GA Mediated OsZAT-12 Expression Improves Salt Resistance of Rice

Imran, Qari Muhammad; Kamran, Muhammad; Shafiq‐ur‐Rehman,; Ghafoor, Abdul; Falak, Noreen; Kim, Kyung–Min; Lee, In‐Jung; Yun, Byung-Wook; Jamil, Muhammad

doi:10.17957/ijab/15.0090

Cited by 9 publications

(5 citation statements)

References 29 publications

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“…Greater shoot fresh and dry biomass was observed in Pirsabak-05 and Lalma-13 (tolerant varieties), in comparison with lowest shoot fresh and dry of variety Uqab-00 (salt sensitive). The low magnitude of light interception due to high salt stress was due to physiological drought (Imran et al, 2016). This study has confirmed that seed priming has enhanced shoot fresh and dry weight in both normal and saline growth environment.…”

Section: Discussionsupporting

confidence: 68%

Response of wheat varieties to salinity stresses as ameliorated by seed priming

Khan¹,

Shafi²,

Bakht³

et al. 2019

PAK.J.BOT.

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Salinity is the most detrimental stress which severely inhibits development of all cultivated crops. In this experiment salinity tolerance of fourteen wheat varieties were assessed with seed priming (50 mM CaCl2) and four levels of (NaCl) salinity (0, 45, 90, 135 mM). The results revealed that effects of salinity and seed priming was significant (p≤0.05) on root length, shoot and root fresh weight, shoot and root dry weight, shoot and root Na + content. Pirsabak-05 variety has produced maximum root length (24.12 cm), shoot dry weight plant -1 (2.08 g), root fresh and dry weight plant -1 (2.36 vs 0.47g). Maximum shoot fresh weight plant -1 (8.61 g) was recorded from Lalma-13. Highest root to shoot ratio was observed in wheat variety Insaf-15. Among all wheat varieties, Uqab-00 variety has accumulated highest shoot and root Na + content (1.31 vs 2.58 mg g -1 dry weight). The seed priming has enhanced root length, shoot and root fresh weight, shoot and root dry weight except shoot and root Na + content. Wheat varieties Pirsabak-05, Lalma-13 and Insaf-15 were more responsive to seed priming compared with Uqab-00 and Seher-06. It is concluded that wheat varieties Pirsabak-05, Lalma-13 and Insaf-15 were more tolerant to salinity compared with other varieties.

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Section: Discussionsupporting

confidence: 68%

Response of wheat varieties to salinity stresses as ameliorated by seed priming

Khan¹,

Shafi²,

Bakht³

et al. 2019

PAK.J.BOT.

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“…Zat12 has not been isolated in bread wheat up to our knowledge, while the homologous gene in rice, OsZat12 , was identified (Imran et al ., ). Using OsZat12 as a query sequence, TaZat12 was found in the newly released wheat genome (Table S1).…”

Section: Resultsmentioning

confidence: 97%

TaCYP81D5, one member in a wheat cytochrome P450 gene cluster, confers salinity tolerance via reactive oxygen species scavenging

Wang

Yuan

Qin

et al. 2019

Plant Biotechnology Journal

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Summary As one of the largest gene families in plants, the cytochrome P450 monooxygenase genes (CYPs) are involved in diverse biological processes including biotic and abiotic stress response. Moreover, P450 genes are prone to expanding due to gene tandem duplication during evolution, resulting in generations of novel alleles with the neo‐function or enhanced function. Here, the bread wheat (Triticum aestivum) gene TaCYP81D5 was found to lie within a cluster of five tandemly arranged CYP81D genes, although only a single such gene (BdCYP81D1) was present in the equivalent genomic region of the wheat relative Brachypodium distachyon. The imposition of salinity stress could up‐regulate TaCYP81D5, but the effect was abolished in plants treated with an inhibitor of reactive oxygen species synthesis. In SR3, a wheat cultivar with an elevated ROS content, the higher expression and the rapider response to salinity of TaCYP81D5 were related to the chromatin modification. Constitutively expressing TaCYP81D5 enhanced the salinity tolerance both at seedling and reproductive stages of wheat via accelerating ROS scavenging. Moreover, an important component of ROS signal transduction, Zat12, was proven crucial in this process. Though knockout of solely TaCYP81D5 showed no effect on salinity tolerance, knockdown of BdCYP81D1 or all TaCYP81D members in the cluster caused the sensitivity to salt stress. Our results provide the direct evidence that TaCYP81D5 confers salinity tolerance in bread wheat and this gene is prospective for crop improvement.

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“…Consequently, these low‐diversity regions may be the result of purifying selection, and may include genes required for specific adaptation to Southeast Asian conditions. According to RAP‐DB (Sakai et al, 2013) and Rice SNP‐Seek (Mansueto et al, 2017) databases, only two known genes reside in the low‐diversity region of Chr 1: OsFBX7 encoding an F‐box containing protein (Hsu et al, 2004), and ZOS1 encoding a C2H2 zinc‐finger protein (Imran et al, 2016; Supplemental Table S5). The known gene RICE FLOWERING LOCUS T1 ( RFT1 ; Komiya et al, 2008) is present in the low‐diversity region of Chr 6 (Supplemental Table S5).…”

Section: Resultsmentioning

confidence: 99%

Profiling SNP and Nucleotide Diversity to Characterize Mekong Delta Rice Landraces in Southeast Asian Populations

et al. 2019

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The Plant Genome R ecent advances in genomic analysis methods can be exploited to shed light on the genetic diversity of various crops, not only that of representative major resources, known as core collections (Gepts, 2006; Phan et al., 2019; Wang et al., 2014), but also minor resources in local collections not yet thoroughly characterized. Such evaluation of crop plant genomic structures may reveal useful resources and/or unique characteristics hidden in local collections (Hermisson and Wagner, 2004;

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GA Mediated OsZAT-12 Expression Improves Salt Resistance of Rice

Cited by 9 publications

References 29 publications

Response of wheat varieties to salinity stresses as ameliorated by seed priming

Response of wheat varieties to salinity stresses as ameliorated by seed priming

TaCYP81D5, one member in a wheat cytochrome P450 gene cluster, confers salinity tolerance via reactive oxygen species scavenging

Profiling SNP and Nucleotide Diversity to Characterize Mekong Delta Rice Landraces in Southeast Asian Populations

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