01347nam0 22003373i 450 PUV095871220231121125620.0019515531920150213d2004 ||||0itac50 baenglatusz01i xxxe z01nEpigrams. Book twoMartialedited with introduction, translation and commentary by Craig A. WilliamsNew YorkOxford university press2004XII, 303 p.24 cm.EpigrammataCFI0157978CFIV02482216716Marziale, Marco Valerio . Epigrammata. 2.CommentiFIRRMLC437661E877.01Satira e umorismo latino. Origini-50021Martialis, Marcus ValeriusCFIV024822070165201Williams, Craig A.MILV230645MarzialeCFIV024823Martialis, Marcus ValeriusMarziale, Marco ValerioCFIV098467Martialis, Marcus ValeriusITIT-0120150213IT-FR0017 Biblioteca umanistica Giorgio ApreaFR0017 NPUV0958712Biblioteca umanistica Giorgio Aprea 52S.SIJ. LL2 Mart.Wil. 52FLS0000283345 VMN RS A 2015021320150213 52Epigrammata16716UNICAS04546nam 2201417z- 450 991055749620332120210501(CKB)5400000000042869(oapen)https://directory.doabooks.org/handle/20.500.12854/68425(oapen)doab68425(EXLCZ)99540000000004286920202105d2021 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierPlant Responses to HypoxiaBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20211 online resource (288 p.)3-0365-0148-7 3-0365-0149-5 Molecular oxygen deficiency leads to altered cellular metabolism and can dramatically reduce crop productivity. Nearly all crops are negatively affected by a lack of oxygen (hypoxia) due to adverse environmental conditions such as excessive rain and soil waterlogging. Extensive efforts to fully understand how plants sense oxygen deficiency and their ability to respond using different strategies are crucial to increase hypoxia tolerance. Progress in our understanding has been significant in recent years. This topic certainly deserves more attention from the academic community; therefore, we have compiled a series of articles reflecting the advancements made thus far.Biology, life sciencesbicsscResearch & information: generalbicsscabiotic stressacetolactate synthaseacidificationActivity of antioxidant enzymesaerenchymaaerobic fermentationalternated stressanaerobic fermentationanaerobic germinationanaerobiosisanoxiaanoxic signalingapoplastic barrierArabidopsisauxinbarrier to radial oxygen loss (ROL)Chlorophyll contentcoleoptiledevelopmentdirect seedingdroughtEin2energy metabolismethanol fermentationethylenefloodingfluorescence microscopyfruit treesgerminationhypertrophied lenticelshypoxiaimidazolinonesjasmonateleaf desiccationleaf gas exchangeleaf greennesslegumesligninLotus japonicuslow O2 stressmaizemetabolic adaptationmetabolomicsmicroRNAsmode of actionn/aO. rufipogonorganic compoundOryza glumaepatulaOryza sativaoxygen sensingpHphloemPhysalis peruviana L.phytoglobinplant growthplant water relationspost-submergence recoverypotassiumPRT6 N-degron pathway of proteolysisPrunusRbohDregulatory mechanismricerice (O. sativa)rice (Oryza sativa)RNA-seqrootroot hypoxiaroot meristemroot respirationshoot to root ratioSolanum dulcamaraSolanum lycopersicumSolanum tuberosumstomatal conductancesuberinsubmergenceSubmergenceteosintetranscription factorTriticum aestivumVII Ethylene Response Factorwaterloggingwaterlogging tolerancewild riceBiology, life sciencesResearch & information: generalLoreti Elenaedt1290188Striker GustavoedtLoreti ElenaothStriker GustavoothBOOK9910557496203321Plant Responses to Hypoxia3021404UNINA