Allocation Patterns of Zinc and Cadmium in Heavy Metal Tolerant and Sensitive Silene vulgaris
References (41)
- et al.
Effects of cadmium-zinc interactions on hydroponically grown bean (Phaseolus vulgaris L.)
Plant Sci.
(1997) - et al.
Synthesis and degradation of phytochelatins in cadmium-sensitive and cadmium-tolerant Silene vulgaris
Plant Sci.
(1995) - et al.
Uptake and transport of zinc in zinc-sensitive and zinc-tolerant Silene vulgaris
J. Plant Physiol.
(1993) - et al.
Quantitative micro-PIXE comparison of elemental distribution in Ni-hyperaccumulating and nonaccumulating genotypes of Senecio coronatus
Nucl. Instr. Met. Physics Res. B.
(1997) - et al.
Heavy metal tolerance in Minuartia verna
J. Plant Physiol.
(1997) - et al.
Localization of zinc and cadmium in Thlaspi caerulescens (Brassicaceae), a metallophyte that can hyperaccumulate both metals
J. Plant Physiol.
(1992) - et al.
Evidence for an important role of the tonoplast in the mechanism of naturally selected zinc tolerance in Silene vulgaris
J. Plant Physiol.
(1998) - et al.
Plant water relations as affected by heavy metal stress: a review
J. Plant Nutr.
(1990) - et al.
Compartmentalization and transport of zinc in barley primary leaves as basic mechanisms involved in zinc tolerance
Plant Cell Env.
(1994) - et al.
Differential toxicity of heavy metals is partly related to a loss of preferential extraplasmatic compartmentalization: a comparison of Cd-, Mo-, Ni-, and Zn-stress
New Phytol.
(1995)
Distribution of cadmium in leaves of cadmium tolerant and sensitive ecotypes of Silene vulgaris
Physiol. Plant.
The role of iron-deficiency stress responses in stimulating heavy metal transport in plants
Plant Physiol.
Zinc-induced vacuolation in root meristematic cells of Festuca rubra L
Plant Cell Env.
Evidence against a role for phytochelatins in naturally selected increased cadmium tolerance in Silene vulgaris (Moench) Garcke
New Phytol.
Phytochelatins in cadmium-sensitive and cadmium-tolerant Silene vulgaris: chainlength distribution and sulfide incorporation
Plant Physiol.
Glutathione depletion due to copper-induced phytochelatin synthesis causes oxidative stress in Silene cucubalus
Plant Physiol.
Effects of heavy metals in plants at the cellular and organismic level
Schwermetallvegetation der Erde
Evolutionary biology of metal resistance in Silene vulgaris
Evol. Trends Plants.
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Use of seed priming to improve Cd accumulation and tolerance in Silene sendtneri, novel Cd hyper-accumulator
2021, Ecotoxicology and Environmental SafetyCitation Excerpt :This plant has been selected as a model in this study, due to high production of seeds, the longevity of seeds (germination rate over 80% after 10-year storage; personal observation), high biomass production, It is a perennial plant which is a close relative to the highly investigated well known hyperaccumulating species Silene vulgaris. Literature data suggests that Silene vulgaris has many natural populations (ecotypes) and they can belong to heavy metal sensitive or highly tolerant populations (Chardonnens et al., 1999). Tolerant ecotypes include ecotypes that can accumulate zinc and cadmium (Ernst and Nelissen, 2000), copper (Verkleij et al., 2001), lead and nickel (Muszyńska et al., 2019) and arsenate (Sneller et al., 2000).
Contribution of mine wastes to atmospheric metal deposition in the surrounding area of an abandoned heavily polluted mining district (Rio Tinto mines, Spain)
2013, Science of the Total EnvironmentCitation Excerpt :Metal coarse particles resulting from mine waste resuspension can be deposited in the upper respiratory system, swallowed and go through the digestive system where contaminants may be absorbed, depending on their bioavailability (Krombach et al., 1997; Park and Wexler, 2008; Valiulis et al., 2008). Not only the metallic particles have a direct impact on human health, but some studies have found negative effects from metals and metalloids on plant matter also (Chardonnens et al., 1999; Ernst and Nelissen, 2000; Alonso et al., 2002; Kim et al., 2003; Youse et al., 2011). Although living organisms generally need trace amounts of elements (including metals) for good health, it has been shown that large amount of these elements may cause chronic or acute toxicity (Trepka et al., 1997; Benin et al., 1999; Küpper et al., 2002).
Cd speciation and localization in the hyperaccumulator Arabidopsis halleri
2012, Environmental and Experimental BotanyCitation Excerpt :Studying the distribution of Cd at the plant scale may reveal preferential allocation or storage in specific regions, tissues or leaves of different ages. This can be done by physical separation followed by chemical analyses (e.g., Chardonnens et al., 1999; Dahmani-Muller et al., 2000; Perronnet et al., 2003), or directly by autoradiography (e.g., Crafts and Yamaguchi, 1964; Cunningham et al., 1975; Cosio et al., 2005, 2006; Page et al., 2006; Dauthieu et al., 2009). This latter technique enables the study of plants at low metal exposure (down to 2.2 × 10−3 μM 109Cd in Cosio et al. (2005)).
A review on the importance of metals and metalloids in atmospheric dust and aerosol from mining operations
2012, Science of the Total EnvironmentDifferences in U root-to-shoot translocation between plant species explained by U distribution in roots
2010, Journal of Environmental RadioactivityCitation Excerpt :Specific distribution in plant tissues could also contribute to metal detoxification in plants. Higher Zn concentrations have been found in epidermal tissues than in mesophyll of shoots of barley (Brune et al., 1994) and Silene vulgaris (Chardonnens et al., 1999). In Thalspi caerulescens, Ma et al. (2005) measured 2-fold higher Zn and Cd concentration in epidermal tissue than in mesophyll tissue.