-Hz High Intensity Electric landing fields." Biological personal effects of Extremely Low Frequency Electromagnetic expanses. Oak Ridge, TN: practiced Information Center,: 1979.
Brayman, Andrew A., and Morton W. Miller. "60-Hz Electric Field Exposure Inhibits Net obvious H+ -Ion Excretion from Excised germs of Zea mays L." Radiation question 123 (1990): 22-31.
Brayman, Andrew A., A. Brulfert, and Morton W. Miller. "Induction of ELF Transmembrane Potentials in Relation to Power-Frequency Electric Field Bioeffects in a Plant Root Model System. II. The movement of 60-Hz Electric Fields on the Growth of Different Regions of the Cucurbit Root Elongation Zone." Radiation and Environmental Biophysics 25 (1983): 151-157.
Robertson, Dominique, and Morton W. Miller. "60-Hz Electric Field Induced Inhi
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