about
Plant neurobiology: no brain, no gain?Some data on the polygenic control of two quantitative traits in a vegetatively propagated flower plant, the carnation.A turanose-insensitive mutant suggests a role for WOX5 in auxin homeostasis in Arabidopsis thaliana.Proteomic identification of differentially expressed proteins in the anoxic rice coleoptile.Sugar modulation of alpha-amylase genes under anoxiaVolatile organic compounds in truffle (Tuber magnatum Pico): comparison of samples from different regions of Italy and from different seasonsProteins from Tuber magnatum Pico fruiting bodies naturally grown in different areas of ItalyDistinct mechanisms for aerenchyma formation in leaf sheaths of rice genotypes displaying a quiescence or escape strategy for flooding tolerance.Metabolic engineering of the iodine content in Arabidopsis.Hormonal interplay during adventitious root formation in flooded tomato plants.Effects of leupeptin on proteinase and germination of castor beans.Comparative analysis of anoxic coleoptile elongation in rice varieties: relationship between coleoptile length and carbohydrate levels, fermentative metabolism and anaerobic gene expression.Effects of o(2) concentration on rice seedlings.Sucrose-specific induction of the anthocyanin biosynthetic pathway in Arabidopsis.Identification of sugar-modulated genes and evidence for in vivo sugar sensing in Arabidopsis.Expansin gene expression and anoxic coleoptile elongation in rice cultivars.Immunological detection of acetaldehyde-protein adducts in ethanol-treated carrot cells.Cytosolic aconitase participates in the glyoxylate cycle in etiolated pumpkin cotyledons.Embryo-suspensor relations in Phaseolus coccineus: cytokinins during seed development.Growth regulator levels in embryo and suspensor of Phaseolus coccineus at two stages of development.Regulatory interplay of the Sub1A and CIPK15 pathways in the regulation of α-amylase production in flooded rice plants.Environmental conditions influence the biochemical properties of the fruiting bodies of Tuber magnatum Pico.Expression of glyoxylate cycle genes in cucumber roots responds to sugar supply and can be activated by shading or defoliation of the shootGlucose repression of alpha-amylase in barley embryos is independent of GAMYB transcriptionCharacterization of isoforms of hexose kinases in rice embryoGlucose modulates the abscisic acid-inducible Rab16A gene in cereal embryosCharacterization of two Arabidopsis thaliana fructokinasesEffect of Anoxia on Carbohydrate Metabolism in Rice SeedlingsAmylolytic Activities in Cereal Seeds under Aerobic and Anaerobic ConditionsTranscript profiling of the anoxic rice coleoptileThe heat-inducible transcription factor HsfA2 enhances anoxia tolerance in ArabidopsisDifferential expression of two fructokinases in Oryza sativa seedlings grown under aerobic and anaerobic conditionsGibberellins in Suspensors of Phaseolus coccineus L. SeedsGibberellins in Embryo-Suspensor of Phaseolus coccineus Seeds at the Heart Stage of Embryo DevelopmentPattern of Variations in Abscisic Acid Content in Suspensors, Embryos, and Integuments of Developing Phaseolus coccineus SeedsEthanol-induced injuries to carrot cells : the role of acetaldehydeLevel of Abscisic Acid in Integuments, Nucellus, Endosperm, and Embryo of Peach Seeds (Prunus persica L. cv Springcrest) during DevelopmentPeroxisomal enzyme activities in attached senescing leavesLocalization of glyoxylate-cycle marker enzymes in peroxisomes of senescent leaves and green cotyledonsEthanol production and toxicity in suspension-cultured carrot cells and embryos
P50
Q28293529-365ADDA2-F67C-4179-89D2-868E7E300415Q30737188-E2D8B382-8045-4CAD-84C6-03362F32CDD9Q33341784-583B601C-48FC-4F34-9BC5-8EDF3C008A85Q34020277-861AAB78-61EA-4007-A7F0-0631C5B35945Q34575476-51AA31AC-EF25-433E-9FEF-0CDE680BEB90Q35902203-2A4181E2-F928-40EE-9CC5-FA13E5E4A368Q39298851-2008BB32-8B34-4F04-A7A2-0263184D2660Q42083978-57DEA7B7-CDFB-4AB0-8BB7-8DF25912D4E9Q42565052-EF083627-8CDB-4332-BB45-5D393EB61EBFQ43055626-169A43C0-5D54-40C0-8E36-D65BED5A1DDEQ43517138-DB9ED725-665A-4221-80F5-1B5467576229Q45963191-EF97E142-EBB7-44ED-8736-4E57C22BB95FQ46604282-3D08B678-380A-4BA0-8237-A03F207D34C3Q46872485-E6AF3CDB-0F61-44A6-A5F4-C1E744E0CB03Q46931777-5A94D539-04B6-493F-84C6-0A40F121EA60Q47896564-D0BB879E-121C-46E1-B87B-779C26B8E66CQ47917524-236D5050-AA86-43AA-B7BF-F2A122C94977Q48073245-C1D7638B-B652-4BDC-BA02-B77E6498F00BQ52305316-86232657-4F8D-40AA-ADF0-E1DE58967CB6Q52313826-86CE6F15-405F-43E6-A16C-5658D758E180Q54582373-1A01980C-16D2-4622-A90A-3AF5209EDD7EQ55328263-B04C443B-C502-4A4E-AEBA-E2C02C92F73FQ58035454-95221E51-D89D-4F57-B4AF-B47BF11CA82CQ73232978-BCFA6F9B-C262-41A6-A147-8B95F44C051BQ73460169-4827C2CC-350F-4640-843A-8A114B1D6044Q73751719-BF0BD0B7-D802-404D-AB62-83F08A7E252AQ73835911-6248CBFE-AAF5-47EE-85DB-E48AD52DED65Q74781599-28C4E79E-06B0-44E9-A2DA-7C43BE4DBC47Q74782013-037D2804-76D0-4507-A00B-91CC4DF1A4AFQ79975069-CDD75DDE-DAE1-425F-B3CC-56B5B08F4A22Q82588243-7BADF210-2D21-4A2D-9FF9-512A554116FCQ83202772-A8610735-1BFF-4EB4-979A-ADC7E0D30EBBQ83264210-DFB5E797-840C-45A1-9873-DB87F57F76C8Q83268791-CA8E9E0E-F4D9-4D22-9683-CE2097F9D08BQ83270880-FFFA9B72-A00E-4701-AFE4-D16C50157CF2Q83271163-C44E9530-4BB7-48CC-862D-F28A66C3DAF9Q83272031-016D2F1E-2949-4187-AD91-679B2951FA9BQ86651570-8CAA1539-DF37-4F77-A24B-2C7D27D44DFCQ86671801-7C70CD8E-2E41-4503-9EBD-E45F9FAFA09CQ86720032-342C3232-9A40-42E4-91C0-A0CB13984321
P50
description
researcher ORCID ID = 0000-0002-8770-8516
@en
wetenschapper
@nl
name
Amedeo Alpi
@ast
Amedeo Alpi
@en
Amedeo Alpi
@es
Amedeo Alpi
@nl
type
label
Amedeo Alpi
@ast
Amedeo Alpi
@en
Amedeo Alpi
@es
Amedeo Alpi
@nl
prefLabel
Amedeo Alpi
@ast
Amedeo Alpi
@en
Amedeo Alpi
@es
Amedeo Alpi
@nl
P214
9416149619471304010001
P31
P496
0000-0002-8770-8516