Shade Avoidance 3 Mediates Crosstalk Between Shade and Nitrogen in Arabidopsis Leaf Development

Overview

Journal Front Plant Sci

Date 2022 Jan 31

PMID 35095972

Authors

Xin-Yue Yang

Zhong-Wei Zhang

Yu-Fan Fu

Ling-Yang Feng

Meng-Xia Li

Qi Kang

Chang-Quan Wang

Ming Yuan

Yang-Er Chen

Qi Tao

Ting Lan

Xiao-Yan Tang

Guang-Deng Chen

Jian Zeng

Shu Yuan

Affiliations

Soon will be listed here.

Abstract

After nitrogen treatments, plant leaves become narrower and thicker, and the chlorophyll content increases. However, the molecular mechanisms behind these regulations remain unknown. Here, we found that the changes in leaf width and thickness were largely compromised in the () mutant. The gene encodes an amino-transferase in the auxin biosynthesis pathway. Thus, the crosstalk between shade and nitrogen in Arabidopsis leaf development was investigated. Both hypocotyl elongation and leaf expansion promoted by the shade treatment were reduced by the high-N treatment; high-N-induced leaf narrowing and thickening were reduced by the shade treatment; and all of these developmental changes were largely compromised in the mutant. Shade treatment promoted expression, while high-N treatment repressed expression, which then increased or decreased auxin accumulation in cotyledons/leaves, respectively. SAV3 also regulates chlorophyll accumulation and nitrogen assimilation and thus may function as a master switch responsive to multiple environmental stimuli.

Citing Articles

Whether do plant cells sense nitrate changes without a sensor?.

Fu Y, Xie L, Yang X, Zhang Z, Yuan S Front Plant Sci. 2022; 13:1083594.

PMID: 36507373 PMC: 9731675. DOI: 10.3389/fpls.2022.1083594.

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