Hostname: page-component-78c5997874-ndw9j Total loading time: 0 Render date: 2024-11-19T17:24:49.372Z Has data issue: false hasContentIssue false

Diversity patterns of fauna in dripping water of caves from Transylvania

Published online by Cambridge University Press:  22 June 2011

Ioana N. Meleg*
Affiliation:
“Emil Racoviţă” Institute of Speleology, Department of Cluj, Romanian Academy, Clinicilor 5, PO Box 58, 400006 Cluj-Napoca, Romania
Oana T. Moldovan*
Affiliation:
“Emil Racoviţă” Institute of Speleology, Department of Cluj, Romanian Academy, Clinicilor 5, PO Box 58, 400006 Cluj-Napoca, Romania
Sanda Iepure
Affiliation:
“Emil Racoviţă” Institute of Speleology, Department of Cluj, Romanian Academy, Clinicilor 5, PO Box 58, 400006 Cluj-Napoca, Romania
Frank Fiers
Affiliation:
Royal Belgian Institute of Natural Sciences, Vautierstraat 29, B-1000 Brussels, Belgium
Traian Brad
Affiliation:
“Emil Racoviţă” Institute of Speleology, Department of Cluj, Romanian Academy, Clinicilor 5, PO Box 58, 400006 Cluj-Napoca, Romania
*
*Corresponding author: [email protected]
Get access

Abstract

Recent studies substantiate the importance of the unsaturated zone in ground-water biodiversity of karst areas. Few investigations, however, have addressed the temporal changes in community composition in relation to water physico-chemical features. We provide information on the distribution pattern of the fauna in dripping water at spatial and temporal scales. This is related to variation in water chemistry and other environmental features in five caves within two hydrographic basins of the Pădurea Craiului Mountains (northwestern Romania). The analysis revealed no major pollution in the dripping water. The physico-chemical parameters varied within and between caves over one year. The dripping water fauna is heterogeneously distributed within and between the caves, containing a mixture of epigean and hypogean species. This emphasizes high microhabitat partition and also underlines the influence of physico-chemical parameters. The species composition among the two hydrographic basins was different. Crustaceans are the best represented in terms of both abundance and species richness. Six out of 15 crustacean species are endemic to the Pădurea Craiului Mountains and four are new to science. All these point to the importance of unsaturated karstic habitats as biodiversity hot spots in ground-water ecosystems.

Type
Research Article
Copyright
© EDP Sciences, 2011

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Bobić, M., 2003. Microfauna of percolating waters in Lazareva Cave (East Serbia, YU). In: Proceeding of 4th Symposium on Karst Protection, Beograd, 101104.Google Scholar
Botoşăneanu, L. (ed.), 1986. Stygofauna Mundi, E.J. Brill and Dr W. Backhuys, Leiden, The Netherlands, 740 p.Google Scholar
Bou, C., 1979. La grotte Trois-Cloches et son intérêt scientifique. Bull. Féd. tarnaise Spéléo-Archéol., 16, 310.Google Scholar
Boxshall, G. and Defaye, D., 2008. Global diversity of copepods (Crustacea: Copepoda) in freshwater. Hydrobiologia, 595, 195207.CrossRefGoogle Scholar
Brancelj, A., 2002. Microdistribution and high diversity of Copepoda (Crustacea) in a small cave in central Slovenia. Hydrobiologia, 477, 5972.CrossRefGoogle Scholar
Camacho, A.I., Valdecasas, A.G., Rodriguez, J., Cuezva, S., Lario, J. and Sanchez-Moral, S., 2006. Habitat constraints in epikarstic water of an Iberian Peninsula cave system. Ann. Limnol. - Int. J. Lim., 42, 127140.CrossRefGoogle Scholar
Clarke, K.R. and Warwick, R.M., 2001. Change in marine communities: an approach to statistical analysis and interpretation, Plymouth Marine Laboratory, Plymouth.Google Scholar
Colwell, R.K., 2005. EstimateS: statistical estimation of species richness and shared species from samples Version 7.5. User's Guide and application published at http://purl.oclc.org/estimates.
Colwell, R.K., Mao, C.X. and Chang, J., 2004. Interpolating, extrapolating and comparing incidence-based species accumulation curves. Ecology, 85, 27172727.CrossRefGoogle Scholar
Culver, D.C. and Pipan, T., 2007. Subterranean ecosystems. In: Levin, S.A. (ed.), Encyclopedia of biodiversity, Elsevier Academic Press, Amsterdam, 119.Google Scholar
Damian-Georgescu, A., 1963. Copepoda. Fam. Cyclopidae (forme de apă dulce). Fauna Republicii Populare Romîne, Academia Republicii Socialiste Romînia, Crustacea, 4, 205 p. [In Romanian. Illustrated keys to families, genera, and species.]
Delay, B., 1968. Données sur le peuplement de la zone de percolation temporaire. Ann. Spéléolog., 20, 705716.Google Scholar
Dole-Olivier, M.J., Malard, F., Martin, D., Bure, T.L. and Gibert, J., 2009. Relationships between environmental variables and groundwater biodiversity at the regional scale. Freshwater Biol., 54, 797813.CrossRefGoogle Scholar
Ferreira, D., Malard, F., Dole-Olivier, M.J. and Gibert, J., 2007. Obligate groundwater fauna of France: diversity patterns and conservation implications. Biodiv. Conserv., 16, 567596.CrossRefGoogle Scholar
Fiers, F. and Moldovan, O.T., 2008. Redescription of Spelaeocamptus spelaeus (Chappuis 1925), a subterranean copepod endemic to the Apuseni Mountains in Romania (Copepoda Harpacticoida). Subt. Biol., 6, 5164.Google Scholar
Galassi, D.M.P., 2001. Groundwater copepods: diversity patterns over ecological and evolutionary scales. Hydrobiologia, 453, 227253.CrossRefGoogle Scholar
Galassi, D.M.P., Huys, R. and Reid, J., 2009. Diversity, ecology and evolution of groundwater copepods. Freshwater Biol., 54, 691708.CrossRefGoogle Scholar
Gibert, J. and Deharveng, L., 2002. Subterranean ecosystems: a truncated functional biodiversity. BioScience, 52, 473481.CrossRefGoogle Scholar
Gibert, J., Stanford, J., Dole-Olivier, M.J. and Ward, J.V., 1994. Basic attributes of ground water ecosystems and prospects for research. In: Gibert, J., Danielopol, D.L. and Stanford, J. (eds.), Groundwater ecology, Academic Press, San Diego, CA, 740.CrossRefGoogle Scholar
Gibert, J., Culver, D.C., Dole-Olivier, M.J., Malard, F., Christman, M.C. and Deharveng, L., 2009. Assessing and conserving groundwater biodiversity: synthesis and perspectives. Freshwater Biol., 54, 930941.CrossRefGoogle Scholar
Gray, J.S., 2000. The measurement of marine species diversity, with an application to the benthic fauna of the Norwegian continental shelf. J. Exp. Mar. Biol. Ecol., 250, 2349.CrossRefGoogle ScholarPubMed
Hammer, Ǿ., Harper, D.A.T. and Ryan, P.D., 2002. PAST – PAlaeontological STatistics, ver. 0.93.
Iepure, S., 2007. Cyclopoida Copepoda. In: Moldovan, O.T. (ed.), Lista faunistică a României. Specii terestre şi de apa dulce (Checklist of Romania fauna. Terrestrial and freshwater), CristalPrint, Cluj–Napoca, 8990.
Jones, W.K., Culver, D.C. and Herman, J.S. (eds.), 2004. Proceedings of the Symposium on Epikarst, Shepherdstown, West Virginia, 1–4 October 2003, Karst Waters Institute Special Publication 9, Charles Town, WV, 160 p.Google Scholar
Juberthie, C., 2000. The diversity of the karstic and pseudokarstic hypogean habitats in the world. In: Wilkens, H., Culver, D.C. and Humphreys, W.F. (eds.), Ecosystems of the world, 30, Subterranean ecosystems, Elsevier Academic Press, Amsterdam, 1739.Google Scholar
Juberthie, C. and Decu, V. (eds.), 1994. Encyclopaedia Biospeleogica I, Société de Biospéléologie, Moulis–Bucarest, 834 p.Google Scholar
Juberthie, C. and Decu, V. (eds.), 1998. Encyclopaedia Biospeleogica II, Société de Biospéléologie, Moulis–Bucarest, 8351373.Google Scholar
Juberthie, C. and Decu, V. (eds.), 2001. Encyclopaedia Biospeleogica III, Société de Biospéléologie, Moulis–Bucarest, 13742294.Google Scholar
Malard, F., Boutin, C., Camacho, A.I., Ferreira, D., Michel, G., Sket, B. and Stoch, F., 2009. Diversity patterns of stygobiotic crustaceans across multiple spatial scales in Europe. Freshwater Biol., 54, 756776.CrossRefGoogle Scholar
Mangin, A., 1994. Karst hydrogeology. In: Gibert, J., Danielopol, D.L. and Stanford, J. (eds.), Groundwater ecology, Academic Press, San Diego, CA, 4364.CrossRefGoogle Scholar
Moldovan, O., Iepure, S. and Perşoiu, A., 2005. Biodiversity and protection of Romanian karst areas: the example of interstitial fauna. In: Stevanović, Z. and Milanović, P. (eds.), Water resources & environmental problems in karst, National Committee of the International Association of Hydrogeologists (IAH) of Serbia and Montenegro, Belgrade, 831837.Google Scholar
Moldovan, O.T., Pipan, T., Iepure, S., Mihevc, A. and Mulec, J., 2007. Biodiversity and ecology of fauna in percolating water in selected Slovenian and Romanian caves. Acta Carsol., 36, 493501.CrossRefGoogle Scholar
Musgrove, M. and Banner, J.L., 2004. Controls on the spatial and temporal variability of vadose dripwater chemistry: Edwards Aquifer, central Texas. Geochim. Cosmochim. Acta, 68, 10071020.CrossRefGoogle Scholar
Onac, B., 2002. Endokarst – Cave deposits. In: Racoviţă, G., Moldovan, O. and Onac, B. (eds.), The karst of Pădurea Craiului Mountains, Monographic study, Presa Universitară, Cluj–Napoca, 6777.Google Scholar
Orăşeanu, I., 1991. Hydrogeological map of the Pădurea Craiului Mountains (Romania). Theor. Appl. Karstol., 4, 97127.Google Scholar
Paran, F., Malard, F., Mathieu, J., Lafont, M., Galassi, D.M.P. and Marmonier, P., 2005. Distribution of groundwater invertebrates along an environmental gradient in a shallow water-table aquifer. In: Gibert, J. (ed.), Proceedings of an International Symposium on World Subterranean Biodiversity, Villeurbanne, France, 8–10 December 2004, University of Lyon, France, 99105.Google Scholar
Pipan, T., 2005. Epikarst – A promising habitat, ZRC Publishing, Karst Research Institute at ZRC SAZU, Postojna, Ljubljana, 101 p.Google Scholar
Pipan, T. and Brancelj, A., 2001. Ratio of copepods (Crustacea: Copepoda) in fauna of percolation water in six karst caves in Slovenia. Acta Carsol., 30, 257265.Google Scholar
Pipan, T. and Brancelj, A., 2003. Fauna of epikarst – Copepoda (Crustacea) in percolation water of karst caves in Slovenia. Ann., Ser. Hist. Nat., 13, 223228.Google Scholar
Pipan, T. and Brancelj, A., 2004a. Diversity and peculiarity of epikarst fauna: Case study from six caves in Slovenia (Europe). In: Jones, W.K., Culver, D.C. and Herman, J.S. (eds.), Proceedings of the Symposium on Epikarst, Shepherdstown, West Virginia, 1–4 October 2003, Karst Waters Institute Special Publication 9, Charles Town, WV, 119126.Google Scholar
Pipan, T. and Brancelj, A., 2004b. Distribution patterns of copepods (Crustacea: Copepoda) in percolation waters of the Postojnska Jama Cave System (Slovenia). Zool. Stud., 43, 206210.Google Scholar
Pipan, T. and Culver, D.C., 2005. Estimating biodiversity in the epikarstic zone of a West Virginia cave. J. Cave Karst Stud., 67, 103109.Google Scholar
Pipan, T. and Culver, D.C., 2007a. Epikarst communities: biodiversity hotspots and potential water tracers. Environ. Geol., 53, 265269.CrossRefGoogle Scholar
Pipan, T. and Culver, D.C., 2007b. Copepod distribution as an indicator of epikarst system connectivity. Hydrogeol. J., 15, 817822.CrossRefGoogle Scholar
Pipan, T. and Culver, D.C., 2007c. Regional species richness in an obligate subterranean dwelling fauna – epikarst copepods. J. Biogeogr., 34, 854861.CrossRefGoogle Scholar
Pipan, T., Blejec, A. and Brancelj, A., 2006. Multivariate analysis of copepod assemblages in epikarstic waters of some Slovenian caves. Hydrobiologia, 559, 213223.CrossRefGoogle Scholar
Pipan, T., Navodnik, V., Janžekovič, F. and Novak, T., 2008. Studies of the fauna of percolation water of Huda Luknja, a cave in isolated karst in northeast Slovenia. Acta Carsol., 37, 141151.CrossRefGoogle Scholar
Pleşa, C., 1969. Cercetări asupra periodicităţii reproductive la unele crustacee cavernicole troglobionte, Ph.D. Thesis, Inst. Biologie “Tr. Săvulescu”, Bucarest.
Pleşa, C., 1985. Conspectul sistematic al Cyclopidelor (crustacee, copepode) cunoscute până în prezent din R.P.R. Studia Univ. Victor Babeş – Bolyai, II, 137150.Google Scholar
Rouch, R., 1968. Contribution à la connaissance des Harpacticides hypogés. Ann. Spéléol., 23, 1167.Google Scholar
Rusu, T., 1988. Pe urmele apelor subterane. Carstul din Munţii Pădurea Craiului, Ed. Dacia, Cluj–Napoca, 253 p.
Sket, B., Trontelj, P. and Žagar, C., 2004. Speleobiological characterization of the epikarst and its hydrological neighborhood: its role in dispersion of biota, its ecology and vulnerability. In: Jones, W.K., Culver, D.C. and Herman, J.S. (eds.), Proceedings of the Symposium on Epikarst, Shepherdstown, West Virginia, 1–4 October 2003, Karst Waters Institute Special Publication, 9, Charles Town, WV, 104113.Google Scholar
Stoch, F., 1995. The ecological and historical determinants of Crustacean diversity in groundwaters, or: why are there so many species? Mém. Biospéol., 22, 139160.Google Scholar
Vălenaş, L. and Iurkiewicz, A., 1981. Studiu complex al carstului din zona Şuncuiuş–Mişid (Munţii Pădurea Craiului), Muzeul Ţării Crişurilor Oradea, Biblioteca Nymphaea, 378 p.Google Scholar
Whittaker, R.H., 1972. Evolution and measurement of species diversity. Taxon, 21, 213251.CrossRefGoogle Scholar