Impact of release of Neochetina spp. on growth and density of water hyacinth Eichhornia crassipes
Authors
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Manonmaniam Sundaranar University, Sri Paramakalyani Centre of Excellence in Environmental Sciences, Alwarkurichi - 627412, Tirunelveli ,IN
K. Sivaraman -
Manonmaniam Sundaranar University, Sri Paramakalyani Centre of Excellence in Environmental Sciences, Alwarkurichi - 627412, Tirunelveli ,INA. G. Murugesan
DOI:
https://doi.org/10.18311/jbc/2016/15596Keywords:
Biological control, Chittar river, Eichhornia crassipes, Neochetina bruchi, Neochetina eichhorniae, water hyacinthAbstract
Water hyacinth (Eichhornia crassipes) is an invasive aquatic macrophyte which creates several problems in irrigation system of rivers. To control their rapid distribution in water bodies the biological control method was carried by employing weevils Neochetina bruchi and Neochetina eichhorniae on river based field trial. The study demonstrates effectiveness of biocontrol weevil open field release on experimental site (Chittar river). When compared to first release in field, the weevil intensity was increased in numbers. Active scraping was observed in the leaves and decay spots were seen in the stems of weed. Both N. bruchi and N. eichhorniae (250 No) were introduced biyearly at experimental site for one year. During these two years of observation period, stunted growth and reduced population were observed in the study site. The study highlights importance of Neochetina spp. on the management of E. crassipes.
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Abjar ZE, Bashir M. 1984. Biology and life tables of Neochetina bruchi Hustache (Coleoptera, Curculionidae) introduced to the White Nile, Sudan, for the biological control of water hyacinth. Zeitsch Ang Entomol. 97(15): 282–286.
Murugesan AG, Paulraj JRMG. 2004. Sustained management of the floating aquatic weed Eichhornia crassipes (Solms.) Mart. employing potential arthropodan biocontrol agents. National J Life Sci. 1(1): 123–128.
Aguilar JA, Camarena OM, Center TD, Bojorquez G. 2003. Biological control of water hyacinth in Sinaloa Mexico with the weevils Neochetina eichhorniae and N. bruchi. BioControl. 48(5): 595–608.
Ajuonu O, Schade V, Veltman B, Sedjro K, Neuenschwander P. 2003. Impact of the weevils Neochetina eichhorniae and N. bruchi (Coleoptera: Curculionidae) on water hyacinth, Eichhornia crassipes (Pontederiaceae), in Benin, West Africa. African Entomol. 11(2): 153–161.
Center T, Hill M, Cordo H, Julien M. 2002. Water hyacinth. Biological control of invasive plants in the Eastern United States. Morgantown, WV, USA: US Forest Service, FHTET-2002-04. pp. 41–64.
Center TD, Dray FA, Jubinsky GP, Leslie AJ. 1999a. Water hyacinth weevils (Neochetina eichhorniae and N. bruchi) inhibit water hyacinth (Eichhornia crassipes) colony development. Biol Control. 15(1): 39–50.
Center TD, Dray Jr FA. 1992. Associations between water hyacinth weevils (Neochetina eichhorniae and N. bruchi) and phenological stages of Eichhornia crassipes in southern Florida. Florida Entomol. 75(2): 196–211.
Center TD, Dray Jr FA, Jubinsky GP, Grodowitz MJ. 1999b. Biological control of water hyacinth under conditions of maintenance management: can herbicides and insects be integrated? Environmental Management 23(2): 241–256.
Center TD, Van TK. 1989. Alteration of water hyacinth (Eichhornia crassipes (Mart.) Solms) leaf dynamics and phytochemistry by insect damage and plant density. Aquatic Botany 35(2): 181–195.
Charudattan R. 1996. Biological control of weeds. An international overview. In pp 9-14. V. SICONBIOL (Simposio de Controle Biologico), Foz do Iguacu, Brazil, Jun.
Cilliers CJ, Hill MP, Ogwang JA, Ajuonu O. 2003. Aquatic weeds in Africa and their control. Biological Control in IPM systems in Africa. pp. 161–178.
De Groote H, Ajuonu O, Attignon S, Djessou R, Neuenschwander P. 2003. Economic impact of biological control of water hyacinth in Southern Benin. Ecol Econ. 45(1): 105–117.
DeLoach C, Cordo H. 1976. Life cycle and biology of Neochetina bruchi, a weevil attacking water hyacinth in Argentina, with notes on N. eichhorniae. Annals Entomol Soc America 69(4): 643–652.
Firehun Y, Struik P, Lantinga E, Taye T. 2015. Adaptability of two weevils (Neochetina bruchi and Neochetina eichhorniae) with potential to control water hyacinth in the Rift Valley of Ethiopia Crop Prot. 76: 75–82.
Grodowitz MJ. 1998. An active approach to the use of insect biological control for the management of non-native aquatic plants. J Aquatic Plant Mgmt. 36: 57–61.
Honmura J, Miyauchi N. 1998. A survey on the growth of water hyacinth (Eichhornia crassipes (Mart.) Solms) in Kagoshima Prefecture. Bull Fac Agric, Kagoshima Univ. 48: 7–14.
Jayanth K. 1987. Comparative studies on the fecundity and longevity of Neochetina eichhorniae and N. bruchi, potential biocontrol agents of water hyacinth. J Biol Control 1(2): 129–132.
Joffe S, Cooke S. 1997. Management of water hyacinth and other invasive aquatic weeds. Issues for the World Bank. Washington, DC. World Bank Internal Report.
Julien M. 2000. Biological control of water hyacinth with arthropods: A review to 2000. Aciar Proc Citeseer. pp. 8–20.
Julien M. 2008. Plant biology and other issues that relate to the management of water hyacinth: A global perspective with focus on Europe1. EPPO bulletin 38(3): 477–486.
Julien MH, Griffiths M, Wright AD. 2011. Biological control of water hyacinth: the weevils Neochetina bruchi and N. eichhorniae biologies, host ranges, and rearing, releasing and monitoring techniques for biological control of Eichhornia crassipes. Monographs.
Mallya G, Mjema P, Ndunguru J. 2000. Water hyacinth control through integrated weed management strategies in Tanzania. Month 2000(2000).
Masifwa WF, Twongo T, Denny P. 2001. The impact of water hyacinth, Eichhornia crassipes (Mart) Solms on the abundance and diversity of aquatic macroinvertebrates along the shores of northern Lake Victoria, Uganda. Hydrobiologia 452(1-3): 79–88.
Mshigeni KE, Mohamud M, Mwandemele OD. 2002. Editorial the water hyacinth crisis in africa: A potent socio-economic opportunity for poverty reduction and sustainable livelihoods. Discovery and Innovation 14(3): 137–141.
Naseema A, Praveena R, Nair R, Peethambaran C. 2004. Fusarium pallidoroseum for management of water hyacinth. Curr Sci. 86(6): 770–771.
Ochiel G, Njoka S, Mailu A, Gitonga W. 2001. Establishment, spread and impact of Neochetina spp. on water hyacinth in Lake Victoria, Kenya. In pp 89-95. Biological and integrated control of water hyacinth, Eichhornia crassipes. Australian Cent Intl Agric Res. Canberra, Australia.
Ogutu-Ohwayo R, Hecky RE, Cohen AS, Kaufman L. 1997. Human impacts on the African great lakes. Env Biol Fishes 50(2): 117–131.
Ogwang JA, Molo R. 2004. Threat of water hyacinth resurgence after a successful biological control program. Biocontrol Sci Technol. 14(6): 623–626.
Perrings C, Williamson M, Barbier EB, Delfino D, Dalmazzone S, Shogren J, Simmons P, Watkinson A. 2002. Biological invasion risks and the public good: An economic perspective. Cons Ecol. 6(1): 1.
Philbrick CT, Les DH. 1996. Evolution of aquatic angiosperm reproductive systems what is the balance between sexual and asexual reproduction in aquatic angiosperms? Biosci. 46(11): 813–826.
Reddy K, De Busk W. 1985. Nutrient removal potential of selected aquatic macrophytes. J Env Quality 14(4): 459–462.
Wilson JR, Ajuonu O, Center TD, Hill MP, Julien MH, Katagira FF, Neuenschwander P, Njoka SW, Ogwang J, Reeder RH. 2007. The decline of water hyacinth on Lake Victoria was due to biological control by Neochetina spp. Aquatic Bot. 87(1): 90–93.
