黑莓糖基转移酶基因UGT78H2的分离鉴定及与类黄酮化合物的分子对接

doi:10.7525/j.issn.1673-5102.2015.02.015

摘要/Abstract

摘要： 糖基化修饰对于维持植物小分子化合物的多样性具有重要的作用。糖基转移酶是催化该反应发生的主体，但其底物受体和供体特异识别机制仍未清楚。本研究从黑莓（Rubus spp.）材料中获得了一个糖基转移酶全长编码基因，并提交国际糖基转移酶命名委员会命名为UGT78H2（GenBank登录号：KM061379）。该基因编码区全长1 380 bp，共编码459个氨基酸。编码蛋白的预测分子量为50.6 kD，等电点为5.88。生物信息学分析表明该酶具有植物糖基转移酶超家族I成员具有的植物次生代谢产物糖基转移酶保守区；系统发育树分析，UGT78H2属拟南芥糖基转移酶F类群，可能参与类黄酮化合物糖基化。氨基酸水平与月季RhUF3GT1（UGT78H1）最相似，一致性为88%。UGT78H2在黑莓幼果期表达量最高，随着果实成熟，表达量迅速下降。以蒺藜苜蓿UGT78G1（PDB：3HBF）蛋白晶体结构为模板，同源模建了UGT78H2的结构，以其鉴定的受体催化活性中心与常见的11种类黄酮小分子进行分子对接。结果表明，UGT78H2最有可能催化的三种类黄酮化合物依次为黄酮醇槲皮素，柚皮素和黄烷醇表儿茶素。

关键词: 黑莓, UGT78H2, 克隆, 类黄酮, 分子对接

Abstract: Glycosylation plays a pivotal role in determining the diversities of plant small molecules. Glycosyltransferases are ubiquitous proteins involved in such reactions. However, the exact mechanisms of sugar donor or acceptor substrate recognition are still to be elusive. We reported the isolation of a new glycosyltransferase gene from blackberry plants(Rubus spp.), nominated as UGT78H2(GenBank Accession No.:KM061379) by the international UDP Glucosyltransferase Nomenclature Committee. The full length of the gene contained an open reading frame of 1 380 nucleotides, encoding a 50.6 kD polypeptides of 459 amino acids. By further analysis, the deduced enzyme was a typical family-1 glucosyltransferase with the plant secondary product glucosyltransferase signature motif in the C terminal. Phylogenetic trees revealed the clustering of UGT78H2 in the F node together with other Arabidopsis thaliana GTs, inferring the possible catalysis activity toward flavonoid compounds. Amino acids of UGT78H2 shared most, but only 88% identity to the RhUF3GT(UGT78H1) in Rose hybrid when aligned to other glycosyltransferases. Most abundant transcripts of the gene were observed in the immature blackberry fruits, a stage when little anthocyanins were produced. Additionally, transcription levels decreased dramatically with the maturation of fruits. We used the Medicago truncatula UGT78G1(PDB: 3HBF) as a template to homologically model the protein of UGT78H2 that was subsequently docked with 12 common flavonoid molecules. UGT78H2 was predicted to be a glucosyltransferase having maximum binding affinity towards quercetin, tangeritin and epicatechin.

Key words: blackberry, UGT78H2, cloning, flavonoids, molecular docking

中图分类号:

陈清1；江雷雨1；王燕1；张云婷1；王小蓉2；汤浩茹1*. 黑莓糖基转移酶基因UGT78H2的分离鉴定及与类黄酮化合物的分子对接[J]. 植物研究, doi: 10.7525/j.issn.1673-5102.2015.02.015.

CHEN Qing1；JIANG Lei-Yu1；WANG Yan1；ZHANG Yun-Ting1；WANG Xiao-Rong2；TANG Hao-Ru1*. Characterization of the Glycosyltransferase Gene UGT78H2 from Blackberry and Docking with Flavonoid Molecules[J]. Bulletin of Botanical Research, doi: 10.7525/j.issn.1673-5102.2015.02.015.

参考文献

1.Lairson L L,Henrissat B,Davies G J,et al.Glycosyltransferases:structures,functions,and mechanisms［J］.Annual review of biochemistry,2008,77:521-555.

2.Wink M.Introduction［M］.//Annual Plant Reviews Volume 39:Functions and Biotechnology of Plant Secondary Metabolites.London:Wiley-Blackwell,2010:1-20.

3.Bowles D,Isayenkova J,Lim E K,et al.Glycosyltransferases:managers of small molecules［J］.Current opinion in plant biology,2005,8(3):254-263.

4.YonekuraSakakibara K,Hanada K.An evolutionary view of functional diversity in family 1 glycosyltransferases［J］.The Plant journal,2011,66(1):182-193.

5.Campbell A J,Davies J G,Bulone V,et al.A classification of nucleotide-diphospho-sugar glycosyltransferases based on amino acid sequence similarities［J］.The Biochemical journal,1997,326:929-939.

6.Mackenzie I P,Owens S I,Burchell B,et al.The UDP glycosyltransferase gene superfamily:recommended nomenclature update based on evolutionary divergence［J］.Pharmacogenetics,1997,7(4):255-269.

7.Mackenzie I P,Bock K W,Burchell B,et al.Nomenclature update for the mammalian UDP glycosyltransferase(UGT) gene superfamily［J］.Pharmacogenetics and genomics,2005,15(10):677-685.

8.Chen Q,Yu H,Tang H,et al.Identification and expression analysis of genes involved in anthocyanin and proanthocyanidin biosynthesis in the fruit of blackberry［J］.Scientia Horticulturae,2012,141:61-68.

9.王小蓉,汤浩茹,付华清,等.15个引进树莓品种的核型［J］.林业科学,2008,44(12):147-150.

10.Perkins-Veazie P,Clark J R,Huber D J,et al.Ripening physiology in ‘Navaho’ thornless blackberries:color,respiration,ethylene production,softening,and compositional changes［J］.Journal of American Society for Horticultural Science,2000,125(3):357-363.

11.Bhat W W,Dhar N,Razdan S,et al.Molecular characterization of UGT94F2 and UGT86C4,two glycosyltransferases from Picrorhiza kurrooa:Comparative structural insight and evaluation of substrate recognition［J］.PloS one,2013,8(9):e73804.

12.Osmani A S,Bak S,Moller B L.Substrate specificity of plant UDP-dependent glycosyltransferases predicted from crystal structures and homology modeling［J］.Phytochemistry,2009,70(3):325-347.

13.Achnine L,Huhman V D,Farag A M,et al.Genomics-based selection and functional characterization of triterpene glycosyltransferases from the model legume Medicago truncatula［J］.The Plant Journal,2005,41(6):875-887.

14.Pang Y,Cheng X,Huhman D V,et al.Medicago glucosyltransferase UGT72L1:potential roles in proanthocyanidin biosynthesis［J］.Planta,2013,238(1):139-154.

15.Pang Y,Peel G J,Sharma S B,et al.A transcript profiling approach reveals an epicatechin-specific glucosyltransferase expressed in the seed coat of Medicago truncatula［J］.Proceedings of the National Academy of Sciences of the United States of America,2008,105(37):14210-14215.

16.Veljanovski V,Constabel C P.Molecular cloning and biochemical characterization of two UDP-glycosyltransferases from poplar［J］.Phytochemistry,2013,91:148-57.

17.Modolo V L,Blount W J,Achnine L,et al.A functional genomics approach to (iso)flavonoid glycosylation in the model legume Medicago truncatula［J］.Plant molecular biology,2007,64(5):499-518.

18.Caputi L,Malnoy M,Goremykin V,et al.A genome-wide phylogenetic reconstruction of family 1 UDP-glycosyltransferases revealed the expansion of the family during the adaptation of plants to life on land［J］.The Plant journal,2012,69(6):1030-1042.

19.Li Y,Baldauf S,Lim E K,et al.Phylogenetic analysis of the UDP-glycosyltransferase multigene family of Arabidopsis thaliana［J］.The Journal of biological chemistry,2001,276(6):4338-4343.

20.Lim EK,Baldauf S,Li Y,et al.Evolution of substrate recognition across a multigene family of glycosyltransferases in Arabidopsis［J］.Glycobiology,2003,13(3):139-145.

21.Masako F M,Misako A,Kanako I,et al.Biochemical and molecular characterization of anthocyanidin/flavonol 3-glucosylation pathways in Rosa hybrida［J］.Plant Biotechnology,2011,28(2):239-244.

22.Modolo L V,Escamilla-Trevi O L L,Dixon R A,et al.Single amino acid mutations of Medicago glycosyltransferase UGT85H2 enhance activity and impart reversibility［J］.FEBS letters,2009,583(12):2131-2135.

23.Ono E,Homma Y,Horikawa M,et al.Functional differentiation of the glycosyltransferases that contribute to the chemical diversity of bioactive flavonol glycosides in grapevines(Vitis vinifera)［J］.The Plant cell,2010,22(8):2856-2871.

24.Modolo L V,Li L,Pan H,et al.Crystal structures of glycosyltransferase UGT78G1 reveal the molecular basis for glycosylation and deglycosylation of (iso) flavonoids［J］.Journal of molecular biology,2009,392:1292-1302.

[1]	张昊楠, 陈珊珊, 徐建民, 罗萍, 王晓萍, 许志茹, 范春节. 巨桉EgrWAT1基因克隆和功能初步分析[J]. 植物研究, 2023, 43(4): 601-611.
[2]	宋海云, 张涛, 贺鹏, 郑树芳, 王立丰, 王文林. 澳洲坚果MibZIP1基因克隆及表达规律分析[J]. 植物研究, 2023, 43(1): 131-139.
[3]	李娜, 王潇楠. 拟南芥种皮色素形成突变体的筛选与表型鉴定[J]. 植物研究, 2023, 43(1): 59-68.
[4]	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.
[5]	栗赫铭, 秦洪涛, 魏德强, 李旭, 蓝兴国. 羽衣甘蓝BoMAPK4原核表达、抗体制备及蛋白表达分析[J]. 植物研究, 2022, 42(4): 584-591.
[6]	杨宇宁, 董昊, 董实伟, 王乃锐, 宋跃, 张含国, 李淑娟. 长白落叶松转录因子LobHLH34克隆及表达分析[J]. 植物研究, 2022, 42(1): 112-120.
[7]	赵佳明, 樊二勤, 刘轶, 王智, 王军辉, 曲冠证. 楸树CbuATX1，CbuATX1-like和CbuATX2基因克隆及生物信息学分析[J]. 植物研究, 2022, 42(1): 47-61.
[8]	谭秋锦, 张涛, 韦媛荣, 郑树芳, 汤秀华, 王文林. 澳洲坚果开花相关MiMADS-box基因克隆及表达载体构建[J]. 植物研究, 2021, 41(6): 888-895.
[9]	纪欣童, 于磊, 詹亚光. 水曲柳BZR1基因克隆及其表达模式分析[J]. 植物研究, 2021, 41(5): 744-752.
[10]	柯维忠, 钟雯娟, 刘凯盈, 李祥媛, 尹明华. 黄独微型块茎鲨烯合酶的基因克隆与序列分析[J]. 植物研究, 2021, 41(2): 243-250.
[11]	王文林, 陈海生, 郑树芳, 樊松乐, 王立丰, 谭秋锦, 覃振师, 黄锡云, 贺鹏, 汤秀华, 许鹏. 澳洲坚果MiMYB2基因克隆及结构与功能分析[J]. 植物研究, 2020, 40(6): 913-922.
[12]	董实伟, 杨宇宁, 王乃锐, 张含国, 李淑娟. 毛果杨固有无序蛋白质基因克隆及胁迫响应分析[J]. 植物研究, 2020, 40(4): 575-582.
[13]	李阳, 施亚坤, 高士科, 李晓屿, 蓝兴国. 羽衣甘蓝类蛋白质二硫键异构酶PDIL1-2的基因克隆及蛋白表达分析[J]. 植物研究, 2020, 40(2): 293-300.
[14]	李新宇, 何利明, 詹亚光. 水曲柳FmWRKY44基因克隆及表达分析[J]. 植物研究, 2019, 39(4): 529-538.
[15]	白晓明, 董实伟, 杨宇宁, 宋跃, 张含国, 李淑娟. 长白落叶松过氧化氢酶LoCAT1基因克隆及表达分析[J]. 植物研究, 2019, 39(4): 539-546.