01043nam a22002531i 450099100191981970753620040305112515.0040407s1935 fr |||||||||||||||||fre b12843271-39ule_instARCHE-082289ExLDip.to Scienze StoricheitaA.t.i. Arché s.c.r.l. Pandora Sicilia s.r.l.230.41Vignaux, Paul159234Luther commentateur des sentences :livre 1., distinction 17. /par Paul VignauxParis :J. Vrin,1935112 p. ;26 cmÉtudes de philosophie médiévale ;21Pietro :Lombardo.Libri sententiarum.L.1.Dis. 17.Commento di Martin Lutero.b1284327102-04-1416-04-04991001919819707536LE009 MSM VII Coll. 8/2112009000188044le009-E0.00-no 00000.i1339791616-04-04Luther commentateur des sentences297950UNISALENTOle00916-04-04ma -frefr 0105348nam 22015973a 450 991036775530332120250203235433.09783039215157303921515910.3390/books978-3-03921-515-7(CKB)4100000010106164(oapen)https://directory.doabooks.org/handle/20.500.12854/56239(ScCtBLL)49f713bf-8812-4018-b798-26a5d4b9bd97(OCoLC)1163826642(oapen)doab56239(EXLCZ)99410000001010616420250203i20192019 uu engurmn|---annantxtrdacontentcrdamediacrrdacarrierPhysiological Responses to Abiotic and Biotic Stress in Forest TreesAndrea Polle, Heinz RennenbergMDPI - Multidisciplinary Digital Publishing Institute2019Basel, Switzerland :MDPI,2019.1 electronic resource (294 p.)9783039215140 3039215140 As sessile organisms, plants have to cope with a multitude of natural and anthropogenic forms of stress in their environment. Due to their longevity, this is of particular significance for trees. As a consequence, trees develop an orchestra of resilience and resistance mechanisms to biotic and abiotic stresses in order to support their growth and development in a constantly changing atmospheric and pedospheric environment. The objective of this Special Issue of Forests is to summarize state-of-art knowledge and report the current progress on the processes that determine the resilience and resistance of trees from different zonobiomes as well as all forms of biotic and abiotic stress from the molecular to the whole tree level.History of engineering and technologybicsscpure standsion relationHeterobasidion annosumsalicylic acidantioxidant enzymesantioxidant activityLuquasorbintrinsic water-use efficiencyGreecePinus koraiensis Sieb. et Zucc.ion homeostasisphotosynthesisPinus massonianaStockosorbwater relationsNorway sprucerubber treehydrophilic polymersdrought stression relationshipsCarpinus betulustree ringsN nutritiondisturbancePopulus simonii Carr. (poplar)infectionsubcellular localizationbasal area incrementmixed standsphotosynthetic responsesAleppo pinewater potentialelevation gradientliving cellphysiological responseantioxidant enzyme activityion contentssignal networkexpressionsoil NGA-signaling pathwaydifferentially expressed genesCa2+ signalclimateecophysiologyRobinia pseudoacacia L.Heterobasidion parviporummid-termplant tolerancecanopy conductanceDELLAtapping panel drynessosmotic adjustment substancesabiotic stresswood formationmalondialdehydesalinity treatmentsorganic osmolytesbamboo forestnon-structural carbohydrateAbies alba Mill.treesalt stressPopulus euphraticaprolinenutritionCarpinus turczaninowiiplasma membrane Ca2+ channelsgene regulationpathogenTCPforest typefunctional analysisFraxinus mandshurica Rupr.long-term droughtdefense responsecold stresssilicon fertilizationgas exchangeFagus sylvatica L.glutaredoxinwater availability24-epiBL applicationKonjac glucomannanleaf propertiesreactive oxygen speciessap flow?13Csalinitymorphological indiceschloroplast ultrastructureMoso Bamboo (Phyllostachys edulis)droughtsoluble sugarmolecular cloningstarchgrowthHistory of engineering and technologyPolle Andrea1320457Rennenberg H(Heinz),ScCtBLLScCtBLLBOOK9910367755303321Physiological Responses to Abiotic and Biotic Stress in Forest Trees3034331UNINA