[目的]利用木本植物修复重金属污染土壤是经济、安全、有效的方法.研究锌铁转运蛋白家族中SmZIP11 基因表达对吸收和转运重金属的影响,为重金属污染土壤植物修复提供重要的基因资源.[方法]采用馒头柳(Salix matsudana var.matsudana f.umbraculifera Rehd.)无性系一年生幼苗进行水培试验.幼苗在正常营养液中生长 60 天后进行重金属胁迫处理,重金属处理包括:200µmol/L ZnSO4、100µmol/L CuSO4 和100µmol/L CdSO4.在重金属处理 0、1、4、7、14 和 21 天时,取根、茎和叶组织样品提取RNA,利用实时荧光定量PCR(quantitative real-time PCR,qRT-PCR)测定SmZIP11 的表达水平.利用叶盘法将提取的SmZIP11 基因转入银灰杨(Populus×canescens)中,经卡那霉素抗性筛选共得到 8 个过表达SmZIP11 基因的转化杨树株系(OEs).选择SmZIP11 基因表达水平较高的 3 个转基因株系和野生型株系(WT)于重金属胁迫营养液中培养14 天后,测定根、茎、叶生物量和重金属含量,计算耐受性指数和转移系数.[结果]SmZIP11 基因编码区序列长度为 1053 bp,编码 351 个氨基酸,分子量为 37.71 kDa,含有 9 个保守的跨膜结构域,该基因编码的蛋白定位于细胞膜.系统进化树分析结果显示,馒头柳SmZIP11 与杨柳科的亲缘关系最近,与大戟科、锦葵科、伞形科植物的ZIP11 亲缘关系相对较远.qRT-PCR结果表明,在Zn、Cu和Cd胁迫下,馒头柳茎和叶片中的SmZIP11 比对照显著上调;在Cd和Zn胁迫下,根、茎和叶片中该基因的表达量都显著提高.在转基因杨树中,SmZIP11 基因显著增强了植株对Zn和Cu的耐受性,促进了Cd从根系向茎中转移,以及Zn向叶片中转移,同时将Cu富集在根部.与WT相比,OE7 株系对Zn的耐受指数和地上部Zn的含量及转移系数都显著提高.[结论]馒头柳SmZIP11 基因增强了转基因杨树对Cu和Zn的耐受性,并提高了从根系向地上部转移Cd和Zn的能力,为植物修复土壤重金属污染提供了基因资源和理论指导.
[Objective]Woody plants are cost-effective and friendly sources for the remediation of heavy metal-contaminated soils.Investigating the function and the effect of gene SmZIP11,a member of zinc-regulated transporter and iron-regulated transporter-like protein family,on the uptake and translocation of heavy metals will provide valuable gene resources for plant remediation strategies.[Methods]The 60-day-old rooted cuttings of willow(Salix matsudana var.matsudana f.umbraculifera Rehd.)were subjected to nutrient solutions containing 200µmol/L ZnSO4,100µmol/L CuSO4,and 100µmol/L CdSO4,respectively.At the 0,1,4,7,14,and 21 days of stress,root,stem,and leaf samples were collected for the RNA extraction and determination of the expression levels of SmZIP11 by quantitative real-time PCR(qRT-PCR).Then,the SmZIP11 genes were transfected into Populus×canescens through the leaf disk method,and eight transgenic Populus×canescens plants(OEs)were constructed.Three OE plants with high SmZIP11 expression levels and the wild Populus×canescens plant(WT)were subjected to the heavy metal stress for 14 days,then the biomass and heavy metal contents were determined for the calculation of tolerance index and translocation factor.[Results]The coding region of the SmZIP11 gene spans 1053 bp,encoding 351 amino acids with a molecular weight of 37.71 kDa.It harbors nine conserved transmembrane domains,and encoded protein was located in the cell membrane.Phylogenetic analysis revealed that SmZIP11 was closely related to Salicaceae,while showing more distant relationship to ZIP11 in Euphorbiaceae,Malvaceae,and Umbelliferaceae.SmZIP11 expression in leaves and stems were up-regulated under Zn,Cu,and Cd stress compared to the control.Meanwhile,the expression levels of SmZIP11 in roots,stems,and leaves showed a significant increase under Cd and Zn stress.In transgenic poplars,the SmZIP11 gene significantly enhanced the tolerance and transfer capabilities of Zn and Cu,facilitated Cd transfer from roots to stems and Zn to leaves,and accumulated Cu in roots.Compared to WT,OE7 plants exhibited higher tolerance to Zn,as well as Zn concentration and translocation factor in the aboveground parts.[Conclusion]SmZIP11 enhanced tolerance to Cu and Zn,and improved the ability to transfer Cd and Zn from the root system to the aboveground parts.These findings will provide genetic resources and theoretical guidance for phytoremediation of soil heavy metal pollution.
杨钰颖;陈舒鑫;于淼;贾瑜涵;陆铸畴;樊俐娇;卓仁英;韩小娇
中国林业科学研究院/林木遗传育种国家重点实验室,北京 100091||中国林业科学研究院亚热带林业研究所/浙江省林木育种重点实验室,浙江杭州 311400
馒头柳;SmZIP11基因;重金属胁迫;功能分析
Salix matsudana var.matsudana f.umbraculifera Rehd.;SmZIP11;heavy metal stress;functional analysis
《植物营养与肥料学报》 2024 (004)
689-701 / 13
国家重点研发计划项目(2021YFD2200201);国家自然科学基金项目(31872168).
10.11674/zwyf.2023511
评论