Meta-QTL Analysis in Rice and Cross-Genome Talk of the Genomic Regions Controlling Nitrogen Use Efficiency in Cereal Crops Revealing Phylogenetic Relationship.

Nitika Sandhu,Mehak Sethi,Mohini Prabha Singh,Jasneet Singh,Kanika Phagna,Aman Kumar,Om Prakash Raigar,Dinesh Kumar Saini,Gomsie Pruthi,Pooja Ankush Ade

doi:10.3389/fgene.2021.807210

Abstract

The phenomenal increase in the use of nitrogenous fertilizers coupled with poor nitrogen use efficiency is among the most important threats to the environment, economic, and social health. During the last 2 decades, a number of genomic regions associated with nitrogen use efficiency (NUE) and related traits have been reported by different research groups, but none of the stable and major effect QTL have been utilized in the marker-assisted introgression/pyramiding program. Compiling the data available in the literature could be very useful in identifying stable and major effect genomic regions associated with the root and NUE-related trait improving the rice grain yield. In the present study, we performed meta-QTL analysis on 1,330 QTL from 29 studies published in the past 2 decades. A total of 76 MQTL with a stable effect over different genetic backgrounds and environments were identified. The significant reduction in the confidence interval of the MQTL compared to the initial QTL resulted in the identification of annotated and putative candidate genes related to the traits considered in the present study. A hot spot region associated with correlated traits on chr 1, 4, and 8 and candidate genes associated with nitrate transporters, nitrogen content, and ammonium uptake on chromosomes 2, 4, 6, and 8 have been identified. The identified MQTL, putative candidate genes, and their orthologues were validated on our previous studies conducted on rice and wheat. The research-based interventions such as improving nitrogen use efficiency via identification of major genomic regions and candidate genes can be a plausible, simple, and low-cost solution to address the challenges of the crop improvement program.

Highlights

Asian rice (Oryza sativa) is a major cereal crop grown worldwide and an essential food source for over half of the world’s population (Nayar, 2014)
In order to identify the consensus genomic regions associated with the 33 nitrogen use efficiency and related traits, we compiled the information on a total of 1,330 QTLs derived from 28 relevant studies including 11-backcross population (BC), 13-recombinant inbred lines (RILs), 3-double haploids (DHs), and 1-chromosome segment substitution lines (CSSLs) with the population size that ranged from 75 to 611 reported between 2001 and 2021
nitrogen use efficiency (NUE) is a quantitative trait controlled by multiple genes and the co-localization of genomic regions associated with yield/ yield-related traits and root traits improving NUE providing key candidate genes for the rice crop improvement

Summary

Introduction

Asian rice (Oryza sativa) is a major cereal crop grown worldwide and an essential food source for over half of the world’s population (Nayar, 2014). Nitrogen is the essential macronutrient, and it is considered as the limiting factor for crop productivity. The world’s agriculture is facing new challenges, and the global grain and food security problem persists (Kalugina, 2014). 119.41 million tons of nitrogen (N) fertilizers are being applied to the cereal crops to achieve the desirable crop yield (FAO, 2018). The rice crop has the lowest NUE among the major cereal crops (Norton et al, 2015). The increasing use of nitrogenous fertilizers for crop production coupled with poor nitrogen use efficiency (NUE) has led to the degradation of soil, water, and environment. The uptake, transport, assimilation/utilization, and remobilization of N are controlled by a complex and interconnected network of genes involved in various biological processes (Kant et al, 2011)

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Conclusion