First published online June 28, 2002; 10.1104/pp.001198
Plant Physiol, July 2002, Vol. 129, pp. 1382-1390
Ethylene Emission and Responsiveness to Applied Ethylene Vary
among Poa Species That Inherently Differ in Leaf
Elongation Rates1
Fabio
Fiorani,2
Gerard M.
Bögemann,
Eric J.W.
Visser,
Hans
Lambers, and
Laurentius A.C.J.
Voesenek*
Plant Ecophysiology, Utrecht University, Sorbonnelaan 16, 3584 CA
Utrecht, The Netherlands (F.F., H.L., L.A.C.J.V.); Department of
Experimental Plant Ecology, University of Nijmegen, Toernooiveld 1, 6525 ED, Nijmegen, The Netherlands (G.M.B., E.J.W.V.); and Plant
Sciences, Faculty of Agriculture, The University of Western Australia,
Nedlands, WA 6907, Australia (H.L.)
A plant's ability to produce and respond to ethylene is
essential for its vegetative growth. We studied whole-shoot ethylene emission and leaf growth responses to applied ethylene in four Poa spp. that differ inherently in leaf elongation rate
and whole-plant relative growth rate. Compared with the fast-growing
Poa annua and Poa trivialis, the shoots
of the slow-growing species Poa alpina and Poa
compressa emitted daily 30% to 50% less ethylene, and their
leaf elongation rate was more strongly inhibited when ethylene
concentration was increased up to 1 µL L 1. To our
surprise, however, low ethylene concentrations (0.02-0.03 µL
L1) promoted leaf growth in the two slow-growing species;
at the same concentrations, leaf elongation rate of the two
fast-growing species was only slightly inhibited. All responses were
observed within 20 min after ethylene applications. Although ethylene
generally inhibits growth, our results show that in some species, it
may actually stimulate growth. Moreover, in the two slow-growing
Poa spp., both growth stimulation and inhibition
occurred in a narrow ethylene concentration range, and this effect was
associated with a much lower ethylene emission. These findings suggest
that the regulation of ethylene production rates and perception of the gas may be more crucial during leaf expansion of these species under
non-stressful conditions and that endogenous ethylene concentrations are not large enough to saturate leaf growth responses. In the two
fast-growing species, a comparatively higher ethylene endogenous concentration may conversely be present and sufficiently high to
saturate leaf elongation responses, invariably leading to growth inhibition.
1
This work was funded by a PhD scholarship from
Utrecht University (The Netherlands) to F.F.
2
Present address: DCMB Group, Biology Department, Box
91000, Duke University, Durham, NC 27708-1000.
*
Corresponding author; e-mail L.A.C.J.Voesenek{at}bio.uu.nl; fax
31-30-2518366.
© 2002 American Society of Plant Physiologists
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