Laboratory Evaluation of Bacillus subtilis Bioactivity on Musca domestica (Linn) (Diptera: Muscidae) Larvae from Poultry Farms in South Western Nigeria
Muscid flies are known to be vectors of disease agents and species that annoy humans and domesticated animals. An example of these flies is Musca domestica (house fly) whose adult and immature stages occur in a variety of filthy organic substances including household garbage and animal manures. They contribute to microbial contamination of foods. It is therefore imperative to control these flies as a result of their role in Public health. The second and third instars of Musca domestica (Linn) were infected with varying cell loads of Bacillus subtilisin vitro for a period of 48 hours to evaluate its larvicidal activities. Mortality of the larvae increased with incubation period after treatment with the varying cell loads. Investigation revealed that the second instars larvae were more susceptible to treatment than the third instars treatments. Values obtained from the third instar group were significantly different (P<0.05) from those obtained from the second instars group in all the treatments. Lethal concentration (LC50) at 24 hours for 2nd instars was 2.35 while LC50 at 48 hours was 4.31.This study revealed that Bacillus subtilis possess good larvicidal potential for use in the control of Musca domestica in poultry farms.
[1] Banjo A,D., Lawal,A.O. and Osinuga BO, (2004). Reservoir competence of Alphitobius disperinus (Coleoptera: Tenebrioridae) in South West Nigeria poultry houses. Asian J. Microbial. Biotechnol. Environ. Sci.;3:67-11
[2] Brain, M., Wiegmann, D.K., Yeates, J.L. and Thorne, H. K.(2005). "a fly’s head, showing compound eyes and hair”. en.wikipedia.org/wiki/housefly
[3] Dewey MC,(1999).Housefly. University of Rhode Island http://www.edu/ce/factsheets/houseflies.html
[4] Finney, D.J. (1971). Probit analysis.1stedition.Cambridge University Press. Cambridge. London.; Pp 100 - 121
[5] Gunasekaran, K. and Boopathi, P.S. (2004). Vaidyanathan K. Laboratory and field evaluation of Teknar HP-D, a biolavicidal formulation of Bacillus thuringiensisssp.isrealensis against mosquito vectors. Actatropica; 92: 109-118
[6] Hald, B., Sommer, H.M. and Skovguard, H. (2007). Use of fly screens to reduce Campylobacter spp. Introduction in broiler houses. Emerging Infectious Diseases 13: 1951-1953
[7] Hedges, S.A. (2004). The mallis handbook of pest control. 9th edition GIE Media, Cleveland.Pp. 1396
[8] Holt. J.G., Kreig,N.R. andSneath, P.H.A., Staley,J.T. andWilliams, S.T. (1994). Bergey’sManual of Determinative Bacteriology. 9thEdn. Lippincott Williams and Wilkins, Baltimore.
[9] Imai, C. (2000). A new method to control house flies, Muscadomestica, at waste disposal sites. Research in Population Ecology.27: 111-123
[10] Kaufman, P.E., Scott, J.G. and Rutz, D.A. (2001). Monitoring insecticide resistance in house flies from New York dairies.
[11] Kurstak, E.(2002). Microbial and Viral pesticides. 4th edition Marcel Dekker. New York Pp 75
[12] Morgan, P.B., LaBrecque, G.C. and Patterson, R.S. (1978). Mass culturing the microhymenopteran parasite Spalangiaendius (Hymenoptera: Pteromalidae). Journal of medical entomology. 14: 671-3
[13] Omoya, F.O., Boboye,B.E. and Akinyosoye,F.A. (2009). Mosquito-Degradative-Potential of Cockroach and Mosquito Borne Bacteria. Journal of Medical Science. 9: 202-207.
[14] Ostrolenk,M. and Welch,H. (2002). The common housefly (Musca domestica) as a sourcse of pollution in food establishments. Food Research. 7: 192-200
[15] Sheri, M.B., Steelman, C.D. and Szalanski, A.L. (2007). "Detection of pathioden DNA from filth flies (Diptera:Muscidae) using filter paper spot cards” Journal of Agricultural and Urban24: 13-18.
[16] Stuart, M. B.(2008). Muscadomestica. The common housefly. www.the-piedpiper.co.uk
[17] Sun, C., Georghiou, G.P. and Weiss, K. (1980). Toxicity of Bacillus thuringiensis var.isrealensis to mosquito larvae variously resistant to conventional insecticidesMosquito news. 40: 614-618
[18] Szalanski, L.A., Owens,B.C., Mckay, T. and Steelman, D.C. (2004). "Detection of Campylobacter and Escherichia coli 0157:H7 fron flies by polymerase chain reaction” Medical and veterinary Entomology18: 241-246
[19] Weinzierl, D., Nowak, J.C. and Dofty, B.A. (2002). Use of various organisms for the biocontrol of diseases: Principle, Mechnism of Action and Future Prospects. Applied and Environmental Microbiology.1: 4951-59.
[1] Banjo A,D., Lawal,A.O. and Osinuga BO, (2004). Reservoir competence of Alphitobius disperinus (Coleoptera: Tenebrioridae) in South West Nigeria poultry houses. Asian J. Microbial. Biotechnol. Environ. Sci.;3:67-11
[2] Brain, M., Wiegmann, D.K., Yeates, J.L. and Thorne, H. K.(2005). "a fly’s head, showing compound eyes and hair”. en.wikipedia.org/wiki/housefly
[3] Dewey MC,(1999).Housefly. University of Rhode Island http://www.edu/ce/factsheets/houseflies.html
[4] Finney, D.J. (1971). Probit analysis.1stedition.Cambridge University Press. Cambridge. London.; Pp 100 - 121
[5] Gunasekaran, K. and Boopathi, P.S. (2004). Vaidyanathan K. Laboratory and field evaluation of Teknar HP-D, a biolavicidal formulation of Bacillus thuringiensisssp.isrealensis against mosquito vectors. Actatropica; 92: 109-118
[6] Hald, B., Sommer, H.M. and Skovguard, H. (2007). Use of fly screens to reduce Campylobacter spp. Introduction in broiler houses. Emerging Infectious Diseases 13: 1951-1953
[7] Hedges, S.A. (2004). The mallis handbook of pest control. 9th edition GIE Media, Cleveland.Pp. 1396
[8] Holt. J.G., Kreig,N.R. andSneath, P.H.A., Staley,J.T. andWilliams, S.T. (1994). Bergey’sManual of Determinative Bacteriology. 9thEdn. Lippincott Williams and Wilkins, Baltimore.
[9] Imai, C. (2000). A new method to control house flies, Muscadomestica, at waste disposal sites. Research in Population Ecology.27: 111-123
[10] Kaufman, P.E., Scott, J.G. and Rutz, D.A. (2001). Monitoring insecticide resistance in house flies from New York dairies.
[11] Kurstak, E.(2002). Microbial and Viral pesticides. 4th edition Marcel Dekker. New York Pp 75
[12] Morgan, P.B., LaBrecque, G.C. and Patterson, R.S. (1978). Mass culturing the microhymenopteran parasite Spalangiaendius (Hymenoptera: Pteromalidae). Journal of medical entomology. 14: 671-3
[13] Omoya, F.O., Boboye,B.E. and Akinyosoye,F.A. (2009). Mosquito-Degradative-Potential of Cockroach and Mosquito Borne Bacteria. Journal of Medical Science. 9: 202-207.
[14] Ostrolenk,M. and Welch,H. (2002). The common housefly (Musca domestica) as a sourcse of pollution in food establishments. Food Research. 7: 192-200
[15] Sheri, M.B., Steelman, C.D. and Szalanski, A.L. (2007). "Detection of pathioden DNA from filth flies (Diptera:Muscidae) using filter paper spot cards” Journal of Agricultural and Urban24: 13-18.
[16] Stuart, M. B.(2008). Muscadomestica. The common housefly. www.the-piedpiper.co.uk
[17] Sun, C., Georghiou, G.P. and Weiss, K. (1980). Toxicity of Bacillus thuringiensis var.isrealensis to mosquito larvae variously resistant to conventional insecticidesMosquito news. 40: 614-618
[18] Szalanski, L.A., Owens,B.C., Mckay, T. and Steelman, D.C. (2004). "Detection of Campylobacter and Escherichia coli 0157:H7 fron flies by polymerase chain reaction” Medical and veterinary Entomology18: 241-246
[19] Weinzierl, D., Nowak, J.C. and Dofty, B.A. (2002). Use of various organisms for the biocontrol of diseases: Principle, Mechnism of Action and Future Prospects. Applied and Environmental Microbiology.1: 4951-59.
@article{"International Journal of Biological, Life and Agricultural Sciences:67283", author = "Funmilola O. Omoya", title = "Laboratory Evaluation of Bacillus subtilis Bioactivity on Musca domestica (Linn) (Diptera: Muscidae) Larvae from Poultry Farms in South Western Nigeria", abstract = "Muscid flies are known to be vectors of disease agents and species that annoy humans and domesticated animals. An example of these flies is Musca domestica (house fly) whose adult and immature stages occur in a variety of filthy organic substances including household garbage and animal manures. They contribute to microbial contamination of foods. It is therefore imperative to control these flies as a result of their role in Public health. The second and third instars of Musca domestica (Linn) were infected with varying cell loads of Bacillus subtilis in vitro for a period of 48 hours to evaluate its larvicidal activities. Mortality of the larvae increased with incubation period after treatment with the varying cell loads. Investigation revealed that the second instars larvae were more susceptible to treatment than the third instars treatments. Values obtained from the third instar group were significantly different (P", keywords = "Bacillus subtilis, larvicidal activities, Musca domestica, poultry farms.", volume = "8", number = "6", pages = "561-3", }
