84K杨组培苗高效毛状根遗传转化体系构建

doi:10.11707/j.1001-7488.LYKX20250266

摘要/Abstract

摘要：

目的: 针对药用植物毛状根本源转化困难的技术难题，基于异源转化技术发展潜力，选用速生型84K杨构建高效毛状根遗传转化体系。方法: 本研究以84K杨组培苗为材料，通过比较菌株类型、外植体类型、菌液浓度、侵染时间，构建高效的毛状根遗传转化体系。进一步克隆金钗石斛萜类生物碱合成途径下游基因LOC110095726（LOC2），评估异源转化效果。结果: 最佳的诱导菌株是C58C1，21天毛状根诱导率达100%，诱导的平均根数（5.06 ± 2.36）条，平均根长为（12.83 ± 5.75） mm，且转化率为46.67% ± 11.55%；最佳的诱导外植体是叶片，14天毛状根诱导率达93.33% ± 11.55%，诱导的平均根数（3.89 ± 2.53）条，平均根长为（8.36 ± 4.24） mm；最佳的侵染浓度是0.8 （OD₆₀₀），21天毛状根诱导率达100%，诱导的平均根数为6.03 ± 2.10条，平均根长为17.77 ± 9.23 mm；最佳的侵染时间是15 min，21天毛状根诱导率达100%，诱导的平均根数为6.03 ± 2.10条，平均根长为17.76 ± 9.23 mm。成功克隆了金钗石斛LOC2基因到过表达载体，并转入发根农杆菌C58C1中，获得了LOC2的阳性毛状根。结论: 84K杨毛状根最佳的遗传转化体系为菌液浓度（OD₆₀₀）0.8的C58C1菌液侵染叶片15 min。这套方法以其简便、快捷、稳定性高等优点，可在药用植物代谢物活性成分功能验证和高活性成分植物创制中应用。该体系不仅适用于代谢途径相似的药用植物活性成分功能验证，也能为规模化生产药用活性成分提供可靠的技术基础。

关键词: 84K杨, 发根农杆菌, 毛状根, 金钗石斛, 遗传转化

Abstract:

Objective: In order to address the technical challenge of transformation of hairy roots in medicinal plants, and based on the development potential of heterologous transformation technology, the fast-growing 84K poplar was selected to construct an efficient genetic transformation system of hairy roots in this study. Method: In this study, the tissue-cultured seedlings of 84K poplar were used as materials to construct an efficient hairy root genetic transformation system by comparing the strain types, explant types, bacterial liquid concentrations, and infection times. Furthermore, the downstream gene LOC110095726 (LOC2) of the terpenoid alkaloid synthesis pathway in Dendrobium nobile was cloned, and the effect of heterologous transformation was evaluated. Result: The best inducing strain was C58C1, and the induction rate of hairy roots reached 100% after 21 days. The average number of induced roots was 5.06 ± 2.36, the average root length was （12.83 ± 5.75） mm, and the transformation rate was 46.67% ± 11.55%. The best explant for induction was the leaf, and the induction rate of hairy roots reached 93.33% ± 11.55% after 14 days, with an average number of induced roots of 3.89 ± 2.53 and an average root length of （8.36 ± 4.24） mm. The optimal infection concentration was 0.8 （OD₆₀₀） value, and, the induction rate of hairy roots reached 100% after 21 days, with the average number of induced roots of 6.03 ± 2.10, and the average root length of （17.77 ± 9.23） mm. The optimal infection time was 15 minutes, and the induction rate of hairy roots reached 100% after 21 days, with an average number of induced roots of 6.03 ± 2.10 and an average root length of （17.76 ± 9.23） mm. LOC2 gene of D. nobile was successfully cloned into an overexpression vector and transferred into Agrobacterium rhizogenes C58C1. Positive hairy roots of LOC2 were obtained in 84K poplar. Conclusion: The optimal transformation system for the hairy roots of 84K poplar is to infect the leaves with C58C1 bacterial solution at a bacterial solution concentration (OD₆₀₀) of 0.8 for 15 minutes. This set of methods, with the advantages of simplicity, rapidity, high stability, etc., can be applied in the functional verification of active ingredients of metabolites in medicinal plants and the creation of plants with high active ingredients.This system is not only applicable to the functional verification of the active ingredients of medicinal plants with similar metabolic pathways, but also provides a reliable technical basis for the large-scale production of medicinal active ingredients.

Key words: 84K poplar, Agrobacterium rhizogenes, hairy root, Dendrobium nobile, genetic transformation

中图分类号:

S792.11

焦阳,乔静,曾智新,王深,杨雪鑫,张英睿,杨玉冰,赵禹森,舒文波. 84K杨组培苗高效毛状根遗传转化体系构建[J]. 林业科学, 2026, 62(1): 122-132.

Yang Jiao,Jing Qiao,Zhixin Zeng,Shen Wang,Xuexin Yang,Yingrui Zhang,Yubing Yang,Yusen Zhao,Wenbo Shu. Construction of an Efficient Hairy Root Genetic Transformation System in 84K Poplar Tissue Culture Seedlings[J]. Scientia Silvae Sinicae, 2026, 62(1): 122-132.

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组分Component	用量Volume/μL
DNA	1
正向引物 Forward primer	1
反向引物 Reverse primer	1
2×Magic Green Taq SuperMix	10
ddH₂O	7

步骤Step	温度Temperature/℃		时间Time
预变性Pre-denaturation	95		3 min
变性Denaturation	95	35 cycles	15 s
退火Annealing	59		15 s
延伸Extension	72		30 s/kb
终延伸Final Extension	72		5 min

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