杨树蔗糖转运体基因PagSUT4的鉴定及功能分析

doi:10.11707/j.1001-7488.20160803

摘要/Abstract

摘要： [目的]植物蔗糖转运体SUTs参与蔗糖由源组织到韧皮部的装载、韧皮部的运输和由韧皮部到库组织的卸载过程，对植物生长发育至关重要。本研究通过在杨树中超表达PagSUT4基因（GenBank登录号：KX545405）并分析转基因株系的表型，探讨PagSUT4在杨树糖转运、光合作用和次生生长中的作用。[方法]利用同源基因克隆技术，克隆银腺杨PagSUT4基因；利用实时荧光定量PCR技术，分析银腺杨PagSUT4基因在根、幼叶、成熟叶、初生茎、次生茎、雄花和雌花及木质部、韧皮部中的表达。通过在烟草叶片瞬时转化35S：YFP-PagSUT4，对PagSUT4的亚细胞定位进行分析。利用Gateway技术，将PagSUT4编码区序列重组进入PMDC32载体，从而构建35S：PagSUT4载体。利用农杆菌介导法转化银腺杨，并选取PagSUT4表达量较高的2个转基因株系用于表型分析。对在温室生长2个月的转基因株系和对照植株的株高、地径、净光合速率、胞间CO₂浓度、气孔导度和蒸腾速率进行测定。此外，通过组织切片对转基因和对照植株的第7节间的解剖学特征进行分析。[结果]PagSUT4基因编码的蔗糖转运蛋白定位于液泡膜。PagSUT4基因在各组织中均有表达，并在成熟叶、次生茎、韧皮部和花中具有较高表达。基于实时荧光定量PCR分析，确认获得13个PagSUT4超表达株系，其PagSUT4在叶片中的表达量均显著高于对照。2个PagSUT4超表达株系（S1和S12）的气孔导度、蒸腾速率和水分利用效率均高于对照，而其胞间CO₂浓度低于对照；净光合速率显著高于对照，分别高出24%和21%；与对照相比，株高分别增加22%和17%，地径分别增加9%和7%。茎解剖分析发现，2个PagSUT4超表达株系第7节间木质部宽度与对照株系相比分别增加32%和21%。[结论]PagSUT4基因主要在成熟叶、次生茎和韧皮部及花中发挥作用。杨树超表达PagSUT4可能通过促进叶片中糖的外运和茎中糖的运输与卸载，提高蔗糖在源端的装载及在库端的卸载效率进而对光合作用产生正反馈效应。光合作用的增强和茎中蔗糖卸载效率的增加，促进杨树的高生长和径向生长（次生木质部发育）。

关键词: 杨树, 超表达, PagSUT4, 糖运输, 光合作用, 木质部发育

Abstract: [Objective] In higher plants, sugars function as the main energy reserves, important signaling molecules, osmotic adjustment substances and the building blocks for other organic compounds, playing important roles during the entire life cycle. As sucrose transporters(SUTs) in plant, SUTs participate in sucrose loading from source tissues to phloem, transporting in phloem, and unloading from phloem to sink tissues. Therefore, SUTs are important in plant growth and development. There are big differences in sink tissues between woody plants and annual herbs and the carbon allocation mechanism in woody plants needs further investigation. In the present study, to further investigate the roles of PagSUT4 (GenBank No. KX545405) in sugar transportation, photosynthesis, and secondary growth, we generated PagSUT4 overexpression Populus lines and analyzed their phenotypes.[Method] The coding sequence of PagSUT4 was cloned using gene-specific primers from hybrid poplar clone 84K (Populus alba×P.glandulosa). The PagSUT4 expressions in roots, young leaves, mature leaves, primary stem, secondary stem, male flowers, female flowers, xylem and phloem were examined using qRT-PCR. To analyze the subcellular localization of PagSUT4, the gene was transiently expressed in tobacco leaf epidermal cells fused with YFP to its C-terminus. The coding sequence was cloned into PMDC32 to produce the 35S:PagSUT4 construct, and the latter was transformed into poplar 84K mediated by Agrobacterium tumefaciens and the transgenic lines with high expression of PagSUT4 were selected for further phenotypic analysis. The stem length, ground diameter, photosynthetic rate, intercellular CO₂ concentration, conductance to H₂O and transpiration rate of 2-month-old transgenic lines and non-transgenic controls in the greenhouse were measured. Moreover, the anatomy of stem sections of the 7^th internodes from them was performed.[Result] The results showed that PagSUT4 gene encoding a tonoplast-localized sucrose transporter. The PagSUT4 gene were ubiquitously expressed and showed high expression level in mature leaves, lignified stem, phloem and flowers. 13 transgenic lines with overexpression of PagSUT4 were obtained and the level of expression in leaves was significantly higher than that in the control. Stomatal conductance, transpiration rate and water use efficiency of the selected transgenic lines (S1 and S12) were higher than that of the non-transgenic controls, while the intercellular CO₂ concentration was lower in transgenic lines than that of the controls. The 2 transgenic lines exhibited 24% and 21% higher photosynthetic rate compared with the non-transgenic controls, respectively. The transgenic lines showed 22% and 17% increase in stem height, 9% and 7% increase in ground diameter, respectively. In addition, the two transgenic lines showed 32% and 21% increase in the xylem width of the seventh internodes, respectively.[Conclusion] Overall, PagSUT4 functions in mature leaves, secondary stem, phloem and flowers. Overexpression of PagSUT4 may promote the sucrose efflux from the leaves, the sucrose transport and unloading in the stem, have positive feedback effect on the photosynthesis through the enhancement of sucrose loading in source tissues and the unloading in sink tissues. The enhanced photosynthesis and increased sucrose unloading efficiency in the stem have promoted both height and diameter growth (development of secondary xylem) of the transgenic poplar trees.

Key words: Populus, overexpression, PagSUT4, sugar transport, photosynthesis, xylem development

中图分类号:

S718.46

张利, 徐向东, 王丽娟, 卢孟柱. 杨树蔗糖转运体基因PagSUT4的鉴定及功能分析[J]. 林业科学, 2016, 52(8): 21-28.

Zhang Li, Xu Xiangdong, Wang Lijuan, Lu Mengzhu. Identification and Functional Analysis of the Populus Sucrose Transporter Gene PagSUT4[J]. Scientia Silvae Sinicae, 2016, 52(8): 21-28.

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