01400nam--2200421---450-99000034969020331620060901124743.00034969USA010034969(ALEPH)000034969USA01003496920010306d1978----km-y0itay0103----baengDE||||||||001yyOperating systemsan advanced courseM.J. Flynn ...<et al.>edited by R, Bayer, R.M. Graham and G. SeegmullerBerlinSpringer1978X, 593 p.ill.24 cmLecture notes in computer science60The advanced course on operating systems was held at the Technical University in Minich from July 28 to August 5, 19772001Lecture notes in computer science60001-------2001001.64GRAHAM,R.M.SEEGMULLER,ITsalbcISBD990000349690203316001 LNCS 603192001 LNCS00101378BKSCIPATTY9020010306USA011458PATTY9020010306USA01145920020403USA011643PATRY9020040406USA011624PATRY9020060901USA011246PATRY9020060901USA011247Operating systems334589UNISA05001nam 2201453z- 450 991105321890332120230911(CKB)5690000000228621(oapen)doab113939(EXLCZ)99569000000022862120230920c2023uuuu -u- -engurmn|---annantxtrdacontentcrdamediacrrdacarrierStrategies for Tree Improvement under Stress ConditionsMDPI - Multidisciplinary Digital Publishing Institute20231 online resource (306 p.)3-0365-8494-3 Perennial woody plants usually face multifactorial adverse conditions during their long lifespan, which impairs their growth and productivity. To cope with these adverse conditions, trees deploy morphyological, physiological and molecular responses to adapt to the environmental constraints. By using high-throughput sequencing and bioinformatic approaches, many hub genes that are involved in stress response were identified. In recent years, with the advantages of transgenic technology in woody plants, many candidate genes participating in stress responses were functionally characterized and showed great potential for tree improvement under different stresses. On the other hand, cultivation strategies (including beneficial microorganism investigation, beneficial microorganism inoculation, mixed forest and so on) also play crucial roles in tree improvement under abiotic and biotic stress.Biology, life sciencesbicsscResearch & information: generalbicsscabscisic acidantioxidant enzyme activityantioxidant enzymesaquaporinsarbuscular mycorrhizal fungi (AMF)auxinauxin response factorsbiomassboron deficiencyCamellia oilCamellia oleiferachlorophyllchlorophyll fluorescenceclimatic factorsCunninghamia lanceolatadrip fertigationdroughtdrought toleranceepigeneticsexpression analysisfatty acidfertilizationfine root traitsfine-root distributionfoliar fertilizergas exchangegenegene regulationgenetic effectgraftingHibiscus hamabo Sieb. et ZuccHibiscus syriacus Linn.hormone treatmenthydraulic characteristicsidentificationJuglans regiaLoess PlateauMaTCP transcription factormicronutrientsmorphological characteristics of root systemmulberryn/aNaCl stressnitrogen formsnutrient-pooroptimized furrow fertilizationorgan-specificoxidative stressPaulownia fortuneipecanphotosynthesisphotosynthetic ratephysiological parametersphysiologyphytoremediationplant-available waterpoplarpoplar plantationPopulus × euramericanaPopulus × hopeiensis Hu & ChowPP2C familyPtrWRKY51qRT-PCRregulationRobinia pseudoacaciaroot architectureroot developmentroot morphologyROS scavengingSalixSalix matsudanasalt stresssalt tolerancesalt tolerance genesalt tolerance indexSantalum album L.Schima superbascion growthsecondary metabolismsecondary metabolitessexual dimorphismsiblingssoil contaminationsoil nitrogenSpsNAC005 genestress tolerancetranscription factortranscriptometranscriptome sequencingvariationwalnut oilwater deficitwater-use efficiencywhole-genome bisulfite sequencing (WGBS)zinc stressBiology, life sciencesResearch & information: generalBOOK9911053218903321Strategies for Tree Improvement under Stress Conditions4525338UNINA