Role of Gibberellins in the Environmental Control of Stem Growth in Thlaspi arvense L

Abstract

Field pennycress (T. arrense L.) is a winter annual that requires a cold treatment for the induction of stem elongation. An inbred line was selected in which no stem elongation was observed in plants grown for 6 mo. at 21.degree. C regardless of the prevailing photoperiod. Increased exposure time of plants grown initially at 21.degree. C to cold (2.degree. C) induced a greater rate of stem elongation when the plants were returned to 21.degree. C. Moreover, longer cold treatments resulted in a greater maximum stem height and reduced the lag period for the onset of measurable intermode elongation. The optimal temperature range for thermoinduced stem growth was broad: rates of stem growth in plants maintained for 4 wk at either 2.degree. or 10.degree. C were virtually identical. A 4-wk thermoinductive treatment at 15.degree. C resulted in a greater lag period for the initiation of stem elongation and a decreased growth rate. The rate of cold-induced stem elongation was greater in plants subjected to long days than for plants subjected to short days following the cold treatment. Photoperiod does not control the induction of stem elongation, but does regulate stem elongation in progress. Exongenous GA3 was able to substitute for the cold requirement, but elicited a greater response in plants maintained under long days than short days. Photoperiod influences the plant''s sensitivity to GAs. The GA biosynthesis inhibitor, 2-chloroethyltrimethyl amononium chloride, inhibited low temperature-induced stem elongation, and this inhibition was completely reversed by exogenous GA3. These results suggest that cold-induced stem elongation in field pennycress is mediated by some change in the endogenous GA status.