芜菁类黄酮3′-羟化酶基因的功能鉴定及启动子初步分析

doi:10.7525/j.issn.1673-5102.2015.04.016

摘要/Abstract

摘要： 类黄酮3′-羟化酶（Flavonoid 3′-hydroxylase，F3′H）是细胞色素P450单加氧酶，在花青素合成途径中催化二氢山奈酚生成二氢槲皮素，进而形成矢车菊色素。利用津田芜菁BrF3′H1和赤丸芜菁BrF3′H2基因构建过量表达载体后遗传转化烟草，转基因植株的花色加深。通过染色体步移法克隆了BrF3′H1和BrF3′H2基因上游846和851 bp的启动子序列。生物信息学分析表明，BrF3′H1P和BrF3′H2P均包含TATA box、CAAT box、光调控元件、MRE、ABRE、ATGCAAAT-motif、ERE、O2-site、RY-element、LTR等多个顺式作用元件；二者的核苷酸序列在7个位点存在差异。利用BrF3′H1P和BrF3′H2P序列替换pCAMBIA1301植物表达载体的35S启动子后遗传转化烟草。GUS组织化学染色结果表明，BrF3′H1P和BrF3′H2P序列均能驱动GUS基因表达。通过PCR方法获得了BrF3′H1P和BrF3′H2P的一系列缺失片段，融合GUS基因后转化烟草。染色结果显示，BrF3′H1P和BrF3′H2P系列缺失片段均具有起始GUS基因表达的活性。BrF3′H1和BrF3′H2基因的功能鉴定及启动子的初步分析将为揭示津田芜菁和赤丸芜菁F3′H基因的光诱导表达调控机理奠定研究基础。

关键词: 芜菁, 类黄酮3′-羟化酶基因, 遗传转化, 启动子, 功能分析

Abstract: Flavonoid 3′-hydroxylase(F3′H) is a cytochrome P450 monooxygenase, it can convert dihydrokaempferol to dihydroquercetin in the pathway of anthocyanin biosynthesis, and the cyanidin can be formed. The overexpression vectors of BrF3′H1 and BrF3′H2 genes cloned from ‘Tsuda’ turnip and ‘Yurugi Akamaru’ turnip, respectively, were constructed, and then were transformed into tobacco. The flower color of transgenic tobacco plants was darker. The 846 and 851 bp promoter fragments upstream of BrF3′H1 and BrF3′H2 genes were obtained by genome walking method. Many cis-acting elements in BrF3′H1 and BrF3′H2 promoters were identified by bioinformatics analysis, such as TATA box, CAAT box, light responsive elements, MRE, ABRE, ATGCAAAT-motif, ERE, O2-site, RY-element and LTR. The nucleotide sequences of BrF3′H1P and BrF3′H2P had 7 differences. The 35S promoter of pCAMBIA1301 plant expression vector was substituted by BrF3′H1P and BrF3′H2P, respectively, and then the recombinants were introduced into tobacco through the mediation of Agrobacterium tumefaciens. Histochemical staining result of GUS indicated that the expression of GUS reporter gene could be driven by BrF3′H1P and BrF3′H2P sequence. A series of 5′-end deleted fragments of BrF3′H1P and BrF3′H2P were obtained by PCR, which were fused with GUS reporter gene and then were transformed into tobacco. The stain result showed that the deleted fragments of BrF3′H1P and BrF3′H2P had starting activity that could initiate the expression of GUS gene. The functional identification of BrF3′H1 and BrF3′H2 genes and the preliminary analysis of their promoters would lay a foundation for clarifying the mechanism on light inducible expression regulation of F3′H genes in ‘Tsuda’ turnip and ‘Yurugi Akamaru’ turnip.

Key words: Turnip, fvonoid 3′-hydroxylase gene, genetic transformation, promoter, functional analysis

中图分类号:

许志茹1,2,3；马静1,2,3；崔国新1,2,3；刘通1,2,3；刘关君1,2,3. 芜菁类黄酮3′-羟化酶基因的功能鉴定及启动子初步分析[J]. 植物研究, 2015, 35(4): 572-582.

XU Zhi-Ru1,2,3；MA Jing1,2,3；CUI Guo-Xin1,2,3；LIU Tong1,2,3；LIU Guan-Jun1,2,3. Functional Identification and Promoter Preliminary Analysis of Flavonoid 3′-Hydroxylase Genes in Turnip[J]. Bulletin of Botanical Research, 2015, 35(4): 572-582.

参考文献

1.He F,Pan Q H,Shi Y,et al.Biosynthesis and genetic regulation of proanthocyanidins in plants［J］.Molecules,2008,13(10):2674-2703.

2.张龙,李卫华,姜淑梅,等.花色素苷生物合成与分子调控研究进展［J］.园艺学报,2008,35(6):909-916.

3.Saito K,Yonekura-Sakakibara K,Nakabayashi R,et al.The flavonoid biosynthetic pathway in Arabidopsis:Structural and genetic diversity［J］.Plant Physiol Biochem,2013,72:21-34.

4.Brugliera F,Barri-Rewell G,Holton T A,et al.Isolation and characterization of a flavonoid 3′-hydroxylase cDNA clone corresponding to the Ht1 locus of Petunia hybrida［J］.Plant J,1999,19(4):441-451.

5.Seitz C,Eder C,Deiml B,et al.Cloning,functional identification and sequence analysis of flavonoid 3′-hydroxylase and flavonoid 3′,5′-hydroxylase cDNAs reveals independent evolution of flavonoid 3′,5′-hydroxylase in the Asteraceae family［J］.Plant Mol Biol,2006,61(3):365-381.

6.Niu S S,Xu C J,Zhang W S,et al.Coordinated regulation of anthocyanin biosynthesis in Chinese bayberry(Myrica rubra) fruit by a R2R3 MYB transcription factor［J］.Planta,2010,231(4):887-899.

7.Yuan Y,Ma X,Shi Y,et al.Isolation and expression analysis of six putative structural genes involved in anthocyanin biosynthesis in Tulipa fosteriana［J］.Sci Hortic,2013,153(4):93-102.

8.Guo Y,Qiu L J.Allele-specific marker development and selection efficiencies for both flavonoid 3′-hydroxylase and flavonoid 3′,5′-hydroxylase genes in soybean subgenus soja［J］.Theor Appl Genet,2013,126(6):1445-1455.

9.Toda K,Yang D,Yamanaka N,et al.A single-base deletion in soybean flavonoid 3′-hydroxylase gene is associated with gray pubescence color［J］.Plant Mol Biol,2002,50(2):187-196.

10.Toda K,Takahashi R,Iwashina T,et al.Difference in chilling-induced flavonoid profiles,antioxidant activity and chilling tolerance between soybean near-isogenic lines for the pubescence color gene［J］.J Plant Res,2011,124(1):173-182.

11.Xu B B,Li J N,Zhang X K,et al.Cloning and molecular characterization of a functional flavonoid 3′-hydroxylase gene from Brassica napus［J］.J Plant Physiol,2007,164(3):350-363.

12.Thill J,Miosic S,Gotame T P,et al.Differential expression of flavonoid 3′-hydroxylase during fruit development establishes the different B-ring hydroxylation patterns of flavonoids in Fragaria×ananassa and Fragaria vesca［J］.Plant Physiol Biochem,2013,72:72-78.

13.Martins T R,Berg J J,Blinka S,et al.Precise spatio-temporal regulation of the anthocyanin biosynthetic pathway leads to petal spot formation in Clarkia gracilis(Onagraceae)［J］.New Phytol,2013,197(3):958-969.

14.Glover B J,Walker R H,Moyroud E,et al.How to spot a flower［J］.New Phytol,2013,197(3):687-689.

15.Han Y,Vimolmangkang S,Soria-Guerra R E,et al.Ectopic expression of apple F3′H genes contributes to anthocyanin accumulation in the Arabidopsis tt7 mutant grown under nitrogen stress［J］.Plant Physiol,2010,153(2):2806-2820.

16.Ishiguro K,Taniguchi M,Tanaka Y.Functional analysis of Antirrhinum kelloggii flavonoid 3′-hydroxylase and flavonoid 3′,5′-hydroxylase genes; critical role in flower color and evolution in the genus Antirrhinum［J］.J Plant Res,2012,125(3):451-456.

17.Nakatsuka T,Nishihara M,Mishiba K,et al.Heterologous expression of two gentian cytochrome P450 genes can modulate the intensity of flower pigmentation in transgenic tobacco plants［J］.Mol Breed,2006,17(2):91-99.

18.Feng S,Wang Y,Yang S,et al.Anthocyanin biosynthesis in pears is regulated by a R2R3-MYB transcription factor PyMYB10［J］.Planta,2010,232(1):245-255.

19.Petroni K,Tonelli C.Recent advances on the regulation of anthocyanin synthesis in reproductive organs［J］.Plant Sci,2011,181(3):219-229.

20.Chiu L W,Li L.Characterization of the regulatory network of BoMYB2 in controlling anthocyanin biosynthesis in purple cauliflower［J］.Planta,2012,236(4):1153-1164.

21.Medina-Puche L,Cumplido-Laso G,Amil-Ruiz F,et al.MYB10 plays a major role in the regulation of flavonoid/phenylpropanoid metabolism during ripening of Fragaria×ananassa fruits［J］.J Exp Bot,2014,65(2):401-417.

22.Yamagishi M,Toda S,Tasaki K.The novel allele of the LhMYB12 gene is involved in splatter-type spot formation on the flower tepals of Asiatic hybrid lilies(Lilium spp.)［J］.New Phytol,2014,201(3):1009-1020.

23.Morita Y,Saitoh M,Hoshino A,et al.Isolation of cDNAs for R2R3-MYB,bHLH,and WDR transcriptional regulators and identification of c and ca mutations conferring white flowers in the Japanese morning glory［J］.Plant Cell Physiol,2006,47(4):457-470.

24.Ali M B,Howard S,Chen S,et al.Berry skin development in Norton grape:distinct patterns of transcriptional regulation and flavonoid biosynthesis［J］.BMC Plant Biol,2011,doi:10.1186/1471-2229-11-7.

25.Chu H,Jeong J C,Kim W J,et al.Expression of the sweetpotato R2R3-type IbMYB1a gene induces anthocyanin accumulation in Arabidopsis［J］.Physiol Plant,2013,148(2):189-199.

26.葛翠莲,黄春辉,徐小彪.果实花青素生物合成研究进展［J］.园艺学报,2012,39(9):1655-1664.

27.Toda K,Akasaka M,Dubouzet E G,et al.Structure of flavonoid 3′-hydroxylase gene for pubescence color in soybean［J］.Crop Sci,2005,45(6):2212-2217.

28.Sharma M,Cortes-Cruz M,Ahern K R,et al.Identification of the pr1 gene product completes the anthocyanin biosynthesis pathway of maize［J］.Genetics,2011,188(1):69-79.

29.Sharma M,Chai C,Morohashi K,et al.Expression of flavonoid 3′-hydroxylase is controlled by P1,the regulator of 3-deoxyflavonoid biosynthesis in maize［J］.BMC Plant Biol,2012,doi:10.1186/1471-2229-12-196.

30.Zhou Y,Guo D,Li J,et al.Coordinated regulation of anthocyanin biosynthesis through photorespiration and temperature in peach(Prunus persica f.atropurpurea)［J］.Tree Genet Genomes,2013,9(1):265-278.

31.Takashi N,Misa S,Eri Y,et al.Isolation and characterization of GtMYBP3 and GtMYBP4,orthologues of R2R3-MYB transcription factors that regulate early flavonoid biosynthesis,in gentian flowers［J］.J Exp Bot,2012,63(18):6505-6517.

32.Cominelli E,Gusmaroli G,Allegra D,et al.Expression analysis of anthocyanin regulatory genes in response to different light qualities in Arabidopsis thaliana［J］.J Plant Physiol,2008,165(8):886-894.

33.胡可,韩科厅,戴思兰.环境因子调控植物花青素苷合成及呈色的机理［J］.植物学报,2010,45(3):307-317.

34.Das P K,Geul B,Choi S B,et al.Photosynthesis-dependent anthocyanin pigmentation in Arabidopsis［J］.Plant Signal Behav,2011,6(1):23-25.

35.Wang Y,Zhou B,Sun M,et al.UV-A light induces anthocyanin biosynthesis in a manner distinct from synergistic blue+UV-Blight and UV-A/blue light responses in different parts of the hypocotyls in turnip seedlings［J］.Plant Cell Physiol,2012,53(8):1470-1480.

36.Zhang Y,Li J H,Xin H P,et al.Anthocyanin profile and gene expression in berry skin of two red Vitis vinifera grape cultivars that are sunlight dependent versus sunlight independent［J］.Aust J Grape Wine R,2013,19(2):238-248.

37.Shih C H,Chu I K,Yip W K,et al.Differential expression of two flavonoid 3′-hydroxylase cDNAs involved in biosynthesis of anthocyanin pigments and 3-deoxyanthocyanidin phytoalexins in sorghum［J］.Plant Cell Physiol,2006,47(10):1412-1419.

38.Schoenbohm C,Martens S,Eder C,et al.Identification of the Arabidopsis thaliana flavonoid 3′-hydroxylase gene and functional expression of the encoded P450 enzyme［J］.Biol Chem,2000,381(8):749-753.

39.Dubos C,Le Gourrierec J,Baudry A,et al.MYBL2 is a new regulator of flavonoid biosynthesis in Arabidopsis thaliana［J］.Plant J,2008,55(6):940-953.

40.许志茹,崔国新,李春雷,等.芜菁的类黄酮3′-羟化酶基因克隆和UV-A诱导表达特性［J］.植物生理学通讯,2008,44(5):931-935.

41.许志茹,刘通,崔国新,等.芜菁二氢黄酮醇4-还原酶基因的克隆与功能鉴定［J］.园艺学报,2014,41(4):687-700.

42.李琳玲,程华,程水源,等.银杏查尔酮合成酶基因启动子（GbCHSP）调控元件及功能分析［J］.园艺学报,2010,37(12):1919-1928.

43.Tanaka Y,Sasaki N,Ohmiya A.Biosynthesis of plant pigments:anthocyanins,betalains and carotenoids［J］.Plant J,2008,54(4):733-749.

44.夏涛,高丽萍.类黄酮及茶儿茶素生物合成途径及其调控研究进展［J］.中国农业科学,2009,42(8):2899-2908.

45.Dixon R A,Liu C,Jun J H.Metabolic engineering of anthocyanins and condensed tannins in plants［J］.Curr Opin Biotechnol,2013,24(2):329-335.

46.He F,Mu L,Yan G L,et al.Biosynthesis of anthocyanins and their regulation in colored grapes［J］.Molecules,2010,15(12):9057-9091.

47.Qi Y,Lou Q,Li H,et al.Anatomical and biochemical studies of bicolored flower development in Muscari latifolium［J］.Protoplasma,2013,250(6):1273-1281.

48.Aza-González C,Herrera-Isidrón L,Núǔez-Palenius H G,et al.Anthocyanin accumulation and expression analysis of biosynthesis-related genes during chili pepper fruit development［J］.Biologia Plantarum,2013,57(1):49-55.

49.Tsai C J,Harding S A,Tschaplinski T J,et al.Genome-wide analysis of the structural genes regulating defense phenylpropanoid metabolism in Populus［J］.New Phytologist,2006,172(1):47-62.

50.Nagamatsu A,Masuta C,Matsuura H,et al.Down-regulation of flavonoid 3′-hydroxylase gene expression by virus-induced gene silencing in soybean reveals the presence of a threshold mRNA level associated with pigmentation in pubescence［J］.J Plant Physiol,2009,166(1):32-39.

51.Momose M,Nakayama M,Itoh Y,et al.An active hAT transposable element causing bud mutation of carnation by insertion into the flavonoid 3′-hydroxylase gene［J］.Mol Genet Genomics,2013,288(3-4):175-184.

52.Zufall R A,Rausher M D.Genetic changes associated with floral adaptation restrict future evolutionary potential［J］.Nature,2004,428(6985):847-850.

53.Guo J,Han W,Wang M H.Ultraviolet and environmental stresses involved in the induction and regulation of anthocyanin biosynthesis［J］.Afr J Biotechnol,2008,7(25):4966-4972.

54.Zhang Z Z,Li X X,Chu Y N,et al.Three types of ultraviolet irradiation differentially promote expression of shikimate pathway genes and production of anthocyanins in grape berries［J］.Plant Physiol Biochem,2012,57:74-83.

55.Lai B,Li X J,Hu B,et al.LcMYB1 is a key determinant of differential anthocyanin accumulation among genotypes,tissues,developmental phases and ABA and light stimuli in Litchi chinensis［J］.PLoS One,2014,9(1):e86293.

56.郑晓瑜,郭晋艳,张毅,等.植物非生物胁迫诱导启动子顺式作用元件的研究方法［J］.植物生理学报,2011,47(2):129-135.

57.曾凡锁,钱晶晶,康君,等.转基因白桦中GUS基因表达的定量分析［J］.植物学报,2009,44(4):484-490.

58.Yoshida K,Iwasaka R,Shimada N,et al.Transcriptional control of the dihydroflavonol 4-reductase multigene family in Lotus japonicus［J］.J Plant Res,2012,123(6):801-805.

[1]	何旭, 高源, 张群野, 周晨光, 李伟, 李爽. 白城小黑杨遗传转化体系建立及其应用[J]. 植物研究, 2023, 43(5): 667-678.
[2]	杜金霞, 申婷婷, 王浩然, 林一萍, 李慧玉, 张连飞. 白桦BpSPL9基因抑制表达载体的构建及遗传转化研究[J]. 植物研究, 2023, 43(1): 30-35.
[3]	李登高, 林睿, 穆青慧, 周娜, 张焱如, 白薇. 马铃薯StNPR4基因的克隆与功能分析[J]. 植物研究, 2022, 42(5): 821-829.
[4]	谢望, 李天静, 李鑫窈, 杨丰铭, 姚银安, 高永峰. 胡杨PeNAC121基因启动子的分离鉴定和胁迫应答模式分析[J]. 植物研究, 2022, 42(2): 234-242.
[5]	杜恬恬, 李会萍, 王博雅, 欧倩, 黄艳, 曹颖, 胡尚连. 梁山慈竹DfMYB3基因克隆及启动子分析[J]. 植物研究, 2021, 41(5): 729-737.
[6]	王万奇, 齐婉竹, 赵秋爽, 曾栋, 刘轶, 付鹏跃, 曲冠证, 赵曦阳. 白桦BpJMJ18基因启动子克隆及表达分析[J]. 植物研究, 2020, 40(5): 751-759.
[7]	姜骋, 张曦, 田晴, 李莉. 白桦BpbHLH112基因克隆及其启动子表达特性分析[J]. 植物研究, 2020, 40(4): 583-592.
[8]	张磊, 熊欢欢, 曹庆, 赵佳丽, 张含国. 瞬时遗传转化长白落叶松NAC基因植株抗旱性的研究[J]. 植物研究, 2020, 40(3): 394-400.
[9]	丁宝娟, 安利佳, 苏乔. 过表达钾转运蛋白基因trkH提高玉米的钾营养[J]. 植物研究, 2020, 40(1): 141-147.
[10]	秦琳琳, 张曦, 姜骋, 李莉. 白桦BpZFP4基因启动子克隆和逆境响应元件功能分析[J]. 植物研究, 2019, 39(6): 917-926.
[11]	樊二勤, 刘彩霞, 付鹏跃, 杨传平, 曲冠证. 84K杨PagC3H3基因表达模式分析[J]. 植物研究, 2019, 39(4): 521-528.
[12]	周敏, 蒋丹, 刘玥秀, 王小蓉, 汤浩茹, 陈清. P119驱动amiRNA介导的PL基因沉默对草莓果实硬度的影响[J]. 植物研究, 2019, 39(3): 441-449.
[13]	颜斌, 武丹阳, 李慧玉. 白桦BpBEE2基因的遗传转化及抗逆性分析[J]. 植物研究, 2019, 39(2): 287-293.
[14]	王晟宇, 张淇, 张正一, 胡晓晴, 田晶, 张勇, 刘雪梅. 白桦BpSPL2基因启动子的克隆及表达分析[J]. 植物研究, 2019, 39(1): 96-103.
[15]	李文静, 孙艳香. 水稻谷蛋白基因GluC启动子的克隆及表达分析[J]. 植物研究, 2018, 38(6): 921-930.