Altitude variation in chilling tolerance among natural populations of <Emphasis Type="Italic">Elymus nutans</Emphasis> in the Tibetan Plateau

Low temperatures limit plant growth, development, and reproductive success. A series of complex adaptive responses in plants evolved to withstand this environmental challenge. Here, eight accessions of Elymus nutans, which originated in Tibet at altitudes between 3720 and 5012 m above sea level, were used to identify heritable adaptations to chilling stress. Dynamic responses of phytohormone, sugar, and gene expression levels related to chilling tolerance were analyzed. During the initial stage of chilling stress (0–24 h), some high-altitude E. nutans accessions exhibited rapid increases in abscisic acid (ABA), jasmonic acid (JA), and zeatin content. This coordinated with decreases in the levels of auxin (IAA), salicylic acid (SA), gibberellins (GA), and the ethylene precursor 1-aminocyclopropane-1-carboxylic acid (ACC). EnCBF9 and EnCBF14 expression in the high-altitude accessions, Baqing, Xainza, Damxung, and Ali, increased within 1 h of chilling exposure, while chilling induction of EnCOR14a was detected after 3 h of chilling stress. Accessions from high altitudes displayed an increased sucrose and raffinose accumulation and a reduced degradation of chlorophyll under chilling stress. After 24–120 h of chilling exposure, plant adaptation to the chilling treatment was associated with a lower accumulation of ABA and moderate rise of zeatin, IAA, GA, ACC, SA, and JA. EnCBF9, EnCBF14, and EnCOR14a genes were down-regulated during the late stage of chilling stress. Taken together, the dynamic responses of phytohormones and sugars, and the higher expression of the EnCBFs and EnCOR genes play critical roles in the acclimation to chilling in high-altitude accessions of E. nutans, thereby allowing them to achieve higher chilling tolerance.     

MicroRNAs in durum wheat seedlings under chronic and short-term nitrogen stress

Nitrogen is an essential macronutrient for plant growth and reproduction. In durum wheat, an appropriate nitrogen soil availability is essential for an optimal seed development. miRNAs contribute to the environmental change adaptation of plants through the regulation of important genes involved in stress processes. In this work, nitrogen stress response was evaluated in durum wheat seedlings of Ciccio and Svevo cultivars. Eight small RNA libraries from leaves and roots of chronically stressed plants were sequenced to detect conserved and novel miRNAs. A total of 294 miRNAs were identified, 7 of which were described here for the first time. The expression level of selected miRNAs and target genes was analyzed by qPCR in seedlings subjected to chronic (Ciccio and Svevo, leaves and roots) or short-term (Svevo roots) stress conditions. Some miRNAs showed an immediate stress response, and their level of expression was either maintained or returned to a basal level during a long-term stress. Other miRNAs showed a gradual up- or downregulation during the short-term stress. The newly identified miRNA ttu-novel-106 showed an immediate strongly downregulation after nitrogen stress, which was negatively correlated with the expression of MYB-A, its putative target gene. PHO2 gene was significantly upregulated after 24–48-h stress, corresponding to a downregulation of miR399b. Ttu-miR399b putative binding sites in the 5′ UTR region of the Svevo PHO2 gene were identified in the A and B genomes. Both MYB-A and PHO2 genes were validated for their cleavage site using 5′ RACE assay.