Impaired pH homeostasis in Arabidopsis lacking the vacuolar dicarboxylate transporter and analysis of carboxylic acid transport across the tonoplast.
about
Ion channels in plantsWhat controls fleshy fruit acidity? A review of malate and citrate accumulation in fruit cellsRethinking Guard Cell MetabolismNovel tonoplast transporters identified using a proteomic approach with vacuoles isolated from cauliflower buds.Vacuolar ion channels in the liverwort Marchantia polymorpha: influence of ion channel inhibitors.Engineering crassulacean acid metabolism to improve water-use efficiencyMolecular properties of the SLC13 family of dicarboxylate and sulfate transportersTranscriptome analysis at four developmental stages of grape berry (Vitis vinifera cv. Shiraz) provides insights into regulated and coordinated gene expressionExploiting the potential of plants with crassulacean acid metabolism for bioenergy production on marginal lands.Circadian oscillatory transcriptional programs in grapevine ripening fruitsInvolvement of CitCHX and CitDIC in developmental-related and postharvest-hot-air driven citrate degradation in citrus fruitsTransport of primary metabolites across the plant vacuolar membrane.Anion channels and transporters in plant cell membranes.Transporters of ligands for essential metal ions in plants.Review. CLC-mediated anion transport in plant cells.Identification and Functional Characterization of a Tonoplast Dicarboxylate Transporter in Tomato (Solanum lycopersicum).Exploiting natural variation to uncover candidate genes that control element accumulation in Arabidopsis thaliana.STOP1 regulates multiple genes that protect arabidopsis from proton and aluminum toxicities.Adjustment of host cells for accommodation of symbiotic bacteria: vacuole defunctionalization, HOPS suppression, and TIP1g retargeting in Medicago.Multiple Transport Pathways for Mediating Intracellular pH Homeostasis: The Contribution of H(+)/ion Exchangers.2-Hydroxy Acids in Plant Metabolism.Fe deficiency differentially affects the vacuolar proton pumps in cucumber and soybean roots.Evolutionary relationships and functional diversity of plant sulfate transporters.Vacuolar Chloride Fluxes Impact Ion Content and Distribution during Early Salinity Stress.Increased activity of the vacuolar monosaccharide transporter TMT1 alters cellular sugar partitioning, sugar signaling, and seed yield in Arabidopsis.NAD-malic enzymes of Arabidopsis thaliana display distinct kinetic mechanisms that support differences in physiological control.Analysis of Arabidopsis with highly reduced levels of malate and fumarate sheds light on the role of these organic acids as storage carbon molecules.An InDel in the Promoter of Al-ACTIVATED MALATE TRANSPORTER9 Selected during Tomato Domestication Determines Fruit Malate Contents and Aluminum Tolerance.Opposite variations in fumarate and malate dominate metabolic phenotypes of Arabidopsis salicylate mutants with abnormal biomass under chilling.Alteration of organic acid metabolism in Arabidopsis overexpressing the maize C4 NADP-malic enzyme causes accelerated senescence during extended darkness.Vacuolar processing enzyme 4 contributes to maternal control of grain size in barley by executing programmed cell death in the pericarp.Impaired Malate and Fumarate Accumulation Due to the Mutation of the Tonoplast Dicarboxylate Transporter Has Little Effects on Stomatal Behavior.Metabolism within the specialized guard cells of plants.MdMYB1 Regulates Anthocyanin and Malate Accumulation by Directly Facilitating Their Transport into Vacuoles in Apples.Vacuolar transporters - Companions on a longtime journey.Purification and functional characterization of the vacuolar malate trans-porter tDT from Arabidopsis.Identification of a vacuolar sucrose transporter in barley and Arabidopsis mesophyll cells by a tonoplast proteomic approach.The R2R3-MYB transcription factor MdMYB73 is involved in malate accumulation and vacuolar acidification in apple.Citrus CitNAC62 cooperates with CitWRKY1 to participate in citric acid degradation via up-regulation of CitAco3.Metabolic responses to lead of metallicolous and nonmetallicolous populations of Armeria maritima.
P2860
Q26995173-A25A7C26-5D8F-4A17-81AF-1151029DE4A5Q27002007-87891D88-FFE8-4F75-9132-8B0CBC068FD3Q28076463-BBFFFDD4-C92B-49FD-94DB-257669C8E8E8Q33344307-E8E9478E-77C1-4088-BEC2-15EFDC7CE379Q33563858-927500D6-9A3C-4A65-AEDE-5E477EA3CC52Q33787477-00EA4438-6434-4FC2-AF12-0190B392CA7EQ34457752-133B602B-4D0B-4F0C-BF77-1542027E9039Q34507496-0ECABCA9-C5F4-48B5-AA1B-B5CB52D22F7DQ34606936-9D2BF373-A0C9-47B7-A9B6-A6FE8789633DQ35130858-1AED647A-EF82-428D-8ED5-06BAFCBA8480Q35571512-D58E49E5-1370-4B15-9D28-00651444C8D5Q36738815-0C7D5396-9742-42E9-911B-C3C137D73877Q36791989-040331E4-0FCF-459E-BFBC-70E4B67370B0Q36797247-B3BDE624-94F9-4202-A6DC-9CBB4EFE6421Q37310613-93EC8945-48DF-4093-A232-2D7BBB0005FBQ37643873-83DAC3F4-635B-4B9B-AC92-B0DBAA82AB24Q37992064-9BEE0535-EE27-4E38-BDE4-110C60C8B689Q38355558-9D5FF1D7-49F2-489B-A6E4-19CF2DA01FB0Q41740865-B90A6DFB-B6E4-44A7-945C-AE7B924B12D9Q41818249-DFB51149-3463-4C70-9C76-F913FF55A1D4Q41938841-9F0F356D-3711-41A2-AF90-CFD76AA880C0Q42138695-05D96C66-5D09-4703-8C11-8AEFC2BDD6BEQ42174606-08A8AAC0-2721-486D-AD51-FB1CCC947FD6Q42774225-D18E6DC9-3ECC-4599-90A0-B90A94047678Q42937224-002CB280-D9A1-43CF-9B37-C4019B1DADFCQ43042682-06285B9A-B69C-4DFB-AEC0-F8AC037DBC48Q43182569-073A0BA9-19F0-41FA-898A-593EF4E61EC1Q46320025-A70FB85E-EDC3-426A-A405-02106163C165Q46905380-C9BC92C9-2031-4801-97C4-528F5F7BD641Q46989240-938850CD-8ED5-4CF4-BFC4-E13BD5EA7948Q47192306-06EA8591-259E-482B-964B-DBE0DEFFD19AQ47775179-70509E56-9A5B-43B9-81C6-C6FA78949E0EQ47855154-59502356-877C-4E0C-8E3B-9AAB8723E947Q48093830-8E45A3F2-B312-4F7C-90EA-6E8D5B76D207Q49358894-C56D3191-B6DF-492E-B3D0-665F18F45F46Q49789091-182B8EB8-C5CE-418E-A446-9A1455454473Q50734799-EF3FD7A1-38A6-4C79-9AE7-963E3CA4035FQ50910378-3A4E14CA-6D5D-45B5-8EF8-C52CBAFC1D0EQ50933567-DD4161AA-A01E-4510-AF29-9594C3CDE6ABQ51707587-51D3868D-59E3-4B3A-B9B0-F516D37BB545
P2860
Impaired pH homeostasis in Arabidopsis lacking the vacuolar dicarboxylate transporter and analysis of carboxylic acid transport across the tonoplast.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh
2005年學術文章
@zh-hant
name
Impaired pH homeostasis in Ara ...... ransport across the tonoplast.
@en
Impaired pH homeostasis in Ara ...... ransport across the tonoplast.
@nl
type
label
Impaired pH homeostasis in Ara ...... ransport across the tonoplast.
@en
Impaired pH homeostasis in Ara ...... ransport across the tonoplast.
@nl
prefLabel
Impaired pH homeostasis in Ara ...... ransport across the tonoplast.
@en
Impaired pH homeostasis in Ara ...... ransport across the tonoplast.
@nl
P2093
P2860
P356
P1433
P1476
Impaired pH homeostasis in Ara ...... ransport across the tonoplast.
@en
P2093
Franco Gambale
H Ekkehard Neuhaus
Marco Alois Hurth
Monica Bregante
Su Jeoung Suh
Tobias Kretzschmar
P2860
P304
P356
10.1104/PP.104.058453
P407
P577
2005-02-22T00:00:00Z