00973nam--2200337---450 99643765360331620210928163527.00-8153-4024-9000332268USA01000332268(ALEPH)000332268USA0100033226820091001d2008----km-y0itay50------baengUSa---||||001yyUnderstanding bioinformaticsMarketa Zvelebil and Jeremy BaumLondon and New YorkRoutledge2008797 p.ill.28 cmBioinformaticaApplicazioniBNCF574.0285ZVELEBIL,Marketa606031BAUM,Jeremy606032ITsalbcISBD996437653603316574.028 ZVE 1 b24251 Ing.574.02800334474BKTECRSIAV79020091001USA011550Understanding bioinformatics1121228UNISA10558nam 2203673z- 450 991105319200332120230911(CKB)5690000000228620(oapen)doab113915(EXLCZ)99569000000022862020230920c2023uuuu -u- -engurmn|---annantxtrdacontentcrdamediacrrdacarrierPlant Biotic and Abiotic StressesVolume IIMDPI - Multidisciplinary Digital Publishing Institute20231 online resource (526 p.)3-0365-8539-7 Plants under natural conditions often face multiple stresses, including drought, salinity, temperature extremes, submergence stress, bacteria, viruses, fungi, insects, etc. These biotic and abiotic stresses negatively influence plant growth and productivity. Various approaches have recently been used to overcome stresses in plants. It is necessary to evaluate and explore how diverse molecular techniques can be applied to different biological studies to improve biotic and abiotic stress tolerance in plants. This will help reduce production losses and increase crop tolerance to various stresses. It is now the time to make a difference by developing plants that can withstand biotic and abiotic stresses.Biology, life sciencesbicsscResearch & information: generalbicsscabiotic and biotic stressabiotic stressabiotic stressesactinobacteriaadaptationadditiveaerobic riceAl-induced PCDAlgeriaallelopathyalternative plant vitrification solutionAMFammonium-free mediumantagonistic and synergic effectsantioxidant activityantioxidant enzymesantioxidant systemantioxidantsantioxidative protectionArabidopsis thalianaarbuscular mycorrhizal fungiarchivesarid regoinsartificial lightascorbateAspergillus nigerauxinsaxillary budBactrocera oleaeBAG (Bcl-2-associated anthanogene) family proteinsbio-fertilizerbiofertilizersbiostimulantsbiotic stressbotanical collectionBotrytis fabaeBrassicaceaebrassicalesbread wheatBt toxinsC4 speciescadmium stresscallus cellscandidate genesCandidatus Liberibacter asiaticuscell wall extensibilitycell wall polysaccharidecentellaChenopodium quinoa Willd.chickpeachicorychilli fruit rotchitinasechitosanchlorophyll a fluorescence transientchlorophyll fluorescencechlorophyll fluorescence efficiencychlorophyllschocolate spot diseaseCicer arietinum L.circadian clockclimate changeclimate changescold stresscoleoptileColletotrichum scovilleiColletotrichum truncatumcombined stressescommon centaurycomprehensive controlconventional breedingCopper hyperaccumulationcorn smutcottonCRISPRcrop improvementcrop productivitycrop residuesCry1Ah1 transgenic poplarcytotoxicitydehydration-responsive element binding (DREB) transcription factorsDendrobium catenatumdesertificationdifferent MS salts concentrationdisease gradientdisease outbreakdispersal ecologydistributiondroplet-vitrificationdroughtdrought stressdrought tolerancedrought tolerant genotypesecologyecotypesEDTA and IAAendangered speciesenvironmentenzyme activityexpression patternexpression profilefaba beanfungus infectionFusarium oxysporumFusarium wiltgene expressiongene familygenome-widegenomicsgenotypesglucosinolatesglutathioneGlycine max L.Greecegrowth attributesgrowth inhibitiongrowth parametersgrowth-promoting fungihalophytesheat shock protein 20heterozygosityhigh temperaturehormoneshydrogen peroxideinulinionic attributesionic homeostasisjewel sweet potatokaolinlandscapelate embryogenesis abundant proteinlead (Pb)leaf gas exchangelipaseliquid bio-formulationliquid overlaymaizemalondialdehydeMalus seedlingsMASMDAmega nucleasesmelatoninmembrane damagemetabolic responsesmetabolites variationmetabolomicsmetabolomics and proteomicsmicrobiotamicroorganismsmicropropagationmilk thistlemolecular breedingmolecular chaperonemolecular makersmolecular markersmossesmulti-omicsNa+ contentNaCl treatmentsnatural farmingnitrilesnon-thermal plasmanutritionoilseedsorganic amendmentsorganic olivicultureorthogrouposmolyteosmoprotectorosmotic regulationoxidative stressP-deficientpapaya (Carica papaya)pathogenpeanutpearl milletPGPBsPGPRphenolic compoundsphenolicsphosphorus utilizationphotoperiodismphotosynthesisphotosynthetic responsesphylogeneticphysical factorsphysiological and biochemical analysisphysiological and biochemical traitsphysiological changesphysiological traitsphytostimulatorPKS5plant defenseplant epidemicplant growth promotionplant growth regulatorsplant performanceplant protectionplant stressesplant tolerancepost-translational modificationpotassiumPR proteinspre-rebellion periodprimingprofitabilityprolineprotein banding and anatomyproteomic analysisPucciniaqRT-PCRQTLsqualityreactive oxygen speciesredox implicationsregrowth mediumRhizobium leguminosarumrhizospherericeRNA sequencingRNSROSRSSSaharasalinitysalinity stressscreen houseseaweedsecondary metabolitesselection indicesshoot tipsignal transduction and stressed conditionssignalingsignaling pathwaysmutsodium nitroprussidesoil biologysoil enzymessoil fertilitysoil layerssoil microorganismssorghumsoybeanspinosadSSRsstomatal apertureStreptomyces tuirusstress mitigationstress tolerancestressful conditionssugarcanesunflowersurveillancesustainabilitysustainableTALENTLPtolerancetomatototal flavonoidtranscriptomicstransgenic linestransient soil salinityTripolium pannonicumTriticum aestivum L.vermicompostvirus-induced gene silencingVOCswater loggingwheatwheat stripe rustwiltingwithin-plant phenotypic plasticityWRKYyeast-one-hybridyieldZFNzincβ-1,3-glucanaseBiology, life sciencesResearch & information: generalBOOK9911053192003321Plant Biotic and Abiotic Stresses4524625UNINA