The WRKY transcription factor (TF) belongs to one of the major plant protein superfamilies. The WRKY TF gene family plays an important role in the regulation of transcriptional reprogramming associated with plant stress responses. Change in the expression patterns of WRKY genes or the modifications in their action; participate in the elaboration of numerous signaling pathways and regulatory networks. WRKY proteins contribute to plant growth, for example, gamete formation, seed germination, post-germination growth, stem elongation, root hair growth, leaf senescence, flowering time, and plant height. Moreover, they play a key role in many types of environmental signals, including drought, temperature, salinity, cold, and biotic stresses. This review summarizes the current progress made in unraveling the functions of numerous WRKY TFs under drought, salinity, temperature, and cold stresses as well as their role in plant growth and development.
Cold and freezing stress is one of the most harmful environmental stresses, especially in temperate and subtropical areas, that adversely affects plant growth, development, and yield production. Betula platyphylla Sukaczev, also known as white birch, is one of the most valuable, important, and widely distributed tree species in East Asia. This study explored the effects of cold acclimation (CA) in reducing the destructive effect of freezing stress in B. platyphylla seedlings. We measured the physiological and biochemical characteristics of B. platyphylla seedlings, such as chlorophyll content, electrolyte leakage (EL), malondialdehyde (MDA), antioxidant enzymes (such as superoxide dismutase (SOD), peroxidase (POD), and catalase (CAT)), and proline content before and after freezing stress to observe the contribution of CA in reducing the detrimental effects of freezing stress. The results showed that CA increased physiological and biochemical characteristics of B. platyphylla seedlings before and after freezing stress, except for chlorophyll content. Antioxidant enzymes were significantly positively correlated with proline, MDA, and EL content, and negatively correlated with chlorophyll content. Moreover, histochemical detection (H2O2 and O2−) and cell death were revealed to be induced by cold stress in B. platyphylla seedlings. Furthermore, it was revealed that increased time and decreased temperature of the CA process significantly influenced the physiological and biochemical parameters. Overall, the CA process significantly reduced the detrimental effects of freezing stress compared to the control treatment in B. platyphylla seedlings. Taken together, these findings provide beneficial information toward understanding the mechanism of CA and freezing stress in B. platyphylla. Furthermore, the substantial activity of physiological and biochemical results could be used as selection criteria for screening time and temperature points of cold/freezing stress in further omics analyses. In addition, the combination of current study results, further omics analyses, and genetic engineering techniques directly contribute to sustainable forest management systems, tree plantations, and conservation of tree species, especially non-cold/non-freezing tolerant tree species.
Plants comprise an expanded endomembrane system, and transport within the network requires well-organized and accurate vesicle transport. Tethering complexes facilitate the early, exact contact among donor and acceptor membranes, operate to bring vesicles into a closer proximity for trans-SNARE complex assembly docking; these are classified as either long coiled-coil proteins or multi-subunit tethering complexes (MTCs). Numerous MTCs that function at different membrane trafficking steps have been recognized, where they function as significant interfaces between SNARE proteins, Rabs, and phosphoinositides. SNARE proteins assemble into complexes that catalyze the fusion between a donor and a target membrane. Studies of the diverse SNARE proteins provided further valuable information about vacuole biogenesis and vacuolar trafficking pathways related to cell-type specificity, plant development, growth, and the plant developed a specific traffic route to overcome environmental stress. In conclusion, tethers' selective recruitment during membrane fusion is controlled via diverse small GTPases, such as those in the RAB family. The MTCs promote SNARE complex assembly by direct interactions of MTC subunits with Q-SNAREs. A subset of MTC subunits exploits structurally similar CATCHR domains to mediate inter-subunit interactions as well as SNARE protein interactions. MTCs are subdivided into CATCHR (complexes associated with tethering containing helical rods: Dsl1, COG, GARP, EARP, and exocyst) and non-CATCHR (TRAPP I, II and III, HOPS and CORVET) complexes based on the structure of their subunits. This review summarized new information about SNARE proteins and tethering complexes, highlight new insights about their function, and discuss current debates and future perspectives.Recent Advances in Synergy Among SNARE Proteins and Multi-Subunit Tethering Complexes (MTCs) 3
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