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Leaf Orientation of Soybean Seedlings. I. Effect of Water Potential and Photosynthetic Photon Flux Density on Paraheliotropism

Dep. of Biology, Univ. of Northern Iowa, Cedar Falls, IA 50614
Dep. of Plant Pathology, Iowa State Univ., Ames, IA 50011

^* Corresponding author.

Paraheliotropic (light avoiding) leaf movements can reduce transpirational water loss by lowering light interception by the leaf through action of the pulvinus. We investigated effects of plant water potential (_w) and photosynthetic photon flux density (PPFD) on paraheliotropism in young seedlings of soybean [Glycine max (L.) Merr. cv. Northrup King S1346], The effect of paraheliotropism on leaf temperature, _w, and stomatal conductance (g_e) was determined. The angles of unifoliolate and lower trifoliolate leaves were measured for plants at a range of _w values under different sources of illumination (sun, metal halide lamp, and fluorescent light bank) at PPFD ranging from 500 to 1600 µmol m^-2 s^-1. Leaf temperatures and g_c were measured for selected plants, including those with'leaves restrained in a horizontal position. The angle between unifoliolate leaves, measured at the base of the leaves, was highly correlated with _w. Both unifoliolate leaves and the terminal leaflets of trifoliolate leaves exhibited less paraheliotropism at a given _w when PPFD was reduced. Paraheliotropism was associated with improved plant water status and lower leaf temperatures, but g_c did not differ between paraheliotropic leaves and those restrained in a horizontal position. Paraheliotropic leaf movement and stomatal closure acted in parallel, commencing at approximately –0.4 MPa. Paraheliotropic leaf movements in soybean seedlings provide a mechanism that, with stomatal closure, can reduce transpiration under conditions of low _w and high PPFD.

Received for publication June 16, 1989.