Genetic gains with rapid‐cycle genomic selection for combined drought and waterlogging tolerance in tropical maize (Zea mays L.)

Genetic gains with rapid‐cycle genomic selection for combined drought and waterlogging tolerance in tropical maize (Zea mays L.)

Abstract Rapid cycle genomic selection (RC‐GS) helps to shorten the breeding cycle and reduce the costs of phenotyping, thereby increasing genetic gains in terms of both cost and time. We implemented RC‐GS on two multi‐parent yellow synthetic (MYS) populations constituted by intermating ten elite li...

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Main Authors: Reshmi R. Das, M. T. Vinayan, Manish B. Patel, Ramesh K. Phagna, S. B. Singh, J. P. Shahi, Akashi Sarma, N. S. Barua, Raman Babu, K. Seetharam, Juan A. Burgueño, P. H. Zaidi
Format: Article
Language:English
Published: Wiley 2020-11-01
Series:The Plant Genome
Online Access:https://doi.org/10.1002/tpg2.20035
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spelling doaj-5453e24bbaaf4f4d8a492a3d4cee831f2020-11-25T04:02:51ZengWileyThe Plant Genome1940-33722020-11-01133n/an/a10.1002/tpg2.20035Genetic gains with rapid‐cycle genomic selection for combined drought and waterlogging tolerance in tropical maize (Zea mays L.)Reshmi R. Das0M. T. Vinayan1Manish B. Patel2Ramesh K. Phagna3S. B. Singh4J. P. Shahi5Akashi Sarma6N. S. Barua7Raman Babu8K. Seetharam9Juan A. Burgueño10P. H. Zaidi11CIMMYT Asia Maize Program ICRISAT Campus Hyderabad 502324 IndiaCIMMYT Asia Maize Program ICRISAT Campus Hyderabad 502324 IndiaAnand Agricultural University Godhara IndiaICAR Indian Institute of Maize Research Ludhiana IndiaICAR Indian Institute of Maize Research Ludhiana IndiaBanaras Hindu University Varanasi IndiaAssam Agricultural University Jorhat IndiaAssam Agricultural University Jorhat IndiaCIMMYT Asia Maize Program ICRISAT Campus Hyderabad 502324 IndiaCIMMYT Asia Maize Program ICRISAT Campus Hyderabad 502324 IndiaCIMMYT El‐Batan MexicoCIMMYT Asia Maize Program ICRISAT Campus Hyderabad 502324 IndiaAbstract Rapid cycle genomic selection (RC‐GS) helps to shorten the breeding cycle and reduce the costs of phenotyping, thereby increasing genetic gains in terms of both cost and time. We implemented RC‐GS on two multi‐parent yellow synthetic (MYS) populations constituted by intermating ten elite lines involved in each population, including four each of drought and waterlogging tolerant donors and two commercial lines, with proven commercial value. Cycle 1 (C1) was constituted based on phenotypic selection and intermating of the top 5% of 500 S2 families derived from each MYS population, test‐crossed and evaluated across moisture regimes. C1 was advanced to the next two cycles (C2 and C3) by intermating the top 5% selected individuals with high genomic estimated breeding values (GEBVs) for grain yield under drought and waterlogging stress. To estimate genetic gains, population bulks from each cycle were test‐crossed and evaluated across locations under different moisture regimes. Results indicated that the realised genetic gain under drought stress was 0.110 t ha−1 yr−1 and 0.135 t ha−1 yr−1, respectively, for MYS‐1 and MYS‐2. The gain was less under waterlogging stress, where MYS‐1 showed 0.038 t ha−1 yr−1 and MYS‐2 reached 0.113 t ha−1 yr−1. Genomic selection for drought and waterlogging tolerance resulted in no yield penalty under optimal moisture conditions. The genetic diversity of the two populations did not change significantly after two cycles of GS, suggesting that RC‐GS can be an effective breeding strategy to achieve high genetic gains without losing genetic diversity.https://doi.org/10.1002/tpg2.20035
collection DOAJ
language English
format Article
sources DOAJ
author Reshmi R. Das
M. T. Vinayan
Manish B. Patel
Ramesh K. Phagna
S. B. Singh
J. P. Shahi
Akashi Sarma
N. S. Barua
Raman Babu
K. Seetharam
Juan A. Burgueño
P. H. Zaidi
spellingShingle Reshmi R. Das
M. T. Vinayan
Manish B. Patel
Ramesh K. Phagna
S. B. Singh
J. P. Shahi
Akashi Sarma
N. S. Barua
Raman Babu
K. Seetharam
Juan A. Burgueño
P. H. Zaidi
Genetic gains with rapid‐cycle genomic selection for combined drought and waterlogging tolerance in tropical maize (Zea mays L.)
The Plant Genome
author_facet Reshmi R. Das
M. T. Vinayan
Manish B. Patel
Ramesh K. Phagna
S. B. Singh
J. P. Shahi
Akashi Sarma
N. S. Barua
Raman Babu
K. Seetharam
Juan A. Burgueño
P. H. Zaidi
author_sort Reshmi R. Das
title Genetic gains with rapid‐cycle genomic selection for combined drought and waterlogging tolerance in tropical maize (Zea mays L.)
title_short Genetic gains with rapid‐cycle genomic selection for combined drought and waterlogging tolerance in tropical maize (Zea mays L.)
title_full Genetic gains with rapid‐cycle genomic selection for combined drought and waterlogging tolerance in tropical maize (Zea mays L.)
title_fullStr Genetic gains with rapid‐cycle genomic selection for combined drought and waterlogging tolerance in tropical maize (Zea mays L.)
title_full_unstemmed Genetic gains with rapid‐cycle genomic selection for combined drought and waterlogging tolerance in tropical maize (Zea mays L.)
title_sort genetic gains with rapid‐cycle genomic selection for combined drought and waterlogging tolerance in tropical maize (zea mays l.)
publisher Wiley
series The Plant Genome
issn 1940-3372
publishDate 2020-11-01
description Abstract Rapid cycle genomic selection (RC‐GS) helps to shorten the breeding cycle and reduce the costs of phenotyping, thereby increasing genetic gains in terms of both cost and time. We implemented RC‐GS on two multi‐parent yellow synthetic (MYS) populations constituted by intermating ten elite lines involved in each population, including four each of drought and waterlogging tolerant donors and two commercial lines, with proven commercial value. Cycle 1 (C1) was constituted based on phenotypic selection and intermating of the top 5% of 500 S2 families derived from each MYS population, test‐crossed and evaluated across moisture regimes. C1 was advanced to the next two cycles (C2 and C3) by intermating the top 5% selected individuals with high genomic estimated breeding values (GEBVs) for grain yield under drought and waterlogging stress. To estimate genetic gains, population bulks from each cycle were test‐crossed and evaluated across locations under different moisture regimes. Results indicated that the realised genetic gain under drought stress was 0.110 t ha−1 yr−1 and 0.135 t ha−1 yr−1, respectively, for MYS‐1 and MYS‐2. The gain was less under waterlogging stress, where MYS‐1 showed 0.038 t ha−1 yr−1 and MYS‐2 reached 0.113 t ha−1 yr−1. Genomic selection for drought and waterlogging tolerance resulted in no yield penalty under optimal moisture conditions. The genetic diversity of the two populations did not change significantly after two cycles of GS, suggesting that RC‐GS can be an effective breeding strategy to achieve high genetic gains without losing genetic diversity.
url https://doi.org/10.1002/tpg2.20035
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