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Movement of Pulses of Labeled Auxin in Corn Coleoptiles ¹

Department of Biology, Yale University, New Haven, Connecticut 06520

The transit of indole-3-acetic acid through 20-mm sections of corn coleoptiles can be separated from processes involved in the uptake of auxin by the section and the exit of auxin from the section. Aerobic sections are supplied with an exogenous source of ¹⁴C IAA for a limited time, and after the source is removed, a pulse of ¹⁴C IAA moves down at 12 to 15 mm/hour. After transfer to nitrogen, movement of the pulse at the aerobic rate persists for about 10 minutes; thereafter drops to only 1 to 2 mm/hour and remains at this level during the next 4 hours. Within 2 hours, 70% of the total ¹⁴C in aerobic sections has moved 10 mm or more down the section from the position of the initial peak, whereas after the same time in nitrogen less than 10% of the total ¹⁴C has moved as far.

During the migration down the coleoptile, the peak of radioactivity becomes broader and less distinct. This dispersion is more rapid in aerobic than anaerobic sections, but appears to be nonpolar and to occur along the existing concentration gradients. Diffusion probably contributes to this dispersion.

In both inhibited and uninhibited sections, the movement of the peak, in contrast to its dispersion, is A) polar (downward) and B) independent of existing concentration gradients. Thus transit within the section possesses the fundamental properties of the overall transport system. The reduced amount of transport in inhibited sections is more likely maintained by glycolysis than by a low level of aerobic respiration dependent on the residual oxygen in the tissue.

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				J. R. Shinkle, R. Kadakia, and A. M. Jones Dim-Red-Light-Induced Increase in Polar Auxin Transport in Cucumber Seedlings . I. Development of Altered Capacity, Velocity, and Response to Inhibitors Plant Physiology, April 1, 1998; 116(4): 1505 - 1513. [Abstract] [Full Text]