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| 不同海拔云南黄连生物量和主要有效成分变化 | |
| 引用本文: | 张霁,蔡传涛,蔡志全,刘贵周,罗媛,杨志雄.不同海拔云南黄连生物量和主要有效成分变化[J].应用生态学报,2008,19(7):1455-1461. |
| 作者姓名: | 张霁 蔡传涛 蔡志全 刘贵周 罗媛 杨志雄 |
| 作者单位: | 1. 中国科学院西双版纳热带植物园,昆明,650223;中国科学院研究生院,北京,100049 2. 中国科学院西双版纳热带植物园,昆明,650223 3. 云南福维临生物药业有限公司,云南六库,673100 |
| 基金项目: | 国家财政部资助国家农业综合开发重点产业化项目 , 云南省省院省校科技合作项目 , 中国科学院专项基金 |
| 摘 要: | 研究了不同海拔(2 100~2 700 m)下,野生和人工栽培云南黄连的生物量、主要有效成分含量及产量.结果表明:野生云南黄连根茎和根生物量沿海拔梯度呈上升趋势,但无显著性差异(P>0.05);人工栽培云南黄连根茎生物量平均值在海拔2 600 m和2 700 m处分别为87.5 kg·hm-2和97.0 kg·hm-2,显著高于海拔2 300 m处(34.8 kg·hm-2,P<0.05),且海拔2 300、2 600和2 700 m的人工栽培云南黄连根茎和根生物量均大于野生云南黄连,但无显著性差异(P>0.05). 野生云南黄连的根茎和根生物量均与全株生物量呈显著正相关. 野生云南黄连根茎和根小檗碱含量在海拔2 700 m处最高,分别为4.60%和1.93%; 根茎巴马汀和药根碱含量、根药根碱含量在海拔2 600~2 700 m处最高;根巴马汀含量在2 300 m处最高.人工云南黄连根茎和根小檗碱含量在海拔2 600 m处最高,分别为4.41%和1.90%; 根茎巴马汀含量,根小檗碱、巴马汀和药根碱含量在海拔2 600~2 700 m处最高;根茎药根碱含量在海拔2 300 m处最高.海拔2 600~2 700 m处野生云南黄连根茎和根中各有效成分产量显著高于海拔2 100和2 300 m处(P<0.05). 野生云南黄连分株的根茎生物量、根生物量、叶生物量、总生物量、高度和冠幅沿海拔梯度呈先升后降趋势.增大种植密度和加强人工管理可以提高云南黄连生物量和主要有效成分产量. |
| 关 键 词: | 云南黄连 生物量 有效成分 不同海拔 云南 总生物量 成分变化 altitude gradient compounds active major biomass patterns 人工管理 加强 种植密度 冠幅 高度 分株 有效成分 小檗碱含量 巴马汀 相关 |
| 收稿时间: | 2007-12-20 |
Variation patterns of Coptis teeta biomass and its major active compounds along an altitude gradient. |
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| ZHANG Ji,CAI Chuan-tao,CAI Zhi-quan,LIU Gui-zhou,LUO Yuan,YANG Zhi-xiong.Variation patterns of Coptis teeta biomass and its major active compounds along an altitude gradient.[J].Chinese Journal of Applied Ecology,2008,19(7):1455-1461. | |
| Authors: | ZHANG Ji CAI Chuan-tao CAI Zhi-quan LIU Gui-zhou LUO Yuan YANG Zhi-xiong |
| Institution: | Xishuangbanna Tropical Botanical Garden, Chinese Academy of Sciences, Kunming 650223, China;Graduate University of Chinese Academy of Sciences, Beijing 100049, China;Fuweilin Biological Pharmacy Co. Ltd., Liuku 673100, Yunnan, China |
| Abstract: | An investigation was made on the biomass and major active compounds of wild and cultivated Coptis teetaalong an altitude gradient in Nujiang of Yunnan. The results showed that the rhizome and root biomass of wild C. teeta increased from the altitude 2 100 m to 2 700 m, but the difference was not significant. The rhizome biomass of cultivated C. teeta was 87.5 kg·hm-2 at 2 600 m and 97.0 kg·hm-2 at 2 700 m, being much higher than 34.8 kg·hm-2 at 2 300 m (P<0.05). At the same altitudes (2 300 m, 2 600 m, and 2 700 m), cultivated C. teeta had higher rhizome and root biomass than wild C. teeta, but the difference was not significant. There was a significant positive correlation between the rhizome and root biomass and the whole plant biomass of wild C. teeta. Wild C. teeta had the highest content of berberine in rhizome (4.60%) and root (1.93%) at 2 700 m, plamatinein in rhizome, and jatrorrhizine in rhizome and root at 2 600-2 700 m, and plamatinein in root at 2 300 m; while cultivated C. teetahad the highest content of berberine in rhizome (4.41%) and root (1.90%) at 2 600 m, plamatinein in rhizome and root, and berberine and jatrorrhizine in root at 2 600-2 700 m, and jatrorrhizine in rhizome at 2 300 m. The content of major active compounds in wild C. teeta rhizome and root were significantly higher at 2 600 m and 2 700 m than at 2 100 m and 2 300 m (P<0.05), and the rhizo me biomass, root biomass, leaf biomass, total biomass, height, and canopy diameter of wildC. teeta ramet increased first and decreased then from the altitude 2 100 m to 2 700 m. Increasing planting density and enhancing artificial management could improve the biomass of C. teeta and its major active compounds concentrations. |
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