The reaction center is the sensitive target of the mercury(II) ion in intact cells of photosynthetic bacteria

Asztalos, Emese; Sipka, Gábor; Kis, Mariann; Trotta, Massimo; Maróti, Péter

doi:10.1007/s11120-012-9749-2

Cited by 26 publications

(24 citation statements)

References 41 publications

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“…Mercury affects both light and dark reactions of bacterial photosynthesis and strongly inhibits the photosynthetic electron transport chain in which the reaction center (RC) protein is the most sensitive target (Asztalos et al 2012;Kis et al 2015). On the acceptor side, the Hg-induced inhibition is attributed to the damage of the interquinone electron transfer from QA to QB and/or to the increase of the fraction of closed RCs (QA − ).…”

Section: Introductionmentioning

confidence: 99%

Stoichiometry and kinetics of mercury uptake by photosynthetic bacteria

2017

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Mercury adsorption on the cell surface and intracellular uptake by bacteria represent the key first step in the production and accumulation of highly toxic mercury in living organisms. In this work, the biophysical characteristics of the mercury bioaccumulation are studied in intact cells of photosynthetic bacteria by use of analytical (dithizone) assay and physiological photosynthetic markers (pigment content, fluorescence induction and membrane potential) to determine the amount of mercury ions bound to the cell surface and taken up by the cell. It is shown that the Hg(II) uptake mechanism 1) has two kinetically distinguishable components, 2) includes co-opted influx through heavy metal transporters since the slow component is inhibited by Ca 2+ channel blockers, 3) shows complex pH-dependence demonstrating the competition of ligand binding of Hg(II) ions with H + ions (low pH) and high tendency of complex formation of Hg(II) with hydroxyl ions (high pH) and 4) is not a passive but an energy-dependent process as evidenced by light-activation and inhibition by protonophore. Photosynthetic bacteria can accumulate Hg(II) in amounts much (about 10 5 ) greater than their own masses by well defined strong and weak binding sites with equilibrium binding constants in the range of 1 (μM) -1 and 1 (mM) -1 , respectively. The strong binding sites are attributed to sulfhydryl groups as the uptake is blocked by use of sulfhydryl modifying agents and their number is much (two orders of magnitude) smaller than the number of weak binding sites. Biofilms developed by some bacteria (e.g. Rvx. gelatinosus) increase the mercury binding capacity further by a factor of about five. Photosynthetic bacteria in the light act as sponge of Hg(II) and can be potentially used for biomonitoring and bioremediation of mercury contaminated aqueous cultures.2

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Section: Introductionmentioning

confidence: 99%

Stoichiometry and kinetics of mercury uptake by photosynthetic bacteria

2017

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“…Mercury and its compounds are considered to be potentially hazardous to all biological organisms (Asztalos et al 2012;Boening 2000;Chen and Yang 2012). Mercury cannot be destroyed biologically but only transformed into volatile metallic mercury, HgO (Hobman and Brown 1997) or biomethylated by a number of bacterial species to gaseous methyl mercury (De et al 2008) or dimethyl mercury (Rodriguez et al 2005).…”

Section: Introductionmentioning

confidence: 99%

Ecological strategy for soil contaminated with mercury

et al. 2016

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Aims The paper presents results from plot experiments aimed at the development of an ecological strategy for soil contaminated with mercury. Meadow grass (Poa pratensis) was tested on mercury contaminated soil in a former chlor-alkali plant (CAP) in southern Poland for its phytoremediation potential. Methods The stabilisation potential of the plants was investigated on plots without additives and after the addition of granular sulphur. Biomass production, uptake and distribution of mercury by plants, as well as leachates and rhizosphere microorganisms were investigated, along with the growth and vitality of plants during one growing season. Results The analysed plants grew easily on mercury contaminated soil, accumulating lower amounts of mercury, especially in the roots, from soil with additive of granular sulphur (0.5 % w/w) and sustained a rich microbial population in the rhizosphere. After amendment application the reduction of Hg evaporation was observed.Conclusions The obtained results demonstrate the potential of using Poa pratensis and sulphur for remediation of mercury contaminated soil and reduction of the Hg evaporation from soil. In the presented study, methods of Hg reduction on Bhot spots^were proposed, with a special focus on environmental protection. This approach provides a simple remediation tool for large areas heavily contaminated with mercury.

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“…In higher plants, photosynthesis is reduced indirectly by heavy metal accumulation in leaves which influences the stomata performance (Yu et al, 2014a,b). In addition, Hg 2+ ions affected both light and dark reactions of photosynthesis and strongly inhibited the photosynthetic electron transport chain, photosystem (PS) II being the most sensitive target (Asztalos et al, 2012). In this research, the absorption and accumulation of heavy metal ion Hg 2+ led to the drop in Pn of wheat seedlings to some extent at different times.…”

Section: Discussionmentioning

confidence: 74%

Dynamic change of wheat eco-physiology and implications for establishing high-efficient stable agro-ecosystems under Hg stress

Halin

Song

Han

et al. 2014

Ecological Engineering

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a b s t r a c tHeavy metal-poisoning exerts the serious influence on crops growth, yield and quality. This research has focused on the impacts of HgCl 2 with different concentrations on the dynamic trends of photosynthesis, transpiration and water use efficiency (WUE) by using different wheat varieties as materials. The results showed that under 100 M HgCl 2 treatment, wheat leaf photosynthetic rate (Pn) and transpiration rate (Tr) exhibited significant changes, but photosynthetic characteristics presented no obvious regularity, and this kind of impact exerted the critical effects on different Hg 2+ concentrations. Similar changes sometimes appeared under low concentration and concentrations. WUE changed more regularly, and WUE of each wheat variety tended to drop after Hg 2+ treatments, except the individual concentration treatment. This change indicated that HgCl 2 treatment changed normal transpiration and photosynthesis, which led to the changes in leaf water use efficiency and related wheat eco-physiological parameters. All these results provide valuable information for establishing high-efficient stable agro-ecosystems in abiotic-stress area.

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The reaction center is the sensitive target of the mercury(II) ion in intact cells of photosynthetic bacteria

Cited by 26 publications

References 41 publications

Stoichiometry and kinetics of mercury uptake by photosynthetic bacteria

Stoichiometry and kinetics of mercury uptake by photosynthetic bacteria

Ecological strategy for soil contaminated with mercury

Dynamic change of wheat eco-physiology and implications for establishing high-efficient stable agro-ecosystems under Hg stress

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