Impaired pH Homeostasis in Arabidopsis Lacking the Vacuolar Dicarboxylate Transporter and Analysis of Carboxylic Acid Transport across the Tonoplast

Arabidopsis (Arabidopsis thaliana) mutants lacking the tonoplastic malate transporter AttDT (A. thaliana tonoplast dicarboxylate transporter) and wild-type plants showed no phenotypic differences when grown under standard conditions. To identify putative metabolic changes in AttDT knock-out plants,...

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Bibliographic Details
Published in:Plant physiology (Bethesda) 2005-03, Vol.137 (3), p.901-910
Main Authors: Hurth, Marco Alois, Suh, Su Jeoung, Kretzschmar, Tobias, Geis, Tina, Bregante, Monica, Gambale, Franco, Martinoia, Enrico, Neuhaus, H. Ekkehard
Format: Article
Language:English
Subjects:
Acidification
Arabidopsis - genetics
Arabidopsis - metabolism
Arabidopsis Proteins - genetics
Arabidopsis Proteins - metabolism
Arabidopsis thaliana
Biochemical Processes and Macromolecular Structures
Biological and medical sciences
Biological Transport, Active
Carboxylates
Carboxylic acids
Cell physiology
cell respiration
Citrates
Citric Acid - metabolism
dicarboxylic acids
Fumarates - metabolism
Fundamental and applied biological sciences. Psychology
Gene Expression Regulation, Plant - physiology
Homeostasis
Hydrogen-Ion Concentration
knockout mutants
Malates - metabolism
Membrane Potentials
mesophyll
Molecular Sequence Data
Mutation
Organic Anion Transporters - genetics
Organic Anion Transporters - metabolism
oxygen
Oxygen Consumption
oxygen evolution
Photosynthesis
physiological transport
Plant Leaves - metabolism
Plant physiology and development
Plants
Plasma membrane and permeation
Protoplasts
Tonoplast
tonoplastic malate transporter
transporters
Vacuoles
Vacuoles - metabolism
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Summary:Arabidopsis (Arabidopsis thaliana) mutants lacking the tonoplastic malate transporter AttDT (A. thaliana tonoplast dicarboxylate transporter) and wild-type plants showed no phenotypic differences when grown under standard conditions. To identify putative metabolic changes in AttDT knock-out plants, we provoked a metabolic scenario connected to an increased consumption of dicarboxylates. Acidification of leaf discs stimulated dicarboxylate consumption and led to extremely low levels of dicarboxylates in mutants. To investigate whether reduced dicarboxylate concentrations in mutant leaf cells and, hence, reduced capacity to produce OH⁻ to overcome acidification might affect metabolism, we measured photosynthetic oxygen evolution under conditions where the cytosol is acidified. AttDT::tDNA protoplasts showed a much stronger inhibition of oxygen evolution at low pH values when compared to wild-type protoplasts. Apparently citrate, which is present in higher amounts in knock-out plants, is not able to replace dicarboxylates to overcome acidification. To raise more information on the cellular level, we performed localization studies of carboxylates. Although the total pool of carboxylates in mutant vacuoles was nearly unaltered, these organelles contained a lower proportion of malate and fumarate and a higher proportion of citrate when compared to wild-type vacuoles. These alterations concur with the observation that radioactively labeled malate and citrate are transported into Arabidopsis vacuoles by different carriers. In addition, wild-type vacuoles and corresponding organelles from AttDT::tDNA mutants exhibited similar malate channel activities. In conclusion, these results show that Arabidopsis vacuoles contain at least two transporters and a channel for dicarboxylates and citrate and that the activity of AttDT is critical for regulation of pH homeostasis.
ISSN:0032-0889
1532-2548
DOI:10.1104/pp.104.058453