杨树维管组织特异启动子的克隆与启动活性分析

杨树维管组织特异启动子的克隆与启动活性分析

基金项目:
国家863计划项目(2006AA100109);国际先进农业科学技术(948)重大创新项目(2006-4-C01)

Cloning and Functional Analysis of a Vascular Tissue-specific Promoter from Populus tomentosa

摘要: 启动子在基因表达调控中起关键性作用,它在很大程度上决定所控基因表达的时间、空间和强度。依据拟南芥ATH1芯片分析杨树维管形成时期特异表达基因的结果,选取了差异表达基因NST3,通过BLAST比对在杨树EST数据库(PopulusDB)中找到同源性较高的基因NAC068。以毛白杨为材料,在其基因组中克隆得到该基因5＇侧翼区901 bp长的片段,命名为pProNAC068,将该片段置换pBI121载体中的CaMV 35S启动子,并在84K杨中检测报告基因GUS的表达情况。经过GUS活性检测分析发现:该启动子可以控制外源基因在次生维管组织中特异表达,从而为基因工程中有目的的控制外源基因在维管组织中的表达奠定基础。
- 维管组织
- / 启动子
- / 组织特异
- / GUS染色
- / 基因工程
Abstract: Promoter plays a key role not only in regulating the level of gene expression but also in controlling the expression in a spatial and temporal manner. According to the expression profile generated using Arabidopsis ATH1 genechip to analyze genes involved in the regeneration of the secondary vascular system in Populus tomentosa Carr, a differentially expressed gene NST3 was chosen and its homologous gene NAC068 in poplar were found using BLAST software against poplar EST database (PopulusDB). Then the 5′- upstream sequence of this gene was cloned from Populus tomentosa Carr. and put into the plant expression vector pBI121 to replace the 35S promoter to control the reporter gene gus. After transformation of polar 84K via Agrobactera, the GUS activity was detected in cambium zone, suggesting this promoter could control gene expression in secondary vascular system thus should be useful in genetic engineering to control exogenous gene specific expression in vascular system.
- vascular tissue
- / promoter
- / tissue-specific
- / GUS stain
- / genetic engineering

[1]	Plomion C, Leprovost G, Stokes A. Wood Formation in Trees[J]. Plant Physiology, 2001, 127(4): 1513-1523
[2] 卢孟柱, 胡建军. 我国转基因杨树的研究及应用现状[J]. 林业科技开发, 2006, 20(6): 1-4
[3] Kloti A, Henrich C, Bieri S, et al. Upstream and downstream sequence elements determine the specificity of the rice tungro bacilliform virus promoter and influence RNA production after transcription initiation[J]. Plant molecular biology, 1999, 40(2): 249-266
[4] Saito T, Tadakuma K, Takahashi N, et al. Two cytosolic cyclophilin genes of Arabidopsis thaliana differently regulated in temporal-and organ-specific expression[J]. Bioscience, biotechnology, and biochemistry, 1999, 63(4): 632-637
[5] Du J, Xie H L, Zhang D Q, et al. Regeneration of the secondary vascular system in poplar as a novel system to investigate gene expression by a proteomic approach[J]. Proteomics, 2006, 6(3): 881-895
[6] Wang M J, Qi X L, Zhao S T, et al. Dynamic changes in transcripts during regeneration of the secondary vascular system in Populus tomentosa Carr. revealed by cDNA microarrays[J]. BMC Genomics, 2009, 10: 215
[7] Murray M G, Thompson W F. Rapid isolation of high molecular weight plant DNA[J]. Nucleic Acids Research, 1980, 8(19): 4321-4325
[8] Mitsuda N, Iwase A, Yamamoto H, et al. NAC transcription factors, NST1 and NST3, are key regulators of the formation of secondary walls in woody tissues of Arabidopsis[J]. The Plant Cell, 2007, 19(1): 270
[9] Zhong R, Richardson E A, Ye Z H. Two NAC domain transcription factors, SND1 and NST1, function redundantly in regulation of secondary wall synthesis in fibers of Arabidopsis[J]. Planta, 2007, 225(6): 1603-1611
[10]	[10] Mitsuda N, Seki M, Shinozaki K, et al. The NAC transcription factors NST1 and NST2 of Arabidopsis regulate secondary wall thickenings and are required for anther dehiscence[J]. The Plant Cell, 2005, 17(11): 2993-3006
[11]	[11] Zhong R, Demura T, Ye Z H. SND1, a NAC domain transcription factor, is a key regulator of secondary wall synthesis in fibers of Arabidopsis[J]. The Plant Cell, 2006, 18(11): 3158
[12]	[12] Sambrook J, Russell D W. Molecular cloning: a laboratory manual[M]. NY: Cold Spring Harbor Laboratory Press, 2001: 898-915
[13]	[13] Higo K, Ugawa Y, Iwamoto M, et al. Plant cis-acting regulatory DNA elements (PLACE) database[J]. Nucleic Acids Research, 1999, 27(1): 297-300
[14]	[14] Jefferson R A. Assaying chimeric genes in plants: the GUS gene fusion system[J]. Plant Molecular Biology Reporter, 1987, 5(4): 387-405
[15]	[15] Pedersen A G, Baldi P, Chauvin Y, et al. The biology of eukaryotic promoter prediction—a review[J]. Computers and Chemistry, 1999, 23(3-4): 191-207
[16]	[16] Lewin B. Gene VIII[M]. NJ: Pearson Prentice Hall, 2004
[17]	[17] Tjaden G, Coruzzi G M. A novel AT-rich DNA binding protein that combines an HMG I-like DNA binding domain with a putative transcription domain[J]. The Plant Cell, 1994, 6(1): 107-118
[18]	[18] Bustos M M, Guiltinan M J, Jordano J, et al. Regulation of β-Glucuronidase Expression in Transgenic Tobacco Plants by an A/T-Rich, cis-Acting Sequence Found Upstream of a French Bean β-Phaseolin Gene[J]. The Plant Cell, 1989, 1(9): 839-853
[19]	[19] Yang N S, Christou P. Cell type specific expression of a CaMV 35S-GUS gene in transgenic soybean plants[J]. Developmental Genetics, 1990, 11(4): 289-293
[20]	[20] Torres-schumann S, Ringli C, Heierli D, et al. In vitro binding of the tomato bZIP transcriptional activator VSF-1 to a regulatory element that controls xylem-specific gene expression.[J]. The Plant Journal, 1996, 9(3): 283
[21]	[21] Keller B, Baumgartner C. Vascular-specific expression of the bean GRP 1.8 gene is negatively regulated[J]. The Plant Cell, 1991, 3(10): 1051-1061
[22]	[22] Hatton D, Sablowski R, Yung M H, et al. Two classes of cis sequences contribute to tissue-specific expression of a PAL2 promoter in transgenic tobacco[J]. The Plant Journal, 1995, 7(6): 859-876
[23]

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杨树维管组织特异启动子的克隆与启动活性分析

Cloning and Functional Analysis of a Vascular Tissue-specific Promoter from Populus tomentosa

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杨树维管组织特异启动子的克隆与启动活性分析

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Cloning and Functional Analysis of a Vascular Tissue-specific Promoter from Populus tomentosa

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杨树维管组织特异启动子的克隆与启动活性分析

Cloning and Functional Analysis of a Vascular Tissue-specific Promoter from Populus tomentosa

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杨树维管组织特异启动子的克隆与启动活性分析

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Cloning and Functional Analysis of a Vascular Tissue-specific Promoter from Populus tomentosa

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