Abstract
NF-YAs play important roles in abiotic stress. However, their characteristics and functions in abiotic stress of poplar, a model woody plant, have not been fully investigated. Here, the biological functions of PtNF-YA9 (Potri.011G101000), an NF-YA gene from Populus trichocarpa, were first fully investigated. PtNF-YA9 is located in the nucleus. The expression of PtNF-YA9 was reduced by mannitol, NaCl, and abscisic acid (ABA). The GUS staining of ProNF-YA9::GUS transgenic lines was also reduced by mannitol treatments. In the PtNF-YA9-overexpressed Arabidopsis (OxPtNA9), OxPtNA9 lines exhibited sensitivity to simulated drought, ABA, and salinity stress during germination stage, and growth arrest emerged at post-germination stage. These phenomena might involve the ABA signaling pathway via the regulation of ABI3, ABI4, and ABI5. At vegetative stages, OxPtNA9 lines decreased in water loss via promoting stomatal closure and displayed high instantaneous water-use efficiency (WUE) of the leaf to exhibit enhanced drought tolerance. Furthermore, OxPtNA9 lines exhibited long primary root in the half-strength Murashige–Skoog agar medium supplemented with NaCl and conferred strong tolerance in the soil under salt stress. Additionally, PtNF-YA9 exhibited dwarf phenotype, short hypocotyl, small leaf area and biomass, delayed flowering, and increased chlorophyll content. Above all, our research proposes a model in which PtNF-YA9 not only plays a key role in reducing plant growth but also can play a primary role in the mechanism of an acclimatization strategy in response to adverse environmental conditions.
Highlights
Plants are usually subjected to various abiotic challenges from the environment, especially in extreme temperature, high salinity, and long-term drought
The results showed that the expression levels of ABI3, ABI4, and ABI5 were significantly elevated under 300 mM mannitol, 100 mM NaCl, and 0.5 μM abscisic acid (ABA) at germination stage (Figure 4F)
We have demonstrated that PtNF-YA9 plays an important role in the regulation of drought stress in Arabidopsis via the ABAmediated signaling pathway
Summary
Plants are usually subjected to various abiotic challenges from the environment, especially in extreme temperature, high salinity, and long-term drought. With the development of biotechnology, Multifunctional Analysis of P. trichocarpa PtNF-YA9 the identification and application of genetic transformation technology to enhance stress tolerance of plants are essential for screening and breeding new resistant plants (Valliyodan and Nguyen, 2006). In terms of gene regulation, transcription factor families (Zhu, 2002), including NAC (Lu et al, 2017), MYB (Wei et al, 2017), AP2/ERF (Ahn et al, 2017), bHLH (Dong et al, 2014), and WRKY (Jiang et al, 2014), all play significant roles in regulating the expression level of functional genes to enhance drought tolerance. Many studies have investigated the identification and application of transcription factors in plant genetic engineering to increase plant resistance
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