木糖选择系统下xylA & BADH双价基因对二色胡枝子的遗传转化

doi:10.11707/j.1001-7488.20210608

摘要/Abstract

摘要：

目的: 建立安全、无抗生素的二色胡枝子遗传转化体系，通过基因工程技术进一步提高二色胡枝子的抗逆性。方法: 采用PCR法从大肠杆菌DH5α菌株中克隆木糖异构酶基因（xylA）；构建含有xylA和甜菜碱醛脱氢酶基因（BADH）的植物表达载体pBI121-xylA-BADH；培养基中用木糖取代一定量的蔗糖建立二色胡枝子的木糖选择系统；以农杆菌介导法对二色胡枝子的子叶节进行遗传转化，通过PCR和Southern检测确定转基因植株；对转化植株及非转化植株进行0.5~2 g·L^-1NaCl胁迫，观测植株生长表现，测定1 g·L^-1NaCl胁迫下转化植株和非转化植株的甜菜碱醛脱氢酶活性、叶绿素、电导率。提取转化植株及非转化植株组培苗叶片中的可溶性总糖，用高效液相色谱仪分析糖成分。结果: 测序结果表明，克隆的木糖异构酶基因与GenBank公布的大肠杆菌xylA核苷酸序列的同源性达到100%，PCR及酶切检测表明正确构建了pBI121-xylA-BADH植物表达载体。在二色胡枝子遗传转化过程中，应在纯木糖培养基上筛选抗性芽，在抗性芽增殖和生根过程中，可以采用蔗糖5 g·L^-1、木糖25 g·L^-1的糖类混合剂进行进一步筛选。在农杆菌介导的遗传转化中，外植体预培养1天后，采用LBA4404菌株侵染20~30 min，共培养3天，可以获得相对较多的木糖抗性芽。对获得的部分抗性芽进行PCR及Southern检测，得到2个转基因株系，二色胡枝子遗传转化率低于4.7%。耐盐性观测表明，转基因植株能够在含有2 g·L^-1NaCl的培养基上生长并生根，而非转基因植株在相同培养基上则叶子变黄、脱落，且不能生根。无盐胁迫时，转基因和非转基因植株在甜菜碱醛脱氢酶活性、叶绿素含量和电导率方面无显著性差异；盐胁迫后，非转基因植株的甜菜碱醛脱氢酶活性无明显变化，而转基因植株的甜菜碱醛脱氢酶活性大幅度提升，且达到非转基因植株的8~10倍；盐胁迫后，转基因植株的叶绿素含量显著高于非转基因植株，而电导率则显著低于非转基因植株。高效液相色谱的分析结果显示，转基因植株叶片中测出了果糖和葡萄糖，而非转基因植株叶片中测出了葡萄糖和一种未标示的糖类。结论: 建立了二色胡枝子在木糖选择系统下的遗传转化体系，并获得稳定表达的转基因植株。外源甜菜碱醛脱氢酶基因可提高二色胡枝子的耐盐性；来源于大肠杆菌的木糖异构酶基因的导入会影响二色胡枝子的糖代谢。

关键词: 二色胡枝子, 遗传转化, 甜菜碱醛脱氢酶基因, 木糖异构酶基因, 木糖选择

Abstract:

Objective: To establish a safe and antibiotic-free genetic transformation system of Lespedeza bicolor. Using genetic engineering technology to improve the tolerance to abiotic stress of L. bicolor. Method: The coding sequence of xylose isomerase gene (xylA) was cloned from Escherichia coli DH5α strain by PCR amplification. The pBI121-xylA-BADH plant expression vector with xylA & betaine aldehyde dehydrogenase gene (BADH) was built. The xylose selection system of L. bicolor was built by using xylose instead of a certain amount of sucrose in the mediums. The cotyledonary node explants of L. bicolor were transformed by using the Agrobacterium tumefaciens-mediated method. The transgenic plants were confirmed by PCR amplification and Southern blot analysis. The growth performance of transgenic and wild-type plants under 0.5-2 g·L^-1 NaCl stress was measured. The betaine aldehyde dehydrogenase activity,contents of chlorophyll and conductivity of transgenic and wild-type plants in vitro under 1.0 g·L^-1 NaCl stress were assayed. The total soluble sugars were extracted separately from the leaves of wild-type plants and transgenic plants in vitro. The sugars were assayed by high performance liquid chromatograph. Result: After DNA sequence analysis,the homology is up to 100% between the cloned product and the published xylA DNA sequence from E. coli in GenBank. The PCR products and restriction enzyme digestion assays showed the pBI121-xylA-BADH plant expression vector was correctly constructed. In the transformation of L. bicolor,the selective mediums for regeneration of adventitious buds from cotyledonary nodes should be the medium which contained xylose as the sole carbon resource,while the selective mediums for shoot segment multiplying or rooting should be the mediums which contained 5 g·L^-1 sucrose and 25 g·L^-1 xylose. In Agrobacterium-mediated genetic transformation,the explants were precultured for 1 day,then infected with LBA4404 strain for 20-30 min,and cultured with Agrobacterium tumefaciens for a total of 3 days,relatively more xylose-resistant buds were obtained. Some xylose-resistant buds were assayed by PCR amplification and Southern blot analysis. Two transgenic lines were obtained. The genetic transformation rate of L. bicolor was lower than 4.7%. The growth performance of transgenic and wild-type plants under NaCl stress showed that the transgenic plants grew and rooted normally in the medium containing 2 g·L^-1 NaCl,while the wild-type plants defoliated after leaves turning into yellow,and were unable to root. BADH activity,the contents of chlorophyll and conductivity showed no significant differences between the transgenic and wild-type plants under no NaCl stress. There was no significant change of the BADH activity in wild-type plants when they were treated with NaCl or without NaCl. The BADH activity in transgenic plants increased greatly and up to 8-10 times as high as the wild-type plants when treated with NaCl. The transgenic plants had significant higher contents of chlorophyll and lower conductivity than the wild-type plants under NaCl stress. The assay on total soluble sugars by the high performance liquid chromatograph showed there were fructose and glucose in transgenic plants,while there were glucose and an unlabeled saccharide without standard sample in wild-type plants. Conclusion: The genetic transformation system of L. bicolor under xylose selection system was established. The transgenic plants with stable expression were obtained. The introduction of exogenous betaine aldehyde dehydrogenase gene increased the tolerance of L. bicolor plants to NaCl stress. The introduction of exogenous xylose isomerase gene from E. coli affected the glycometabolism of L. bicolor plants.

Key words: Lespedeza bicolor, genetic transformation, betaine aldehyde dehydrogenase gene, xylose isomerase gene, xylose selection

中图分类号:

S718.46

杨晓红,陈晓阳. 木糖选择系统下xylA & BADH双价基因对二色胡枝子的遗传转化[J]. 林业科学, 2021, 57(6): 74-84.

Xiaohong Yang,Xiaoyang Chen. Transformation of Lespedeza bicolor with Bivalent Gene xylA & BADH under Xylose Selection System[J]. Scientia Silvae Sinicae, 2021, 57(6): 74-84.

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糖种类及含量 Kind and contents of saccharides	子叶节Cotyledonary node		茎段Shoot segment		组培苗生根Rooting in vitro
糖种类及含量 Kind and contents of saccharides	分化率 Differentiation rate (%)	平均分化不定芽数 Average bud number	分化率 Differentiation rate (%)	平均分化不定芽数 Average bud number	生根率 Rooting percentage (%)	平均生根数 Average root number
CK(蔗糖30 g·L^-1) (Sucrose 30 g·L^-1)	100.0±3.4 a	4.2±0.16 a	94.0±2.63 a	2.79±0.20 a	92.0±9.93 a	2.90±0.11 a
木糖15 g·L^-1+蔗糖15 g·L^-1 Xylose 15 g·L^-1+sucrose 15 g·L^-1	90.0±5.9 b	0.9±0.12 b	22.0±1.28 b	0.48±0.01 b	42.0±3.57 b	0.86±0.14 b
木糖20 g·L^-1+蔗糖10 g·L^-1 Xylose 20 g·L^-1+sucrose 10 g·L^-1	68.0±4.6 c	0.3±0.11 c	12.0±0.01 c	0.10±0.03 c	40.0±0.24 b	0.64±0.28 b
木糖25 g·L^-1+蔗糖5 g·L^-1 Xylose 25 g·L^-1+sucrose 5 g·L^-1	52.0±2.4 d	0.1±0.01 c	0.0±0.00 d	0.00±0.00 c	0.0±0.00 c	0.00±0.00 c
木糖30 g·L^-1 Xylose 30 g·L^-1	2.0±0.1 e	0.0±0.00 c	0.0±0.00 d	0.00±0.00 c	0.0±0.00 c	0.00±0.00 c

处理 Treatment	侵染时间 Infection time/min	共培养时间 Cocultivation time /d	抗性芽再生率 Regeneration rate of resistant buds (%)
1	20	2	5.0
2	30	3	6.7
3	20	3	3.6
4	30	2	0

处理 Treatment	株系 Line	BADH活性 BADH activity/(mmol·mg^-1min^-1)	叶绿素 Chlorophyll/(mg·g^-1FW)	电导率 Electric conductivity (%)
无盐处理 Without NaCl stress	CK	0.072 6±0.036 a	4.71±0.16 a	11.041±0.088 a
	株1 Line 1	0.144 8±0.019 a	4.85±0.20 a	11.570±0.137 a
	株2 Line 2	0.113 5±0.025 a	5.07±0.25 a	11.521±0.076 a
NaCl处理 Under NaCl stress	CK	0.128±0.029 a	3.01±0.03 a	58.106±0.049 a
	株1 Line 1	1.369±0.133 b	4.25±0.08 b	32.232±0.043 b
	株2 Line 2	1.067±0.213 b	4.37±0.04 b	35.519±0.042 b

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