Arsenic tolerance mechanisms in halophytes: the case of Tamarix gallica.

Halophytes and climate change: adaptive mechanisms and potential uses Pub Date : 1900-01-01 DOI:10.1079/9781786394330.0255

D. B. Sghaier, S. Pedro, B. Duarte, I. Caador, N. Sleimi

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引用次数: 4

Abstract

Abstract Toxic compounds in the ecosphere are the consequence of environmental pollution, and have a disruptive influence in the environment. They affect ecosystems, entering food chains and ultimately touching human health. Metal consumption has increased by 300% in the last 50 years and the anthropogenic release of metallic elements such as Pb, Hg, As, Cd, Al and Cr has increased since the beginning of the industrial era. Different strategies have been identified to overcome metallic stress. Knowledge of plant stress responses and adaptations at physiological, biochemical and cellular levels is a priority in understanding the impact of these constraints on plant biodiversity. These adaptations have evolved naturally in halophytes as responses to their colonization of saline ecosystems, and therefore make halophytes good model plants. In this chapter we discuss the biophysical mechanisms underlying energy capture and transduction in halophytes and their relation to pigment profile alteration, compartmentation and subcellular localization, to devise sustainable strategies for environmental or ecosystem management and safety.

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盐生植物的砷耐受机制:以高卢柽柳为例。

生态圈中的有毒化合物是环境污染的结果，对环境具有破坏性影响。它们影响生态系统，进入食物链，最终影响人类健康。金属消费量在过去50年中增加了300%，自工业时代开始以来，人为释放的金属元素如Pb、Hg、as、Cd、Al和Cr有所增加。已经确定了不同的策略来克服金属应力。了解植物在生理、生化和细胞水平上的胁迫反应和适应是理解这些限制对植物生物多样性影响的优先事项。这些适应是盐生植物对其在盐碱地生态系统中定居的自然反应，因此使盐生植物成为良好的模式植物。在本章中，我们讨论了盐生植物能量捕获和转导的生物物理机制，以及它们与色素谱改变、区隔和亚细胞定位的关系，以制定可持续的环境或生态系统管理和安全策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Halophytes and climate change: adaptive mechanisms and potential uses

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