Green revolution ‘stumbles’ in a dry environment: Dwarf wheat with Rht genes fails to produce higher grain yield than taller plants under drought

In dry conditions, tall and fast‐growing wheat plants with good tolerance to drought may offer higher grain yields than ‘Green revolution’ wheat.

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Published inPlant, cell and environment Vol. 43; no. 10; pp. 2355 - 2364
Main Authors Jatayev, Satyvaldy, Sukhikh, Igor, Vavilova, Valeriya, Smolenskaya, Svetlana E., Goncharov, Nikolay P., Kurishbayev, Akhylbek, Zotova, Lyudmila, Absattarova, Aiman, Serikbay, Dauren, Hu, Yin‐Gang, Borisjuk, Nikolai, Gupta, Narendra K., Jacobs, Bertus, Groot, Stephan, Koekemoer, Francois, Alharthi, Badr, Lethola, Katso, Cu, Dan T., Schramm, Carly, Anderson, Peter, Jenkins, Colin L. D., Soole, Kathleen L., Shavrukov, Yuri, Langridge, Peter
Format Journal Article
LanguageEnglish
Published Chichester, UK John Wiley & Sons, Ltd 01.10.2020
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Abstract In dry conditions, tall and fast‐growing wheat plants with good tolerance to drought may offer higher grain yields than ‘Green revolution’ wheat.
AbstractList In dry conditions, tall and fast‐growing wheat plants with good tolerance to drought may offer higher grain yields than ‘Green revolution’ wheat.
Author Vavilova, Valeriya
Cu, Dan T.
Koekemoer, Francois
Jenkins, Colin L. D.
Zotova, Lyudmila
Anderson, Peter
Gupta, Narendra K.
Serikbay, Dauren
Shavrukov, Yuri
Smolenskaya, Svetlana E.
Alharthi, Badr
Langridge, Peter
Kurishbayev, Akhylbek
Jatayev, Satyvaldy
Absattarova, Aiman
Hu, Yin‐Gang
Goncharov, Nikolay P.
Jacobs, Bertus
Sukhikh, Igor
Lethola, Katso
Groot, Stephan
Soole, Kathleen L.
Borisjuk, Nikolai
Schramm, Carly
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  givenname: Dan T.
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  givenname: Kathleen L.
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  organization: Flinders University
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  surname: Langridge
  fullname: Langridge, Peter
  organization: University of Adelaide
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Notes Correction added on 10 August 2020, after first online publication: The header ‘9 | SOME SEMI‐DWARF MUTANT ALLELES OFFER A PROMISING ALTERNATIVE 2016 STRATEGY’ has been corrected in this version.
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Australian ACIAR Project, Grant/Award Number: CIM/2005/111; China 111 Project, Grant/Award Number: B12007; Kazakh Ministry of Education and Science, Grant/Award Number: BR05236500; National Natural Science Foundation of China, Grant/Award Number: 31671695; Russian Science Foundation, Grant/Award Number: 16‐16‐10021
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– volume: 20
  start-page: 1623
  year: 2018
  ident: e_1_2_15_5_1
  article-title: Terminal drought stress adaptability in synthetic derived bread wheat is explained by alleles of major adaptability genes and superior phenology
  publication-title: International Journal of Agriculture and Biology
  contributor:
    fullname: Afzal F.
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Snippet In dry conditions, tall and fast‐growing wheat plants with good tolerance to drought may offer higher grain yields than ‘Green revolution’ wheat.
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SubjectTerms Crop yield
Dehydration
Drought
Edible Grain - growth & development
Edible Grain - physiology
Genes, Plant - physiology
Green revolution
Plant Breeding
Quantitative Trait, Heritable
Triticum - genetics
Triticum - growth & development
Triticum - physiology
Wheat
Title Green revolution ‘stumbles’ in a dry environment: Dwarf wheat with Rht genes fails to produce higher grain yield than taller plants under drought
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fpce.13819
https://www.ncbi.nlm.nih.gov/pubmed/32515827
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https://search.proquest.com/docview/2411103477
Volume 43
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