Introgression of Root and Water Use Efficiency Traits Enhances Water Productivity: An Evidence for Physiological Breeding in Rice (Oryza Sativa L.)

Overview

Journal Rice (N Y)

Date 2019 Mar 9

PMID 30847616

Citations 7

Authors

Prathibha M Dharmappa

Pushpa Doddaraju

Mohankumar V Malagondanahalli

Raju B Rangappa

N M Mallikarjuna

Sowmya H Rajendrareddy

Ramachandra Ramanjinappa

Rajanna P Mavinahalli

Trichy Ganesh Prasad

Makarla Udayakumar

Sreeman M Sheshshayee

Affiliations

Soon will be listed here.

Abstract

Background: Semi-irrigated aerobic cultivation of rice has been suggested as a potential water saving agronomy. However, suitable cultivars are needed in order to sustain yield levels. An introgression of water mining and water use efficiency (WUE) traits is the most appropriate strategy for a comprehensive genetic enhancement to develop such rice cultivars.

Results: We report a novel strategy of phenotyping and marker-assisted backcross breeding to introgress water mining (root) and water use efficiency (WUE) traits into a popular high yielding cultivar, IR-64. Trait donor genotypes for root (AC-39020) and WUE (IET-16348) were crossed separately and the resultant Fs were inter-mated to generate double cross Fs (DCF). Progenies of three generations of backcross followed by selfing were charatcerised for target phenotype and genome integration. A set of 260 trait introgressed lines were identified. Root weight and root length of TILs were 53% and 23.5% higher, while ΔC was 2.85‰ lower indicating a significant increase in WUE over IR-64. Five best TILs selected from BCF generation showed 52% and 63% increase in yield over IR-64 under 100% and 60% FC, respectively. The trait introgressed lines resembled IR64 with more than 97% of genome recovered with a significant yield advantage under semi-irrigated aerobic conditions The study validated markers identified earlier by association mapping.

Conclusion: Introgression of root and WUE into IR64, resulted in an excellent yield advantage even when cultivated under semi-irrigated aerobic condition. The study provided a proof-of-concept that maintaining leaf turgor and carbon metabolism results in improved adaptation to water limited conditions and sustains productivity. A marker based multi-parent backcross breeding is an appropriate approach for trait introgression. The trait introgressed lines developed can be effectively used in future crop improvement programs as donor lines for both root and WUE.

Citing Articles

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Mondal R, Kumar A, Gnanesh B Heliyon. 2023; 9(1):e12973.

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Engineering drought-tolerant apple by knocking down six genes and potential application of transgenic apple as a rootstock.

Jiang L, Shen W, Liu C, Tahir M, Li X, Zhou S Hortic Res. 2022; 9:uhac122.

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Unlocking the Nexus between Leaf-Level Water Use Efficiency and Root Traits Together with Gas Exchange Measurements in Rice ( L.).

Gobu R, Dash G, Lal J, Swain P, Mahender A, Anandan A Plants (Basel). 2022; 11(9).

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Identification of Markers for Root Traits Related to Drought Tolerance Using Traditional Rice Germplasm.

Verma H, Sarma R Mol Biotechnol. 2021; 63(12):1280-1292.

PMID: 34398447 DOI: 10.1007/s12033-021-00380-1.

Induction of Acquired Tolerance Through Gradual Progression of Drought Is the Key for Maintenance of Spikelet Fertility and Yield in Rice Under Semi-irrigated Aerobic Conditions.

Lekshmy V, Vijayaraghavareddy P, Nagashree A, Ramu V, Ramegowda V, Makarla U Front Plant Sci. 2021; 11:632919.

PMID: 33679820 PMC: 7930615. DOI: 10.3389/fpls.2020.632919.

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