Coastal Plain Yellowtops Flaveria bidentis (L.) Kuntze

Chapter
First Online:
Part of the Invading Nature - Springer Series in Invasion Ecology book series (INNA, volume 13)

Abstract

The coastal plain yellowtops, Flaveria bidentis (L.) Kuntze, a C4 annual or perennial herb native to South America, has damaged local ecosystems and caused great economic loss in China. Its large seeds, strong ability to adapt to different environmental conditions and strong allelopathy to inhibit the growth of other plants lead to its expansion to Hebei, Henan and Shandong Provinces now. Based on biological and geographical characteristics, South, East and Central China are the potential distribution ranges of this weed. The main methods of controlling the invasive plant are chemical control, mechanical eradication and biological control. Sorghum sudanense (Piper) Stapf is the best alternative plant to control the growth of F. bidentis.

Keywords

Flaveria bidentis Alleopathy Distribution Ecological adaptability Control methods 
This is a preview of subscription content, log in to check access.

References

  1. Bai YZ, Cao XF, Chen C, Hu BS, Liu FQ (2009) Potential distribution areas of alien invasive plant Flaveria bidentis (Asteraceae) in China. Chin J Appl Ecol 20(10):2377–2383Google Scholar
  2. Chai MW, Shi FC, He KS, Li RL, Cao D, He ZZ (2012) Effects of saline-alkaine stress on early growth strategy and colonization success of Flaveria bidentis (L.) Kuntze (Asteracae) – a new exotic plant in northern China. Pol J Ecol 60:559–565Google Scholar
  3. Chang RH, Huangfu CH, Yang DL, Chang H (2011) Effects of biological replacement on fungi communities’ diversity of soil invaded by Flaveria bidentis. Chin Agric Sci Bull 27(33):60–66Google Scholar
  4. Chen DQ, Huangfu CH, Liu HM, Wang NN, Yang DL (2013) Effects of water stress arid fungicide on the growth and dwught resistance of Flaveria bidentis. Acta Ecol Sin 33(7):2113–2120CrossRefGoogle Scholar
  5. Dong HJ, Ban XD, Li C, Huo JQ, Zhan HG, Zhan HK, Jin GD, Zhang JL (2014) Synthesis of 3-Hexyl-4-cyan-6,7-dimethoxy Isocoumarin. Asian J Chem 26:3623–3625Google Scholar
  6. Feng JY, Tao P, Pang MH, Liu YC (2009) Study on allelopathic substances releasing mode of Flaveria bidentis. J Agric Univ Hebei 32(1):72–77Google Scholar
  7. Gao XM, Tang TG, Liang Y, Zheng TX, Sang WG, Chen YL (2004) An alert regarding biological invasion by a new exotic plant, Flaveria bidentis, and strategies for its control. Biodivers Sci 12(2):274–279Google Scholar
  8. Huangfu CH, Chen DQ, Wang NN, Yang DL (2010a) The mutual allelopathic effect between invasive plant Flaveria bidentis and four forgage species. Acta Prataculturae Sin 19(4):22–32Google Scholar
  9. Huangfu CH, Wang NN, Chen DQ, Yang DL, Ma J (2010b) Effects of increased soil nitrogen on the competitive performance of Flaveria bidentis and Sorghum bicolor Sorghum sudanense at seedling stage. Ecol Environ Sci 19(3):672–678Google Scholar
  10. Huo JQ, Xing JH, Zhang LH, Kang ZH, Zhang JL (2014) Isolation and structural identification of herbicidal active substance from root of Flaveria bident (L.) Kuntze. J Integr Agric 13(4):804–810CrossRefGoogle Scholar
  11. Ji QF, Song Z, Zhang GL, Fu WD (2014) Effects of Flaveria bidentis invasion on the diversity of phosphorus bacteria in soil. J Agric Resour Environ 31(2):175–181Google Scholar
  12. Jia YY, Zhang XY, Yan J, Yin JL, Zhang FJ (2015) Effects of three asteraceae invasive plants on soil fertility of invaded domain. J Hebei Univ 35(5):494–502Google Scholar
  13. Jiang N, Huangfu CH, Wang NN, Chen DQ, Tu CY, Yang DL, Wang CL (2012) Effects of replacement control with forage species on the biomass allocation and photosynthetic characteristics of Flaveria bidentis. Chin J Ecol 31(8):1903–1910Google Scholar
  14. Li XJ, Wang GQ, Zhang C-X et al (2006) Flaveria bidentis, a new exotic plant, distribution, characteristics and chemical control. Weed Sci 4:58–61Google Scholar
  15. Li HN, Liu WX, Wan FH (2011) Effect of Ageratina adenophora(Spreng.)and Flaveria bidentis(Linn.)invasion on soil microbial community and Oryza sativa L. growth. Chin J EcoAgric 19(6):1365–1371Google Scholar
  16. Li HY, Chen DQ, Wang H, Yang DL, Huangfu CH (2015) Effects of fungicide on interspecific competition between Flaveria bidentis and Amaranthus retroflexus in different planting densities. Chin J Ecol 34(4):1013–1018Google Scholar
  17. Lu ZG, Zhou WJ (2006) Potential risk assessment and control strategies of Flaveria bidentis (L.) Kuntze, an exotic plant. Weed Sci 4:4–5Google Scholar
  18. Lv Y, Wang GQ, Zheng L, Ni HW (2011) Competitiveness of invasive plant Flaveria bidentis with native weed plants. Chin J Ecol 30(4):677–681Google Scholar
  19. Ma J, Yi J, Huangfu CH, Yang DL (2010) Competitive effects between invasive plant Flaveria bidentis and three pasture species. Acta Bol Boreal-Occident Sin 30(5):1020–1028Google Scholar
  20. Ma JW, Geng SL, Wang SB, Zhang GL, Fu WD, Shu B (2011) Genetic diversity of the newly invasive weed Flaveria bidentis (Asteraceae) reveals consequences of its rapid range expansion in northern China. Weed Res 51:363–372CrossRefGoogle Scholar
  21. Peng J, Ma Y, Li XJ, Ma XY, Xi JP, Ma YJ, Li XF (2012) Competition of an Alien invasive weed Flaveria bidentis with cotton. Cotton Sci 24(3):272–278Google Scholar
  22. Powell AM (1978) Annals of the Missouri botanical garden. Systematics of Flaveria 65(2):590–636Google Scholar
  23. Ren YP, Jiang S, Gu S, Zhang SQ, Zhao N (2009) Preliminary studies on allelopathy of the aqueous extracts of an alien plant, Flaveria bidentis. Plant Prot 35(3):36–40Google Scholar
  24. Sun XC, Fu WD, Zhang GL, Tang XL, Bi CW (2011) Three new diseases recorded on the invasive weed yellow-top (Flanueria bidentis) in north China: diagnosis and pathogen identification. J Southeast Univ (natural science) 33(4):24–30Google Scholar
  25. Tu CY, Huangfu CH, Jiang N, Gao SB, Yang DL (2013) Comparison of leaf construction cost between invasive plant Flaveria bidentis and its five co-occuring plants. Chin J Ecol 32(11):2985–2991Google Scholar
  26. Wang GQ, Xu X, Wang JP, Li SQ, Li Y, Ni HW (2011) Effects of different density of Flaveria bidentis on the growth and yield of cotton. Plant Prot 37(3):84–86Google Scholar
  27. Wang Y, Zhang YM, Li Q, Zhang FJ, Wan FH (2016) Comparative study on the microbial community structure in different depth of rhizosphere soil in Flaveria bidentis invasion region. J Agric Univ Hebei 39(1):35–42Google Scholar
  28. Wei Y, Gao YL, Xie QQ, Zhang GL, Fu WD (2011a) Isolation of chlorogenic acid from Flaveria bidentis (L.) Kuntze by CCC and synthesis of chlorogenic acid-intercalated layered double hydroxide. Chromatographia 73(Suppl 1):S97–S102CrossRefGoogle Scholar
  29. Wei Y, Xie QQ, Fisher D, Sutherland IA (2011b) Separation of patuletin-3-O-glucoside, astragalin, quercetin, kaempferol and isorhamnetin from Flaveria bidentis (L.) Kuntze by elution-pump-out high-performance counter-current chromatography. J Chromatogr A 218:6206–6211CrossRefGoogle Scholar
  30. Wei Y, Du JL, Lu YY (2012a) Preparative separation of bioactive compounds from essential oil of Flaveria bidentis (L.) Kuntze using steam distillation extraction and one step high-speed counter-current chromatography. J Sep Sci 35:2608–2614CrossRefPubMedGoogle Scholar
  31. Wei Y, Zhang K, Yin L, Du JL, Zhang GL (2012b) Isolation of bioactive components from Flaveria bidentis (L.) Kuntze using high-speed counter-current chromatography and time-controlled collection method. J Sep Sci 35:869–874CrossRefPubMedGoogle Scholar
  32. Wei Y, Yin L, Xie QQ, Zhang GL (2013) An efficient strategy based on macroporous resins and semi-preparative high performance liquid chromatography for rapid separation of five flavonoids components from Flaveria bidentis(L.) Kuntze. Sep Sci Technol 48:140–147CrossRefGoogle Scholar
  33. Wei Y, Gao YL, Xie QQ, Zhang GL, Fu WD (2016) Isolation of herbicidal substance, α-terthienyl, from the root of Flaveria bidentis using HSCCC and HPLC. Int J Agric Biol 18:155–159Google Scholar
  34. Xie QQ, Wei Y, Zhang GL (2010) Separation of flavonol glycosides from Flaveria bidentis (L.) Kuntze by high- speed counter-current chromatography. Sep Purif Technol 72:229–233CrossRefGoogle Scholar
  35. Xie QQ, Yin L, Zhang GL, Wei Y (2012) Separation and purification of isorhamnetin 3-sulphate from Flaveria bidentis (L.) Kuntze by counter-current chromatography comparing two kinds of solvent systems. J Sep Sci 35:159–165CrossRefPubMedGoogle Scholar
  36. Xu WC, Xu J, Tao B, Yuan WH, Zhang JL (2007) Preliminary study on allelopathic effect of the invasive species Flaveria bidentis (L.) Kuntze. J Agric Univ Hebei 6(30):63–67Google Scholar
  37. Xu J, Xu WC, Yang YJ, Tao B, Zhang JL (2008) The allelopathy of Flaveria bidentis (L.) Kuntze, an invasive weed species. Front Agric China 2:446–450CrossRefGoogle Scholar
  38. Yan SL, Huangfu CH, Li G, Zuo ZJ, Ma J, Yang DL (2011) Effects of replacement control with four forage species on bacterial diversity of soil invaded by Flaveria bidentis. Chin J Plant Ecol 35(1):45–55CrossRefGoogle Scholar
  39. Yang X, Zhang LH, Shi CP, Shang Y, Zhang JL, Han JM, Dong JG (2014) The extraction, isolation and identification of exudates from the roots of Flaveria bidentis. J Integr Agric 13(1):105–114CrossRefGoogle Scholar
  40. Yin JL, Zhang XY, Yan J, Li Q, Jia YY, Zhang FJ, Wan FH (2015) The Feedback of arbuscular mycorrhizal fungi on the competition between Flaveria bidentis and cotton. Ecol Environ Sci 24(7):1132–1136Google Scholar
  41. Zhang FJ, Xu XY, Chen FM, Guo AY, Long R (2008) Allelopathic effect of aqueous extract of Flavera bidentis(L.) Kunta on Chinese cabbage and rice seedlings growth. Acta Bot Boreal-Occident Sin 28(8):1669–1674Google Scholar
  42. Zhang FJ, Li JQ, Xu XY, Guo AY, Hu JR, Du SX, Wan FH (2009) Influence of environmental factors on seed germination of Flavera bidentis (L.) Kuntza. Acta Ecol Sin 9(4):1947–1953Google Scholar
  43. Zhang TR, Huangfu CH, Bai XM, Yang DL, Li G, Lai X, Zhao JN (2010) Effects of Flaveria bidentis invasion on soil nutrient contents and enzyme activities. Chin J Ecol 29(7):1353–1358Google Scholar
  44. Zhang TR, Huangfu CH, Yang DL, Bai XM (2011) Invasion mechanism and ecological management of exotic plant, Flaveria bidentis. Acta Praculturae Sin 20(3):268–278Google Scholar
  45. Zhang RH, Fu WD, Zhang GL, Zhang YL (2012a) Study on displacement control of Flaveria bidentis Kuntze with alfalfa and sunflower. J Southwest Agric Univ 34(2):33–38Google Scholar
  46. Zhang FJ, Guo JY, Chen FX, Guo AY, Wan FH (2012b) Assessment of allelopathic residue of Flaveria bidentis (L.) Kuntze on wheat seedling. Arch Agron Soil Sci 58(3):257–265Google Scholar
  47. Zhang FJ, Guo JY, Liu WX, Wan FH (2012c) Influence of coastal plain yellowtops (Flaveria bidentis) residues on growth of cotton seedlings and soil fertility. Arch Agron Soil Sci 58(10):1117–1128Google Scholar
  48. Zhang YM, Wang Y, Li Q, Zhang FJ, Wan FH (2015) Mechanism of AM fungi on competitive growth betwen invasive plant Flaveria bidentis and native plant Setaria viridis. Acta BotBoreal-Ocident Sin 35:1215–1221Google Scholar
  49. Zhao XH, Huangfu CH, Qu B, Wang YJ, Wang H, Liu HM, Yang DL (2014) Effects of Flaveria bidentis invasion on soil microbial functional diversity. J Agric Resour Environ 31(2):182–189Google Scholar
  50. Zhao XH, Yang DL, Wang H, Liu HM, Qu B, Huangfu CH (2015) Efects of Flaveria bidentis invasion on soil nitrogen cycling and soil microbial biomas in diferent regions. Acta Prataculturae Sin 24(2):62–69Google Scholar
  51. Zhou J. (2010) Analysis of the main adaptative natures yellow-top (Flaveria bidentis) weed to its invaded ecological niches. The thesis of Southwest University.Google Scholar

Copyright information

© Springer Nature Singapore Pte Ltd. 2017 2017

Authors and Affiliations

  1. 1.College of Life ScienceHebei UniversityBaodingChina
  2. 2.State Key Laboratory for Biology of Plant Disease and Insect Pests, Institute of Plant ProtectionChinese Academy of Agricultural SciencesBeijingChina

Personalised recommendations