TaNF-YA7-5B, a gene encoding nuclear factor Y (NF-Y) subunit A in Triticum aestivum, confers plant tolerance to PEG-inducing dehydration simulating drought through modulating osmotic stress-associated physiological processes.

Members of nuclear factor-Y (NF-Y) transcription factors play important roles in regulating physiological processes associated with abiotic stress responses. In this study, we characterized TaNF-YA7-5B, a gene encoding wheat NY-YA subunit, in mediating plant adaptation to PEG-inducing dehydration stress. TaNF-YA7-5B shares high similarities to its homologs across various plant species. The TaNF-YA7-5B protein is specified by its conserved domains as plant NF-YA members and targets onto nucleus after endoplasmic reticulum assortment. Yeast two-hybrid assays indicated that TaNF-YA7-5B interacts with TaNF-YB2 and TaNF-YC7, two members of NF-YB and NF-YC subfamilies, suggesting a heterotrimer constituted by TaNF-YA7-5B and above NF-YB and -YC partners. TaNF-YA7-5B displayed induced expression upon drought and whose PEG-inducing dehydration-elevated transcripts were restored under normal recovery condition, suggesting its involvement in plant PEG-inducing dehydration response through modifying transcription efficiency. Overexpressing TaNF-YA7-5B conferred plant improved growth under PEG-inducing dehydration, which was ascribed largely to the gene function in regulating stomata closing and leaf water retention, osmolyte biosynthesis, and cellular ROS homeostasis. The expression of P5CS gene TaP5CS2 and antioxidant enzyme (AE) genes, namely, TaSOD3, TaCAT1, and TaPOD4, was upregulated and downregulated in lines with overexpression and knockdown of TaNF-YA7-5B, respectively; transgene analysis on them validated their functions in positively regulating proline accumulation and ROS scavenging under PEG-inducing dehydration. RNA-seq analysis revealed modified transcription of numerous genes underlying TaNF-YA7-5B enriched by GO terms 'biological process', 'cellular components', and 'molecular function'. Therefore, TaNF-YA7-5B is a crucial regulator for plant drought adaptation through comprehensively integrating diverse physiological processes associated with drought acclimation.

The N uptake-associated physiological processes at late growth stage in wheat (Triticum aestivum) under N deprivation combined with deficit irrigation condition.

Elucidating physiological mechanisms underlying the plant N uptake benefits breeding of high N use efficiency (NUE) crop cultivars. In this study, we investigated the growth and N uptake-associated processes in wheat under N deprivation and deficit irrigation, using two contrasting NUE cultivars. Compared with sufficient-N (SN), deficient-N (DN) treatment reduced plant biomass, N accumulation, and yields in two cultivars (high NUE Shinong 086 and N deprivation-sensitive Jimai 585), suggesting that N deprivation negatively regulates plant growth and N uptake. Shinong 086 was better on growth and N uptake-associated traits than Jimai 585 due to the improved root biomass across soil profile, which was consistent with the decrease of available N contents in soil layers. These results suggested that the improved root system architecture (RAS) enhances plant acquirement for soil N under N- and water-deprivation condition, contributing to the plant N uptake and yield formation capacities. Transcriptome investigation revealed that numerous genes were differentially expressed (DE) in the N-deprived Shinong 086 plants, which involve the regulation of complicate biochemical pathways. These results suggested that the modified RAS and N uptake in high NUE plants are accomplished underlying the regulation of numerous DE genes. TaWRKY20, a gene in ZFP transcription factor family, was functionally characterized for the role in mediating plant N uptake. Overexpression of it conferred plants improved growth and N uptake under DN due to its regulation on TaNRT2.1 and TaNRT2.2, two nitrate transporter genes. Our investigation provides insights in high NUE mechanisms in wheat under N deprivation.