Contribution of two different Na+ transport systems to acquired salinity tolerance in rice

Contribution of two different Na+ transport systems to acquired salinity tolerance in rice

•Rice varieties differ in their ability to acclimate to salinity stress.•Acclimatized rice varieties exhibited ‘Na+ excluder’ and ‘Na+ accumulator’ characteristics in leaf Na+ homeostasis.•Acclimation treatment increased expression of the OsHKT1;5 or OsNHX1 gene in acclimatized varieties.•Rice devel...

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Veröffentlicht in:Plant science (Limerick) 2020-08, Vol.297, p.110517-110517, Article 110517
Hauptverfasser: Sriskantharajah, Karthika, Osumi, Shota, Chuamnakthong, Sumana, Nampei, Mami, Amas, Junrey C., Gregorio, Glenn B., Ueda, Akihiro
Format: Artikel
Sprache:eng
Schlagworte:
Acclimatization
Cation Transport Proteins - genetics
Cation Transport Proteins - metabolism
Cation Transport Proteins - physiology
Malondialdehyde - metabolism
Na+ exclusion
Oryza - genetics
Oryza - metabolism
Oryza - physiology
OsHKT1
5
OsNHX1
Plant Proteins - metabolism
Plant Proteins - physiology
Potassium - metabolism
Rice
Salinity
Salt acclimation
Salt Stress
Salt-Tolerant Plants - metabolism
Sodium - metabolism
Transcriptome
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container_end_page 110517
container_issue
container_start_page 110517
container_title Plant science (Limerick)
container_volume 297
creator Sriskantharajah, Karthika
Osumi, Shota
Chuamnakthong, Sumana
Nampei, Mami
Amas, Junrey C.
Gregorio, Glenn B.
Ueda, Akihiro
description •Rice varieties differ in their ability to acclimate to salinity stress.•Acclimatized rice varieties exhibited ‘Na+ excluder’ and ‘Na+ accumulator’ characteristics in leaf Na+ homeostasis.•Acclimation treatment increased expression of the OsHKT1;5 or OsNHX1 gene in acclimatized varieties.•Rice develops different mechanisms of salt acclimation using two Na+ transport systems. To elucidate the mechanisms of salt acclimation, physiological parameters of 70 rice varieties were compared under control and salt stress conditions after the acclimation treatment. The results indicated that some rice varieties had the ability to acclimatize to salt stress, exhibiting improved growth following the acclimation treatment under subsequent salinity stress compared to those without acclimation treatment. Conversely, some varieties exhibited reduced growth both with and without acclimation treatment under subsequent salinity stress. Acclimatized varieties had differential patterns of Na+ accumulation in the leaf blades because some varieties reduced Na+ accumulation under salinity stress, whereas others did not. Under salt stress, the acclimatized varieties with low Na+ accumulation in the leaf blades highly induced the expression of the OsHKT1;5 gene in the roots, which may contribute to Na+ exclusion from the shoots. On the other hand, the acclimatized varieties with high Na+ accumulation in the leaf blades exhibited higher induction of the OsNHX1 gene, whose gene product participates in the compartmentalization of Na+ into vacuoles. Thus, rice develops different mechanisms of salinity acclimation using two Na+ transport systems, and active regulation of Na+ transport at the transcription level may be involved in the salt acclimation process and enhance salinity tolerance.
doi_str_mv 10.1016/j.plantsci.2020.110517
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To elucidate the mechanisms of salt acclimation, physiological parameters of 70 rice varieties were compared under control and salt stress conditions after the acclimation treatment. The results indicated that some rice varieties had the ability to acclimatize to salt stress, exhibiting improved growth following the acclimation treatment under subsequent salinity stress compared to those without acclimation treatment. Conversely, some varieties exhibited reduced growth both with and without acclimation treatment under subsequent salinity stress. Acclimatized varieties had differential patterns of Na+ accumulation in the leaf blades because some varieties reduced Na+ accumulation under salinity stress, whereas others did not. Under salt stress, the acclimatized varieties with low Na+ accumulation in the leaf blades highly induced the expression of the OsHKT1;5 gene in the roots, which may contribute to Na+ exclusion from the shoots. On the other hand, the acclimatized varieties with high Na+ accumulation in the leaf blades exhibited higher induction of the OsNHX1 gene, whose gene product participates in the compartmentalization of Na+ into vacuoles. 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To elucidate the mechanisms of salt acclimation, physiological parameters of 70 rice varieties were compared under control and salt stress conditions after the acclimation treatment. The results indicated that some rice varieties had the ability to acclimatize to salt stress, exhibiting improved growth following the acclimation treatment under subsequent salinity stress compared to those without acclimation treatment. Conversely, some varieties exhibited reduced growth both with and without acclimation treatment under subsequent salinity stress. Acclimatized varieties had differential patterns of Na+ accumulation in the leaf blades because some varieties reduced Na+ accumulation under salinity stress, whereas others did not. Under salt stress, the acclimatized varieties with low Na+ accumulation in the leaf blades highly induced the expression of the OsHKT1;5 gene in the roots, which may contribute to Na+ exclusion from the shoots. On the other hand, the acclimatized varieties with high Na+ accumulation in the leaf blades exhibited higher induction of the OsNHX1 gene, whose gene product participates in the compartmentalization of Na+ into vacuoles. 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To elucidate the mechanisms of salt acclimation, physiological parameters of 70 rice varieties were compared under control and salt stress conditions after the acclimation treatment. The results indicated that some rice varieties had the ability to acclimatize to salt stress, exhibiting improved growth following the acclimation treatment under subsequent salinity stress compared to those without acclimation treatment. Conversely, some varieties exhibited reduced growth both with and without acclimation treatment under subsequent salinity stress. Acclimatized varieties had differential patterns of Na+ accumulation in the leaf blades because some varieties reduced Na+ accumulation under salinity stress, whereas others did not. Under salt stress, the acclimatized varieties with low Na+ accumulation in the leaf blades highly induced the expression of the OsHKT1;5 gene in the roots, which may contribute to Na+ exclusion from the shoots. On the other hand, the acclimatized varieties with high Na+ accumulation in the leaf blades exhibited higher induction of the OsNHX1 gene, whose gene product participates in the compartmentalization of Na+ into vacuoles. Thus, rice develops different mechanisms of salinity acclimation using two Na+ transport systems, and active regulation of Na+ transport at the transcription level may be involved in the salt acclimation process and enhance salinity tolerance.</abstract><cop>Ireland</cop><pub>Elsevier B.V</pub><pmid>32563456</pmid><doi>10.1016/j.plantsci.2020.110517</doi><tpages>1</tpages></addata></record>
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identifier ISSN: 0168-9452
ispartof Plant science (Limerick), 2020-08, Vol.297, p.110517-110517, Article 110517
issn 0168-9452
1873-2259
language eng
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source MEDLINE; Elsevier ScienceDirect Journals Complete
subjects Acclimatization
Cation Transport Proteins - genetics
Cation Transport Proteins - metabolism
Cation Transport Proteins - physiology
Malondialdehyde - metabolism
Na+ exclusion
Oryza - genetics
Oryza - metabolism
Oryza - physiology
OsHKT1
5
OsNHX1
Plant Proteins - metabolism
Plant Proteins - physiology
Potassium - metabolism
Rice
Salinity
Salt acclimation
Salt Stress
Salt-Tolerant Plants - metabolism
Sodium - metabolism
Transcriptome
title Contribution of two different Na+ transport systems to acquired salinity tolerance in rice
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