In Arabidopsis thaliana, biosynthesis of the essential thiol antioxidant, glutathione (GSH), is plastid-regulated, but many GSH functions, including heavy metal detoxification and plant defense activation, depend on cytosolic GSH. This finding suggests that plastid and cytosol thiol pools are closely integrated and we show that in Arabidopsis this integration requires a family of three plastid thiol transporters homologous to the Plasmodium falciparum chloroquine-resistance transporter, PfCRT. Arabidopsis mutants lacking these transporters are heavy metal-sensitive, GSH-deficient, and hypersensitive to Phytophthora infection, confirming a direct requirement for correct GSH homeostasis in defense responses. Compartment-specific measurements of the glutathione redox potential using redox-sensitive GFP showed that knockout of the entire transporter family resulted in a more oxidized glutathione redox potential in the cytosol, but not in the plastids, indicating the GSH-deficient phenotype is restricted to the cytosolic compartment. Expression of the transporters in Xenopus oocytes confirmed that each can mediate GSH uptake. We conclude that these transporters play a significant role in regulating GSH levels and the redox potential of the cytosol.T he potentially damaging end-products of aerobic energy metabolism, reactive oxygen species (ROS), are powerful signaling components linking growth, metabolism, and defense responses in cells (1-4). In plant cells, a complex antioxidant network with glutathione (GSH) at its center has evolved to buffer ROS. Because both the levels and oxidation state of GSH are directly influenced by ROS, GSH is a key redox-signaling component (5-10).GSH is synthesized in two steps (11) catalyzed by the ratelimiting glutamate-cysteine ligase (GSH1; EC 6.3.2.2) and glutathione synthase (GSH2; EC 6.3.2.3). In Arabidopsis, GSH1 is exclusively targeted to the plastid, while GSH2 is targeted to both plastid and cytosol (12). Consequently, the pathway intermediate, γ-glutamylcysteine (γ-EC), must be exported from the plastid to allow for cytosolic GSH biosynthesis. This finding was recently confirmed by the observation that inviable gsh2 mutants can be fully complemented by expression of functional GSH2 only in the cytosol (13), suggesting that thiol transport between compartments is essential for maintaining both GSH levels and redox-based signaling pathways, although no plastid thiol transporters have yet been identified (13-17).
Summary• The usefulness of the zinc (Zn)-fluorophore, Zinpyr-1, to examine the localization of Zn in the roots of Arabidopsis has been investigated.• In wild-type roots Zinpyr-1 fluorescence was predominantly in the xylem. The fluorescence signal was abolished by the application of the Zn-chelator, N,N,N',N-tetrakis(2-pyridylmethyl)ethylenediamine (TPEN), and was increased by increasing exogenous Zn in the medium, indicating that fluorescence reflected relative Zn concentrations.• In the hma2 , hma4 double mutant, which is deficient in root to shoot Zn translocation, Zinpyr-1 fluorescence was low in the xylem and high in the adjacent pericycle cells in which HMA2 and HMA4 are specifically expressed in a wild type. Zinpyr-1 fluorescence was also increased in the endodermis.• These results show that Zinpyr-1 can be used to examine the effects of mutations in Zn transporters on the localization of Zn in Arabidopsis roots and should be a useful addition to the tools available for studying Zn homeostasis in plants.New Phytologist (2007) 174 : [39][40][41][42][43][44][45]
HMA2, HMA4, and HMA7 are three of the eight heavy metal transporting P(1B)-type ATPases in the simple plant Arabidopsis thaliana. The first two transport Zn(2+), and the third transports Cu(+). Each protein contains soluble N-terminal metal-binding domains (MBDs) that are essential for metal transport. While the MBD of HMA7 features a CxxC sequence motif characteristic of Cu(I) binding sites, those of HMA2 and HMA4 contain a CCxxE motif, unique for plant Zn(2+)-ATPases. The three MBDs HMA2n (residues 1-79), HMA4n (residues 1-96), and HMA7n (residues 56-127) and an HMA7/4n chimera were expressed in Escherichia coli. The chimera features the ICCTSE motif from HMA4n inserted in place of the native MTCAAC motif of HMA7n. Binding affinities for Zn(II) and Cu(I) of each MBD were determined by ligand competition with a number of chromophoric probes. The challenges of using these probes reliably were evaluated, and the relative affinities of the MBDs were verified by independent cross-checks. The affinities of HMA2n and HMA4n for Zn(II) are higher than that of HMA7n by a factor of 20-30, but the relative affinities for Cu(I) are inverted by a factor of 30-50. These relativities are consistent with their respective roles in metal selection and transportation. Chimera HMA7/4n binds Cu(I) with an affinity between those of HMA4n and HMA7n but binds Zn(II) more weakly than either parent protein does. The four MBDs bind Cu(I) more strongly than Zn(II) by factors of >10(6). It is apparent that the individual MBDs are not able to overcome the large thermodynamic preference for Cu(+) over Zn(2+). This information highlights the potential toxicity of Cu(+) in vivo and why copper sensor proteins are approximately 6 orders of magnitude more sensitive than zinc sensor proteins. Metal speciation must be controlled by multiple factors, including thermodynamics (affinity), kinetics (including protein-protein interactions), and compartmentalization. The structure of Zn(II)-bound HMA4n defined by NMR confirmed the predicted ferredoxin betaalphabetabetaalphabeta fold. A single Zn atom was modeled onto a metal-binding site with protein ligands comprising the two thiolates and the carboxylate of the CCxxE motif. The observed (113)Cd chemical shift in [(113)Cd]HMA4n was consistent with a Cd(II)S(2)OX (X = O or N) coordination sphere. The Zn(II) form of the Cu(I) transporter HMA7n is a monomer in solution but crystallized as a polymeric chain [(Zn(II)-HMA7n)(m)]. Each Zn(II) ion occupied a distorted tetrahedral site formed from two Cys ligands of the CxxC motif of one HMA7n molecule and the amino N and carbonyl O atoms of the N-terminal methionine of another.
Summary The Zn/Cd‐transporting ATPase, HMA2, has N‐ and C‐terminal domains that can bind Zn ions with high affinity. Mutant derivatives were generated to determine the significance of these domains to HMA2 function in planta. Mutant derivatives, with and without a C‐terminal GFP tag, were expressed from the HMA2 promoter in transgenic hma2,hma4, Zn‐deficient, plants to test for functionality. A deletion mutant lacking the C‐terminal 244 amino acids rescued most of the hma2,hma4 Zn‐deficiency phenotypes with the exception of embryo or seed development. Root‐to‐shoot Cd translocation was fully rescued. The GFP‐tagged derivative was partially mis‐localized in the root pericycle cells in which it was expressed. Deletion derivatives lacking the C‐terminal 121 and 21 amino acids rescued all phenotypes and localized normally. N‐terminal domain mutants localized normally but failed to complement the hma2,hma4 phenotypes. These observations suggest that the N‐terminal domain of HMA2 is essential for function in planta while the C‐terminal domain, although not essential for function, may contain a signal important for the subcellular localization of the protein.
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