The morphogenic responses and phytochelatin complexes induced by arsenic in Pteris vittata change in the presence of cadmium

M. Ronzan; L.  Zanella; L.  Fattorini; D. Rovere; D. Urgast; S.  Cantamessa; A.  Nigro; M.  Barbieri; L. Sanita di Toppi; G.  Berta; J. Feldmann; MM.  Altamura; G.  Falasca

doi:10.1016/j.envexpbot.2016.10.011

The morphogenic responses and phytochelatin complexes induced by arsenic in Pteris vittata change in the presence of cadmium

M. Ronzan, L. Zanella, L. Fattorini, D. Rovere, D. Urgast, S. Cantamessa, A. Nigro, M. Barbieri, L. Sanita di Toppi, G. Berta, J. Feldmann, MM. Altamura, G. Falasca

Chemistry

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Abstract

Arsenic (As) and cadmium (Cd) are toxic elements frequently present simultaneously in the environment. Pteris vittata L. (Chinese brake fern) is a natural As hyperaccumulator, able to accumulate very high levels of As in the fronds. The fern is also capable to adsorb Cd and to accumulate it, at moderate levels, in the root. To date, the mechanisms triggered by the fern in the presence of As and Cd are poorly known, and it is unknown whether Cd alters the fern As hyperaccumulating capabilities. The research aim was to analyse the responses of P. vittata when exposed simultaneously to As and Cd. In particular, in this work it was investigated whether Cd alters the capabilities/strategies that the fern activates to hyperaccumulate As. Results showed that co-exposure to Cd and As negatively affects P. vittata by inducing cyto-histological damage in the fronds, and reducing plant biomass. Cadmium presence increases As uptake but reduces As translocation to the frond. Co-exposure to Cd and As causes variations in the formation of As-phytochelatin complexes, mainly inducing the synthesis of long chain thiols binding As. Moreover, the co-exposure to Cd and As enhances extrusion of exudates containing As and Cd from the fronds. All together the data show that Cd alters the natural capabilities of the fern to hyperaccumulate As, but also suggest that P.vittata is able to contrast the toxicity due to As plus Cd, at least within defined limits.

Original language	English
Pages (from-to)	176-187
Number of pages	12
Journal	Environmental and Experimental Botany
Volume	133
Early online date	17 Oct 2016
DOIs	https://doi.org/10.1016/j.envexpbot.2016.10.011
Publication status	Published - Jan 2017

Bibliographical note

This work was supported by Progetti Ateneo Sapienza University of Rome (Year 2013 − prot. C26A138JM3 and Year 2014 − prot. C26A14AFZ7) to G.F.

Keywords

arsenic
As-PCs
cadmium
frond damages
metal/metalloid frond extrusion
Pteris vittata

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Ronzan, M., Zanella, L., Fattorini, L., Rovere, D., Urgast, D., Cantamessa, S., Nigro, A., Barbieri, M., di Toppi, L. S., Berta, G., Feldmann, J., Altamura, MM., & Falasca, G. (2017). The morphogenic responses and phytochelatin complexes induced by arsenic in Pteris vittata change in the presence of cadmium. Environmental and Experimental Botany, 133, 176-187. https://doi.org/10.1016/j.envexpbot.2016.10.011

Ronzan, M, Zanella, L, Fattorini, L, Rovere, D, Urgast, D, Cantamessa, S, Nigro, A, Barbieri, M, di Toppi, LS, Berta, G, Feldmann, J, Altamura, MM & Falasca, G 2017, 'The morphogenic responses and phytochelatin complexes induced by arsenic in Pteris vittata change in the presence of cadmium', Environmental and Experimental Botany, vol. 133, pp. 176-187. https://doi.org/10.1016/j.envexpbot.2016.10.011

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title = "The morphogenic responses and phytochelatin complexes induced by arsenic in Pteris vittata change in the presence of cadmium",

abstract = "Arsenic (As) and cadmium (Cd) are toxic elements frequently present simultaneously in the environment. Pteris vittata L. (Chinese brake fern) is a natural As hyperaccumulator, able to accumulate very high levels of As in the fronds. The fern is also capable to adsorb Cd and to accumulate it, at moderate levels, in the root. To date, the mechanisms triggered by the fern in the presence of As and Cd are poorly known, and it is unknown whether Cd alters the fern As hyperaccumulating capabilities. The research aim was to analyse the responses of P. vittata when exposed simultaneously to As and Cd. In particular, in this work it was investigated whether Cd alters the capabilities/strategies that the fern activates to hyperaccumulate As. Results showed that co-exposure to Cd and As negatively affects P. vittata by inducing cyto-histological damage in the fronds, and reducing plant biomass. Cadmium presence increases As uptake but reduces As translocation to the frond. Co-exposure to Cd and As causes variations in the formation of As-phytochelatin complexes, mainly inducing the synthesis of long chain thiols binding As. Moreover, the co-exposure to Cd and As enhances extrusion of exudates containing As and Cd from the fronds. All together the data show that Cd alters the natural capabilities of the fern to hyperaccumulate As, but also suggest that P.vittata is able to contrast the toxicity due to As plus Cd, at least within defined limits.",

keywords = "arsenic, As-PCs, cadmium, frond damages, metal/metalloid frond extrusion, Pteris vittata",

author = "M. Ronzan and L. Zanella and L. Fattorini and D. Rovere and D. Urgast and S. Cantamessa and A. Nigro and M. Barbieri and {di Toppi}, {L. Sanita} and G. Berta and J. Feldmann and MM. Altamura and G. Falasca",

note = "This work was supported by Progetti Ateneo Sapienza University of Rome (Year 2013 − prot. C26A138JM3 and Year 2014 − prot. C26A14AFZ7) to G.F.",

year = "2017",

month = jan,

doi = "10.1016/j.envexpbot.2016.10.011",

language = "English",

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journal = "Environmental and Experimental Botany",

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T1 - The morphogenic responses and phytochelatin complexes induced by arsenic in Pteris vittata change in the presence of cadmium

AU - Ronzan, M.

AU - Zanella, L.

AU - Fattorini, L.

AU - Rovere, D.

AU - Urgast, D.

AU - Cantamessa, S.

AU - Nigro, A.

AU - Barbieri, M.

AU - di Toppi, L. Sanita

AU - Berta, G.

AU - Feldmann, J.

AU - Altamura, MM.

AU - Falasca, G.

N1 - This work was supported by Progetti Ateneo Sapienza University of Rome (Year 2013 − prot. C26A138JM3 and Year 2014 − prot. C26A14AFZ7) to G.F.

PY - 2017/1

Y1 - 2017/1

N2 - Arsenic (As) and cadmium (Cd) are toxic elements frequently present simultaneously in the environment. Pteris vittata L. (Chinese brake fern) is a natural As hyperaccumulator, able to accumulate very high levels of As in the fronds. The fern is also capable to adsorb Cd and to accumulate it, at moderate levels, in the root. To date, the mechanisms triggered by the fern in the presence of As and Cd are poorly known, and it is unknown whether Cd alters the fern As hyperaccumulating capabilities. The research aim was to analyse the responses of P. vittata when exposed simultaneously to As and Cd. In particular, in this work it was investigated whether Cd alters the capabilities/strategies that the fern activates to hyperaccumulate As. Results showed that co-exposure to Cd and As negatively affects P. vittata by inducing cyto-histological damage in the fronds, and reducing plant biomass. Cadmium presence increases As uptake but reduces As translocation to the frond. Co-exposure to Cd and As causes variations in the formation of As-phytochelatin complexes, mainly inducing the synthesis of long chain thiols binding As. Moreover, the co-exposure to Cd and As enhances extrusion of exudates containing As and Cd from the fronds. All together the data show that Cd alters the natural capabilities of the fern to hyperaccumulate As, but also suggest that P.vittata is able to contrast the toxicity due to As plus Cd, at least within defined limits.

AB - Arsenic (As) and cadmium (Cd) are toxic elements frequently present simultaneously in the environment. Pteris vittata L. (Chinese brake fern) is a natural As hyperaccumulator, able to accumulate very high levels of As in the fronds. The fern is also capable to adsorb Cd and to accumulate it, at moderate levels, in the root. To date, the mechanisms triggered by the fern in the presence of As and Cd are poorly known, and it is unknown whether Cd alters the fern As hyperaccumulating capabilities. The research aim was to analyse the responses of P. vittata when exposed simultaneously to As and Cd. In particular, in this work it was investigated whether Cd alters the capabilities/strategies that the fern activates to hyperaccumulate As. Results showed that co-exposure to Cd and As negatively affects P. vittata by inducing cyto-histological damage in the fronds, and reducing plant biomass. Cadmium presence increases As uptake but reduces As translocation to the frond. Co-exposure to Cd and As causes variations in the formation of As-phytochelatin complexes, mainly inducing the synthesis of long chain thiols binding As. Moreover, the co-exposure to Cd and As enhances extrusion of exudates containing As and Cd from the fronds. All together the data show that Cd alters the natural capabilities of the fern to hyperaccumulate As, but also suggest that P.vittata is able to contrast the toxicity due to As plus Cd, at least within defined limits.

KW - arsenic

KW - As-PCs

KW - cadmium

KW - frond damages

KW - metal/metalloid frond extrusion

KW - Pteris vittata

U2 - 10.1016/j.envexpbot.2016.10.011

DO - 10.1016/j.envexpbot.2016.10.011

M3 - Article

SN - 0098-8472

VL - 133

SP - 176

EP - 187

JO - Environmental and Experimental Botany

JF - Environmental and Experimental Botany

ER -

The morphogenic responses and phytochelatin complexes induced by arsenic in Pteris vittata change in the presence of cadmium

Abstract

Bibliographical note

Keywords

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