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The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage

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Zeitschriftentitel: Plant Biotechnology Journal
Personen und Körperschaften: Liu, Citao, Schläppi, Michael R., Mao, Bigang, Wang, Wei, Wang, Aiju, Chu, Chengcai
In: Plant Biotechnology Journal, 17, 2019, 9, S. 1834-1849
Format: E-Article
Sprache: Englisch
veröffentlicht:
Wiley
Schlagwörter:
Plant Science
Agronomy and Crop Science
Biotechnology
author_facet Liu, Citao
Schläppi, Michael R.
Mao, Bigang
Wang, Wei
Wang, Aiju
Chu, Chengcai
Liu, Citao
Schläppi, Michael R.
Mao, Bigang
Wang, Wei
Wang, Aiju
Chu, Chengcai
author Liu, Citao
Schläppi, Michael R.
Mao, Bigang
Wang, Wei
Wang, Aiju
Chu, Chengcai
spellingShingle Liu, Citao
Schläppi, Michael R.
Mao, Bigang
Wang, Wei
Wang, Aiju
Chu, Chengcai
Plant Biotechnology Journal
The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
Plant Science
Agronomy and Crop Science
Biotechnology
author_sort liu, citao
spelling Liu, Citao Schläppi, Michael R. Mao, Bigang Wang, Wei Wang, Aiju Chu, Chengcai 1467-7644 1467-7652 Wiley Plant Science Agronomy and Crop Science Biotechnology http://dx.doi.org/10.1111/pbi.13104 <jats:title>Summary</jats:title><jats:p>Cold temperature during the reproductive stage often causes great yield loss of grain crops in subtropical and temperate regions. Previously we showed that the rice transcription factor <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup> plays an important role in cold adaptation at the seedling stage. Here we further demonstrate that <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup> also confers cold stress tolerance at the reproductive stage. <jats:italic><jats:styled-content style="fixed-case">bZIP</jats:styled-content>73</jats:italic><jats:sup><jats:italic>Jap</jats:italic></jats:sup> was up‐regulated under cold treatment and predominately expressed in panicles at the early binucleate and flowering stages. <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup> forms heterodimers with <jats:styled-content style="fixed-case">bZIP</jats:styled-content>71, and co‐expression of <jats:italic><jats:styled-content style="fixed-case">bZIP</jats:styled-content>73</jats:italic><jats:sup><jats:italic>Jap</jats:italic></jats:sup> and <jats:italic><jats:styled-content style="fixed-case">bZIP</jats:styled-content>71</jats:italic> transgenic lines significantly increased seed‐setting rate and grain yield under natural cold stress conditions. <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup>:<jats:styled-content style="fixed-case">bZIP</jats:styled-content>71 not only repressed <jats:styled-content style="fixed-case">ABA</jats:styled-content> level in anthers, but also enhanced soluble sugar transport from anthers to pollens and improved pollen grain fertility, seed‐setting rate, and grain yield. Interestingly, <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup>:<jats:styled-content style="fixed-case">bZIP</jats:styled-content>71 also regulated the expression of <jats:italic><jats:styled-content style="fixed-case">qLTG</jats:styled-content>3‐1</jats:italic><jats:sup><jats:italic>Nip</jats:italic></jats:sup>, and <jats:italic><jats:styled-content style="fixed-case">qLTG</jats:styled-content>3‐1</jats:italic><jats:sup><jats:italic>Nip</jats:italic></jats:sup> overexpression lines greatly improved rice tolerance to cold stress during the reproductive stage. Therefore, our work establishes a framework for rice cold stress tolerance through the <jats:styled-content style="fixed-case">bZIP</jats:styled-content>71‐<jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup>‐<jats:styled-content style="fixed-case">qLTG</jats:styled-content>3‐1<jats:sup>Nip</jats:sup>‐sugar transport pathway. Together with our previous work, our results provide a powerful tool for improving rice cold stress tolerance at both the seedling and the reproductive stages.</jats:p> The <scp>bZIP</scp>73 transcription factor controls rice cold tolerance at the reproductive stage Plant Biotechnology Journal
doi_str_mv 10.1111/pbi.13104
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publisher Wiley
recordtype ai
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series Plant Biotechnology Journal
source_id 49
title The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
title_unstemmed The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
title_full The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
title_fullStr The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
title_full_unstemmed The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
title_short The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
title_sort the <scp>bzip</scp>73 transcription factor controls rice cold tolerance at the reproductive stage
topic Plant Science
Agronomy and Crop Science
Biotechnology
url http://dx.doi.org/10.1111/pbi.13104
publishDate 2019
physical 1834-1849
description <jats:title>Summary</jats:title><jats:p>Cold temperature during the reproductive stage often causes great yield loss of grain crops in subtropical and temperate regions. Previously we showed that the rice transcription factor <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup> plays an important role in cold adaptation at the seedling stage. Here we further demonstrate that <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup> also confers cold stress tolerance at the reproductive stage. <jats:italic><jats:styled-content style="fixed-case">bZIP</jats:styled-content>73</jats:italic><jats:sup><jats:italic>Jap</jats:italic></jats:sup> was up‐regulated under cold treatment and predominately expressed in panicles at the early binucleate and flowering stages. <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup> forms heterodimers with <jats:styled-content style="fixed-case">bZIP</jats:styled-content>71, and co‐expression of <jats:italic><jats:styled-content style="fixed-case">bZIP</jats:styled-content>73</jats:italic><jats:sup><jats:italic>Jap</jats:italic></jats:sup> and <jats:italic><jats:styled-content style="fixed-case">bZIP</jats:styled-content>71</jats:italic> transgenic lines significantly increased seed‐setting rate and grain yield under natural cold stress conditions. <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup>:<jats:styled-content style="fixed-case">bZIP</jats:styled-content>71 not only repressed <jats:styled-content style="fixed-case">ABA</jats:styled-content> level in anthers, but also enhanced soluble sugar transport from anthers to pollens and improved pollen grain fertility, seed‐setting rate, and grain yield. Interestingly, <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup>:<jats:styled-content style="fixed-case">bZIP</jats:styled-content>71 also regulated the expression of <jats:italic><jats:styled-content style="fixed-case">qLTG</jats:styled-content>3‐1</jats:italic><jats:sup><jats:italic>Nip</jats:italic></jats:sup>, and <jats:italic><jats:styled-content style="fixed-case">qLTG</jats:styled-content>3‐1</jats:italic><jats:sup><jats:italic>Nip</jats:italic></jats:sup> overexpression lines greatly improved rice tolerance to cold stress during the reproductive stage. Therefore, our work establishes a framework for rice cold stress tolerance through the <jats:styled-content style="fixed-case">bZIP</jats:styled-content>71‐<jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup>‐<jats:styled-content style="fixed-case">qLTG</jats:styled-content>3‐1<jats:sup>Nip</jats:sup>‐sugar transport pathway. Together with our previous work, our results provide a powerful tool for improving rice cold stress tolerance at both the seedling and the reproductive stages.</jats:p>
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author Liu, Citao, Schläppi, Michael R., Mao, Bigang, Wang, Wei, Wang, Aiju, Chu, Chengcai
author_facet Liu, Citao, Schläppi, Michael R., Mao, Bigang, Wang, Wei, Wang, Aiju, Chu, Chengcai, Liu, Citao, Schläppi, Michael R., Mao, Bigang, Wang, Wei, Wang, Aiju, Chu, Chengcai
author_sort liu, citao
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description <jats:title>Summary</jats:title><jats:p>Cold temperature during the reproductive stage often causes great yield loss of grain crops in subtropical and temperate regions. Previously we showed that the rice transcription factor <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup> plays an important role in cold adaptation at the seedling stage. Here we further demonstrate that <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup> also confers cold stress tolerance at the reproductive stage. <jats:italic><jats:styled-content style="fixed-case">bZIP</jats:styled-content>73</jats:italic><jats:sup><jats:italic>Jap</jats:italic></jats:sup> was up‐regulated under cold treatment and predominately expressed in panicles at the early binucleate and flowering stages. <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup> forms heterodimers with <jats:styled-content style="fixed-case">bZIP</jats:styled-content>71, and co‐expression of <jats:italic><jats:styled-content style="fixed-case">bZIP</jats:styled-content>73</jats:italic><jats:sup><jats:italic>Jap</jats:italic></jats:sup> and <jats:italic><jats:styled-content style="fixed-case">bZIP</jats:styled-content>71</jats:italic> transgenic lines significantly increased seed‐setting rate and grain yield under natural cold stress conditions. <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup>:<jats:styled-content style="fixed-case">bZIP</jats:styled-content>71 not only repressed <jats:styled-content style="fixed-case">ABA</jats:styled-content> level in anthers, but also enhanced soluble sugar transport from anthers to pollens and improved pollen grain fertility, seed‐setting rate, and grain yield. Interestingly, <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup>:<jats:styled-content style="fixed-case">bZIP</jats:styled-content>71 also regulated the expression of <jats:italic><jats:styled-content style="fixed-case">qLTG</jats:styled-content>3‐1</jats:italic><jats:sup><jats:italic>Nip</jats:italic></jats:sup>, and <jats:italic><jats:styled-content style="fixed-case">qLTG</jats:styled-content>3‐1</jats:italic><jats:sup><jats:italic>Nip</jats:italic></jats:sup> overexpression lines greatly improved rice tolerance to cold stress during the reproductive stage. Therefore, our work establishes a framework for rice cold stress tolerance through the <jats:styled-content style="fixed-case">bZIP</jats:styled-content>71‐<jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup>‐<jats:styled-content style="fixed-case">qLTG</jats:styled-content>3‐1<jats:sup>Nip</jats:sup>‐sugar transport pathway. Together with our previous work, our results provide a powerful tool for improving rice cold stress tolerance at both the seedling and the reproductive stages.</jats:p>
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spelling Liu, Citao Schläppi, Michael R. Mao, Bigang Wang, Wei Wang, Aiju Chu, Chengcai 1467-7644 1467-7652 Wiley Plant Science Agronomy and Crop Science Biotechnology http://dx.doi.org/10.1111/pbi.13104 <jats:title>Summary</jats:title><jats:p>Cold temperature during the reproductive stage often causes great yield loss of grain crops in subtropical and temperate regions. Previously we showed that the rice transcription factor <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup> plays an important role in cold adaptation at the seedling stage. Here we further demonstrate that <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup> also confers cold stress tolerance at the reproductive stage. <jats:italic><jats:styled-content style="fixed-case">bZIP</jats:styled-content>73</jats:italic><jats:sup><jats:italic>Jap</jats:italic></jats:sup> was up‐regulated under cold treatment and predominately expressed in panicles at the early binucleate and flowering stages. <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup> forms heterodimers with <jats:styled-content style="fixed-case">bZIP</jats:styled-content>71, and co‐expression of <jats:italic><jats:styled-content style="fixed-case">bZIP</jats:styled-content>73</jats:italic><jats:sup><jats:italic>Jap</jats:italic></jats:sup> and <jats:italic><jats:styled-content style="fixed-case">bZIP</jats:styled-content>71</jats:italic> transgenic lines significantly increased seed‐setting rate and grain yield under natural cold stress conditions. <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup>:<jats:styled-content style="fixed-case">bZIP</jats:styled-content>71 not only repressed <jats:styled-content style="fixed-case">ABA</jats:styled-content> level in anthers, but also enhanced soluble sugar transport from anthers to pollens and improved pollen grain fertility, seed‐setting rate, and grain yield. Interestingly, <jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup>:<jats:styled-content style="fixed-case">bZIP</jats:styled-content>71 also regulated the expression of <jats:italic><jats:styled-content style="fixed-case">qLTG</jats:styled-content>3‐1</jats:italic><jats:sup><jats:italic>Nip</jats:italic></jats:sup>, and <jats:italic><jats:styled-content style="fixed-case">qLTG</jats:styled-content>3‐1</jats:italic><jats:sup><jats:italic>Nip</jats:italic></jats:sup> overexpression lines greatly improved rice tolerance to cold stress during the reproductive stage. Therefore, our work establishes a framework for rice cold stress tolerance through the <jats:styled-content style="fixed-case">bZIP</jats:styled-content>71‐<jats:styled-content style="fixed-case">bZIP</jats:styled-content>73<jats:sup>Jap</jats:sup>‐<jats:styled-content style="fixed-case">qLTG</jats:styled-content>3‐1<jats:sup>Nip</jats:sup>‐sugar transport pathway. Together with our previous work, our results provide a powerful tool for improving rice cold stress tolerance at both the seedling and the reproductive stages.</jats:p> The <scp>bZIP</scp>73 transcription factor controls rice cold tolerance at the reproductive stage Plant Biotechnology Journal
spellingShingle Liu, Citao, Schläppi, Michael R., Mao, Bigang, Wang, Wei, Wang, Aiju, Chu, Chengcai, Plant Biotechnology Journal, The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage, Plant Science, Agronomy and Crop Science, Biotechnology
title The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
title_full The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
title_fullStr The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
title_full_unstemmed The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
title_short The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
title_sort the <scp>bzip</scp>73 transcription factor controls rice cold tolerance at the reproductive stage
title_unstemmed The bZIP73 transcription factor controls rice cold tolerance at the reproductive stage
topic Plant Science, Agronomy and Crop Science, Biotechnology
url http://dx.doi.org/10.1111/pbi.13104