ACCELERATED CELL DEATH 6 Acts on Natural Leaf Senescence and Nitrogen Fluxes in Arabidopsis

As the last step of leaf development, senescence is a molecular process involving cell death mechanism. Leaf senescence is trigged by both internal age-dependent factors and environmental stresses. It must be tightly regulated for the plant to adopt a proper response to environmental variation and t...

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Bibliographic Details
Published in:Frontiers in plant science 2021-01, Vol.11, p.611170-611170
Main Authors: Jasinski, Sophie, Fabrissin, Isabelle, Masson, Amandine, Marmagne, Anne, LĂ©cureuil, Alain, Bill, Laurence, Chardon, Fabien
Format: Article
Language:English
Subjects:
aging
Arabidopsis thaliana
Life Sciences
nitrogen remobilization
nitrogen uptake
Plant Science
quantitative trait loci
seed filling
Vegetal Biology
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Summary:As the last step of leaf development, senescence is a molecular process involving cell death mechanism. Leaf senescence is trigged by both internal age-dependent factors and environmental stresses. It must be tightly regulated for the plant to adopt a proper response to environmental variation and to allow the plant to recycle nutrients stored in senescing organs. However, little is known about factors that regulate both nutrients fluxes and plant senescence. Taking advantage of variation for natural leaf senescence between accessions, and , we did a fine mapping of a quantitative trait loci for leaf senescence and identified ( ) as the causal gene. Using two near-isogeneic lines, differing solely around the locus, we showed that regulates rosette growth, leaf chlorophyll content, as well as leaf nitrogen and carbon percentages. To unravel the role of in N remobilization, the two isogenic lines and mutant were grown and labeled with N at the vegetative stage in order to determine N partitioning between plant organs at harvest. Results showed that N remobilization efficiency was significantly lower in all the genotypes with lower activity irrespective of plant growth and productivity. Measurement of N uptake at vegetative and reproductive stages revealed that did not modify N uptake efficiency but enhanced nitrogen translocation from root to silique. In this study, we have evidenced a new role of ACD6 in regulating both sequential and monocarpic senescences and disrupting the balance between N remobilization and N uptake that is required for a good seed filling.
ISSN:1664-462X
1664-462X
DOI:10.3389/fpls.2020.611170