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It is hoped that this article will also set a stage for expanded efforts in the identification, characterization, and functional interrogation of plant sirtuins; and the development and exploration of their chemical modulators (activators and inhibitors) in plant research and agriculture. Iron (Fe) is an essential micronutrient for plant life and development. However, in soil, Fe bioavailability is often limited and variable in space and time, thus different regions of the same root system might be exposed to different nutrient provisions. Few studies showed that the response to variable Fe provision is controlled at local and systemic levels, albeit the identity of the signals involved is still elusive. Iron itself was suggested as local mediator, whilst hormones were proposed for the long-distance signalling pathway. Therefore, the aim of this work was to assess whether Fe, when localized in a restricted area of the root system, might be involved in both local and systemic signaling. The combination of resupply experiments in a split-root system, the use of 57Fe isotope and chemical imaging techniques allowed tracing Fe movement within cucumber plants. Soon after the resupply, Fe is distributed to the whole plant, likely to overcome a minimum Fe concentration threshold aimed at repressing the deficiency response. Iron was then preferentially translocated to leaves and, only afterwards, the root system was completely resupplied. Collectively, these observations might thus highlight a root-to-shoot-to-root Fe translocation route in cucumber plants grown on a patchy nutrient substrate. The large-scale untargeted proteomic and metabolomic studies were conducted in strawberry (Fragaria × ananassa) cv. Akihime fruit at five developmental stages. We found that some C6 volatiles highly contributed to the enrichment of volatiles at the red stage of strawberry fruit. We found that 12 genes involved in LOX pathway for volatile biosynthesis showed multiple patterns in protein abundance during fruit development and ripening, and 9 out of the 12 genes exhibited a significant increase in their relative expression levels at the red stage of fruit. We also found that the MYB9 gene (FaMYB9) expression level was positively correlated with the content of C6 volatiles (R = 0.989) and with the relative expression level and protein abundance of FaLOX5 at different strawberry fruit developmental stages (R = 0.954). The interaction between FaMYB9 and FaLOX5 was detected by yeast two-hybrid, co-immunoprecipitation (Co-IP), bimolecular fluorescence complementation (BiFC), and immunofluorescence (IF) analyses. Transient silencing of FaMYB9 delayed the fruit development and ripening, resulting in a significant decrease in the contents of C6 volatiles, while overexpression of FaMYB9 increased the fruit development and ripening and the contents of C6 volatiles in Akihime fruit. Therefore, FaMYB9 is positively involved in C6 volatile biosynthesis. When a plant is attacked by a pathogen, an immune response is activated to help protect it from harm. ERF transcription factors have been reported to regulate immune responses in plants. Here, three ERF transcription factors from Chinese wild Vitis quinquangularis, VqERF112, VqERF114 and VqERF072, are shown to respond to pathogen inoculation by powdery mildew, Pseudomonas syringae pv. tomato (Pst) DC3000 and Botrytis cinerea and to hormone treatments including with ET, SA, MeJA or ABA. Tissue specific expression analysis shows the highest expression levels of VqERF112 and VqERF114 were in mature berries and of VqERF072 was in tendrils. A GUS activity assay indicates that the promoters of VqERF112, VqERF114 and VqERF072 can be induced by powdery mildew inoculation and by hormone treatment, including with ET, SA and MeJA. Overexpression of VqERF112, VqERF114 and VqERF072 in transgenic Arabidopsis enhanced the resistance to Pseudomonas syringae pv. tomato DC3000 (Pst DC3000) and B. cinerea, and it increased the expression of the SA signaling-related genes AtNPR1 and AtPR1 and of the JA/ET signaling-related genes AtPDF1.2, AtLOX3, AtPR3 and AtPR4. Compared to Col-0 plants, the H2O2 accumulation in transgenic Arabidopsis increased after Pst DC3000 inoculation but decreased after B. cinerea inoculation. These results demonstrate that VqERF112, VqERF114 and VqERF072 positively regulate resistance to Pst DC3000 and B. selleck products cinerea. Annexin, a multi-gene family in plants, is essential for plant growth and stress responses. Recent studies demonstrated a positive effect of annexin in abiotic stress responses. Interestingly, we found OsANN10, a putative annexin gene in rice, negatively regulated plant responses to osmotic stress. Knocking down OsANN10 significantly decreased the content of H2O2 by increasing Peroxidase (POD) and Catalase (CAT) activities, further reducing oxidative damage in rice leaves, suggesting a negative regulation of OsANN10 in protecting cell membrane against oxidative damage via scavenging ROS under osmotic stress. V.Nitrogen is one of the main factors that affect plant growth and development. However, high nitrogen concentrations can inhibit both shoot and root growth, even though the processes involved in this inhibition are still unknown. The aim of this work was to identify the metabolic alterations that induce the inhibition of root growth caused by high nitrate supply, when the whole plant growth is also reduced. High nitrate altered nitrogen and carbon metabolism, reducing the content of sugars and inducing the accumulation of Ca2+ and amino acids, such as glutamate, alanine and γ-aminobutyrate (GABA), that could act to replenish the succinate pool in the tricarboxylic acid cycle and maintain its activity. Other metabolic alterations found were the accumulation of the polyamines spermidine and spermine, and the reduction of jasmonic acid (JA) and the ethylene precursor aminocyclopropane-1-carboxylic acid (ACC). These results indicate that the growth root inhibition by high NO3- is a complex metabolic response that involves GABA as a key link between C and N metabolism which, together with plant growth regulators such as auxins, cytokinins, abscisic acid, JA, and the ethylene precursor ACC, is able to regulate the metabolic response of root grown under high nitrate concentrations.