Auxin Distribution in Lateral Root Primordium Development Affects the Size and Lateral Root Diameter of Rice

Overview

Journal Front Plant Sci

Date 2022 May 2

PMID 35498720

Authors

Tsubasa Kawai

Ryosuke Akahoshi

Israt J Shelley

Takaaki Kojima

Moeko Sato

Hiroyuki Tsuji

Yoshiaki Inukai

Affiliations

Soon will be listed here.

Abstract

Lateral roots (LRs) occupy a large part of the root system and play a central role in plant water and nutrient uptake. Monocot plants, such as rice, produce two types of LRs: the S-type (short and thin) and the L-type (long, thick, and capable of further branching). Because of the ability to produce higher-order branches, the L-type LR formation contributes to efficient root system expansion. Auxin plays a major role in regulating the root system development, but its involvement in developing different types of LRs is largely unknown. Here, we show that auxin distribution is involved in regulating LR diameter. () genes were isolated as causative genes of the mutants with increased L-type LR number and diameter than wild-type (WT). In the mutants, reduced endocytic activity was detected in rice protoplast and LRs with a decreased OsPIN1b-GFP endocytosis in the protoplast. Analysis of auxin distribution using auxin-responsive promoter revealed the upregulated auxin signaling in L-type LR primordia (LRP) of the WT and the mutants. The application of polar auxin transport inhibitors enhanced the effect of exogenous auxin to increase LR diameter with upregulated auxin signaling in the basal part of LRP. Inducible repression of auxin signaling in the m system suppressed the increase in LR diameter after root tip excision, suggesting a positive role of auxin signaling in LR diameter increase. A positive regulator of LR diameter, , was auxin-inducible and upregulated in the mutants more than the WT, and revealed as a potential target of ARF transcriptional activator. Therefore, auxin signaling upregulation in LRP, especially at the basal part, induces expression, increasing LR diameter.

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