Wu Jianfei, Wang Tao, Huang Yin, Xiao Shuiping, Luo Xiaoxia, Deng Yanfeng, Yang Xiu, Kong Qingquan, Tang Feiyu
Key Laboratory of Crop Physiology, Ecology and Genetic Breeding, Ministry of Education, College of Agronomy, Jiangxi Agricultural University, Nanchang, 330045, China.
Jiangxi Provincial Key Laboratory of Plantation and High Valued Utilization of Specialty Fruit Tree and Tea, Cash Crops Research Institute of Jiangxi Province, Nanchang, 330000, China.
BMC Plant Biol. 2025 Jan 6;25(1):21. doi: 10.1186/s12870-024-06025-0.
Cotton is a non-edible fiber crop with considerable potential for the remediation of copper-polluted soil. However, the Cu toxicity tolerance mechanism in cotton remains largely obscure. To address the issue, we first identified two cotton lines contrasting in response to Cu toxicity by examining 12 morphological and physiological attributes of 43 origin scattered cotton genotypes under Cu excess. Then both lines were subjected to a comprehensive comparative study, aiming to unravel the cotton Cu tolerance mechanism through integrated morphological, physio-biochemical, Cu uptake and distribution, and related molecular expression analyses.
Based on the phenotypic values and corresponding tolerance indexes of 12 parameters, A2304 and A1415 were identified as Cu-tolerant and -sensitive, respectively. Compared to A1415, A2304 exhibited significantly higher antioxidant enzyme activities and non-enzymatic antioxidant levels, producing fewer amounts of reactive oxygen species and a lower level of malonyldialdehyde. On Cu excess, A2304 accumulated lower concentrations of Cu ions in various plant parts and subcellular components, and fewer Cu ions were presented in active chemical forms. However, the total Cu uptake amount per plant did not differ between both lines due to larger plant biomass with A2304. In contrast to A1415, Cu stress activated or increased the expressions of Cu homeostasis regulator (GhSPL7) and genes responsible for Cu delivery (GhCCS, GhCOX17), chelation (GhMT2), and compartmentation into vacuoles (GhHMA5), while inactivating or decreasing the expressions of genes accounting for Cu uptake (GhCOPT1) and Cu exporting from vacuoles (GhCOPT5) in the root cell with A2304. Additionally, A2304 may impede the root cell wall from binding Cu ions by enhancing the pectin methylesterification degree by up-regulating GhPMEI3 and GhPMEI9 encoding pectin methylesterase inhibitor and stabilizing the cell wall organization by down-regulating GhPLY8 and GhPLY20 encoding pectate lyases.
To cope with Cu toxicity, the Cu-tolerant genotype activates its antioxidative defense system, immobilizing chemically active Cu ions, and lowering the Cu uptake, bioavailability and immigration within cells by regulating the expressions of genes related to Cu uptake, transport, delivery and cell wall metabolism. This comprehensive comparison study provides insights into breeding Cu-tolerant cotton cultivars that can be utilized for the phytoremediation of Cu-contaminated soils.
棉花是一种不可食用的纤维作物,在修复铜污染土壤方面具有巨大潜力。然而,棉花对铜毒性的耐受机制在很大程度上仍不清楚。为解决这一问题,我们首先通过检测43个来自不同产地的棉花基因型在铜过量条件下的12个形态和生理特性,鉴定出两个对铜毒性反应不同的棉花品系。然后对这两个品系进行了全面的比较研究,旨在通过综合形态、生理生化、铜吸收与分配以及相关分子表达分析来揭示棉花对铜的耐受机制。
根据12个参数的表型值和相应的耐受指数,分别鉴定出A2304为耐铜品系,A1415为铜敏感品系。与A1415相比,A2304表现出显著更高的抗氧化酶活性和非酶抗氧化水平,产生的活性氧种类较少,丙二醛水平较低。在铜过量时,A2304在各植物部位和亚细胞组分中积累的铜离子浓度较低,且以活性化学形式存在的铜离子较少。然而,由于A2304的植株生物量较大,两个品系单株的总铜吸收量没有差异。与A1415相反,铜胁迫激活或增加了A2304根细胞中铜稳态调节因子(GhSPL7)以及负责铜传递(GhCCS、GhCOX17)、螯合(GhMT2)和区室化进入液泡(GhHMA5)的基因的表达,同时使负责铜吸收(GhCOPT1)和从液泡输出铜(GhCOPT5)的基因表达失活或降低。此外,A2304可能通过上调编码果胶甲酯酶抑制剂的GhPMEI3和GhPMEI9来提高果胶甲酯化程度,从而阻止根细胞壁结合铜离子,并通过下调编码果胶裂解酶的GhPLY8和GhPLY20来稳定细胞壁结构。
为应对铜毒性,耐铜基因型激活其抗氧化防御系统,固定化学活性铜离子,并通过调节与铜吸收、运输、传递和细胞壁代谢相关基因的表达,降低细胞内铜的吸收、生物有效性和迁移。这项全面的比较研究为培育可用于铜污染土壤植物修复的耐铜棉花品种提供了见解。
