06206nam 2201681z- 450 991074327190332120230911(CKB)5690000000228589(oapen)doab113884(EXLCZ)99569000000022858920230920c2023uuuu -u- -engurmn|---annantxtrdacontentcrdamediacrrdacarrierPlant Responses to Biotic and Abiotic Stresses: Crosstalk between Biochemistry and EcophysiologyMDPI - Multidisciplinary Digital Publishing Institute20231 online resource (362 p.)3-0365-8400-5 Amid challenging environmental conditions throughout their life cycle, plants display an extraordinary ability to sense, process, and respond to a diverse array of stimuli with adaptability. The complexity of their stress responses unfolds across various levels-physiological, biochemical, transcriptomic, and cellular-demanding a profound comprehension of the intricate mechanisms at work. These stresses intertwine, triggering cellular damage and initiating a cascade of responses within plants. Critical growth phases under severe stress encounter mechanical damage and alterations in cellular macromolecule synthesis. While plants possess inherent defense mechanisms against oxidative damage, excessive oxygen production overwhelms their detoxification capacity, leading to detrimental reactions like loss of osmotic responsiveness, wilting, and necrosis. This reprint undertakes a comprehensive analysis, exploring multiple perspectives such as gas exchange, metabolomics, proteomics, isotopic, and genomic approaches, to unveil the drivers and specific strategies that empower plants to adapt to stressful growth conditions. By examining trait selection, phenotypic plasticity, and other factors, this reprint uncovers the physiological and molecular mechanisms underlying plant resilience amidst adversity. A valuable resource for scientists, academics, and professionals, this reprint unveils the mysteries of plant resilience and productivity, fostering innovative strategies for sustainable agriculture in our ever-changing world.Plant Responses to Biotic and Abiotic StressesBiology, life sciencesbicsscResearch and information: generalbicsscabiotic stressAcacia melanoxylonagronomical managementalkaline soilsallelochemicalsallelopathic potentialalpha-lipoic acidalveographic parametersantioxidantantioxidant capacityantioxidant enzymesantioxidant systemantioxidantsArachis hypogaeaArbuscular mycorrhizal fungibenzoquinonebioactivebiocharbiochemical traitsbioethanolbiomassC and N cyclingCadmiumCamellia oleiferacanopy temperaturechemical compositionChenopodium quinoachlorophyll florescencechlorophyll fluorescencecropping patterncropping systemscysteinedegradationdesertdroughtelementsfatty acidsflavonoidfood securityfunctional plant traitsgenotypesgrain qualitygrain yieldgrowth parametersheat stressheavy metalHordeum vulgareHPLC seedling growth FlavonoidesHSPsintercroppingion homeostasisirrigatedisotope ecologyisotopic compositionLactuca sativaLathyrus odoratuslignin metabolismlodging tolerancelowland ricemicrobesn/aNa+/H+ antiportersnitric oxidenitrogenomicsosmolytesoxidative damageparacetamolphenolphenolicsphotosynthesisphotosynthetic efficiencyphotosynthetic pigmentsphotosystem IIphytochemistryprolineQTLsreactive nitrogen speciesreactive oxygen speciesresistance genesricesaline water stresssalinitysalinity stresssalt stresssalt toleranceseawaterseed primingseed yieldsilvicultural methodsSiNPssoil healthsoil nutritional statussoil qualitysorgoleonespinachstable isotopestable isotope composition of carbon and nitrogenstay greenstress indicesstress tolerancesustainable productionterminal water stressTriticum aestivum L.vegetation typewater deficit conditionswater soluble carbohydrateswater stressweed suppressionwheatyieldyield stabilityZea mays L.Biology, life sciencesResearch and information: generalBOOK9910743271903321Plant Responses to Biotic and Abiotic Stresses: Crosstalk between Biochemistry and Ecophysiology3560517UNINA