Abstract
Under laboratory conditions, the comparative effects of two insect growth regulators, chlorfluazuron and oxymatrine, and spinosad as a biopesticide were examined on honey bee workers (Apis mellifera L.). Separate groups of bees were left for 24 h to feed on 50% sucrose solution containing different concentrations of the tested insecticides, and the lethal concentration that caused 50% mortality (LC50) was estimated. The inhibitory effects on acetylcholinesterase (AChE) and adenosine triphosphatase (ATPase) activities as biochemical indicators were determined in vivo after 24 h in head, thorax, and abdomen of surviving bees obtained after treatments with a view to explore the possible mode of action of these compounds. Results indicated that exposure to spinosad showed toxicity to honey bees with LC50 value of 7.34 mg L−1, followed by oxymatrine (LC50 = 10.68 mg L−1), while chlorfluazuron was the least acutely toxic of the tested compounds (LC50 = 2,526 mg L−1). Oxymatrine and spinosad at the same tested concentrations (2.5, 5, 10, and 20 mg L−1) significantly inhibited AChE activity in different organs of honey bee workers, and high inhibition percentage was obtained with the enzyme isolated from the thorax. However, chlorfluazuron at 400, 1,000, 2,000, and 4,000 mg L−1 caused high inhibition of AChE activity isolated from the head (39.65% and 44.22% at 2,000 and 4,000 mg L−1, respectively). In addition, the toxic effects of the tested compounds on activity of ATPase indicated that spinosad caused the highest inhibitory effect in different organs compared with oxymatrine at the same concentrations, and high inhibition was found with ATPase isolated from the head. The results also indicated that oxymatrine was the least active compound for inhibition of AChE and ATPase.
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References
Abramson CI, Squire J, Sheridan A, Mulder PG (2004) The effect of insecticides considered harmless to honey bees (Apis mellifera): Proboscis conditioning studies by using the insect growth regulator tebufenozide and diflubenzuron. Environ Entomol 33:378–388
Adams SM, Shepard KK, Greeley MS, Jimenez BD, Ryan MG, Shugart LR, McCarthy JF, Hinton DE (1989) The use of bioindicators for assessing the effects of pollutant stress on fish. Marine Environ Res 28:459–464
Anderson LD, Atkins EL (1968) Pesticide usage in relation to bee keeping. Ann Rev Entomol 13:213–238
Atkins EL (1992) Injury to honey bee by poisoning. In: Graham JE (ed) The hive and the honey bee. Dadant and Sons, Hamilton, pp 1153–1208
Atkins EL, Kellum D, Atkins KW (1981) Reducing pesticides hazard to honey bees: mortality prediction techniques and integrated management strategies. Division of Agricultural Sciences, University of California, Leaf. 2883, 22 pp. (with: Supplemental list to leaflet 2883 (1981) compiled by E. Atkins, Nov. 1990)
Badiou A, Meled M, Belzunces LP (2008) Honeybee Apis mellifera acetylcholinesterase—a biomarker to detect deltamethrin exposure. Ecotoxicol Environ Saf 69:246–253
Belzunces LP, Toutant JP, Bounias M (1988) Acetylcholinesterase from Apis mellifera head, evidence for amphiphilic and hydrophilic forms characterized by Triton X-114 phase separation. J Biochem 255:463–470
Bendahou N, Bounias M, Fleche C (1999) Toxicity of cypermethrin and fenitrothion on the hemolymph carbohydrates, head acetylcholinesterase, and thoracic muscle Na+, K+-ATPase of emerging honey bees (Apis mellifera L). Ecotoxicol Environ Saf 44:139–146
Celli G, Maccagnani B (2003) Honey bees as bioindicators of environmental pollution. Bull Insectol 56:137–139
Celli G, Porrini C, Baldi M, Ghigli E (1991) Pesticides in Ferrara Province: two years’ monitoring with honey bees (1987–1988). Ethol Ecol Evol 1:111–115
Copping LG, Menn JJ (2000) Biopesticides: a review of their action, applications and efficacy. Pest Manag Sci 56:651–676
Crane E (1984) Bees, honey and pollen as indicators of metals in the envirnment. Bee World 55:47–49
Currie RW (1999) Fluvalinate queen tabs for use against Varroa jacobsoni: efficacy and impact on honey bee, Apis mellifera, queen and colony performance. Am Bee J 139:871–876
Darvas B, Polgar LA (1998) Novel type insecticides: specificity and effects on non-target organisms. In: Ishaaya I, Degheele D (eds) Insecticides with novel modes of action. Springer, Berlin, pp 188–259
Decourtye A, Devillers J, Cluzeau S, Charreton M, Pham-Delègue MH (2004) Effects of imidacloprid and deltamethrin on associative learning in honeybee under semi-field and laboratory conditions. Ecotox Environ Safe 57:410–419
Decourtye A, Devillers J, Genecque E, Le Menach K, Budzinski H, Cluzeau S, Pham-Delègue MH (2005) Comparative sublethal toxicity of nine pesticides on olfactory learning performances of the honeybee Apis mellifera. Arch Environ Contam Toxicol 48:242–250
Desneux N, Decourtye A, Delpuech JM (2007) The sublethal effects of pesticides on beneficial arthropods. Annu Rev Entomol 52:81–106
Ellman GL, Courtney D, Andres V, Featherstone RM (1961) A new and rapid colorimetric determination of acetylcholinesterase activity. Biochem Pharm 7:88–95
Finney DJ (1971) Probit analysis, 3rd edn. Cambridge University Press, London
Frasco MF, Fournier D, Carvalho F, Guilhermino L (2005) Do metals inhibit acetylcholinesterase (AChE)? Implementation of assay conditions for the use of AChE activity as a biomarker of metal toxicity. Biomarkers 10:360–375
Free JB (1993) Insect pollination. Academic Press, New York
Ghini S, Fernandez M, Pico Y (2004) Occurrence and distribution of pesticides in the province of Bologna, Italy, using honeybees as bioindicators. Arch Environ Contam Toxicol l47:479–488
Giesy JP, Graney RL (1989) Recent developments in and intercomparisons of acute and chronic bioassays and bioindicators. Hydrobiologia 188(189):21–60
Grue CE, Hart ADM, Mineau P (1991) Biological consequences of depressed brain cholinesterase activity in wildlife. In: Mineau P (ed) Cholinesterase-inhibiting Insecticides—their impact on wildlife and the environment. Elsevier, Amsterdam, pp 151–210
Guilhermino L, Barros P, Silva MC, Soares AMVM (1998) Should the use of inhibition of cholinesterases as a specific biomarker for organophosphate and carbamate pesticides be questioned? Biomarkers 3:157–163
Haynes KF (1988) Sublethal effects of neurotoxic insecticides on insect behavior. Ann Rev Entomol 33:149–168
Heller J, Mattioda H, Klein E, Sagenmuller A (1992) Field evaluation of RH 5992 on lepidopterous pests in Europe. Brighton Crop Prot Conf Pests Dis 1:59–65
Huang ZY, Knowles C (1990) Nicotinic and muscarininc cholinergic receptors in honey bee (Apis mellifera) brain. Comp Biochem Physiol 97:275–281
Hyne RV, Maher WA (2003) Invertebrate biomarkers: links to toxicosis that predict population decline. Ecotoxicol Environ Saf 54:366–374
Iwasa T, Motoyama N, Ambrose JT, Michael Roe R (2004) Mechanism for the differential toxicity of neonicotinoid insecticides in the honey bee, Apis mellifera. Crop Prot 23:371–378
Koch RB (1969) Chlorinated hydrocarbon insecticides: inhibition of rabbit brain ATPase activities. J Neurochem 16:269–271
Lagadic L, Caquet T, Ramade F (1994) The role of biomarkers in environmental assessment (5). Invertebrate populations and communities. Ecotoxicology 3:193–208
Liu SQ, Shi JJ, Cao H, Jia FB, Liu XQ, Shi GL (2000) Survey of pesticidal component in plant. In: Dianmo L (Ed.), Entomology in China in 21st Century. Proceedings of conference of Chinese Entomological Society. Science and Technique Press, Beijing, China, pp 1098–1104
Lowry OH, Rosebrough NJ, Farr AL, Randall RJ (1951) Protein measurement with the Folin phenol reagent. J Biol Chem 193:265–275
MacKenzie KE, Winston ML (1989) Effects of sublethal exposure to diazinon on longevity and temporal division of labor in the honey bee (Hymenoptera: Apidae). J Econ Entomol 82:75–82
Mayer DF, Lunden JD (1986) Toxicity of fungicides and an acaricide to honey bees (Hymenoptera: Apidae) and their effects on bee foraging behavior and pollen viability on blooming apples and pears. Environ Entomol 15:1047–1049
Mayer DF, Johansen CA, Lunden JD, Rathbone L (1987) Bee hazard of insecticides combined with chemical stickers. Am Bee J 127:493–495
Mayer DF, Kovacs G, Brett BL, Brisabri BL (2001) The effects of spinosad insecticide to adults of Apis mellifera, Megachile rotundata and Nomia melanderi (Hymenoptera:Apidae). Int J Horticul Sci 7:93–97
Mayes MA, Thompson GD, Husband B, Miles MM (2003) Spinosad toxicity to pollinators and associated risk. Rev Environ Contam Toxicol 179:37–71
M’diaye K, Bounias M (1993) Time- and dose-related effects of the pyrethroid fluvalinate on haemolymph carbohydrates and gut lipids of honeybees following in vivo injection of very low doses. Biochem Environ Sci 6:145–153
Medrzycki P, Montanari R, Bortolotti L, Sabatini AG, Maini S, Porrini C (2003) Effects of imidacloprid administered in sub-lethal doses on honey bee behaviour. Laboratory tests. Bull Insectol 56:59–62
Michener CD (1974) The social behavior of the bees: a comparative study. Harvard University Press, Cambridge
Miles M (2003) The effects of spinosad, a naturally derived insect control agent to the honeybee. Bull Insectol 56:119–124
Milles M, Dutton R (2000) Spinosad a naturally derived insect control agent with potential for use in glasshouse integrated pest management systems. Med Fac Landbouww Univ Gent 65:393–400
Mommaerts V, Sterk G, Smagghe G (2006) Bumblebees can be used in combination with juvenile hormone analogues and ecdysone agonists. Ecotoxicol 15:513–521
Murphy SD (1986) Pesticides. In: Klaassen CD, Amdur M, Doull J (eds) The basic science of poisons. Macmillan, New York
NRC (1987) Committee on Biological Markers of the National Research Council (NRC), biological markers in environmental health research. Environ Health Perspect 74:3–9
Ozcan Oruc E, Uner N, Tamer L (2002) Comparison of Na+, K+-ATPase activities and malondialdehyde contents in liver tissue for three fish species exposed to azinphosmethyl. Bull Environ Contam Toxicol 69:271–277
Payne JF, Mathieu A, Melvin W, Fancy LL (1996) Acetylcholinesterase, an old biomarker with a new future? Fiels trials in association with two urban rivers and a paper mill in Newfounfland. Mar Pollut Bull 32:225–231
Picardnizou AL, Phamdelegue MH, Kerguelen V, Marilleau R, Olsen L, Grison R, Toppan A, Masson C (1995) Foraging behavior of honey bees (Apis mellifera L.) on transgenic oilseed rape (Brassica napus L. Var Oleifera). Transgenic Res 4:270–276
Porrini C, Colombo V, Celli G (1996) The honey bee (Apis mellifera L.) as pesticide bioindicator. Evaluation of the degree of pollution by means of environmental hazard indexes. In: Proceedings XX International Congress of Entomology, Firenze, Italy, August 25–31, p 444
Porrini C, Ghini S, Girotti S, Sabatini AG, Gattavecchia E, Celli G (2002) Use of honey bees as bioindicators of environmental pollution in Italy. In: Devillers J, Pham-Délègue MH (eds) Honey bees: estimating the environmental impact of chemicals. Taylor & Francis, London and New York, pp 186–247
Porrini C, Sabatini AG, Girotti S, Fini F, Monaco L, Celli G, Bortolotti L, Ghini S (2003) The death of honey bees and environmental pollution by pesticides: the honey bees as biological indicators. Bull Insectol 56:147–152
Salgado VL (1998) Studies on the mode of action of spinosad: Insect symptoms and physiology correlates. Pest Biochem Physiol 60:91–102
Salgado VL, Sheets JJ, Watson GB, Schmidt AL (1998) Studies on the mode of action of spinosad: the internal effective concentration and the concentration dependence of neural excitation. Pest Biochem Physiol 60:103–110
Schmidt HW (1996) The reaction of bees under the influence of the insecticide Imidacloprid. In: Lewis GB (ed) Proceedings of the 6th ICP-BR international symposium on hazards of pesticides, September 17–19, BBA Braunschweig, Germany, Appendix n. 12
Schneider M, Smagghe G, Viñuela E (2003) Susceptibility of Hyposoter didymator (Hymenoptera: Ichenumonidae) adults to several IGRs pesticides and spinosad by different exposure methods. IOBC/wprs Bull 26:111–122
Seeley T (1995) The wisdom of the hive. Princeton University Press, Princeton, NJ
Smirle MJ, Winston ML, Woodward KL (1984) Development of a sensitive bioassay for evaluating sublethal pesticide effects on the honey bee (Hymenoptera: Apidae). J Econ Entomol 77:63–67
Smith RK, Wilcox MM (1990) Chemicals residues in bees, honey and beeswax. Am Bee J 130:188–192
Stevenson JH, Needham PH, Walker J (1978) Poisoning of honeybees by pesticides: investigations of the changing patterns in Britain over 20 years. Rothamsted Experimental Station Report 1977:55–72
Stone JC, Abramson CI, Price JM (1997) Task dependent effects of dicofol (kelthane) on learning in the honey bee (Apis mellifera). Bull Environ Contam Toxicol 58:177–183
Tasei JN (2001) Effects of insect growth regulators on honey bees and non-Apis bees. A Rev Apidol 32:527–545
Thompson GD, Michel KH, Yao RC, Mynderse JS, Mosburg CT, Worden TV, Chio EH, Sparks TC, Hutchins SH (1997) The discovery of Saccharopolyspora spinosa and new class of insect control products. Down to Earth, Dow Agro Sciences 52:1–5
Thompson HM, Wilkins S, Battersby AH, Waite RJ, Wilkinson D (2005) The effects of four insect growth-regulating (IGR) insecticides on honey bee (Apis mellifera L.) colony development, queen rearing and drone sperm production. Ecotoxicol 14:757–769
Tonelli D, Gattavecchia E, Ghini S, Porrini C, Celli G, Mercuri AM (1990) Honey bees and their products as indicators of environmental radioactive pollution. J Radioanalyt Nucl Chem 141:427–436
Vandame R, Meled M, Colin ME, Belzunces LP (1995) Alteration of the homing-flight in the honey bee Apis mellifera exposed to sublethal dose of deltamethrin. Environ Toxicol Chem 14:855–860
Wallwork-Barber MK, Ferenbaugh RW, Gladney ES (1982) The use of honeybees as monitors of environmental pollution. Am Bee J 122:770–772
Weick J, Thorn RS (2002) Effects of acute sublethal exposure to coumaphos or diazinon on acquisition and discrimination of odor stimuli in the honey bee (Hymenoptera: Apidae). J Econ Entomol 95:227–236
Winston ML (1987) The biology of the honey bee. Harvard University Press, Cambridge
Yadwad VB, Kallapur VL, Basalingappa S (1990) Inhibition of gill Na+, K+-ATPase activity in dragonfly larva, Pantala flavesens, by endosulfan. Bull Environ Contam Toxicol 44:585–589
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Rabea, E.I., Nasr, H.M. & Badawy, M.E.I. Toxic Effect and Biochemical Study of Chlorfluazuron, Oxymatrine, and Spinosad on Honey Bees (Apis mellifera). Arch Environ Contam Toxicol 58, 722–732 (2010). https://doi.org/10.1007/s00244-009-9403-y
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DOI: https://doi.org/10.1007/s00244-009-9403-y