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RESEARCH ARTICLE
Contents Vol 34(1)

Model-assisted physiological analysis of Phyllo, a rice architectural mutant

Delphine Luquet A D , You Hong Song B , Sonia Elbelt A , Dominique This C , Anne Clément-Vidal A , Christophe Périn A , Denis Fabre A and Michael Dingkuhn A
+ Author Affiliations
- Author Affiliations

A CIRAD, Amis Dpt, TA40/01 Avenue Agropolis, 34 398 Montpellier Cedex 5, France.

B Institute of Botany, the Chinese Academy of sciences, 100 093, Beijing, China.

C Ecole Nationale Supérieure Agronomique de Montpellier, UMR 1096, 2, place P. Viala, 34 060 Montpellier Cedex, France.

D Corresponding author. Email: luquet@cirad.fr

Functional Plant Biology 34(1) 11-23 https://doi.org/10.1071/FP06180
Submitted: 24 July 2006  Accepted: 11 October 2006   Published: 19 January 2007

Abstract

Studies of phenotype of knockout mutants can provide new insights into physiological, phenological and architectural feedbacks in the plant system. Phyllo, a mutant of Nippon Bare rice (Oryza sativa L.) producing small leaves in rapid succession, was isolated during multiplication of a T-DNA insertion library. Phyllo phenotype was compared with the wild type (WT) during vegetative development in hydroponics culture using a wide range of physiological and biometric measurements. These were integrated with the help of the functional–structural model EcoMeristem, explicitly designed to study interactions between morphogenesis and carbon assimilation. Although the phenotype of the mutant was caused by a single recessive gene, it differed in many ways from the WT, suggesting a pleiotropic effect of this mutation. Phyllochron was 25 (1–4 leaf stage) to 38% (>>4 leaf stage) shorter but showed normal transition from juvenile to adult phase after leaf 4. Leaf size also increased steadily with leaf position as in WT. The mutant had reduced leaf blade length : width and blade : sheath length ratios, particularly during the transition from heterotrophic to autotrophic growth. During the same period, root : shoot dry weight ratio was significantly diminished. Specific leaf area (SLA) was strongly increased in the mutant but showed normal descending patterns with leaf position. Probably related to high SLA, the mutant had much lower light-saturated leaf photosynthetic rates and lower radiation use efficiency (RUE) than the WT. Leaf extension rates were strongly reduced in absolute terms but were high in relative terms (normalised by final leaf length). The application of the EcoMeristem model to these data indicated that the mutant was severely deficient in assimilate, resulting from low RUE and high organ initiation rate causing high assimilate demand. This was particularly pronounced during the heterotrophic–autotrophic transition, probably causing shorter leaf blades relative to sheaths, as well as a temporary reduction of assimilate partitioning to roots. The model accurately simulated the mutant’s high leaf mortality and absence of tillering. The simulated assimilate shortage was supported by observed reductions in starch storage in sheaths. Soluble sugar concentrations differed between mutant and WT in roots but not in shoots. Specifically, the hexose : sucrose ratio was 50% lower in the roots of the mutant, possibly indicating low invertase activity. Furthermore, two OsCIN genes coding for cell wall invertases were not expressed in roots, and others were expressed weakly. This was interpreted as natural silencing via sugar signalling. In summary, the authors attributed the majority of observed allometric and metabolic modifications in the mutant to an extreme assimilate shortage caused by hastened shoot organogenesis and inefficient leaf morphology.

Additional keywords: cell-wall invertase, EcoMeristem model, leaf photosynthetic rate, T-DNA insertion mutant, Oryza sativa, phyllochron, source–sink relationships, sugar metabolism.


Acknowledgements

The authors wish to express their gratitude to the French Ministry for Foreign Affairs for financial support of a post-doctoral project.


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