Released Characteristics of Volatile Organic Compounds in Cunninghamia lanceolata

doi:10.3969/j.issn.1009-7791.2022.03.003

Subtropical Plant Science ›› 2022, Vol. 51 ›› Issue (3): 178-183.DOI: 10.3969/j.issn.1009-7791.2022.03.003

• Plant physiology, biochemistry and molecular biology • Previous Articles Next Articles

Released Characteristics of Volatile Organic Compounds in Cunninghamia lanceolata

XIE De-zhi, MA Hong-yan*, LAI Wu-ting, ZHANG Hui-lin, YUAN Fu-jian, QIAN Yin-lan

(Guangzhou Tanhui Forestry Co. Ltd., Guangzhou 510520, Guangdong China)

Received:2022-04-19 Accepted:2022-05-26 Online:2022-06-30 Published:2022-10-17
Contact: MA Hong-yan

杉木挥发性有机物释放特征研究

谢德志，马红岩*，赖武婷，张慧琳，袁富坚，钱银兰

(广州碳汇林业有限公司，广东广州 510520)

通讯作者: 马红岩
基金资助:
石门公园储备林杉木多目标经营示范林项目(穗石门公园资合字[2018]13号)

Abstract

Abstract: To clarify the composition and variation rules of contents of components of volatile organic compounds (VOCs) in Cunninghamia lanceolata, seasonal changes of composition and relative contents of components of VOCs released by C. lanceolata were compared and analyzed by using dynamic headspace air-circulation method and thermal desorption-gas chromatography-mass spectrum (TDS-GC-MS) technique. The results showed that total of 60 compounds were identified in the VOCs released by C. lanceolata. The number of compound types rose first and then decline in all year, and the number of compounds released in summer was the most abundant, reaching 42. The largest number of detected compound types consisted of alkanes, aldehydes, esters, and alcohols, accounting for 73.33% of all types of detected compounds. Compound types of C. lanceolata VOCs released in Spring were mainly alcohols, with the total relative content of 27.19%, terpenes in Summer, with the total relative content of 17.29%, and aldehydes in Autumn, with the total relative content of 23.55%. In summary, C. lanceolata has a certain intensive effect on health care, and summer is the best time for forest recreation in C. lanceolata forest.

Key words: Cunninghamia lanceolata, volatile organic compounds (VOCs), seasonal change, forest health care

摘要： 为了明确杉木(Cunninghamia lanceolata)挥发性有机物(VOCs)的成分组成和含量的变化规律，采用动态顶空采集法和热脱附-气质联用(TDS-GC-MS)技术，对杉木释放的VOCs成分组成和相对含量的季节性变化进行分析。结果表明，杉木释放的VOCs中共鉴定出60种化合物，一年中释放的化合物种数随季节变化呈先升后降的趋势，夏季释放种类最多，达42种。检测到的烷烃类、醛类、酯类和醇类化合物种类最多，占检测到的化合物总种类数的73.33%。春季杉木释放的VOCs以醇类化合物为主，总相对含量为27.19%；夏季以萜烯类化合物为主，总相对含量为17.29%；秋季以醛类化合物为主，总相对含量为23.55%。综上，杉木具有一定的康养功效，夏季是在杉木林中进行康养活动的最佳时期。

关键词: 杉木, 挥发性有机物(VOCs), 季节动态, 森林康养

CLC Number:

S791

XIE De-zhi, MA Hong-yan, LAI Wu-ting, ZHANG Hui-lin, YUAN Fu-jian, QIAN Yin-lan. Released Characteristics of Volatile Organic Compounds in Cunninghamia lanceolata[J]. Subtropical Plant Science, 2022, 51(3): 178-183.

谢德志，马红岩，赖武婷，张慧琳，袁富坚，钱银兰. 杉木挥发性有机物释放特征研究[J]. 亚热带植物科学, 2022, 51(3): 178-183.

References

[1] 李洪远, 王芳, 熊善高, 孟伟庆, 吕铃钥. 植物挥发性有机物的作用与释放影响因素研究进展[J]. 安全与环境学报, 2015, 15(2): 292–296. [2] 高艳芳, 薛彬娥, 郭微, 吴伟, 劳清华, 吴莉娴, 李永泉, 张晖. 枫香叶采后挥发物表征及影响因子研究[J]. 亚热带植物科学, 2021, 50(6): 454–460. [3] 杨小琴. 植物挥发性有机物(VOCs)释放及其环境净化效应概述[J]. 湖南城市学院学报(自然科学版), 2006, 15(4): 57–60. [4] 周琦, 王金凤, 徐永勤, 夏淑芳, 沈凤强, 徐卢雨, 陈卓梅. 樟树叶片挥发性有机物释放季节动态和日动态变化规律[J]. 广西植物, 2020, 40(7): 1021–1032. [5] Ali J G, Alborn H T, Campos-Herrera R, Kaplan F, Duncan L W, Rodriguez-Saona C, Koppenh?fer A M, Stelinski L L. Subterranean, herbivore-induced plant volatile increases biological control activity of multiple beneficial nematode species in distinct habitats[J]. PLoS One, 2012, 7(6): e38146. [6] Robert A R. Wake up and smell the roses: The ecology and evolution of floral scent[J]. Annual Review of Ecology, Evolution, and Systematics, 2008, 39(1): 549–569. [7] Huang M, Sanchez-Moreiras A M, Abel C, Sohrabi R, Lee S, Gershenzon J, Tholl D. The major volatile organic compound emitted from Arabidopsis thaliana flowers, the sesquiterpene (E)-β-caryophyllene, is a defense against a bacterial pathogen[J]. New Phytologist, 2012, 193(4): 997–1008. [8] Baldwin I T, Halitschke R, Paschold A, von Dahl C C, Preston C A. Volatile signaling in plant-plant interactions: "Talking Trees" in the genomics era[J]. Science, 2006, 311(5762): 812–815. [9] Zhang Z, Guo S, Liu X, Gao X. Synergistic antitumor effect of α-pinene and β-pinene with paclitaxel against non-small-cell lung carcinoma (NSCLC)[J]. Drug Research (Stuttg), 2015, 65(4): 214–218. [10] Maria R P, Mark J P, Wendy S G, Alex B G, Sou N M, William R S. The impacts of reactive terpene emissions from plants on air quality in Las Vegas, Nevada[J]. Atmospheric Environment, 2009, 43(27): 4109–4123. [11] 张英凯, 刘鹏举, 刘长春, 任怡. 基于空间聚类的杉木生长预测方法[J]. 林业科学, 2019, 55(11): 137–144. [12] 王金凤, 周琦, 陈卓梅. 木荷枝叶挥发性有机物(VOCs)的季节差异及春季日变化[J]. 植物资源与环境学报, 2022, 31(1): 53–60. [13] 郄光发, 王成, 彭镇华. 森林生物挥发性有机物释放速率研究进展[J]. 应用生态学报, 2005, 16(6): 1151–1155. [14] 李继泉, 金幼菊, 沈应柏, 洪蓉. 环境因子对植物释放挥发性化合物的影响[J]. 植物学通报, 2001, 18(6): 649–656. [15] 郭阿君. 4种园林树木挥发性有机物释放动态及其抑菌作用的研究[D]. 哈尔滨: 东北林业大学硕士学位论文, 2007. [16] 王艳英, 王成, 董建华, 董建文, 傅伟聪. 福州市夏季绿植广场VOCs变化特征研究[J]. 西北林学院学报, 2015, 30(4): 307–314. [17] 朱晓珍, 卢清彪, 胡兴华, 邓涛, 段云博, 方振名, 黄仕训. 罗汉果叶片挥发性成分与访花昆虫: 雌雄株差异及其生态影响[J]. 广西植物, 2020, 40(9): 1259–1268. [18] 赵亚红, 徐翠霞, 马玲, 王彬, 韦赛君, 吕嘉欣, 高岩, 张汝民. 3种常绿树挥发物成分对空气负离子及微生物的影响[J]. 浙江农林大学学报, 2020, 37(4): 654–663. [19] 彭少麟, 南蓬, 钟扬. 高等植物中的萜类化合物及其在生态系统中的作用[J]. 生态学杂志, 2002, 21(3): 33–38. [2] 周禾, 刘自学, 韩建国, 陈光耀, 王堃, 吴序卉, 毛培胜, 戎郁萍. 草坪质量分级[S]. 北京: 中国标准出版社, 2002. [3] 王玉珍, 黄晓, 蔡丽平, 郑惠欣, 侯晓龙, 周垂帆, 张虹, 黄鹏萍, 华聪. 不同温度条件下土壤颗粒组成对宽叶雀稗种子发芽与幼苗生长的影响[J]. 草业学报, 2018, 27(9): 45–55. [4] 朱淑霞, 尹少华, 张俊卫, 王洪顺, 王志勇, 刘福全. 不同废弃物基质对狗牙根无土草皮生产的影响[J]. 草业科学, 2011, 28(1): 68–73. [5] 王友生, 林秀凤, 简丽华, 王益和, 廖棁武. 宽叶雀稗对养分缺乏胁迫的形态与生理响应[J]. 亚热带植物科学, 2020, 49(4): 253–257. [6] 李思诗, 司晓静, 蒋芳市, 林金石, 蔡学智, 吴俣, 黄炎和. 长汀县崩岗区8种禾本科植物根系构型特征[J]. 草业学报, 2018, 27(10): 215–222. [7] 刘华荣, 龙忠富, 邓蓉, 卢敏, 李洪曙, 孟军江. 百喜草在退耕坡地种植中的水土保持效应及养羊效果[J]. 贵州农业科学, 2012, 40(7): 145–148. [8] Zhang C B, Li D R, Jiang J, Zhou X, Niu X Y, Wei Y, Ma J J. Evaluating the potential slope plants using new method for soil reinforcement program[J]. Catena, 2019, 180: 346–354. [9] Danna T, Edward B, Heather K B. Lead phytoremediation in contaminated soils using ornamental landscape plants[J]. Journal of Geoscience and Environment Protection, 2021, 9(5): 152–164. [10] Sadat A S, Ayatollah R, Ali H T S. Identifying superior drought–tolerant bermudagrass accessions and their defensive responses to mild and severe drought conditions[J]. Euphytica, 2021, 217(5): 91–122. [11] 邓辅唐, 喻正富, 杨自全, 吕小玲, 曹明举, 黄少国, 邓辅商. 山毛豆、木豆、猪屎豆在高速公路边坡生态恢复工程中的应用[J]. 中国水土保持, 2006(4): 21–23, 52. [12] 王玉, 杨彬, 郝清玉. 木麻黄种子萌发的限制生态因子[J]. 广西植物, 2020, 40(3): 403–411. [13] 赵雅曼, 陈顺钰, 张韵, 姜云, 侯晓龙, 蔡丽平. 酸、Cd胁迫对宽叶雀稗种子萌发、幼苗生长及亚细胞结构的影响[J]. 农业环境科学学报, 2019, 38(1): 60–69. [14] 刘华荣, 卢敏, 龙忠富, 杨义成, 孟军江. 水引发对百喜草萌发与幼苗生长的影响[J]. 种子, 2012, 31(5): 95–97. [15] 郑嘉诚, 李永霞, 杨小林. 不同基质对江孜沙棘萌发及幼苗生长的影响[J]. 种子, 2019, 38(8): 83–85. [16] 张光辉, 梁一民. 植被盖度对水土保持功效影响的研究综述[J]. 水土保持研究, 1996, 3(2): 104–110. [17] 余晓华. 风化紫色砂岸地区新建高等级公路边坡生态防护草种适应性研究[D]. 兰州: 甘肃农业大学硕士学位论文, 2000. [18] Peppers J M, Mittlesteadt T L, Askew S D. Effects of perennial ryegrass competition on bermudagrass and hybrid bermudagrass cover, biomass, and total nonstructural carbohydrate accumulation[J]. Crop Science, 2021, 61(5): 3179–3186. [19] 李强, 丁武泉, 朱启红, 宋力. 模拟沙埋对三峡库区低位消落带狗牙根恢复生长的影响[J]. 生态学杂志, 2015, 34(4): 919–924. [20] 喻荣岗, 左长清, 杨洁, 王昭艳, 李小强, 刘柏根. 红壤侵蚀区优良水土保持草本植物的选择及评价[J]. 水土保持通报, 2008(2): 205–210. [21] 张娜, 梁一民. 黄土丘陵区天然草地地下/地上生物量的研究[J]. 草业学报, 2002(2): 72–78. [22] 周启龙, 多吉顿珠, 益西央宗. 拉萨地区16个燕麦引进品种的灰色关联度评价[J]. 草地学报, 2020, 28(2): 389–396. [23] 潘希, 罗伟, 段兴武, 钟荣华, 李宇翔. 水土保持效益评价方法研究进展[J]. 中国水土保持科学, 2020, 18(1): 140–150. [24] 彭绍云, 顾祝军, 修平. 南方红壤试验小区乔灌草多年水土保持效应比较[J]. 水土保持研究, 2013, 20(1): 25–29. [2] 牛素贞, 宋勤飞, 樊卫国, 陈正武. 干旱胁迫对喀斯特地区野生茶树幼苗生理特性及根系生长的影响[J]. 生态学报, 2017, 37(21): 7333–7341. [3] 吴春霞, 李阳, 李昊宇, 王文全, 范敬龙. 水分胁迫对竹柳生长的影响[J]. 黑龙江农业科学, 2021(10): 96–103. [4] 王宝宁, 邹世慧, 李玲莉. 两种常绿绿化树种的根系生长规律研究[J]. 绿色科技, 2019(23): 164–166. [5] 郑艺, 张丽, 周宇, 张炳华. 1982–2012年全球干旱区植被变化及驱动因子分析[J]. 干旱区研究, 2017, 34(1): 59–66. [6] 王铁英, 王仰仁, 柴俊芳, 郭文俊. 根系水分胁迫响应函数对土壤水及作物生长动态和产量模拟影响的研究[J]. 干旱区地理, 2022, 45(2): 566–577. [7] 李会杰. 黄土高原林地深层土壤根系吸水过程及其对水分胁迫和土壤碳输入的影响[D]. 杨凌: 西北农林科技大学硕士学位论文, 2019. [8] 杨再强, 邱译萱, 刘朝霞, 陈艳秋, 谭文. 土壤水分胁迫对设施番茄根系及地上部生长的影响[J]. 生态学报, 2016, 36(3): 748–757. [9] 李秧秧, 刘文兆. 土壤水分与氮肥对玉米根系生长的影响[J]. 中国生态农业学报, 2001(1): 23–25. [10] 种培芳, 李航逸, 李毅. 荒漠植物红砂根系对干旱胁迫的生理响应[J]. 草业学报, 2015, 24(1): 72–80. [11] 李鲁华, 李世清, 翟军海, 史俊通. 小麦根系与土壤水分胁迫关系的研究进展[J]. 西北植物学报, 2001(1): 1–7. [12] 夏延国, 董芳宇, 吕爽, 王键铭, 井家林. 极端干旱区胡杨细根的垂直分布和季节动态[J]. 北京林业大学学报, 2015, 37(7): 37–44. [13] 丁红, 张智猛, 戴良香, 康涛, 慈敦伟, 宋文武. 干旱胁迫对花生根系生长发育和生理特性的影响[J]. 应用生态学报, 2013, 24(6): 1586–1592. [14] 杨秀玲. 添加硅酸钠对铅胁迫下香樟幼苗生长和生理的影响[D]. 南宁: 广西大学硕士学位论文, 2020. [15] 骆必刚. 香樟种子调制与催芽技术探讨[J]. 中国园艺文摘, 2015, 31(9): 35–36. [16] 邓东发. 绿化苗木香樟的种子繁殖法[J]. 农家科技, 2010(2): 15. [17] 杨鼎超, 衷诚明, 郭铧艳, 陈言柳, 张林平, 黄永平. 我国樟树病害分布及防治研究进展[J]. 生物灾害科学, 2018, 41(3): 176–183. [18] 钟红. 浅谈氮磷施肥对香樟幼苗生长的意义[J]. 农业与技术, 2017, 37(17): 122–124. [19] 高照全, 张显川, 王小伟. 不同水分条件下桃树根系的分形特征[J]. 天津农业科学, 2006, 12(3): 3. [20] 张仁和, 郑友军, 马国胜, 张兴华, 路海东, 史俊通, 薛吉全. 干旱胁迫对玉米苗期叶片光合作用和保护酶的影响[J]. 生态学报, 2011, 31(5): 1303–1311. [21] 郑云普, 王贺新, 娄鑫, 杨庆朋, 徐明. 木本植物非结构性碳水化合物变化及其影响因子研究进展[J]. 应用生态学报, 2014, 25(4): 1188–1196. [22] 吕爽, 张现慧, 张楠, 夏延国, 井家林, 李景文. 胡杨幼苗根系生长与构型对土壤水分的响应[J]. 西北植物学报, 2015, 35(5): 1005–1012. [23] 杨振亚, 周本智, 陈庆标, 葛晓改, 王小明, 曹永慧, 童冉, 石洋. 干旱对杉木幼苗根系构型及非结构性碳水化合物的影响[J]. 生态学报, 2018, 38(18): 6729–6740. [24] 杨小林, 张希明, 李义玲, 解婷婷, 王伟华. 塔克拉玛干沙漠腹地几种植物根系分形特征[J]. 干旱区地理, 2009, 32(2): 249–254. [25] 杨培岭, 任树梅, 罗远培. 分形曲线度量与根系形态的分形表征[J]. 中国农业科学, 1999, 32(1): 89–92. [26] 单立山, 李毅, 董秋莲, 耿东梅. 红砂根系构型对干旱的生态适应[J]. 中国沙漠, 2012, 32(5): 1283–1290.

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Released Characteristics of Volatile Organic Compounds in Cunninghamia lanceolata

杉木挥发性有机物释放特征研究

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