通过基因组编辑和转化提高植物修复潜力:综述
Increase in Phytoextraction Potential by Genome Editing and Transformation: A Review.
作者信息
Venegas-Rioseco Javiera, Ginocchio Rosanna, Ortiz-Calderón Claudia
机构信息
Departamento de Ecosistemas y Medio Ambiente, Facultad de Agronomía e Ingeniería Forestal, Pontificia Universidad Católica de Chile, Santiago 7820436, Chile.
Center of Applied Ecology and Sustainability, Pontificia Universidad Católica de Chile, Santiago 8331150, Chile.
出版信息
Plants (Basel). 2021 Dec 28;11(1):86. doi: 10.3390/plants11010086.
Abstract
Soil metal contamination associated with productive activities is a global issue. Metals are not biodegradable and tend to accumulate in soils, posing potential risks to surrounding ecosystems and human health. Plant-based techniques (phytotechnologies) for the in situ remediation of metal-polluted soils have been developed, but these have some limitations. Phytotechnologies are a group of technologies that take advantage of the ability of certain plants to remediate soil, water, and air resources to rehabilitate ecosystem services in managed landscapes. Regarding soil metal pollution, the main objectives are in situ stabilization (phytostabilization) and the removal of contaminants (phytoextraction). Genetic engineering strategies such as gene editing, stacking genes, and transformation, among others, may improve the phytoextraction potential of plants by enhancing their ability to accumulate and tolerate metals and metalloids. This review discusses proven strategies to enhance phytoextraction efficiency and future perspectives on phytotechnologies.
摘要
与生产活动相关的土壤金属污染是一个全球性问题。金属不可生物降解,往往会在土壤中积累,对周围的生态系统和人类健康构成潜在风险。已经开发出用于原位修复金属污染土壤的基于植物的技术(植物修复技术),但这些技术存在一些局限性。植物修复技术是利用某些植物修复土壤、水和空气资源的能力来恢复管理景观中的生态系统服务的一组技术。关于土壤金属污染,主要目标是原位稳定(植物稳定)和去除污染物(植物提取)。基因编辑、基因堆叠和转化等基因工程策略,以及其他策略,可能通过增强植物积累和耐受金属及类金属的能力来提高植物提取的潜力。本综述讨论了提高植物提取效率的已证实策略以及植物修复技术的未来前景。
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2
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3
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