Dynamic analysis of gene expression and determination of chemicals in agarwood in Aquilaria sinensis

Zeqing Wu; Wanzhen Liu; Jing Li; Liangwen Yu; Li Lin

doi:10.1007/s11676-019-00970-5

Journal of Forestry Research ›› 2019, Vol. 31 ›› Issue (5) : 1833 -1841. DOI: 10.1007/s11676-019-00970-5

Original Paper

Dynamic analysis of gene expression and determination of chemicals in agarwood in Aquilaria sinensis

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Abstract

Agarwood is the resinous heartwood of Aquilaria species. However, low yields and high costs of existing stimulation methods have led to the need for new techniques to produce agarwood rapidly and effectively. We developed a biological agarwood-inducing technique (Agar-Bit) that produces high yields and quality within 6 months. To better understand agarwood formation by Agar-Bit, dynamic gene expressions of key synthetases pathways of sesquiterpenes and chalcone- related enzymes at different times were determined after both Agar-Bit and the traditional burning chisel drilling (BCD) stimulation on Aquilaria sinensis trees. The qRT-PCR results show that some characteristic synthase genes were expressed at greatly different levels and times compared with the controls. For the Agar-Bit technology, main changes were after the 3rd or 5th month, while BCD expression clearly changed at the 5th month. Essential oils and total chromone contents were simultaneously determined. In the Agar-Bit group, both were higher and similar to natural levels. The Agar-Bit methodology is a new option for producing agarwood as demonstrated by genetic and chemical aspects. The differences in gene expression within 6 months for both groups indicates that the mechanisms of the two methods are different. These findings provide information on genetic variation during the process of agarwood formation.

Keywords

Agarwood / Biological agarwood-inducing technique (Agar-Bit) / Essential oils / Gene expression / Total chromone

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Zeqing Wu, Wanzhen Liu, Jing Li, Liangwen Yu, Li Lin. Dynamic analysis of gene expression and determination of chemicals in agarwood in Aquilaria sinensis. Journal of Forestry Research, 2019, 31(5): 1833-1841 DOI:10.1007/s11676-019-00970-5

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References

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[1]	Blanchette RA, Van Beek HH (2009) Cultivated agarwood. U.S. Patent No. 7638145B2. Minnesota: University of Minnesota

[2]	Chen XD, Zhu XL, Feng MR, Zhong ZJ, Zhou X, Chen XY, Ye W, Zhang WM, Gao XX (2017) Relationship between expression of chalcone synthase genes and chromones in artificial agarwood induced by formic acid stimulation combined with Fusarium spp. A2 inoculation. Molecules 22 (5):686

[3]	Chhipa H, Kaushik N. Fungal and bacterial diversity isolated from Aquilaria malaccensis trees and soil induces agarospirol formation within 3 months after artificial infection. Front Microbiol, 2017, 7: 128.

[4]	CITES (2004) Amendments to appendices I and II of CITES. In: Proceedings of thirteenth meeting of the conference of the Parties, Bangkok, Thailand, 2 October

[5]	Espinoza EO, Lancaster CA, Kreitals NM, Hata M, Cody RB, Blanchette RA (2014) Distinguishing wild from cultivated agarwood (Aquilaria spp.) using direct analysis in real time and time of flight mass spectrometry. Rapid Communications in Mass Spectrometry 28 (3):281 − 289

[6]	Gardner RG, Hampton RY. A highly conserved signal controls degradation of 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase in eukaryotes. J Biol Chem, 1999, 274(44): 31671-31678.

[7]	Guo R, Zhao YF, Li J, Gu YF, Huo HX, Li SS, Song YL, Zhu ZX, Tu PF. GYF-21, an epoxide 2-(2-Phenethyl)-chromone derivative, suppresses innate and adaptive immunity via inhibiting STAT1/3 and NF-kB signaling pathways. Front Pharmacol, 2017, 8: 281.

[8]	Huo HX, Gu YF, Sun H, Zhang YF, Liu WJ, Zhu ZX, Shi SP, Song YL, Jin HW, Zhao YF, Tu PF, Li J. Anti-inflammatory 2-(2-phenylethyl) chromone derivatives from Chinese agarwood. Fitoterapia, 2017, 118: 49-55.

[9]	Jorg B, Gilbert MG, Rodney C. Plant terpenoid synthases: molecular biology and phylogenetic analysis. Proc Natl Academy Sci U S A, 1998, 95(8): 4126-4133.

[10]	Kumeta Y, Ito M. Characterization of delta-guaiene synthases from cultured cells of Aquilaria, responsible for the formation of the sesquiterpenes in agarwood. Plant Phys, 2010, 154(4): 1998-2007.

[11]	Lancaster C, Espinoza E. Evaluating agarwood products for 2-(2-phenylethyl) chromones using direct analysis in real time time-of-flight mass spectrometry. Rapid Commun Mass Spectrom, 2012, 26(23): 2649-2656.

[12]	Lewinsohn E, Gijzen M, Croteau R. Defense mechanisms of conifers: differences in constitutive and wound − induced monoterpene biosynthesis among species. Plant Physiol, 1991, 96(1): 44-49.

[13]	Liao G, Mei WL, Dong WH, Li W, Wang P, Kong FD, Gai CJ, Song XQ, Dai HF. 2-(2-Phenylethyl) chromone derivatives in artificial agarwood from Aquilaria sinensis. Fitoterapia, 2016, 110: 38-43.

[14]	Liao G, Mei WL, Kong FD, Li W, Yuan JZ, Dai HF. 5,6,7,8-tetrahydro-2-(2-phenylethyl) chromones from artificial agarwood of Aquilaria sinensis and their inhibitory activity against acetylcholinesterase. Phytochemistry, 2017, 139: 98-108.

[15]	Lin L, Wu ZQ, Cai DY, Shuai O, Li MC (2015) A combination and a method for holistic agarwood production in Aquilaria sinensis. CN 201510259894.0

[16]

Liu YY, Chen HQ, Yang Y, Zhang Z, Wei JH, Meng H, Chen WP, Feng JD, Gan BC, Chen XY, Gao ZH, Huang JQ, Chen B, Chen HJ. Whole-tree agarwood-inducing technique: an efficient novel technique for producing high-quality agarwood in cultivated Aquilaria sinensis trees. Molecules, 2013, 18(3): 3086-3106.

[17]	Liu AG, Juvik JA, Jeffery EH, Berman-Booty LD, Clinton SK, ErdmanJr JW. Enhancement of broccoli indole glucosinolates by methyl jasmonate treatment and effects on prostate carcinogenesis. J Med Food, 2014, 17(11): 1177-1182.

[18]	Mei WL, Yang DL, Wang H, Yang JL, Zeng YB, Guo B, Dong W, Li W, Dai H. Characterization and determination of 2-(2-phenylethyl) chromones in agarwood by GC-MS. Molecules, 2013, 18(10): 12324-12345.

[19]	Mohamed R, Jong PL, Irdayu IN. Succession patterns of fungi associated to wound-induced agarwood in wild Aquilaria malaccensis revealed from quantitative PCR assay. World J Microbiol Biotechnol, 2014, 30(9): 2427-2436.

[20]	Okugawa H, Ueda R, Matsumoto K, Kawanishi K, Kato A. Effect of jinkoh-eremol and agarospirol from agarwood on the central nervous system in mice. Med Plant Nat Prod Res, 1996, 62(1): 2-6.

[21]	Okugawa H, Ueda R, Matsumoto K, Kawanishi K, Kato K. Effects of sesquiterpenoids from “Oriental incenses” on acetic acid-induced writhing and D2 and 5 − HT_2A receptors in rat brain. Phytomedicine, 2000, 7(5): 417-422.

[22]	Rohmer M. The discovery of a mevalonate-independent pathway for isoprenoid biosynthesis in bacteria, algae and higher plants. Nat Prod Rep, 1999, 16(5): 565-574.

[23]	Sen S, Dehingia M, Talukdar NC, Khan M. Chemometric analysis reveals links in the formation of fragrant bio-molecules during agarwood (Aquilaria malaccensis) and fungal interactions. Sci Rep, 2017, 7: 44406.

[24]	Suzuki A, Miyake K, Saito Y, Rasyid FA, Tokuda H, Takeuchi M, Suzuki N, Ichiishi E, Fujie T, Goto M, Sasaki Y, Nakagawa-Goto K. Phenylethylchromones with in vitro antitumor promoting activity from Aquilaria filaria. Planta Med, 2017, 83(3–04): 300-305.

[25]	Wang XH, Gao BW, Liu X, Dong XJ, Zhang ZX, Fan HY, Zhang L, Wang J, Shi SP, Tu PF. Salinity stress induces the production of 2-(2-phenylethyl) chromones and regulates novel classes of responsive genes involved in signal transduction in Aquilaria sinensis calli. BMC Plant Biol, 2016 16 1 119

[26]	Wang XH, Zhang ZX, Dong XJ, Feng YY, Liu X, Gao BW, Wang JL, Zhang L, Wang J, Shi SP, Tu PF. Identification and functional characterization of three type III polyketide synthases from Aquilaria sinensis calli. Biochem Biophys Res Commun, 2017, 486(4): 1040-1047.

[27]	Wu HQ, Wang L, He X, Bai L, Gao XX, Yan HJ, Zhang WM. Molecular cloning of sesquiterpene synthase gene As-Ses TPS from Aquilaria sinensis and its bioinformatics and expression analysis. Chin Tradit Herb Drugs, 2013, 45: 94-101.

[28]	Wu ZQ, Liu S, Li J, Li MC, Du HF, Qi LK, Lin L. Analysis of gene expressions and quality of agarwood by Agar-Bit in Aquilaria sinensis (Lour.) Gilg. J Trop Forest Sci, 2017, 29(3): 380-388.

[29]	Xiang P, Mei WL, Chen HQ, Li W, Chen ZB, Dai HF. Four new bi-phenylethylchromones from artificial agarwood. Fitoterapia, 2017, 120: 61-66.

[30]	Xu YH, Liu J, Liang L, Yang X, Zhang Z, Gao ZH, Sui C, Wei JH. Molecular cloning and characterization of three cDNAs encoding 1-deoxy-d-xylulose-5-phosphate synthase in Aquilaria sinensis (Lour.) Gilg. Plant Physiol Biochem, 2014, 82: 133-141.

[31]	Yang Y, Mei WL, Kong FD, Chen HQ, Li W, Chen ZB, Dai HF. Four new bi-2-(2-phenylethyl) chromone derivatives of agarwood from Aquilaria crassna. Fitoterapia, 2017, 119: 20-25.

[32]	Zhu ZX, Gu YF, Zhao YF, Song YL, Li Jun TuPF. GYF-17, a chloride substituted 2-(2-phenethyl)-chromone, suppresses LPS-induced inflammatory mediator production in RAW264.7 cells by inhibiting STAT1/3 and ERK1/2 signaling pathways. Int Immunopharmacol, 2016, 35: 185-192.