Eur. J. Entomol. 109 (1): 71-76, 2012 | DOI: 10.14411/eje.2012.009

Survival of ground beetles (Coleoptera: Carabidae) submerged during floods: Field and laboratory studies

Felix N. KOLESNIKOV1, Arevik N. KARAMYAN2, W. Wyatt HOBACK3
1 Bryansk State Agricultural Academy, Kokino, Vigonichy district, Bryansk region, 243365, Russian Federation; e-mail: f.kolesnikov@mail.ru
2 Yerevan State University, Alex Manoogian Street 1, Yerevan 375049, Republic of Armenia
3 University of Nebraska at Kearney, 905 West 25 th Street, Kearney, Nebraska, 68849, USA

Field and laboratory experiments were conducted to assess the time ground beetles (Coleoptera: Carabidae) survive during actual and simulated flood conditions. The effects of three variants of potential flood conditions were tested: (1) beetles trapped on the surface of flood water; (2) beetles trapped in air pockets; (3) submersion of beetles in flood water without access to air. Ground beetles trapped on the surface of water survived more than two weeks (Carabus granulatus - up to 16 days; Oxypselaphus obscurus - up to 22 days). Carabus granulatus in simulated hibernation chambers that had air-pockets also survived for 15 days. The time for which ground beetles submerged without access to air survived differed significantly among species and was affected by season. They survived longest in mid-spring and late-autumn when water temperature is low. In mid-spring, survival times for C. granulatus and Platynus assimilis were 12 days and 9 days, respectively. During late summer and early autumn all species survived for a shorter period of time. In August, at least half of the individuals tested were dead after three days of immersion (water temperature 16-18°C). Removal of both of the elytra of adult of C. granulatus resulted in them surviving immersion for a shorter period, which indicates that air stored in the sub-elytral cavity is used to prolong the period they can survive immersion. The results of these experiments broaden the knowledge of how adult beetles survive seasonal flooding and are able to persist in floodplain habitats.

Keywords: Carabidae, survival time, submergence, flooding, hypoxic conditions

Received: May 19, 2011; Revised: September 23, 2011; Accepted: September 23, 2011; Published: January 3, 2012  Show citation

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KOLESNIKOV, F.N., KARAMYAN, A.N., & HOBACK, W.W. (2012). Survival of ground beetles (Coleoptera: Carabidae) submerged during floods: Field and laboratory studies. EJE109(1), 71-76. doi: 10.14411/eje.2012.009
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    References

    1. ADIS J. 1982: Eco-entomological observations from the Amazon: II. Carabids are adapted to inundation-forests! Coleopt. Bull. 36: 439-440
    2. ADIS J. 1986: An "aquatic" millipede from a Central Amazonian inundation forest. Oecologia (Berlin) 68: 347-349 Go to original source...
    3. AMORIM M.A., ADIS J. & PAARMAN W. 1997: Ecology and adaptations of the tiger beetle Pentacomia egregia (Chaudoir) (Cicindelinae: Carabidae) to Central Amazonian floodplains. Ecotropica 3: 71-82
    4. ANDERSEN J.M. 1968: The effect of inundation and choice of hibernation sites of Coleoptera living on river banks. Norsk Entomol. Tidsskr. 15: 115-133
    5. ANDERSEN J.M. 2005: Riparian beetles, a unique, but vulnerable element in the fauna of Fennoscandia. Biodiv. Conserv. 14: 3497-3524 Go to original source...
    6. BAUMGARTL H., KRITZLER K., ZIMELKA W. & ZINKLER D. 1994: Local PO2 measurements in the environment of submerged soil microarthropods. Acta Oecol. 15: 781-789
    7. BRUST M.L. & HOBACK W.W. 2009: Hypoxia tolerance in adult and larval Cicindela tiger beetles varies by life history but not habitat association. Ann. Entomol. Soc. Am. 102: 462-466 Go to original source...
    8. BRUST M.L., HOBACK W.W., SKINNER K.F. & KNISLEY C.B. 2005: Differential immersion survival by populations of Cicindela hirticollis (Coleoptera: Cicindelidae). Ann. Entomol. Soc. Am. 98: 973-979 Go to original source...
    9. BRUST M.L., HOBACK W.W., SKINNER K.F. & KNISLEY C.B. 2006: Movement of Cicindela hirticollis Say larvae in response to moisture and flooding. J. Insect Behav. 19: 251-263 Go to original source...
    10. DECLEER K. 2003: Population dynamics of marshland spiders and carabid beetles due to flooding: about drowning, air bubbling, floating, climbing and re-colonization. In: Proc. Int. Conference "Towards Natural Flood Reduction Strategies", Warsaw, 3-13 September, 2003. pp. 1-6
    11. FORSCHLER B. & HENDERSON G. 1995: Subterranean termite behavioral reaction to water and survival of inundation: implications for field populations. Environ. Entomol. 24: 1592-1597 Go to original source...
    12. FOSTER W.A. & TREHERNE J.E. 1976: The effects of tidal submergence on an intertidal aphid, Pemphigus trehernei Foster. J. Anim. Ecol. 45: 291-301 Go to original source...
    13. GILBERT M. 1986: The respiratory system and respiratory technique of Hydroporus palustris (L.) (Coleoptera. Dytiscidae). Entomol. Basil. 11: 43-65
    14. HOBACK W.W. & STANLEY D.W. 2001: Insects in hypoxia. J. Insect Physiol. 47: 533-542 Go to original source...
    15. HOBACK W.W., STANLEY D.W., HIGLEY L.G. & BARNHART M.C. 1998: Survival of immersion and anoxia by larval tiger beetles, Cicindela togata. Am. Midl. Nat. 140: 27-33 Go to original source...
    16. HOBACK W.W., PODRABSKY J.E., HIGLEY L.G., STANLEY D.W. & HAND S.C. 2000: Anoxia tolerance of con-familiar tiger beetle larvae is associated with differences in energy flow and anaerobiosis. J. Comp. Physiol. 170: 307-314 Go to original source...
    17. HOBACK W.W., CLARK T.L, MEINKE L.J., HIGLEY L.G. & SCALZITTI J.M. 2002: Immersion survival differs among three Diabrotica species. Entomol. Exp. Appl. 105: 29-34 Go to original source...
    18. HOCHACHKA P.W., NENER J.C., HOAR J., SAURES R.K. & HAND S.C. 1993: Disconnecting metabolism from adenylate control during extreme oxygen limitation. Can. J. Zool. 71: 1267-1270 Go to original source...
    19. IRMLER U. 1979: Abundance fluctuations and habitat changes of soil beetles in Central Amazonian inundation forests (Coleoptera: Carabidae, Staphylinidae). Stud. Neotrop. Fauna Environ. 14: 1-16 Go to original source...
    20. JENKINS M.F. 1960: On the method by which Stenus and Dianous (Coleoptera, Staphylinidae) return to the banks of a pool. Trans. R. Entomol. Soc. Lond. 112: 1-14 Go to original source...
    21. KEHL S. & DETTNER K. 2009: Surviving submerged-setal tracheal gills for gas exchange in adult rheophilic diving beetles. J. Morphol. 270: 1348-1355 Go to original source...
    22. KONVICKA M., NEDVED O. & FRIC Z. 2002: Early-spring floods decrease the survival of hibernating larvae of a wetlandinhabiting population of Neptis kivularis (Lepidoptera: Nymphalidae). Acta Zool. Acad. Sci. Hungar. 48: 79-88
    23. LEHMANN H. 1965: Okologische Untersuchungen ueber die Carabidenfauna des Rheinufers in der Umgebung von KGln. Z. Morph. Okol. Tiere 55: 597-630 Go to original source...
    24. NIELSEN M.G. & CHRISTIAN K.A. 2007: The mangrove ant, Camponotus andersoni, switches to anaerobic respiration in response to elevated CO2 levels. J. Insect Physiol. 53: 505-508 Go to original source...
    25. TAMM J.C. 1984: Surviving long submergence in the egg stage - a successful strategy of terrestrial arthropods living on flood plains (Collembola, Acari, Diptera). Oecologia (Berlin) 61: 417-419 Go to original source...
    26. TAMM J.C. 1986: Temperature-controlled under-water dormancy and postflood hatching in Isotoma viridis (Collembola) as forms of adaptation to annual long-term flooding. Oecologia (Berlin) 68: 241-245 Go to original source...
    27. VLASBLOM A.G. 1970: The respiratory significance of the physical gill in some adults insects. Comp. Biochem. Physiol. 36: 377-385 Go to original source...
    28. WEGENER G. 1993: Hypoxia and post hyoxic recovery in insects: physiological and metabolic aspects. In Hochachka P.W., Lutz P.L., Rosental M., Sick T. & van den Thillart G. (eds): Surviving Hypoxia - Mechanisms of Control and Adaptation. CRC Press, Boca Raton, FL, pp. 417-432 Go to original source...
    29. WYATT T.D. 1986: How a subsocial intertidal beetle, Bledius spectabilis, prevents flooding and anoxia in its burrow. Behav. Ecol. Sociobiol. 19: 323-331 Go to original source...
    30. ZERM M. & ADIS J. 2001: Further observations on the natural history and survavival strategies of riverine tiger beetles (Coleoptera: Cicindelidae) from open habitats in central Amazonian floodplains (Brazil). Ecotropica 7: 115-137
    31. ZERM M., WALENCIAK O., VAL A.L. & ADIS J. 2004: Evidence for anaerobic metabolism in the larval tiger beetle, Phaeoxantha klugii (Col. Cicindelidae) from a Central Amazonian floodplain (Brazil). Physiol. Entomol. 29: 483-488 Go to original source...

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