The Roles of MADS-Box Genes from Root Growth to Maturity in Arabidopsis and Rice

Liaqat Shah,Weixun Wu,Rafiq Ahmad,Shihua Cheng,Amir Sohail,Liyong Cao

doi:10.3390/agronomy12030582

Liaqat Shah, Weixun Wu + Show 4 more

Open Access

https://doi.org/10.3390/agronomy12030582

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Journal: Agronomy	Publication Date: Feb 26, 2022
Citations: 8	License type: CC BY 4.0

Affiliation: China National Rice Research Institute

Abstract

Rice (Oryza sativa L.) and Arabidopsis thaliana (L.) life cycles involve several major phase changes, throughout which MADS-box genes have a variety of functions. MADS-box genes are well recognized for their functions in floral induction and development, and some have multiple functions in apparently unrelated developmental stages. For example, in Arabidopsis, AGL15 and AGL6 play roles in both vegetative development and floral transition. Similarly, in rice, OsMADS1 is involved in flowering time and seed development, and OsMADS26 is expressed not only in the roots, but also in the leaves, shoots, panicles, and seeds. The roles of other MADS-box genes responsible for the regulation of specific traits in both rice and Arabidopsis are also discussed. Several are key components of gene regulatory networks involved in root development under diverse environmental factors such as drought, heat, and salt stress, and are also involved in the shift from vegetative to flowering growth in response to seasonal changes in environmental conditions. Thus, we argue that MADS-box genes are critical elements of gene regulation that underpin diverse gene expression profiles, each of which is linked to a unique developmental stage that occurs during root development and the shift from vegetative to reproductive growth.

Highlights

MADS-box genes are a family of transcription factors initially discovered in eukaryotes [1]
These findings indicate that several MADS-box genes are critical in root development in many species, and that they respond to environmental conditions through complicated regulatory mechanisms
Four MADS-box transcription factor (TF), SOC1, SVP, AGL24, and SEPALLATA 4 (SEP4), suppress inflorescence branching by directly inhibiting TERMINAL FLOWER1 (TFL1) expression in Arabidopsis [63]

Summary

Introduction

MADS-box genes are a family of transcription factors initially discovered in eukaryotes [1]. Based on the ABCDE model, M-type MADS-box genes have been reported to be involved in plant reproduction, the development and functioning of female gametophytes, the embryo, and the endosperm; MIKC-type. Genetic studies in rice and Arabidopsis have revealed the functions of several MADSbox genes in plant development The majority of these studies have shown that MADS-box genes are engaged in a variety of important morphological and physiological functions, including gametophyte cell division, root development, the floral transition, and floral organ control [12–14]. In Arabidopsis and rice, MADS-box genes play roles in a variety of developmental processes, including root development and elongation, meristem specification, the flowering transition from vegetative to reproductive stage, endosperm and seed formation, flower development and fertility, and fruit ripening. Several published reviews have reported on their functions from vegetative transition to reproductive development [1,11,22–28]

MADS-Box Gene Expression Profiles during Root Development

MADS-Box Gene Expression Profiles during Leaf Development in Rice

MADS-Box Genes Are Responsible for Inflorescence Branching

Communicating Role from Vegetative to Flowering Transition

MADS-Box Genes Play an Important Role in Seed Setting and Development