00798cam2 22002531 450 SOBE0005406120161125111319.020161125d1963 |||||ita|0103 baengGB5John LockeAalenScientia1963496 p.22 cm001SOBE000177262001 <<The >>Works of John Locke, in 10. VolumesLocke, JohnA60020005165507044514ITUNISOB20161125RICAUNISOBUNISOB100|Coll|72|K36752SOBE00054061M 102 Monografia moderna SBNW100|Coll|72|K000005RIS36752acquistocatenacciUNISOBUNISOB20161125111246.020161125111319.0catenacci51726849UNISOB05034nam 2201429z- 450 9910404085103321202102113-03928-489-4(CKB)4100000011302287(oapen)https://directory.doabooks.org/handle/20.500.12854/50797(oapen)doab50797(EXLCZ)99410000001130228720202102d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierJasmonic Acid Pathway in PlantsMDPI - Multidisciplinary Digital Publishing Institute20201 online resource (346 p.)3-03928-488-6 The plant hormone jasmonic acid (JA) and its derivative, an amino acid conjugate of JA (jasmonoyl isoleucine, JA-Ile), are signaling compounds involved in the regulation of defense and development in plants. The number of articles studying on JA has dramatically increased since the 1990s. JA is recognized as a stress hormone that regulates the plant response to biotic stresses such as herbivore and pathogen attacks, as well as abiotic stresses such as wounding and ultraviolet radiation. Recent studies have remarkably progressed the understanding of the importance of JA in the life cycle of plants. JA is directly involved in many physiological processes, including stamen growth, senescence, and root growth. JA regulates production of various metabolites such as phytoalexins and terpenoids. Many regulatory proteins involved in JA signaling have been identified by screening for Arabidopsis mutants. However, much more remains to be learned about JA signaling in other plant species. This Special Issue, "Jasmonic Acid Pathway in Plants", contains 5 review and 15 research articles published by field experts. These articles will help with understanding the crucial roles of JA in its response to the several environmental stresses and development in plants.ABA biosynthesisabiotic stressesadventitious rootingalbinoancestral sequencesantioxidant enzyme activityaromaAtRGS1auxinbioinformaticsbiological functionbiosynthesisCamellia sinensisChinese flowering cabbagechlorophyll fluorescence imagingchloroplastcircadian clockcrosstalkcytokinindammarenediol synthasedegrondiffusion dynamicsectopic metaxylemectopic protoxylemelicitorendocytosisenvironmental responseethylenefatty acid desaturasegene expressiongibberellic acidginsenosidegrain developmentgrain numberheterotrimeric G proteinshypocotylJAJA-IleJas domainjasmonateJasmonate-ZIM domainjasmonatesjasmonic acidjasmonic acid (JA) signaling pathwayjasmonic acid signalingJAZ repressorsleaf senescencelight-sensitivelipoxygenaseMAP kinaseMeJAmethyl jasmonatemsdmultiseededMutMapMYB transcription factorn/aNicotiana plantsnitric oxideopr3Panax ginsengpatchouli alcoholPatJAZ6phylogenetic analysisplant developmentPogostemon cablinprimingprolineproteomicsPrunus aviumquantitative proteomicsRalstonia solanacearumricerice bacterial blightROSsalicylic acidsalt responsesecondary metabolitesignal moleculessignalingsignaling pathwaysorghumstressstress defenseteaTIFYtranscription factortranscriptional activationtranscriptional regulatorsTuscan varietiestype III effectorvolatilexylogenesisZea maysGomi Kenjiauth1312857BOOK9910404085103321Jasmonic Acid Pathway in Plants3031035UNINA