Agnes N. Chardonnens scite author profile

SummaryThe zinc hyperaccumulator plant Arabidopsis halleri is able to naturally accumulate 100-fold higher leaf zinc concentrations when compared with non-accumulator species such as the closely related A. lyrata and A. thaliana, without showing toxicity symptoms. A novel member of the cation diffusion facilitator (CDF) protein family, an A. halleri metal tolerance protein 1 (MTP1), and the homologous A. thaliana Zn transporter (ZAT)/AtMTP1 metal-specifically complement the zinc hypersensitivity of a Saccharomyces cerevisiae zrc1 cot1 mutant strain. A fusion of the AhMTP1 protein to green fluorescent protein (GFP) localizes to the vacuolar membrane of A. thaliana protoplasts. When compared with A. lyrata and A. thaliana, the total MTP1 transcript levels are substantially higher in the leaves and upregulated upon exposure to high zinc concentrations in the roots of A. halleri. The high MTP1 transcript levels in A. halleri can be primarily attributed to two genetically unlinked genomic AhMTP1 gene copies. The two corresponding loci co-segregate with zinc tolerance in the back-cross 1 generation of a cross between the zinc-tolerant species A. halleri and the zinc-sensitive species A. lyrata. In contrast, a third MTP1 gene in the genome of A. halleri generates only minor amounts of MTP1 transcripts and does not co-segregate with zinc tolerance. Our data suggests that zinc tolerance in A. halleri involves an expanded copy number of an ancestral MTP1 gene, encoding functional proteins that mediate the detoxification of zinc in the cell vacuole. At the transcript level, MTP1 gene copies of A. halleri are regulated differentially and in response to changes in zinc supply.

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Overexpression of a Novel Arabidopsis Gene Related to Putative Zinc-Transporter Genes from Animals Can Lead to Enhanced Zinc Resistance and Accumulation

Zaal

et al. 1999

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We describe the isolation of an Arabidopsis gene that is closely related to the animal ZnT genes (Zn transporter)Several heavy metals are essential during plant growth and development, but their excess can easily lead to toxic effects. Contamination of soils with heavy metals, either by natural causes or due to pollution, often has pronounced effects on the vegetation, resulting in the appearance of metallophytes, heavy-metal-tolerant plants. The precise mechanisms of uptake, transport, and accumulation of heavy metals in plants are poorly understood, but several genes likely to be involved in these processes have been described. Recently, a family of ZIP genes that are expressed in roots upon Zn deficiency was isolated from Arabidopsis (Grotz et al., 1998). The proteins encoded by the ZIP genes have eight predicted TM regions and a high degree of similarity to the ZRT genes from yeast that are involved in Zn uptake. Expression of the ZIP genes in yeast conferred Zn-uptake activities to these cells, demonstrating that they are probably functional homologs of the yeast ZRT genes (Grotz et al., 1998). The only other metaltransporting protein recently identified in plants belongs to the large family of cation-transporting P-type ATPases (Tabata et al., 1997), but these proteins are structurally very different from the metal-transporting proteins mentioned above.Recent data have provided more insight into the mechanisms of heavy-metal tolerance. Metallophytes often exhibit tolerance to several different heavy metals, but all of these metals need not be present at toxic levels in their habitat (Schat and ten Bookum, 1992a; Schat and Vooijs, 1997, and refs. therein;Schat and Verkleij, 1998). Although such a feature is suggestive of a general mechanism of heavy-metal tolerance, recent genetic evidence has shown that a number of different mechanisms must exist, each with its own metal specificity (Schat and Vooijs, 1997). In Arabidopsis, a plant species with a typical level of tolerance to heavy metals, it has been demonstrated that the Cd-sensitive mutants cad1 and cad2 are defective in the synthesis of the metal-binding compound phytochelatin (Howden et al., 1995). cad1 plants were only slightly more sensitive to Cu and Zn, indicating that phytochelatinmediated detoxification is not sufficient for Cu and Zn detoxification (Howden et al., 1995b). Metallothioneins appear to be of major importance for constitutive Cu tolerance in Arabidopsis (Zhou and Goldsbrough, 1994).Aside from complexation of heavy metals by heavymetal-binding proteins, there is evidence that transportmediated sequestration can contribute to heavy-metal tolerance. In the Zn-tolerant plant Silene vulgaris it was shown that Zn transport across the tonoplast was about 2.5 times higher than in Zn-sensitive plants of the same species (Verkleij et al

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Significance of the V‐type ATPase for the adaptation to stressful growth conditions and its regulation on the molecular and biochemical level

Dietz¹,

Tavakoli²,

Kluge³

et al. 2001

303

173

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Two electrogenic H(+)-pumps, the vacuolar type H(+)-ATPase (V-ATPase) and the vacuolar pyrophosphatase, coexist at membranes of the secretory pathway of plants. The V-ATPase is the dominant H(+)-pump at endomembranes of most plant cells, both in terms of protein amount and, frequently, also in activity. The V-ATPase is indispensable for plant growth under normal conditions due to its role in energizing secondary transport, maintenance of solute homeostasis and, possibly, in facilitating vesicle fusion. Under stress conditions such as salinity, drought, cold, acid stress, anoxia, and excess heavy metals in the soil, survival of the cells depends strongly on maintaining or adjusting the activity of the V-ATPase. Regulation of gene expression and activity are involved in adapting the V-ATPase on long- and short-term bases. The mechanisms known to regulate the V-ATPase are summarized in this paper with an emphasis on their implications for growth and development under stress.

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The use of transgenic plants in the bioremediation of soils contaminated with trace elements

Krämer

Chardonnens

2001

Applied Microbiology and Biotechnology

216

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The use of plants to clean-up soils contaminated with trace elements could provide a cheap and sustainable technology for bioremediation. Field trials suggested that the rate of contaminant removal using conventional plants and growth conditions is insufficient. The introduction of novel traits into high biomass plants in a transgenic approach is a promising strategy for the development of effective phytoremediation technologies. This has been exemplified by generating plants able to convert organic and ionic forms of mercury into the less toxic, volatile, elemental mercury, a trait that occurs naturally only in some bacteria and not at all in plants. The engineering of a phytoremediator plant requires the optimization of a number of processes, including trace element mobilization in the soil, uptake into the root, detoxification and allocation within the plant. A number of transgenic plants have been generated in an attempt to modify the tolerance, uptake or homeostasis of trace elements. The phenotypes of these plants provide important insights for the improvement of engineering strategies. A better understanding, both of micronutrient acquisition and homeostasis, and of the genetic, biochemical and physiological basis of metal hyperaccumulation in plants, will be of key importance for the success of phytoremediation.

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Differential heavy metal tolerance of Arabidopsis halleri and Arabidopsis thaliana: a leaf slice test

Cho¹,

Chardonnens²,

Dietz³

2003

New Phytologist

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Summary• Here, a short-term leaf tissue tolerance test was designed to determine the distinct Zn-, Cd-and Ni-tolerance levels for leaves of the Zn-hyperaccumulating plant Arabidopsis halleri compared with Arabidopsis thaliana .• Leaf slices were incubated in different metal concentrations for 2 h. Quantum yield of photosystem II was used as a parameter dependent on heavy metal concentrations in the incubation medium.• The half effective concentration values (EC50) showed that A. halleri was extremely tolerant to Zn (EC50 » 1 M ), whereas A. thaliana had an EC 50 of only 2.5 m M . For Cd, the EC 50 values were 40 m M and 1.9 m M for A. halleri and A. thaliana , respectively. No differential tolerance was observed for Ni between the two species. Determination of heavy metal uptake by leaf slices under the same conditions revealed decreased uptake rates for A. halleri , suggesting that low metal influx from the apoplast, probably combined with efficient intracellular compartmentation, constitutes the mechanistic basis for Zn-and Cd-hyperaccumulation. It is also shown that pre-exposure of A. halleri with Zn during growth affects tolerance in the subsequent leaf slice test.• The leaf slice test presented here provides a quick and reliable method for estimating heavy metal tolerance levels in individual plants.Key words: heavy metal tolerance, Arabidopsis halleri , Arabidopsis thaliana , Zn, Cd, Ni, leaf slice test. AbbreviationsA, Arabidopsis ; EC50, effective concentration for 50% inhibition; F s ′ steady state chlorophyll a fluorescence; F m ′ maximum chlorophyll a fluorescence after application of a saturating light pulse; Φ PS II, effective quantum yield of photosystem II.

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