生态环境学报
生態環境學報
생태배경학보
ECOLOGY AND ENVIRONMENT
2013年
3期
417-422
,共6页
何金明%肖艳辉*%王羽梅%潘春香
何金明%肖豔輝*%王羽梅%潘春香
하금명%초염휘*%왕우매%반춘향
钾浓度%茴香%生长发育%精油
鉀濃度%茴香%生長髮育%精油
갑농도%회향%생장발육%정유
potassium concentrations%fennel%growth%essential oil
为了揭示钾浓度对植物生长发育和次生代谢产物——精油累积的影响特性及其内在关系,采用水培方法,以日本园试配方中钾含量为标准1K,设计1/8K、1/4K、1/2K、1K和2K处理,研究了不同钾浓度对茴香Foeniculum vulgare Mill.生长发育、精油含量和组分的影响.结果表明:不同钾浓度处理对植株形态(茴香分枝数、节数和花序数)、生物量(地上部鲜质量、全株鲜质量和全株干质量)、碳、氮含量(全氮、蛋白氮、全碳、可溶性糖、C/N)、精油含量、单株精油产量和色素含量(Chl.a、Chl.b、CAR.、Chl.a+b、Chl.a/b)影响显著,综合认为1K为利于茴香初生代谢产物累积(生长发育)的最佳处理,而1/4K、1/8K和1K为利于次生代谢产物累积(精油含量)的较好处理;相关分析表明,精油含量与全碳含量(r=0.72)、可溶性糖含量(r=0.70)成极显著正相关;单株精油产量与全氮含量(r=0.49)呈显著正相关.不同钾浓度处理茴香精油均鉴定出23种成分,其中17种成分的相对含量差异显著.精油第一主要成分反式-茴香脑含量为74.75%~79.15%,第二主要成分柠檬烯含量为8.25%~14.81%,第三主要成分莳萝芹菜脑相对含量2.04%~3.82%,处理间均差异显著.结论:钾浓度不但影响茴香的生长发育,还影响着茴香次生代谢产物精油的含量、产量和成分组成比例;适宜的钾浓度(1K)可以实现茴香初生代谢产物累积(生长发育)与次生代谢产物累积(精油产量)均高的结果.
為瞭揭示鉀濃度對植物生長髮育和次生代謝產物——精油纍積的影響特性及其內在關繫,採用水培方法,以日本園試配方中鉀含量為標準1K,設計1/8K、1/4K、1/2K、1K和2K處理,研究瞭不同鉀濃度對茴香Foeniculum vulgare Mill.生長髮育、精油含量和組分的影響.結果錶明:不同鉀濃度處理對植株形態(茴香分枝數、節數和花序數)、生物量(地上部鮮質量、全株鮮質量和全株榦質量)、碳、氮含量(全氮、蛋白氮、全碳、可溶性糖、C/N)、精油含量、單株精油產量和色素含量(Chl.a、Chl.b、CAR.、Chl.a+b、Chl.a/b)影響顯著,綜閤認為1K為利于茴香初生代謝產物纍積(生長髮育)的最佳處理,而1/4K、1/8K和1K為利于次生代謝產物纍積(精油含量)的較好處理;相關分析錶明,精油含量與全碳含量(r=0.72)、可溶性糖含量(r=0.70)成極顯著正相關;單株精油產量與全氮含量(r=0.49)呈顯著正相關.不同鉀濃度處理茴香精油均鑒定齣23種成分,其中17種成分的相對含量差異顯著.精油第一主要成分反式-茴香腦含量為74.75%~79.15%,第二主要成分檸檬烯含量為8.25%~14.81%,第三主要成分蒔蘿芹菜腦相對含量2.04%~3.82%,處理間均差異顯著.結論:鉀濃度不但影響茴香的生長髮育,還影響著茴香次生代謝產物精油的含量、產量和成分組成比例;適宜的鉀濃度(1K)可以實現茴香初生代謝產物纍積(生長髮育)與次生代謝產物纍積(精油產量)均高的結果.
위료게시갑농도대식물생장발육화차생대사산물——정유루적적영향특성급기내재관계,채용수배방법,이일본완시배방중갑함량위표준1K,설계1/8K、1/4K、1/2K、1K화2K처리,연구료불동갑농도대회향Foeniculum vulgare Mill.생장발육、정유함량화조분적영향.결과표명:불동갑농도처리대식주형태(회향분지수、절수화화서수)、생물량(지상부선질량、전주선질량화전주간질량)、탄、담함량(전담、단백담、전탄、가용성당、C/N)、정유함량、단주정유산량화색소함량(Chl.a、Chl.b、CAR.、Chl.a+b、Chl.a/b)영향현저,종합인위1K위리우회향초생대사산물루적(생장발육)적최가처리,이1/4K、1/8K화1K위리우차생대사산물루적(정유함량)적교호처리;상관분석표명,정유함량여전탄함량(r=0.72)、가용성당함량(r=0.70)성겁현저정상관;단주정유산량여전담함량(r=0.49)정현저정상관.불동갑농도처리회향정유균감정출23충성분,기중17충성분적상대함량차이현저.정유제일주요성분반식-회향뇌함량위74.75%~79.15%,제이주요성분저몽희함량위8.25%~14.81%,제삼주요성분시라근채뇌상대함량2.04%~3.82%,처리간균차이현저.결론:갑농도불단영향회향적생장발육,환영향착회향차생대사산물정유적함량、산량화성분조성비례;괄의적갑농도(1K)가이실현회향초생대사산물루적(생장발육)여차생대사산물루적(정유산량)균고적결과.
The objective of this study was to reveal the response characteristics and the internal correlation of fennel plant growth and essential oil accumulation to potassium concentrations. Effect of different potassium concentrations to fennel plant growth, essential oil content and components was studied by using method of solution culture, and making Japanese garden formula’s potassium content as 1K, and designing 1/8K, 1/4K, 1/2K, 1K and 2K treatments. The results showed that branch number, number of nodes, inflorescence number, shoot fresh weight(F.W), fresh and dry weight(D.W) , total nitrogen, protein nitrogen, total carbon, soluble sugar, C/N, essential oil content, yield of essential oil per plant and pigment indexes were significantly affected by different potassium concentration treatments. In general, growth and development of fennel were the best at 1K , while 1/4K、1/8K and 1K were tested to be the best treatments for essential oil content of fennel. Correlation analysis showed that:essential oil content was positively correlated with total carbon content (r=0.72) and soluble sugar content(r=0.70); yield of essential oil per plant was positively correlated to total nitrogen content(r=0.49). A total of 23 kinds of components in essential oil were identified, and 17 kinds of components of essential oil were significantly different among different potassium concentration treatments. (E)-anethole, which is the dominant essential oil component, contributed 74.75% to79.15% to the total amount of oil. And the following most abundant chemical is limonene, which had the contents of 8.25%to 14.81%in the total amount of oil, while Dill Apiol, the third abundant chemical, had the relative amount of 2.04%to 3.82%. The three components were significantly different among different potassium concentration treatments. Conclusion showed that different potassium concentrations affect not only the fennel plant growth, but also the yield and concentration of essential oil. And appropriate concentration of potassium can contribute to the high rate of plant growth and yield of essential oil.
