毛白杨叶片再繁和遗传转化体系的优化

doi:10.7525/j.issn.1673-5102.2016.02.004

摘要/Abstract

摘要： 主要对毛白杨的叶片再繁和遗传转化体系进行了优化，通过对影响组织培养效率的叶片分化方式、生根培养基、激素组合等因素的筛选和影响遗传转化效率的外植体选材、菌液浓度两个主要因素的研究，得出以下主要结果：叶片通过直接分化培养的方式，20 d即可形成丛芽；6-BA和TDZ(Thidiazuron)激素混合使用可促进叶片分化，叶片分化率可达100%；增加芽伸长步骤提高了单片叶的繁殖系数；生根培养基凝固剂使用水晶洋菜（Gelrite）代替琼脂（Agar），幼芽8 d即可生根，侧根多、长，有二级侧根，根的生长状态良好。对于转化效率，不同茎段继代数的叶片外植体均可用于进行转化，但是继代次数越多，转化效率越低，选择初代培养植株的叶片作外植体，愈伤形成率83.5%，阳性植株得率100%，转化效率可达55%以上。这是一种明显不同于已发表过的具有高效率的毛白杨遗传转化方法。叶片再繁采用直接分化方式，6-BA和TDZ激素混合使用和增加芽伸长步骤，提高了叶片的组织培养效率；生根培养基使用水晶洋菜做凝固剂，无需添加促进生根的激素，有利于植株生长；初代培养植株的叶片外植体，更适合毛白杨的遗传转化。

关键词: 毛白杨, 叶片再繁, 遗传转化, TDZ

Abstract: The experiment was conducted to optimize leaf regeneration and genetic transformation of Populus tomentosa, and performed to select best leaf regenerative method, rooting medium, with an emphasis on hormone combination and compositions, and to select best explants and Agrobacterium concentration. We demonstrated that twenty days were needed for generation of cluster buds through direct differentiation of leaf tissues. With the mixed hormones of 6-BA and TDZ, we observed the 100% leaf differentiation. Further, the propagation coefficient of single leaf was improved by the step of shoot elongation. We also drastically improved root initiation and growth if gelrite was used when compared to commonly used agar, judging with the number and the length of the roots, and the shoots can root for about eight days. For genetic transformation efficiencies, our experiment showed that leaf explants after numerous subcultures can be infected by Agrobacterium but the transformation efficiency was reduced, if the primary cultured leaves were selected as explants and the concentration of bacteria liquid was OD₆₀₀=0.3, transgenic callus formation was greater than 83.5%, all shoots survived the antibiotic selection were 100% transgenic, and the transformation efficiency was more than 55%. We report a highly efficient genetic transformation method for P.tomentosa, it is significantly different from the previously published methods. The regeneration of leaf discs through direct differentiation, the mixed use of hormone 6-BA and TDZ, and the step of shoot elongation can improve the efficiency of leaf tissue culture, also using gelrite as the coagulant in rooting medium without the addition of hormone promotes the initiation and growth of roots, and improves the plant growth as well. The primary cultured leaves are more suitable for genetic transformation of P.tomentosa.

Key words: Populus tomentosa, leaf regeneration, genetic transformation, TDZ

李春利；王孝敬；丁强强；吴寒*. 毛白杨叶片再繁和遗传转化体系的优化[J]. 植物研究, doi: 10.7525/j.issn.1673-5102.2016.02.004.

LI Chun-Li；WANG Xiao-Jing；DING Qiang-Qiang；WU Han*. Optimization of Leaf Regeneration and Genetic Transformation System of Populus tomentosa[J]. Bulletin of Botanical Research, doi: 10.7525/j.issn.1673-5102.2016.02.004.

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