甘蓝型油菜烷羟化酶基因MAH1的克隆与表达分析

doi:10.3724/SP.J.1006.2017.00640

Abstract

Abstract:

In wax biosynthesis, the mid-chain alkane hydroxylase (MAH) catalyzes the hydroxylation reaction from alkanes to secondary alcohols and further to corresponding ketones. In this study, using Arabidopsis P450-dependent enzyme CYP96A15 / MAH1 gene as a probe, the full-length coding sequences of two Brassica napus MAH1 genes, BnMAH 1-1 (GenBank Accession: KT795344) and BnMAH1-2 (GenBank Accession: KT795345), were isolated by in silico cloning and RT-PCR. The ORF lengths of BnMAH1-1 and BnMAH1-2 were 1491 bp, and no intron was included. BnMAH1-1 and BnMAH1-2 shared 92.4% and 90.9% of sequence identity at nucleotide and amino acid level, respectively. The predicted BnMAH1-1 and BnMAH1-2 protein contained 496 amino acid residues, with typical P450 protein family conserved domains P415xR417x, K helix (E359xxR362), C-terminal hemopexin-like domain (F436xxGxRxCxG445) and oxygen binding zone (A/G)G309x(D/E)T312(T/S). NCBI BlastN, multiple alignment of amino acid sequence, and phylogenetic analysis showed that they were most homologous to A. thaliana CYP96A15/MAH1. Real-time quantitative PCR showed that BnMAH1-1 and BnMAH1-2 were mainly expressed in stem, leaf, flower, and silique. The highest expression level was found in leaf and the lowest was in root, which was consistent with the wax deposition on aerial part of plant. The expression of BnMAH1-1 and BnMAH1-2 was barely detected in stem and leaf of wax deficient cultivar, suggesting that the reduced wax deposition is due to the down-regulation of MAH1 transcription. The expression of BnMAH1-1 and BnMAH1-2 was significantly induced by exogenous application of SA, MeJA, ACC, and ABA and exposure to NaCl and drought, among which BnMAH1-1 may play a major role in response to water stress.

Key words: Brassica nupas, Cuticular wax, Alkane hydroxylase

XU Yi**,PENG Yang**,LI Shuai,ZHAO Qiu-Ling,ZHANG Shuang-Juan,LI Jia-Na,NI Yu*. Cloning and Expression Analysis of Alkane Hydroxylase Gene MAH1 from Brassica napus[J].Acta Agron Sin, 2017, 43(05): 640-647.

References

[1]Schreiber L, Skrabs M, Hartmann K D, Diamantopoulos P, Simanova E, Santrucek J. Effect of humidity on cuticular water permeability of isolated cuticular membranes and leaf disks. Planta, 2001, 214: 274–282 [2]Riederer M, Schreiber L. Protecting against water loss: analysis of the barrier properties of plant cuticles. J Exp Bot, 2001, 52: 205–208 [3]Ficke A, Gadoury D M, Godfrey D, Dry I B. Host barriers and responses to Uncinula necator in developing grape berries. Phytopathology, 2004, 94: 438–445 [4]Eigenbrode S D, Rayor L, Chow J, Latty P. Effects of wax bloom variation in Brassica oleracea on foraging by avespid wasp. Entomol Exp Appl, 2000, 97: 161–166 [5]Krauss P, Markst?dter C, Riederer M. Attenuation of UV radiation by plant cuticles from woody species. Plant Cell Environ, 1997, 20: 1079–1085 [6]Ni Y, Xia R E, Li J N. Changes of epicuticular wax induced by enhanced UV-B radiation impact on gas exchange in Brassica napus. Acta Physiol Plant, 2014, 36: 2481–2490 [7]Kunst L, Samuels A L. Biosynthesis and secretion of plant cuticular wax. Prog Lipid Res, 2003, 42: 51–80 [8]Barthhlott W, Neinhuis C. Purity of the sacred lotus, or escape from contamination in biological surface. Planta, 1997, 202: 1–8 [9]Zhou X, Jenks M, Liu J, Liu A, Zhang X, Xiang J, Zou J, Peng Y, Chen X. Overexpression of transcription factor OsWR2 regulates wax and cutin biosynthesis in rice and enhances its tolerance to water deficit. Plant Mol Biol Rep, 2014, 32: 719–731 [10]Al-Abdallat A M, Al-Debei H S, Ayad J Y, Hasan S. Over-expression of SlSHN1 gene improves drought tolerance by increasing cuticular wax accumulation in tomato. Int J Mol Med, 2014, 15: 19499–19515 [11]Lee S B, Kim H, Kim R J, Suh M C. Overexpression of Arabidopsis MYB96 confers drought resistance in Camelina sativa via cuticular wax accumulation. Plant Cell Rep, 2014, 33: 1535–1546 [12]Millar A A, Clemens S, Zachgo S, Giblin M, Taylor D C, Kunst L. CUT1, an Arabidopsis gene required for cuticular wax biosynthesis and pollen fertility, encodes a very-long- chain fatty acid condensing enzyme. Plant Cell, 1999, 11: 825–838 [13]Kolattukudy P E, Liu T Y. Direct evidence for biosynthetic relationships among hydrocarbons, secondary alcohols, and ketones in Brassica oleracea. Biochem Biophys Res Commun, 1970, 41: 1369–1374 [14]Greer S, Wen M, Bird D, Wu X, Samuels L, Kunst L, Jetter R. The cytochrome P450 enzyme CYP96A15 is the mid-chain alkane hydroxylase responsible for formation of secondary alcohols and ketones in stem cuticular wax of Arabidopsis thaliana. Plant Physiol, 2007, 145: 653–667 [15]Pu Y, Gao J, Guo Y, Liu T, Zhu L, Xu P, Yi B, Wen J, Tu J, Ma C, Fu T, Zou J, Shen J. A novel dominant glossy mutation causes suppression of wax biosynthesis pathway and deficiency of cuticular wax in Brassica napus. BMC Plant Biol, 2013, 13: 1471–2229 [16]Liu F, Xiong X, Wu L, Fu D, Hayward A, Zeng X, Cao Y, Wu Y, Li Y, Wu G. BraLTP1, a lipid transfer protein gene involved in epicuticular wax deposition, cell proliferation and flower development in Brassica napus. PloS One, 2014, 9: 1–12 [17]李帅, 赵秋棱, 彭阳, 徐熠, 李加纳, 倪郁. SA、MeJA和ACC处理对甘蓝型油菜叶角质层蜡质组分、结构及渗透性的影响. 作物学报, 2016, 42: 1827–1833 Li S, Zhao Q L, Peng Y, Xu Y, Li J N, Ni Y. Effects of SA, MeJA, and ACC on leaf cuticular wax constituents, structure and permeability in Brassica napus. Acta Agron Sin, 2016, 42: 1827–1833 (in Chinese with English abstract) [18]Durst F, Nelson D R. Diversity and evolution of plant P450 and P450-reductases. Drug Metabol Drug Interact, 1995, 12: 189–206 [19]Nelson D R, Schuler M A, Paquette S M, Werck-Reichhart D, Bak S. Comparative genomics of rice and Arabidopsis: analysis of 727 cytochrome P450 genes and pseudogenes from a monocot and a dicot. Plant Physiol, 2004, 135: 756–772 [20]Lee D S, Nioche P, Hamberg M, Raman C S. Structural insights into the evolutionary paths of oxylipin biosynthetic enzymes. Nature, 2008, 455: 363–368 [21]Schuler M A. Plant Cytochrome P450 monooxygenases. Crit Rev Plant Sci, 1996, 15: 235–284 [22]Chen S, Zhou D. Functional domains of aromatase cytochrome P450 inferred from comparative analyses of amino acid sequences and substantiated by site-directed mutagenesis experiments. J Biol Chem, 1992, 267: 22587–22594 [23]Shepherd T, Wynne Griffiths D. The effects of stress on plant cuticular waxes. New Phytol, 2006, 171: 469–499 [24]Kosma D K, Bourdenx B, Bernard A, Parsons E P, Lü S, Joubès J, Jenks M A. The impact of water deficiency on leaf cuticle lipids of Arabidopsis. Plant Physiol, 2009, 151: 1918–1929 [25]Go Y S, Kim H, Kim H J, Suh M C. Arabidopsis cuticular wax biosynthesis is negatively regulated by the DEWAX gene encoding an AP2/ERF-type transcription factor. Plant Cell, 2014, 26: 1666–1680 [26]Gauvrit C, Gaillardon P. Effect of low-temperatures on 2,4-D behaviour in maize plants. Weed Res, 1991, 31: 135–142 [27]Joubès J, Raffaele S, Bourdenx B, Garcia C, Laroche-Traineau J, Moreau P, Domergue F, Lessire R. The VLCFA elongase gene family in Arabidopsis thaliana: phylogenetic analysis, 3D modelling and expression profiling. Plant Mol Biol, 2008, 67: 547–566 [28]Macková J, Va?ková M, Macek P, Hronková M, Schreiber L, ?antr??ek J. Plant response to drought stress simulated by ABA application: changes in chemical composition of cuticular waxes. Environ Exp Bot, 2013, 86: 70–75 [29]Seo P J, Lee S B, Suh M C, Park M J, Go Y S, Park C M. The MYB96 transcription factor regulates cuticular wax biosynthesis under drought conditions in Arabidopsis. Plant Cell, 2011, 23: 1138–1152

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Comments

Recommended 0

No Suggested Reading articles found!

Cloning and Expression Analysis of Alkane Hydroxylase Gene MAH1 from Brassica napus

RichHTML

PDF

Abstract

Cite this article

share this article

References

Related Articles 7

Metrics

Comments

Recommended 0

[1]	LI Ling-Hong, ZHANG Zhe, CHEN Yong-Ming, YOU Ming-Shan, NI Zhong-Fu, XING Jie-Wen. Transcriptome profiling of glossy1 mutant with glossy glume in common wheat (Triticum aestivum L.) [J]. Acta Agronomica Sinica, 2022, 48(1): 48-62.
[2]	LI Yang,YAO Lu-Hua,GUO Xin,ZHAO Xiao,HUANG Lei,WANG Deng-Ke,ZHANG Xue-Feng,XIAO Qian-Lin,YANG Rui-Ji,GUO Yan-Jun. Chemical compositions of cuticular waxes on stems and leaves of three legume green manure crops [J]. Acta Agronomica Sinica, 2020, 46(01): 131-139.
[3]	LI Shuai,ZHAO Qiu-Ling,PENG Yang,XU Yi,LI Jia-Na,NI Yu. Effects of SA, MeJA, and ACC on Leaf Cuticular Wax Constituents, Structure and Permeability in Brassica napus* [J]. Acta Agron Sin, 2016, 42(12): 1827-1833.
[4]	XU Wen,SHEN Hao,GUO Jun,YU Xiao-Cong,LI Xiang,YANG Yan-Hui,MA Xiao,ZHAO Shi-Jie,SONG Jian-Min. Drought Resistance of Wheat NILs with Different Cuticular Wax Contents in Flag Leaf [J]. Acta Agron Sin, 2016, 42(11): 1700-1707.
[5]	NI Yu,WANG Jing,SONG Chao,XIA Rui-E,SUN Zheng-Yuan,GUO Yan-Jun,LI Jia-Na. Effects of SA Induction on Leaf Cuticular Wax and Resistance to Sclerotinia sclerotiorurn in Brassica napus [J]. Acta Agron Sin, 2013, 39(01): 110-117.
[6]	ZHOU Ling-Yan,JIANG Da-Gang,LI Jing,ZHOU Hai,CAO Wei-Wei,ZHUANG Chu-Xiong. Effect of Stresses on Leaf Cuticular Wax Accumulation and Its Relationship to Expression of OsGL1-Homologous Genes in Rice [J]. Acta Agron Sin, 2012, 38(06): 1115-1120.
[7]	GUO Yan-Jun, NI Yu, GUO Yun-Jiang, HAN Long, TANG Hua, YU Yong-Xiong. Effect of Soil Water Deficit and High Temperature on Leaf Cuticular Waxes and Physiological Indices in Alfalfa (Medicago sativa) Leaf [J]. Acta Agron Sin, 2011, 37(05): 911-917.