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Calcium-permeable channels in plant cellsThe ALMT Family of Organic Acid Transporters in Plants and Their Involvement in Detoxification and Nutrient Securityγ-Aminobutyric acid (GABA) signalling in plants.An S-type anion channel SLAC1 is involved in cryptogein-induced ion fluxes and modulates hypersensitive responses in tobacco BY-2 cells.Protein phosphorylation in stomatal movementMutations in the SLAC1 anion channel slow stomatal opening and severely reduce K+ uptake channel activity via enhanced cytosolic [Ca2+] and increased Ca2+ sensitivity of K+ uptake channels.Molecular Evolution of Slow and Quick Anion Channels (SLACs and QUACs/ALMTs).Anion Channel Inhibitor NPPB-Inhibited Fluoride Accumulation in Tea Plant (Camellia sinensis) Is Related to the Regulation of Ca²⁺, CaM and Depolarization of Plasma Membrane PotentialNew approaches to the biology of stomatal guard cells.Calcium-dependent and -independent stomatal signaling network and compensatory feedback control of stomatal opening via Ca2+ sensitivity priming.Plant signalling in acute ozone exposure.Closing gaps: linking elements that control stomatal movement.Identification of a Stelar-Localized Transport Protein That Facilitates Root-to-Shoot Transfer of Chloride in Arabidopsis.COP1 jointly modulates cytoskeletal processes and electrophysiological responses required for stomatal closure.Metabolite Profiling of Root Exudates of Common Bean under Phosphorus Deficiency.Tiny pores with a global impact.The BIG protein distinguishes the process of CO2 -induced stomatal closure from the inhibition of stomatal opening by CO2.Contribution of the S-type Anion Channel SLAC1 to Stomatal Control and Its Dependence on Developmental Stage in Rice.The Transmembrane Region of Guard Cell SLAC1 Channels Perceives CO2 Signals via an ABA-Independent Pathway in Arabidopsis.PYR/RCAR receptors contribute to ozone-, reduced air humidity-, darkness-, and CO2-induced stomatal regulation.Phosphorylation of the vacuolar anion exchanger AtCLCa is required for the stomatal response to abscisic acid.ROS-Activated Ion Channels in Plants: Biophysical Characteristics, Physiological Functions and Molecular Nature.Involvement of S-type anion channels in disease resistance against an oomycete pathogen in Arabidopsis seedlings
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Q27015701-2275805A-6133-4246-B513-C34281DC7E7DQ28072019-8BF6AE30-75DB-49BC-8140-3E900624F6F7Q34544540-500C89A8-E61C-4492-B823-0222C674EFDEQ34947400-561DBFE6-9254-48F9-AFEB-1712E74F30EFQ36213379-DC02DEC1-4A47-40A6-8AA0-27DE1F368BFFQ36428909-50015ECB-F680-46B4-A7B2-4BC6E1F29CCDQ36431618-1390D311-1AE3-4CB3-9DA2-43B9BB35BCE9Q36512517-A04347A0-BDBE-4BA5-A441-B09380781F0EQ37553730-D8CD16BE-5A9E-456C-B875-EC2E678494F7Q38114416-3427D0DA-B204-481D-A13F-4AAE2CA21CE5Q38177866-E21192CC-4732-47F1-8524-60A32AE6C9BDQ38209707-89327E5F-F482-4D8A-B095-41E843F2B6CDQ39174423-A40349C2-ACB6-48D0-A6A8-C9AB96F0378BQ41868549-76FBB37E-459D-44EE-B824-EFBE91C6F26EQ42110256-FA1D09D0-5E78-46BF-A627-381FF3A11D92Q44674158-04F03283-24FC-4E9B-9E6D-D328CED1DFC8Q47224910-279D6750-4B27-4E2B-A5EE-1B1D6996CC22Q47638872-E53634A1-E542-4916-A19D-C0E9F66F6BB4Q48262773-5FFAF486-647A-4BCD-B3B5-2284BAB06A23Q50964059-1A9DB722-B62F-41A5-B936-0165A946A968Q54339356-9A51A9B6-F35C-4313-95F6-2EDA175C2591Q55345803-25062D9A-FE43-41B2-9AD7-615BC381C8E7Q58789156-75C499D9-FE6A-4EE4-BAEA-227822FD1F97
P2860
description
article científic
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article scientifique
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articol științific
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articolo scientifico
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artigo científico
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artigo científico
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artigo científico
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artikel ilmiah
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artikull shkencor
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artículo científico
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name
Anion channels in plant cells.
@en
Anion channels in plant cells.
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type
label
Anion channels in plant cells.
@en
Anion channels in plant cells.
@nl
prefLabel
Anion channels in plant cells.
@en
Anion channels in plant cells.
@nl
P2860
P1433
P1476
Anion channels in plant cells
@en
P2093
Kristiina Laanemets
Mathieu Jossier
P2860
P304
P356
10.1111/J.1742-4658.2011.08370.X
P407
P577
2011-10-24T00:00:00Z