Institute of Zoology, Jagiellonian University, R. Ingardena 6, 30-060 Cracow, Poland
Bibliografia
BEDNARSKA, A., and R. LASKOWSKI. 2008. Effects of nickel and temperature on the ground beetle Pterostichus oblongopunctatus (Coleoptera: Carabidae). Ecotoxicology 17: 189-198.
CHOLEWA, J., G.P. FEENEY, M. O’REILLY, S.R. STURZENBAUM, A.J. MORGAN, and B. PLYTYCZ. 2006. Autofluorescence in eleocytes of some earthworm species. Fol. Histochem. Cytobiol. 44: 65-71.
CYGAL, M., U. LIS, J. KRUK, and B. PLYTYCZ .2007: Coelomocytes and fluorophores of the earthworm Dendrobaena veneta raised at different ambient temperatures. Acta Biol. Crac. Ser. Zool. 49: 5-11.
ELLIS, S.R., M.E. HODSON, and P. WEGE. 2010. The soildwelling earthworm Allolobophora chlorotica modifies its burrowing behavior in response to carbendazim applications. Ecotox. Environ. Safe. 73: 1424-1428.
HOMA, J., M. NIKLIŃSKA, and B. PŁYTYCZ. 2003. Effect of heavy metals on coelomocytes of the earthworm Allolobophora chlorotica. Pedobiologia 47: 640-645.
KOZIOL, B., M. MARKOWICZ, J. KRUK, and B. PLYTYCZ. 2006. Riboflavin as a source of autofluorescence in Eisenia fetida coelomocytes. Photoch. Photobiol. 82: 570-573.
KWADRANS, A., J. LITWA, S. WOŁOSZCZAKIEWICZ, E. KSIĘŻARCZYK, M. KLIMEK, M. DUCHNOWSKI, J. KRUK, and B. PŁYTYCZ. 2008: Changes in coelomocytes of the earthworm, Dendrobaena veneta, exposed to cadmium, copper, lead or nickel-contaminated soil. Acta Biol. Crac. Ser. Zool. 49: 57-62.
LANGDON, C.J., T.G. PIEARCE, A.A. MEHARG, and K.T. SEMPLE. 2001. Survival and behaviour of the earthworms Lumbricus rubellus and Dendrodrilus rubidus from aresemante-contaminated and non-contaminated sites. Soil Biol. Biochem. 33: 1239-1244.
LAVERACK, M.S. 1961. Tactile and chemical perception in earthworms. II. Responses to acid pH solutions. Comp. Biochem. Physiol. 2: 22-34.
LOUREIRO, S., A.M.V.M. SOARES, and A.J.A. NOGUEIRA. 2005. Terrestrial avoidance behaviour tests as screening tool to assess soil contamination. Environ. Pollut. 138: 121-131.
LUND, M.B., M. HOLMSTRUP, B.A. LOMSTEIN, C. DAMGAARD, and A. SCHRAMM. 2010: Beneficial effect of Verminephrobacter nephridial symbionts on the fitness of the earthworm Aporrectodea tuberculata. Appl. Environ. Microbiol. 76: 4738-43.
MAZUR, A.I., M. KLIMEK, A.J. MORGAN, and B. PLYTYCZ. Riboflavin storage in earthworm chloragocytes and chloragocyte-derived eleocytes and its putative role as chemoattractant for immunocompetent cells. Pedobiologia, submitted.
OLCHAWA, E., M. BZOWSKA, S.R. STüRZENBAUM, A.J. MORGAN, and A. PŁYTYCZ. 2006. Heavy metals affect the coelomocytebacteria balance in earthworms: Environmental interactions between abiotic and biotic stressors. Environ. Pollut. 142: 373-381.
OWOJORI, O.J., and A.J. REINECKE. 2009. Avoidance behaviour of two eco-physiologically different earthworms (Eisenia fetida and Aporrectodea caliginosa) in natural and artificial saline soils. Chemosphere 75: 279-283.
PLYTYCZ, B., J. HOMA, B. KOZIOL, M. ROZANOWSKA, and A.J. MORGAN. 2006. Riboflavin content in autofluorescent earthworm coelomocytes is species-specific. Fol. Histochem. Cytobio. 44: 275-280.
PLYTYCZ, B., U. LIS-MOLENDA, M. CYGAL, E. KIELBASA, A. GREBOSZ, M. DUCHNOWSKI, J. ANDRE, and A.J. MORGAN. 2009. Riboflavin content of coelomocytes in earthworm (.Dendrodrilus rubidus) field populations as a molecular biomarker of soil metal pollution. Environ. Pollut. 157: 3042-3050.
PLYTYCZ, B., E. KIELBASA, A. GREBOSZ, M. DUCHNOWSKI, J. KRUK, and A.J. MORGAN. 2010a. Riboflavin mobilization from eleocyte stores in the earthworm Dendrodrilus rubidus aerially-contaminated Ni-smelter soil. Chemosphere 82: 199-205.
PLYTYCZ, B., M. KLIMEK, B.A. KLIMEK, W. SZYMANSKI, J. KRUK, A.J. and MORGAN. Riboflavin content in the coelomocytes of contrasting earthworm species is differentially affected by edaphic variables including organic matter and metal content. Pedobiologia, submitted.
STEPHENSON, G.L., A. KAUSHIK, N.K. KAUSHIK, K.R. SOLOMON, T. STEELE, and R.P. SCROGGINS. 1998. Use of an avoidance- response test to assess toxicity of contaminated soils to earthworms. (In: Advances in Earthworm Ecotoxicology. SHEPPARD S.C., J.D. BEMBRIDGE, M. HOLMSTRUP and L.POSTHUMA SETAC. Pensacoloa): 67-81.
THAKURIA, D., O. SCHMIDT, A.K. LILIENSIEK, D. EGAN, and F.M. DOOHAN. 2008. Field preservation and DNA extraction methods for intestinal microbial diversity analysis in earthworms. J. Microbiol. Methods 76: 226-33.
VALEMBOIS, P., M. LASSÈGUES, and P. ROCH. 1992. Formation of brown bodies in the coelomic cavity of the earthworm Eisenia fetida andrei and attendant changes in shape and adhesive capacity of constitutive cells. Dev. Comp. Immunol. 16: 95-101.
VERDRENGH, M., and A. TARKOWSKI. 2005. Riboflavin in innate and acquired immune responses. Inflamm. Res. 54, 390-393.
WIECZOREK-OLCHAWA, E., M. NIKLINSKA, J. MIEDZOBRODZKI, and B. PLYTYCZ. 2003. Effects of temperature and soil pollutions on the presence of bacteria, coelomocytes and brown bodies in coelomic fluid of Dendrobaena veneta. Pedobiologia 47: 702-709.
YEARDLEY, JR. R.B., J.M. LAZORCHAK, and L.C. GAST. 1996. The potential of an earthworm avoidance test for evaluation of hazardous waste sites. Environ. Toxicol. Chemistry. 15: 1532-1537.