Search Results (5)

Different movement patterns are crucial behavioral motifs of plant organisms for reaching essential resources necessary for survival. This requires the accurate evaluation (interpretation) of information inputs regarding (i) abiotic factors such as gravity, light, and water; (ii) neighboring plants; (iii) various beneficial symbionts, including fungi and soil bacteria, as well as pests, which involve attack and defense strategies; and (iv) intraorganismic communication, including transcription, translation, immunity, repair, and epigenetic markings relevant to all regulation processes, finally outlined by a plethora of non-coding RNAs. The coordination of all steps and substeps in plant growth and development necessitates a complex organization of various levels of signaling processes within and between cells, tissues, organs, and organisms. Consequently, we can view a plant body as a coordinated entity that integrates these processes to thrive, representing a unique identity within its environmental niche. Full article

Aquaporins are transmembrane proteins that mediate the transport of water, as well as various ions and molecules. In plants, they play a critical role in numerous processes, including stress adaptation, nutrition, cellular communication, and transpiration. Therefore, understanding the function and interactions of these proteins with others—known as interactomes—is of significant agronomic and biological interest. This study aims to analyse the interactome of all aquaporins in Arabidopsis thaliana L. using two distinct databases, STRING and BioGRID. After analysing both interactomes, a wide range of interactions were identified between each aquaporin and a diverse array of proteins, including nutrient transporters for ammonium, potassium, phosphorus, sulphur, copper, and sugars; proteins related to responses to abiotic stresses; proteins mediating vesicle membrane fusion, such as synaptobrevins and syntaxins; ubiquitinases; kinases; and other transmembrane proteins. These extensive connections further underscore the critical importance of aquaporins in numerous biological processes, positioning them as central modulators and integration points for cellular and systemic responses in plants. Full article

Plants are directly exposed to several biotic factors. Among these, mite species belonging to the superfamilies Eriophyoidea and Tetranychoidea stand out due to their ability to injure or even transmit viruses to their host plants. In response to infestations by these organisms, reactive oxygen species (ROS), regulated by enzymatic and non-enzymatic antioxidants (homeostasis), can act as signaling molecules to induce defenses or even acclimatization in attacked plants. However, depending on the severity of the stress, there can be an imbalance between ROS and antioxidants that can result in oxidative stress, leading to membrane damage by lipid peroxidation, organelle inactivation, and even cell death. In this review, we outline for the first time the current state of understanding regarding the role of cellular processes in ROS metabolism, such as signaling, the potential damage induced by ROS, and the defense role of enzymatic antioxidant systems involved in the plant–mite relationship. Furthermore, we identify several gaps between redox metabolism and plant defense against phytophagous mites. Full article

Ca²⁺ and H₂O₂ interact with each other to regulate plant systemic responses. However, their precise mechanism is not fully understood. A recent study revealed that the Ca²⁺ regulates the glycolate oxidase-catalase (GC) switch-mediated photorespiratory H₂O₂ during wounding. Glutamate-receptor-like (GLR) Ca²⁺ channels (GLR 3.3 and GLR3.6) are responsible for Ca²⁺ influx during injury for regulation of the GC switch. Mechanical injury quickly shifts the GC switch to a highly interactive state in the systemic leaves that ultimately results in the reduced peroxisomal H₂O₂. However, the mechanism of H₂O₂ reduction in peroxisome remains elusive. Full article

Isoprene, a lipophilic and unstable compound with the chemical formula C5H8, is transported to plant chloroplasts via the 2-C-methyl-d-erythritol 4-phosphate (MEP) pathway, which relies on photosynthesis. Although only about 20% of terrestrial plants can synthesize isoprene, those that emit it are more adaptable to oxidative and thermal stresses. To shed light on the still-elusive protective mechanism of isoprene, numerous investigations have been conducted. Isoprene has been shown to react with and quench various reactive oxygen species (ROS) such as singlet oxygen (1O2). Its reduced state and conjugated double bonds suggest that it functions as an antioxidant, although this has yet to be conclusively proven. Despite its low abundance relative to other molecules in plant tissues, recent research has explored several potential roles for isoprene including acting as a scavenger of ROS by serving as an antioxidant; strengthening cell membranes; modulating genomic, proteomic and metabolomic profiles; signaling stress responses among neighboring plants compared with other volatile organic compounds (VOCs); regulating metabolic fluxes of hormones produced through the MEP pathway; or even functioning as a free developmental hormone. Future prospective studies, such as identifying the specific receptors for VOCs along with transcription factors (TFs) and other regulatory proteins participating in the signaling pathways and also metabolomic, transcriptomic and physiological analyses could help in comprehending VOC-induced defense responses in plants under stress conditions. Full article