Absorption and subcellular distribution of cadmium in tea plant (Camellia sinensis cv. “Shuchazao”)

Cao, De-ju; Yang, Xihua; Geng, Geng; Wan, Xiaochun; Ma, Ru-xiao; Zhang, Qian; Liang, Yue-gan

doi:10.1007/s11356-018-1671-5

Cited by 21 publications

(10 citation statements)

References 51 publications

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“…Cd in cell walls represented only 11% of the metal content (Carrier et al, 2003). In tea seedlings, most of the Cd accumulated in roots, with about 12% to 30% in the cell walls, while cell wall represented 43.6-83.4% of the very low Cd content in leaves (Cao et al, 2018a). Cosio et al (2005) showed that 33-35% of Cd in the aerial parts of N. caerulescens is in the cell walls.…”

Section: B Storage In the Apoplastmentioning

confidence: 99%

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Mechanisms of Cadmium Accumulation in Plants

Sterckeman

Thomine

2020

Critical Reviews in Plant Sciences

171

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Cadmium is a non-essential trace metal, which is highly toxic to nearly all living organisms. Soil pollution causes Cd contamination of crops, thereby rendering plant products responsible for the chronic low level Cd over-exposure of numerous populations in the world. For this reason, Cd accumulation in plants has been studied for about five decades now. The research first focused on the relationships between plant and soil Cd levels, on the factors of the metal availability in soil, as well as the root uptake processes. Cd distribution in plant organs was also investigated, first using a macroscopic and eco-physiological approach, then with the help of molecular biology tools, at both tissue and cell scale. Cadmium has no biological function and hijacks the transport pathways of micronutrients such as Fe, Mn or Zn, in order to enter the plant through the roots and be distributed to all its organs. The study of the genes that control the influx and efflux of the Cd 2 + ion in the cytosol, vacuoles and vascular tissues has significantly contributed to the understanding of the metal root uptake and of its transfer to the aerial parts. However, the mechanisms responsible for its distribution to the different aboveground tissues and specially to fruits and seeds have yet to be clarified. This review summarizes current knowledge in order to present a detailed overview of Cd transport and storage, from the rhizosphere to the different organs and tissues of the plant.

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Section: B Storage In the Apoplastmentioning

confidence: 99%

“…It should be noted that in several of the above-cited works (Lozano-Rodriguez et al, 1997;Carrier et al, 2003;Cao et al, 2018a), as well as in others (e.g. (Fu et al, 2011;Wang et al, 2015a;Wang et al, 2015b), the method used to determine Cd (or other elements) in cell walls is questionable.…”

Section: B Storage In the Apoplastmentioning

confidence: 99%

Mechanisms of Cadmium Accumulation in Plants

Sterckeman

Thomine

2020

Critical Reviews in Plant Sciences

171

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“…Wang et al found that under low-concentration Cd stress, more than 50% of Cd is combined in the f1 of the root cells of pakchoi varieties Huajun2 and Hanlv, a large amount of Cd enters f3 under higher Cd stress, and the proportion of Cd in f1 is decreased [5]. Yang et al found that the Cd distribution in rice roots is f3 > f1 > f2, and with the increase in the Cd stress, the proportion of Cd in the soluble and cell wall fraction increases significantly [61], which is similar to that in Camellia sinensis L. [62] and Phytolacca americane L. [63]. This may be due to the fixation of Cd in the cell wall after saturation; Cd is transported to the vacuole, and combined with the organic acid, organic base and protein in the vacuole to form a compartmentalization of the vacuole, thereby reducing the distribution of Cd in the organelles [63].…”

Section: Root Cell Wall Might Play a Key Role In The CD Accumulationmentioning

confidence: 72%

Accumulation Mechanism and Risk Assessment of Artemisia selengensis Seedling In Vitro with the Hydroponic Culture under Cadmium Pressure

Tang

Wei

Shen

et al. 2022

IJERPH

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Artemisia selengensis is a perennial herb of the Compositae with therapeutic and economic value in China. The cadmium (Cd) accumulation mechanism and healthy risk evaluation of A. selengensis were investigated in this study. Tissue culture seedlings were obtained by plant tissue culture in vitro, and the effect of Cd stress (Cd concentration of 0.5, 1, 5, 10, 25, 50 and 100 μM) on A. selengensis was studied under hydroponic conditions. The results showed that low-Cd (0.5–1 μM) stress caused a rare effect on the growth of A. selengensis seedlings, which regularly grew below the 10 μM Cd treatment concentration. The biomass growth rate of the 0.5, 1, and 5 μM treatment groups reached 105.8%, 96.6%, and 84.8% after 40 days of cultivation, respectively. In addition, when the concentration of Cd was greater than 10 μM, the plant growth was obviously inhibited, i.e., chlorosis of leaves, blackening roots, destroyed cell ultrastructure, and increased malondialdehyde (MDA) content. The root could be the main location of metal uptake, 57.8–70.8% of the Cd was concentrated in the root after 40 days of cultivation. Furthermore, the root cell wall was involved in the fixation of 49–71% Cd by subcellular extraction, and the involvement of the participating functional groups of the cell wall, such as -COOH, -OH, and -NH2, in metal uptake was assessed by FTIR analysis. Target hazard quotient (THQ) was used to assess the health risk of A. selengensis, and it was found that the edible part had no health risk only under low-Cd stress (0.5 to 1 μM) and short-term treatment (less than 20 days).

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“…More recently, Huang et al (2017b) described the protective role of Ca against Cdinduced toxicity in plants. In a similar study, Cao et al (2018) described how the homeostasis of Ca and Mg in Camellia sinensis after Cd treatment was affected at Cd concentrations between 1 and 15 mg/L, noting that the intracellular Ca content in leaves increased with increasing Cd stress, but was much less pronounced for Mg. As documented by Yang et al (2015), treating horseradish roots with Tb(III) resulted in Tb(III) accumulation in both the extracellular and intracellular spaces of the roots, accompanied by increasing intracellular Ca content as well. These various studies confirm that plant cells do respond to PTM stress with an increased concentration of intracellular Ca.…”

Section: Resultsmentioning

confidence: 98%

Plant cell (Brassica napus) response to europium(III) and uranium(VI) exposure

Moll

Sachs

Geipel

2020

Environ Sci Pollut Res

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Experiments conducted over a period of 6 weeks using Brassica napus callus cells grown in vitro under Eu(III) or U(VI) stress showed that B. napus cells were able to bioassociate both potentially toxic metals (PTM), 628 nmol Eu/gfresh cells and 995 nmol U/gfresh cells. Most of the Eu(III) and U(VI) was found to be enriched in the cell wall fraction. Under high metal stress (200 μM), cells responded with reduced cell viability and growth. Subsequent speciation analyses using both metals as luminescence probes confirmed that B. napus callus cells provided multiple-binding environments for Eu(III) and U(VI). Moreover, two different inner-sphere Eu3+ species could be distinguished. For U(VI), a dominant binding by organic and/or inorganic phosphate groups of the plant biomass can be concluded.

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Absorption and subcellular distribution of cadmium in tea plant (Camellia sinensis cv. “Shuchazao”)

Cited by 21 publications

References 51 publications

Mechanisms of Cadmium Accumulation in Plants

Mechanisms of Cadmium Accumulation in Plants

Accumulation Mechanism and Risk Assessment of Artemisia selengensis Seedling In Vitro with the Hydroponic Culture under Cadmium Pressure

Plant cell (Brassica napus) response to europium(III) and uranium(VI) exposure

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