Abstract
Scyphozoan medusae are very successful foragers which occasionally occur in high abundances in boreal waters and may impact many different groups in the marine ecosystem by means of a variety of toxins. A rainbow trout gill cell line, RTgill-W1, was tested for its suitability as quantitative indicator of the cytotoxicity of Cyanea capillata and Aurelia aurita; the major scyphozoan species in the North and Baltic seas. Cultures of rainbow trout gill cells were exposed to whole venoms extracted from fishing tentacles and oral arms at increasing protein concentrations. The venom caused detachment, clumping and lysis of cells, as well as a drop in vitality, in a dose-dependent manner. Morphological changes in the cells were evident within 1 h after venom addition. The damage to gill cells was quantified by measuring the metabolic activity of the cells by means of the fluorescence of resorufin derived from the nonfluorescent substrate, resazurin. In general, a decrease in the metabolic activity of the cells was detected at a venom (protein) concentration above 2.0 μg ml−1 (corresponding to 0.2 μg 104 cells−1), and a total loss of activity was observed above 40.0 μg ml−1 (corresponding to 4.0 μg 104 cells−1). C. capillata venoms had increased cytotoxic activity as compared to A. aurita venoms at the same concentration. Cnidocyst extracts from oral arms of A. aurita induced an 85% loss of gill cell viability at concentrations of 0.2 μg 104 cells−1, whereas crude venoms from fishing tentacles reduced cell viability by 18% at the same concentration. Gel electrophoresis of the venoms indicated that these consist of a large number of proteins in a fairly wide size range, from 6 to 200 kDa, including some that are the same size as those found in cubomedusae. It also appears that larger (i.e., older) medusae have more complex venoms and, in some cases, more potent venoms than smaller animals.
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Allavena, A., G. L. Mariottini, A. M. Carli, S. Contini & A. Martelli, 1998. In vitro evaluation of the cytotoxic, hemolytic and clastogenic activities of Rhizostoma pulmo toxin(s). Toxicon 36: 933–936.
Avian, M., E. Spanier & B. Galil, 1995. Nematocysts of Rhopilema nomadica (Scyphozoa; Rhiztostomae): an immigrant jellyfish in the eastern Mediterranean. Journal of Morphology 224: 221–231.
Bailey, K. M., 1984. Comparison of laboratory rates of predation of five species of marine fish larvae by three planktonic invertebrates: effects of larval size on vulnerability. Marine Biology 79: 303–309.
Bailey, K. M. & R. S. Batty, 1984. Laboratory study of predation by Aurelia aurita on larvae of cod, flounder, plaice and herring: development and vulnerability to capture. Marine Biology 83: 287–291.
Bailey, P. M., A. J. Bakker, J. E. Seymour & J. A. Wilce, 2005. A functional comparison of the venom of three Australian jellyfish-Chironex fleckeri, Chiropsalmus sp., and Carybdea xaymacana – on cytosolic Ca2+, haemolysis and Artemia sp. lethality. Toxicon 45: 233–242.
Båmstedt, U., 1990. Trophodynamics of the scyphomedusae Aurelia aurita – predation rates in relation to abundance, size and type of prey organism. Journal of Plankton Research 12: 215–229.
Båmstedt, U. & M. B. Martinussen, 2000. Estimating digestion rate and the problem of individual variability, exemplified by a scyphozoan jellyfish. Journal of Experimental Marine Biology and Ecology 251: 1–15.
Båmstedt, U., M. B. Martinussen & S. Matsakis, 1994. Trophodynamics of the two scyphozoan jellyfishes, Aurelia aurita and Cyanea capillata, in western Norway. ICES Journal of Marine Science 51: 369–382.
Barz, K. & H.-J. Hirche, 2007. Abundance, distribution and prey composition of scyphomedusae in the southern North Sea. Marine Biology 151: 1021–1033.
Behrends, G. & G. Schneider, 1995. Impact of Aurelia aurita medusae (Cnidaria, Scyphozoa) on the standing stock and community composition of mesozooplankton in the Kiel Bight (western Baltic Sea). Marine Ecology Progress Series 127: 39–45.
Bloom, D. A., J. W. Burnett & P. Alderslade, 1998. Partial purification of box jellyfish (Chironex fleckeri) nematocyst venom isolated at the beachside. Toxicon 36: 1075–1085.
Bloom, D. A., F. F. Y. Radwan & J. W. Burnett, 2001. Toxinological and immunological studies of capillary electrophoresis fractionated Chrysaora quinquecirrha (Desor) fishing tentacle and Chironex fleckeri Southcott nematocyst venoms. Comparative Biochemistry and Physiology Part C: Toxicology & Pharmacology 128: 75–90.
Blum, H., H. Beier & H. J. Gross, 1987. Improved silver staining of plant proteins, RNA and DNA in polyacrylamide gels. Electrophoresis 8: 93–99.
Bols, N., A. Barlian, M. Chirino-Trejo, S. J. Caldwell, P. Geogan & L. E. J. Lee, 1994. Development of a cell line from primary cultures of rainbow trout, Oncorhynchus mykiss (Walbaum), gills. Journal of Fish Diseases 17: 601–611.
Bradford, M., 1976. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry 72: 248–254.
Brewer, R. H., 1989. The annual pattern of feeding, growth, and sexual reproduction in Cyanea (Cnidaria: Scyphozoa) in the Niantic River Estuary, Connecticut. Biological Bulletin 176: 272–281.
Brinkman, D. & J. Burnell, 2007. Identification, cloning and sequencing of two major venom proteins from the box jellyfish, Chironex fleckeri. Toxicon 50: 850–860.
Burnett, J. W. & G. J. Calton, 1987. Venomous pelagic coelenterates: chemistry, toxicology, immunology and treatment of their stings. Toxicon 25: 581–602.
Burnett, J. W., G. Calton & J. B. Larsen, 1988. Significant envenomation by Aurelia aurita, the moon jellyfish. Toxicon 26: 215–217.
Burnett, J. W., K. O. Long & H. M. Rubinstein, 1992. Beachside preparation of jellyfish nematocyst tentacles. Toxicon 30: 794–796.
Dawson, M. N., 2003. Macro-morphological variation among cryptic species of the moon jellyfish, Aurelia (Cnidaria: Scyphozoa). Marine Biology 143: 369–379.
Dawson, M. N. & L. E. Martin, 2001. Geographic variation and ecological adaptation in Aurelia (Scyphozoa, Semaeostomeae): some implications from molecular phylogenetics. Hydrobiologia 451: 259–273.
Dayeh, V. R., K. Schirmer & N. C. Bols, 2002. Applying whole-water samples directly to fish cell cultures in order to evaluate the toxicity of industrial effluent. Water Research 36: 3727–3738.
Dayeh, V. R., D. H. Lynn & N. C. Bols, 2005. Cytotoxicity of metals common in mining effluent to rainbow trout cell lines and to the ciliated protozoan, Tetrahymena thermophila. Toxicology in vitro 19: 399–410.
Doyle, T. K., H. De Haas, D. Cotton, B. Dorschel, V. Cummins, J. D. R. Houghton, J. Davenport & G. C. Hays, 2008. Widespread occurrence of the jellyfish Pelagia noctiluca in Irish coastal and shelf waters. Journal of Plankton Research 30: 963–968.
Endean, R., 1987. Separation of two myotoxins from the nematocysts of the box jellyfish (Chironex fleckeri). Toxicon 25: 483–492.
Fancett, M. S. & G. P. Jenkins, 1988. Predatory impact of scyphomedusae on ichthyoplankton and other zooplankton in Port Phillip Bay. Journal of Experimental Marine Biology and Ecology 116: 63–77.
Fenner, P. & P. Fitzpatrick, 1986. Experiments with the nematocysts of Cyanea capillata. The Medical Journal of Australia 145: 174.
Gröndahl, F., 1988. A comparative ecological study on the scyphozoans Aurelia aurita, Cyanea capillata and Cyanea lamarckii in the Gullmar Fjord, Western Sweden, 1982 to 1986. Marine Biology 97: 541–550.
Hansson, L. J., 2006. A method for in situ estimation of prey selectivity and predation rate in large plankton exemplified with the jellyfish Aurelia aurita (L.). Journal of Experimental Marine Biology and Ecology 328: 113–126.
Hay, S., 2006. Marine ecology: gelatinous bells may ring change in marine ecosystems. Current Biology 16: 679–682.
Hay, S., J. Hislop & A. M. Shanks, 1990. North Sea Scyphomedusae; summer distribution, estimated biomass and significance particularly for 0-group gadoid fish. Netherlands Journal of Sea Research 25: 113–130.
Heeger, T., 1998. Quallen – Gefährliche Schönheiten. Wissenschaftliche Verlagsgesellschaft, Stuttgart.
Heeger, T., H. Möller & U. Mrowietz, 1992. Protection of human skin against jellyfish (Cyanea capillata) stings. Marine Biology 113: 669–678.
Helmholz, H., C. Ruhnau, C. Schütt & A. Prange, 2007. Comparative study on the cell toxicity and enzymatic activity of two northern scyphozoan species Cyanea capillata (L.) and Cyanea lamarckii (Peron & Leslueur). Toxicon 50: 53–64.
Hiromi, J., S. Handa & T. Sekine, 1997. Lethal effect of an autolysate of Aurelia aurita on red tide flagellates. Fisheries Sciences 63: 478–479.
Kass-Simon, G. & A. Acappaticci, 2002. The behavioral and developmental physiology of nematocysts. Canadian Journal of Zoology 80: 1772–1794.
Kihara, H., M. Anraku & O. Hirokazu, 1988. Tetrodotoxin-unaffected depolarization of frog muscles induced by the venom of jellyfish (Genus: Aurelia). Japanese Journal of Physiology 38: 839–849.
Kintner, A. H., J. E. Seymour & S. L. Edwards, 2005. Variation in lethality and effects of two Australian chirodropid jellyfish venoms in fish. Toxicon 46: 699–708.
Lassen, S., H. Helmholz, C. Ruhnau & A. Prange, 2010. Characterisation of neurotoxic polypeptides from Cyanea capillata medusae (Scyphozoa). Hydrobiologia. doi: 10.1007/s10750-010-0215-x.
Lee, L. E. J., K. Schirmer & N. C. Bols, 2008. Applications and potential uses of RTgill-W1 – a cell line derived from gills of rainbow trout. In Vitro Cellular & Developmental Biology – Animal 44: 17.
Long, K. O. & J. W. Burnett, 1989. Isolation, characterization, and comparison of hemolytic peptides in nematocyst venoms of two species of jellyfish (Chrysaora quinquecirrha and Cyanea capillata). Comparative Biochemistry and Physiology Part B: Biochemistry and Molecular Biology 94: 641–646.
Lynam, C. P., M. R. Heath, S. J. Hay & A. S. Brierley, 2005. Evidence for impacts by jellyfish on North Sea herring recruitment. Marine Ecology Progress Series 298: 157–167.
Lynam, C. P., M. J. Gibbons, B. E. Axelsen, C. A. J. Sparks, J. Coetzee, B. G. Heywood & A. S. Brierley, 2006. Jellyfish overtake fish in a heavily fished ecosystem. Current Biology 16: 1976.
Malej, A., V. Turk, D. Lučić & A. Benović, 2007. Direct and indirect trophic interactions of Aurelia sp. (Scyphozoa) in a stratified marine environment (Mljet Lakes, Adriatic Sea). Marine Biology 151: 827–841.
Martinussen, M. B. & U. Båmstedt, 2001. Digestion rate in relation to temperature of two gelatinous planktonic predators. Sarsia 86: 21–35.
Möller, H., 1980. Scyphomedusae as predators and food competitors of larval fish. Meeresforschung 28: 90–100.
Møller, L. F. & H. U. Riisgård, 2007. Population dynamics, growth and predation impact of the common jellyfish Aurelia aurita and two hydromedusae, Sarsia tubulosa and Aequorea vitrina, in Limfjorden (Denmark). Marine Ecology Progress Series 346: 153–165.
Nagai, H., 2003. Recent progress in jellyfish toxin study. Journal of Health Science 49: 337–340.
Omori, M., H. Ishii & A. I. Fujinaga, 1995. Life history strategy of Aurelia aurita (Cnidaria, Scyphomedusae) and its impact on the zooplankton community of Tokyo Bay. ICES Journal of Marine Sciences 52: 597–603.
Purcell, J. E., 1997. Pelagic cnidarians and ctenophores as predators: selective predation, feeding rates, and effects on prey populations. Annales de l’Institut Oceanographique 73: 125–137.
Purcell, J. E., 2003. Predation on zooplankton by large jellyfish, Aurelia labiata, Cyanea capillata and Aequorea aequorea, in Prince William Sound, Alaska. Marine Ecology Progress Series 246: 137–152.
Purcell, J. E., S. Uye & W.-T. Lo, 2007. Anthropogenic causes of jellyfish blooms and their direct consequences for humans: a review. Marine Ecology Progress Series 350: 153–174.
Radwan, F. F. Y., L. A. Gershwin & J. W. Burnett, 2000. Toxinological studies on the nematocyst venom of Chrysaora achlyos. Toxicon 38: 1581–1591.
Radwan, F. F. Y., J. W. Burnett, D. A. Bloom, T. Coliano, M. E. Eldefrawi, H. Erderly, L. Aurelian, M. Torres & E. P. Heimer-de la Cotera, 2001. A comparison of the toxinological characteristics of two Cassiopea and Aurelia species. Toxicon 39: 245–257.
Regula, C., S. P. Colin, J. H. Costello & H. Kordula, 2009. Prey selection mechanism of ambush-foraging hydromedusae. Marine Ecology Progress Series 374: 135–144.
Rice, N. & W. Powell, 1972. Observations on three species of jellyfish from Chesapeake Bay with special reference to their toxins. II Cyanea capillata. Biological Bulletin 143: 617–622.
Schaegger, H. & G. von Jagow, 1987. Tricine-sodium dodecyl sulfate-polyacrylamide gel electrophoresis for the separation of proteins in the range from 1 to 100 kDa. Analytical Biochemistry 166: 368–379.
Schirmer, K., D. G. Dixon, B. M. Greenberg, D. G. Dixon & N. C. Bols, 1998. Ability of 16 priority PAHs to be directly cytotoxic to a cell line from the rainbow trout gill. Toxicology 127: 129–141.
Segura-Puertas, L., G. Avila-Soria, J. Sanchez-Rodgriguez, M. E. Ramos-Aguilar & J. W. Burnett, 2002. Some toxinological aspects of Aurelia aurita (Linne) from the Mexican Caribbean. Journal of Venomous Animals and Toxins 8: 113–128.
Suchman, C. L. & B. K. Sullivan, 2000. Effect of prey size on vulnerability of copepods to predation by the scyphomedusae Aurelia aurita and Cyanea sp. Journal of Plankton Research 22: 2289–2306.
Sullivan, B. K., C. L. Suchman & J. H. Costello, 1997. Mechanics of prey selection by ephyrae of the scyphomedusa Aurelia aurita. Marine Biology 130: 213–222.
Sun, L.-K., Y. Yoshii, A. Hyodo, H. Tsurushima, A. Saito, T. Harakuni, Y.-P. Li, M. Nozaki & N. Morine, 2002. Apoptosis induced by box jellyfish (Chiropsalmus quadrigatus) toxin in glioma and vascular endothelial cell lines. Toxicon 40: 441–446.
Titelman, J., L. Gandon, A. Goarant & T. Nilsen, 2007. Intraguild predatory interactions between the jellyfish Cyanea capillata and Aurelia aurita. Marine Biology 152: 745–756.
Walker, M. J. A., 1977a. The cardiac actions of a toxin-containing material from the jellyfish, Cyanea capillata. Toxicon 15: 15–27.
Walker, M. J. A., 1977b. Pharmacological and biochemical properties of a toxin containing material from the jellyfish, Cyanea capillata. Toxicon 15: 3–14.
Walker, M. J. A., T. T. Martinez & D. V. Godin, 1977. Investigations into the cardiotoxicity of a toxin from the nematocysts of the jellyfish, Cyanea capillata. Toxicon 15: 339–346.
Wiersbitzky, S., G. Hegewald & B. Gibb, 1973. Glomerulo-tubular nephrosis in rabbits and injection of aqueous extracts from jellyfish (Aurelia aurita). Experimental Pathology 8: 232–235.
Acknowledgements
The authors thank Dr. Christian Schuett and colleagues from the Alfred-Wegener-Institute Station Helgoland and the crew of the RV Heincke for their substantial help and support, and Dr. Juergen Gandrass (Institute for Coastal Research, Department for Marine Bioanalytical Chemistry) for critical reading of this manuscript.
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Guest editors: J. E. Purcell & Dror Angel / Jellyfish Blooms: New Problems and Solutions
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Helmholz, H., Johnston, B.D., Ruhnau, C. et al. Gill cell toxicity of northern boreal scyphomedusae Cyanea capillata and Aurelia aurita measured by an in vitro cell assay. Hydrobiologia 645, 223–234 (2010). https://doi.org/10.1007/s10750-010-0216-9
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DOI: https://doi.org/10.1007/s10750-010-0216-9