The effects of the pharmaceutical carbamazepine on life history characteristics of flat-headed mayflies (Heptageniidae) and aquatic resource interactions

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• 作者：Amanda L. Jarvis ; Melody J. Bernot ; Randall J. Bernot
• 关键词：Freshwater ; Trace organic pollutants ; Macroinvertebrate ; Non ; lethal effects
• 刊名：Ecotoxicology
• 出版年：2014
• 出版时间：November 2014
• 年：2014
• 卷：23
• 期：9
• 页码：1701-1712
• 全文大小：688 KB
• 参考文献：1. Abrams PA, Leimar O, Nylin S, Wiklund C (1996) The effect of flexible growth rates on optimal sizes and development times in a seasonal environment. Am Nat 147:381-95 CrossRef
  2. Alexander AC, Culp JM, Liber K, Cessna AJ (2007) Effects of insecticide exposure on feeding inhibition in mayflies and oligochaetes. Environ Toxicol Chem 26:1726-732 CrossRef
  3. Alexander AC, Heard KS, Culp JM (2008) Emergent body size of mayfly survivors. Freshw Biol 53:171-80
  4. Bernot RJ, Turner AM (2001) Predator identify and trait-mediated indirect effects in a littoral food web. Oecologia 129:139-46 CrossRef
  5. Bernot MJ, Smith L, Frey J (2013) Human and veterinary pharmaceutical abundance and transport in a rural central Indiana stream influenced by confined animal feeding operations (CAFOs). Sci Total Environ 445-46:219-30 CrossRef
  6. Biber K, Fiebich BL, Gebicke-H?rter P, van Calker D (1999) Carbamazepine-induced upregulation of adenosine A₁-receptors in astrocyte cultures affects coupling to the phosphoinositol signaling pathway. Neuropsychopharmacology 20:271-78 CrossRef
  7. Brand?o FP, Rodrigues S, Castro BB, Gon?alves F, Antunes SC, Nunes B (2013) Short-term effects of neuroactive pharmaceutical drugs on a fish species: biochemical and behavioral effects. Aquat Toxicol 144-45:218-29 CrossRef
  8. Brodin T, Fick J, Jonsson M, Klaminder J (2013) Dilute concentrations of a psychiatric drug alter behavior of fish from natural populations. Science 339:814-15 CrossRef
  9. Buchwalter DB, Cain DJ, Clements WH, Luoma SN (2007) Using biodynamic models to reconcile differences between laboratory toxicity tests and field biomonitoring with aquatic insects. Environ Sci Technol 41:4821-828 CrossRef
  10. Bunch AR, Bernot MJ (2011) Distribution of nonprescription pharmaceuticals in central Indiana streams and effects on sediment microbial activity. Ecotoxicology 20:97-09 CrossRef
  11. Carpenter SR, Caraco NF, Correll DL, Howarth RW, Sharpley AN, Smith VH (1998) Nonpoint pollution of surface waters with phosphorus and nitrogen. Ecol Appl 8:559-68 CrossRef
  12. Clements WH, Rohr JR (2009) Community responses to contaminants: using basic ecological principles to predict ecotoxicological effects. Environ Toxicol Chem 28:1789-800 CrossRef
  13. Clements WH, Cadmus P, Brinkman SF (2013) Responses of aquatic insects to Cu and Zn in stream microcosms: understanding differences between single species tests and field responses. Environ Sci Technol 47:7506-513
  14. Cleuvers M (2003) Aquatic ecotoxicity of pharmaceuticals including the assessment of combination effects. Toxicol Lett 142:185-94 CrossRef
  15. Conely JM, Funk DH, Buchwalter DB (2009) Selenium bioaccumulation and maternal transfer in the mayfly / Centroptilum triangulaifer in a life-cycle, periphyton-biofilm trophic assay. Environ Sci Technol 43:7952-957 CrossRef
  16. Corkum LD, Ciborowski JJH, Poulin RG (1997) Effects of emergence date and maternal size on egg development and sizes of eggs and first-instar nymphs of a semelparous aquatic insect. Oecologia 111:69-5 CrossRef
  17. De Lange HJ, Noordoven W, Murk AJ, Lürling M, Peeters ETHM (2006) Behavioural responses of / Gammarus pulex (Crustacea, Amphipoda) to low concentrations of pharmaceuticals. Aquat Toxicol 78:209-16 CrossRef
  18. Delachambre J, Delebecque JP, Provansal A, Grillot JP, De Reggi ML, Cailla HL (1979) Total and epidermal cyclic AMP levels related to the variations of ecdysteroids and bursicon during the metamorphosis of the mealworm / Tenebrio molitor L. Insect Biochem 9:95-9 CrossRef
  19. DeLorenzo ME, Fleming J (2008) Individual and mixture effects of selected pharmaceuticals and personal care products on the marine phytoplankton species / Dunaliella teriolecta. Arch Environ Contam Toxicol 54:203-10 CrossRef
  20. Dussault EB, Balakrishnan VK, Sverko E, Solomon KR, Sibley PK (2008) Toxicity of human pharmaceuticals and personal care products to benthic invertebrates. Environ Toxicol Chem 27:425-32 CrossRef
  21. Ferguson PJ, Bernot MJ, Doll JC, Lauer TE (2013) Detection of pharmaceuticals and personal care products (PPCPs) in near-shore habitats of southern Lake Michigan. Sci Total Environ 458-60:187-96 CrossRef
  22. Fink TJ (1982) Why the simple frequency and Janetschek methods are unreliable for determining instars of mayflies: an analysis of the number of nymphal instars of / Stenonema modestum (Banks) (Ephemeroptera: Heptageniidae) in Virginia, USA. Aquat Insects 4:67-1 CrossRef
  23. Flecker AS, Allan JD, McClintock NL (1988) Male body size and mating success in swarms of the mayfly / Epeorus longimanus. Holarctic Ecol 11:280-85
  24. Gilbert LI, Rybczynski R, Warren JT (2002) Control and biochemical nature of the ecdysteroidogenic pathway. Annu Rev Entomol 47:883-16 CrossRef
  25. Harper MP, Peckarsky BL (2006) Emergence cues of a mayfly in a high-altitude stream ecosystem: potential response to climate change. Ecol Appl 16:612-21 CrossRef
  26. Hughes SR, Kay P, Brown LE (2013) Global synthesis and critical evaluation of pharmaceutical data sets collected from river systems. Environ Sci Technol 47:661-77 CrossRef
  27. Lam MW, Young CJ, Brain RA, Johson DJ, Hanson MA, Wilson CJ, Richards SM, Solomon KR, Mabury SA (2004) Aquatic persistence of eight pharmaceuticals in a microcosm study. Environ Tox Chem 23L:1431-440 CrossRef
  28. Lamichhane K, Garcia SN, Hugget DB, DeAngelis DL, La Point TW (2013) Chronic effects of carbamazepine on life-history strategies of / Ceriodaphnia dubia in three successive generations. Arch Environ Contam Toxicol 64:427-38 CrossRef
  29. L?ffler D, R?mbke J, Meller M, Ternes TA (2005) Environmental fate of pharmaceuticals in water/sediment systems. Environ Sci Technol 39:5209-218 CrossRef
  30. Loos R, Gawlik BM, Locoro G, Rimaviciute E, Contini S, Bidoglio G (2009) EU-wide survey of polar organic persistent pollutants in European river waters. Environ Pollut 157:561-68 CrossRef
  31. Lürling M, Sargant E, Roessink I (2006) Life-history consequences for / Daphnia pulex exposed to pharmaceutical carbamazepine. Environ Toxicol 21:172-80 CrossRef
  32. Malty L (1999) Studying stress: the importance of organism-level responses. Ecol Appl 9:431-40 CrossRef
  33. Martin-Diaz L, Franzellitti S, Buratti S, Valbonesi P, Capuzzo A, Fabbri E (2009) Effects of environmental concentrations of the antiepileptic drug carbamazepine on biomarkers and cAMP-mediated cell signaling in the mussel / Mytilus galloprovincialis. Aquat Toxicol 94:177-85 CrossRef
  34. McCafferty WP (1981) Mayflies (order Ephemeroptera). In: McCafferty WP (ed) Aquatic entomology: the fishermen’s and ecologists-illustrated guide to insects and their relatives. Jones ad Bartlett publishers, INC, Sudbury, pp 106-10
  35. Miao X, Yang J, Metcalfe CD (2005) Carbamazepine and its metabolites in wastewater and in biosolids in a municipal wastewater treatments plant. Environ Sci Technol 39:7469-476 CrossRef
  36. Murray KE, Thomas SM, Bodour AA (2010) Prioritizing research for trace pollutants and emerging contaminants in the freshwater environment. Environ Pollut 158:3462-471 CrossRef
  37. Nentwig G, Oetken M, Oehlmann J (2004) Effects of pharmaceuticals on aquatic invertebrates- the example of carbamazepine and clofibric acid. In: Kümmerer K (ed) Pharmaceuticals in the environment. Sources, fate effects and risks, 2nd edn. Springer, Berlin, pp 195-08
  38. Oetken M, Nentwig G, L?ffler D, Ternes T, Oehlmann J (2005) Effects of pharmaceuticals on aquatic invertebrates: part I the antiepileptic drug carbamazepine. Arch Environ Contam Toxicol 49:353-61 CrossRef
  39. Palmquist KR, Jenkins JJ, Jepson PC (2008) Effects of dietary esfenvalerate exposures on three aquatic insect species representing different functional feeding groups. Environ Toxicol Chem 27:1721-727 CrossRef
  40. Pascoe D, Karntanut W, Müller CT (2003) Do pharmaceuticals affect freshwater invertebrates? a study with the cnidarian / Hyrda vulgaris. Chemosphere 51:521-28 CrossRef
  41. Peckarsky BL (1980) Predator-prey interactions between stoneflies and mayflies: behavioral observations. Ecology 61:932-43 CrossRef
  42. Peckarsky BL, Taylor BW, McIntosh AR, McPeek MA, Lytle DA (2001) Variation in mayfly size at metamorphosis as a developmental response to risk of predation. Ecology 82:740-57 CrossRef
  43. Porter RJ, Meldrum BS (2012) Anti-seizure drugs. In: Katzung BG, Masters SB, Trevor AJ (eds) Basic and clinical pharmacology, 12th edn. McGraw Hill, New York, pp 404-10
  44. Quinn B, Gagné F, Blaise C (2008) An investigation into the acute and chronic toxicity of eleven pharmaceuticals (and their solvents) found in wastewater effluent on the cnidarian, / Hydra attenuate. Sci Total Environ 389:306-14 CrossRef
  45. Relyea RA (2005) The impact of insecticides and herbicides on the biodiversity and productivity of aquatic communities. Ecol Appl 15:618-27 CrossRef
  46. Relyea R, Hoverman J (2006) Assessing the ecology in ecotoxicology: a review and synthesis in freshwater systems. Ecol Lett 9:1157-171 CrossRef
  47. Rewitz KF, Larsen MR, Lobner-Olesen A, Rybczynski R, O’Connor MB, Gilbert LI (2009) A phosphoprteomics approach to elucidate neuropeptide signal transduction controlling insect metamorphosis. Insect Biochem Mol Biol 39:475-83 CrossRef
  48. Rosi-Marshall EJ, Royer TV (2012) Pharmaceutical compounds and ecosystem function: an emerging research challenge for aquatic ecologists. Ecosystems 15:867-80 CrossRef
  49. Runck C (2007) Macroinvertebrate production and food web energetics in an industrially contaminated stream. Ecol Appl 17:740-53 CrossRef
  50. Schluter D, Price TD, Rowe L (1991) Conflicting selection pressures and life history trade-offs. Proc R Soc Lond 246:11-7 CrossRef
  51. Scrimgeour GJ, Culp JM (1994) Feeding while evading predators by a lotic mayfly: linking short-term foraging behaviors to long-term fitness consequences. Oecologia 100:128-34 CrossRef
  52. Smith WA, Gilbert LI, Bollenbacher WE (1984) The role of cyclic AMP in the regulation of ecdysone synthesis. Mol Cell Endocrinol 37:285-94 CrossRef
  53. Soluk DA (1990) Postmolt susceptibility of Ephemerella larvae to predatory stoneflies: constraints on defensive armour. Oikos 58:336-42 CrossRef
  54. Syracuse Physprop Database (2003) http://esc.syrres.com/fatepointer/webprop.asp?CAS=298464. Accessed 27 Oct 2013
  55. Van Calker D, Steber R, Klotz K, Greil W (1991) Carbamazepine distinguishes between adenosine receptors that mediate different second messenger responses. Eur J Pharmacol Mol Pharmacol ion 206:285-90 CrossRef
  56. Veach AM, Bernot MJ (2011) Temporal variation of pharmaceuticals in an urban and agriculturally influence stream. Sci Total Environ 409:4533-563 CrossRef
  
• 作者单位：Amanda L. Jarvis (1)
  Melody J. Bernot (1)
  Randall J. Bernot (1)
  
  1. Department of Biology, Ball State University, Muncie, IN, USA
  
• ISSN：1573-3017

文摘

Pharmaceutical pollutants are commonly detected in freshwater ecosystems around the world and have biological effects on aquatic organisms. However, current understanding of the influence this contaminant class has on freshwater communities and ecosystems is lacking. Recently the scientific community has called for research focusing on certain pharmaceuticals due to their ubiquity and potential toxicity. Carbamazepine is one of these pharmaceuticals. To better understand the effect carbamazepine has on life history characteristics of aquatic organisms and consumer-resource interactions, we quantified the influence of carbamazepine on the development, growth and behavior of mayfly nymphs (Stenonema sp.) and the alterations in food consumer-resource interactions between Stenonema and algae (Chaetophora). Microcosms were assembled in a factorial design containing algae and mayfly nymphs native to central Indiana and dosed with environmentally relevant concentrations of carbamazepine. From this ecotoxicological experiment we were able to infer that carbamazepine at 2,000?ng/L influenced the development and behavior of Stenonema nymphs and the body dimensions of adult individuals. However, it appears that carbamazepine does not influence consumer-resource interactions at concentrations found in surface waters. The pharmaceutical carbamazepine may influence the behavior, growth and development of mayflies, which could have significant consequences at the population, community and ecosystem level.