Sarah Jane Cookson1, Christine Granier. 1. Laboratoire d'Ecophysiologie des Plantes Sous Stress Environnementaux, Institut de Biologie Intégrative des Plantes UMR 759, 2 Place Viala, 34060 Montpellier Cedex 2, France.
Abstract
BACKGROUND AND AIMS: It is well known that plant aerial development is affected by light intensity in terms of the date of flowering, the length of stems and petioles, and the final individual leaf area. The aim of the work presented here was to analyse how shade-induced changes in leaf development occur on a dynamic basis from the whole rosette level to that of the cells. METHODS: Care was taken to ensure that light intensity was the only source of micro-meteorological variation in the study. The dynamics of leaf production, rosette expansion, individual leaf area expansion and epidermal cell expansion were analysed in Arabidopsis thaliana plants grown under two light intensities in three independent experiments. KEY RESULTS: The total area of rosette leaves was reduced by the shading treatment. Both the number of leaves produced and their individual leaf areas were reduced. The reduction in leaf number was associated with a reduction in leaf initiation rate and the duration of the phase of leaf production. The reduction in individual leaf area was associated with a reduction in leaf expansion rate and an increase in the duration of leaf expansion. The changes in leaf expansion dynamics were accompanied by a decrease in epidermal cell number which was partly compensated for by an increase in epidermal cell area. Overall, the whole rosette leaf expansion rate was reduced by shading, whereas the total duration of rosette leaf expansion was unaffected. This was mainly due to the accumulation of the increases in the durations of expansion of each individual leaf which was associated with an increase in cell expansion. CONCLUSIONS: The dynamic analysis presented here reveals a new shade-adaptative response mediated via the control of area expansion at the cell, organ and whole plant levels.
BACKGROUND AND AIMS: It is well known that plant aerial development is affected by light intensity in terms of the date of flowering, the length of stems and petioles, and the final individual leaf area. The aim of the work presented here was to analyse how shade-induced changes in leaf development occur on a dynamic basis from the whole rosette level to that of the cells. METHODS: Care was taken to ensure that light intensity was the only source of micro-meteorological variation in the study. The dynamics of leaf production, rosette expansion, individual leaf area expansion and epidermal cell expansion were analysed in Arabidopsis thaliana plants grown under two light intensities in three independent experiments. KEY RESULTS: The total area of rosette leaves was reduced by the shading treatment. Both the number of leaves produced and their individual leaf areas were reduced. The reduction in leaf number was associated with a reduction in leaf initiation rate and the duration of the phase of leaf production. The reduction in individual leaf area was associated with a reduction in leaf expansion rate and an increase in the duration of leaf expansion. The changes in leaf expansion dynamics were accompanied by a decrease in epidermal cell number which was partly compensated for by an increase in epidermal cell area. Overall, the whole rosette leaf expansion rate was reduced by shading, whereas the total duration of rosette leaf expansion was unaffected. This was mainly due to the accumulation of the increases in the durations of expansion of each individual leaf which was associated with an increase in cell expansion. CONCLUSIONS: The dynamic analysis presented here reveals a new shade-adaptative response mediated via the control of area expansion at the cell, organ and whole plant levels.
Authors: Rahul Bhosale; Veronique Boudolf; Fabiola Cuevas; Ran Lu; Thomas Eekhout; Zhubing Hu; Gert Van Isterdael; Georgina M Lambert; Fan Xu; Moritz K Nowack; Richard S Smith; Ilse Vercauteren; Riet De Rycke; Veronique Storme; Tom Beeckman; John C Larkin; Anna Kremer; Herman Höfte; David W Galbraith; Robert P Kumpf; Steven Maere; Lieven De Veylder Journal: Plant Cell Date: 2018-08-16 Impact factor: 11.277
Authors: Catherine Massonnet; Denis Vile; Juliette Fabre; Matthew A Hannah; Camila Caldana; Jan Lisec; Gerrit T S Beemster; Rhonda C Meyer; Gaëlle Messerli; Jesper T Gronlund; Josip Perkovic; Emma Wigmore; Sean May; Michael W Bevan; Christian Meyer; Silvia Rubio-Díaz; Detlef Weigel; José Luis Micol; Vicky Buchanan-Wollaston; Fabio Fiorani; Sean Walsh; Bernd Rinn; Wilhelm Gruissem; Pierre Hilson; Lars Hennig; Lothar Willmitzer; Christine Granier Journal: Plant Physiol Date: 2010-03-03 Impact factor: 8.340