RNA-seq reveals the involvement of key genes for aerobic adaptation in rice

Amol S Phule,Sheshu Madhav Maganti,P Seguttuvel,D Subrahmanyam,Kalyani M Barbadikar,M B B Prasad Babu,Polumetla A Kumar

doi:10.1038/s41598-019-41703-2

Abstract

Adaptation of rice to the aerobic condition is needed to cope with the water scarcity as well as to ensure sustainable yield in future. To understand the molecular mechanisms responsible for aerobic adaptation in rice, we performed RNA-seq analysis of root and shoot i.e. developing panicle tissues at panicle initiation stage in two cultivars adapted to aerobic (CR Dhan 202) and traditional transplanted anaerobic (BPT 5204) conditions. The RNA-seq data emanated from 1.65 billion clean reads with approximately 37 million reads per sample. The number of differentially expressed transcripts was higher in the root than that in the shoot under both aerobic and anaerobic conditions. The transcription factors viz. MADS4, MADS5, MADS6, MADS7, MADS15 and transporters involved in sugar (SWEET3A) and nutrient uptake (PHT1;6, MDR-like ABC and vacuolar iron transporter homolog 2) were highly and uniquely expressed in the aerobic adapted cultivar (AAC) CR Dhan 202 under aerobic condition indicating their role in adaptation. The hormones such as ethylene and abscisic acid might be significantly involved in imparting aerobic adaptation. The higher expression of root related genes in the AAC under aerobic conditions suggests the involvement and sensitivity of roots to the water limiting condition. The metabolic activities are also more pronounced in the roots which impart rigorous plant establishment under the aerobic condition. The presence of alternative splice variants in the transcripts viz. Tetratrico peptide repeat (TPR) domain containing protein and GOLDEN2-LIKE1 (GLK1) additionally confirms that post transcriptional regulation is also crucial for aerobic adaptation. The QTLs related to root traits and stress tolerance harboring the uniquely expressed genes, which were identified in the present study can be deployed in molecular breeding programs to develop elite, high yielding aerobic rice cultivars.

Highlights

The changing climate, depleting water resources and increasing population make it imperative to develop next-generation climate smart crop varieties for sustainable agriculture
Among the several traits root system architecture is known to play a critical role in adaptation and we have focused on the root system and the developing shoot for unraveling the molecular mechanisms associated with the aerobic adaptation
Lower number differentially expressed transcripts (DETs) were observed under aerobic condition (BPT 5204 Aerobic Shoot, BPT Aerobic Shoot (BAS) vs. CR Dhan Aerobic Shoot (CAS), CR Dhan 202 Aerobic Shoot) than the anaerobic condition (BPT 5204 Anaerobic Shoot, BFS vs. CR Dhan 202 Anaerobic Shoot, CFS), but in adapted cultivar (AAC) higher number DETs were found than the NAC

Summary

Introduction

The changing climate, depleting water resources and increasing population make it imperative to develop next-generation climate smart crop varieties for sustainable agriculture. Aerobic cultivation has emerged as an alternative wherein the crop is raised direct seeded and need based irrigation is provided with proper management practices[1]. This kind of shift in rice cultivation is needed to cope with the water scarcity as well as to maintain the ground water table. Understanding the molecular mechanisms and the genomic regions associated with the adaptation is necessary to design rice improvement strategies especially for water availability and uptake. With the advent of next-generation sequencing, RNA-seq has become very useful to analyze the gene expression and molecular mechanisms underlying various traits. Among the several traits root system architecture is known to play a critical role in adaptation and we have focused on the root system and the developing shoot for unraveling the molecular mechanisms associated with the aerobic adaptation

Methods

Results

Conclusion