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Water cisterns as death traps for amphibians and reptiles in arid environments

Published online by Cambridge University Press:  24 March 2014

LUÍS GARCÍA-CARDENETE
Affiliation:
Departamento de Zoología, Facultad de Ciencias, Universidad de Granada, E-18071 Granada, Spain
JUAN M. PLEGUEZUELOS
Affiliation:
Departamento de Zoología, Facultad de Ciencias, Universidad de Granada, E-18071 Granada, Spain
JOSÉ C. BRITO
Affiliation:
CIBIO/InBIO, Centro de Investigação em Biodiversidade e Recursos Genéticos da Universidade do Porto, Rua Padre Armando Quintas, 4485-661 Vairão, Portugal
FRANCISCO JIMÉNEZ-CAZALLA
Affiliation:
Avenida de Italia 5, Algeciras E-11205, Cádiz, Spain
MARÍA T. PÉREZ-GARCÍA
Affiliation:
Avenida de España 4, Loja E-18300, Granada, Spain
XAVIER SANTOS*
Affiliation:
CIBIO/InBIO, Centro de Investigação em Biodiversidade e Recursos Genéticos da Universidade do Porto, Rua Padre Armando Quintas, 4485-661 Vairão, Portugal
*
*Correspondence: Xavier Santos e-mail: [email protected]

Summary

Arid regions are increasingly being anthropogenically altered. In the north-western Sahara, a growing road network facilitates the use of habitats adjacent to roads. In regions where livestock is the traditional and main economic resource, local people are currently building numerous water cisterns for watering livestock, leading to an increase in the extent of pasturing of domestic livestock. Cisterns may attract desert vertebrates and act as death traps for species with already sparse populations in these arid areas. This paper is the first to examine the impact of cisterns as lethal traps for amphibians and reptiles in the Sahara, using a survey of 823 cisterns in south-western Morocco to identify and quantify species affected. Four amphibians and 35 reptiles were trapped in cisterns, some of which were listed as threatened. At least 459 017 individual amphibians and reptiles were trapped annually within the study area. The low productivity and low population densities of terrestrial vertebrates in this arid region suggest cisterns have a substantial impact upon amphibian and reptile species. As cistern construction is increasing, management actions are required to mitigate this impact on the herpetological community.

Type
Papers
Copyright
Copyright © Foundation for Environmental Conservation 2014 

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References

Barth, E.K. (1977) Stored oil booms can be a trap for gulls. Fauna Oslo 30: 177180.Google Scholar
Böhm, M., and more than 100 other authors (2013) The conservation status of the world's reptiles. Biological Conservation 157: 372385.CrossRefGoogle Scholar
Bons, J. & Geniez, P. (1996) Amphibiens et reptiles du Maroc (Sahara occidental compris). Atlas biogéographique. Barcelona, Spain: Asociación Herpetológica Española.Google Scholar
Brito, J.C., Fahd, S., Geniez, P., Martínez-Freiría, F., Pleguezuelos, J.M. & Trape, J.F. (2011 b) Biogeography and conservation of viperids from North-West Africa: an application of ecological niche-based models and GIS. Journal of Arid Environments 75: 10291037.CrossRefGoogle Scholar
Brito, J.C., Martínez-Freiría, F., Sierra, P., Sillero, N. & Tarroso, P. (2011 a) Crocodiles in the Sahara Desert: an update of distribution, habitats and population status for conservation planning in Mauritania. PLoS ONE 6: e14734 [www document]. URL http://www.plosone.org/article/info:doi/10.1371/journal.pone.0014734 Google Scholar
Brito, J.C., Godinho, R., Martinez-Freiría, F., Pleguezuelos, J.M., Rebelo, H., Santos, X., Gomes, C., Velo-Antón, G., Boratyński, Z., Carvalho, S.B., Ferreira, S., Gonçalves, D.V., Silva, T.L., Tarroso, P., Campos, J.C., Vasco Leite, J., Nogueira, J., Alvares, F., Sillero, N., Sow, A.S., Fahd, S., Crochet, P.-A. & Carranza, S. (2014) Unravelling biodiversity, evolution and threats to conservation in the Sahara-Sahel. Biological Reviews 89 (1): 215231.Google Scholar
Burkett, D.W. & Thompson, B.C. (1994) Wildlife association with human-altered water sources in semiarid vegetation communities. Conservation Biology 8: 682690.Google Scholar
Butt, N., Beyer, H.L., Bennet, J.R., Biggs, D., Maggini, R., Mills, M., Renwick, A.R., Seabrook, L.M. & Possingham, H.P. (2013) Biodiversity risks from fossil fuel extraction. Science 342: 425426.Google Scholar
Cox, N., Chanson, J. & Stuart, S.N. (2006) The Status and Distribution of Reptiles and Amphibians of the Mediterranean Basin. Gland, Switzerland and Cambridge, UK: IUCN.Google Scholar
Cunningham, R.B., Lindenmayer, D.B., Crane, M., Michael, D. & MacGregor, C. (2007). Reptile and arboreal marsupial response to replanted vegetation in agricultural landscapes. Ecological Applications 17: 609–619.CrossRefGoogle ScholarPubMed
Davies, J., Poulsen, L., Schulte-Herbrüggen, B., Mackinnon, K., Crawhall, N., Henwood, W.D., Dudley, N., Smith, J. & Gudka, M. (2012) Conserving Dryland Biodiversity. Nairobi, Kenya: IUCN.Google Scholar
de Pous, P., Beukema, W., Weterings, M., Dummer, I. & Geniez, P. (2011) Area prioritization and performance evaluation of the conservation area network for the Moroccan herpetofauna: a preliminary assessment. Biodiversity and Conservation 20: 89118.Google Scholar
DiMauro, D. & Hunter, M.L. Jr (2002) Reproduction of amphibians in natural and anthropogenic temporary pools in managed forests. Forest Science 48: 397406.Google Scholar
ECOWAS & SWAC-OCDE (2006) The ecologically vulnerable zone of Sahelian countries. Atlas on Regional Integration in West Africa [www document]. URL http://www.atlas-westafrica.org Google Scholar
El Gharbaoui, A. (1987) La Grande Encyclopédie du Maroc. Géographie Physique et Géologie. Rabat, Morocco: GEM Editions.Google Scholar
Enge, K.M., Cobb, D.T., Sprandel, G.L. & Francis, D.L. (1996) Wildlife captures in a pipeline trench in Gadsden County, Florida. Florida Scientist 59: 111.Google Scholar
Frederick, K.D. (1997) Adapting to climate impacts on the supply and demand for water. Climatic Change 37: 141156.Google Scholar
Gazaryan, S.V. & Bakhtadze, G.B. (2002) A chimney of the boiler-house as a technogenic trap for bats. Plecotus et al 5: 99101.Google Scholar
Harris, H.S. Jr (1985) Asphalt as a snake trap and a unique method of removal. Bulletin of the Maryland Herpetological Society 21: 151152.Google Scholar
Hearty, P.J., Olson, S.L., Kaufman, D.S., Edwards, R.L. & Cheng, H. (2004) Stratigraphy and geochronology of pitfall accumulations in caves and fissures, Bermuda. Quaternary Science Reviews 23: 11511171.Google Scholar
Hirschfield, S.E. (1968) Vertebrate fauna of Nichol's Hammock, a natural trap. Quarterly Journal of the Florida Academy of Science 31: 177189.Google Scholar
Korfel, C.A., Mitsch, W.J., Hetherington, T.E. & Mack, J.J. (2010) Hydrology, physiochemistry, and amphibians in natural and created vernal pool wetlands. Restoration Ecology 18: 843854.CrossRefGoogle Scholar
Kornilev, Y.V., Price, S.J. & Dorcas, M.E. (2006) Between a rock and hard place: responses of Eastern Box Turtles (Terrapene carolina) when trapped between railroad tracks. Herpetological Review 37: 145148.Google Scholar
Louw, G.N. & Seely, M.K. (1982) Ecology of Desert Organisms. Essex, UK: Longman Group Limited.Google Scholar
Manning, G.J. (2007) Uta stansburiana (side-blotched lizard). Mortality. Herpetological Review 38: 465.Google Scholar
Márquez-Ferrando, R., Pleguezuelos, J.M., Santos, X., Ontiveros, D. & Fernández-Cardenete, J.R. (2009) Recovering the reptile community after the mine-tailing accident of Aznalcollar (SW Spain). Restoration Ecology 17: 660667.CrossRefGoogle Scholar
Muller, D.M., Kohlmann, S.G. & Alkon, P.U. (1995) A Nubian ibex nursery: creche or natural trap? Israel Journal of Zoology 41: 163174.Google Scholar
Pautasso, A.A., Raimondi, V.B., Bierig, P.L. & Leiva, L.A. (2010) Mortalidad de venado de las pampas (Ozotoceros bezoarticus) y aguara guazu (Chrysocyon brachyurus) en represas de almacenamiento de agua en los bajos submeridionales de Santa Fe, Argentina. Notulas Faunisticas 52: 16.Google Scholar
Pedler, R.D. (2010) The impacts of abandoned mining shafts: fauna entrapment in opal prospecting shafts at Coober Pedy, South Australia. Ecological Management and Restoration 11: 3642.Google Scholar
Pimm, S.L. (2008) Biodiversity: climate change or habitat loss. Which will kill more species? Current Biology 18: 117119.CrossRefGoogle ScholarPubMed
Pleguezuelos, J.M., Brito, J.C., Fahd, S., Feriche, M., Mateo, J.A., Moreno-Rueda, G., Reques, R. & Santos, X. (2010) Regional red listing of the amphibians and reptiles of Morocco. Its utility for setting conservation priorities. Oryx 44: 501508.Google Scholar
Pokines, J.T., Nowell, A., Bisson, M.S., Cordova, C.E. & Ames, C.J. (2011) The functioning of a natural faunal trap in a semi-arid environment: preliminary investigations of WZM-1, a limestone sinkhole site near Wadi Zarqa Ma’in, Hashemite Kingdom of Jordan. Journal of Taphonomy 9: 89115.Google Scholar
Safriel, U. & Adeel, Z. (2008) Development paths of drylands: thresholds and sustainability. Sustainability Science 3: 117123.Google Scholar
Schlaepfer, M. A, Runge, M. C. & Sherman, P. W.. (2002) Ecological and evolutionary traps. Trends in Ecology and Evolution 17: 474480.CrossRefGoogle Scholar
Schleich, H.H., Kästle, W. & Kabisch, K. (1996) Amphibians and Reptiles of North Africa. Biology, Systematics, Field Guide. Koenigstein, Germany: Koeltz Scientific Books.Google Scholar
Scoccianti, C. (2001) I tombini, i pozzetti stradali, le cisterne e altre infrastrutture come causa di caduta, intrappolamento e morte della’fauna minore nelle campagne e nella periferia delle citta. L'esempio di alcune popolazioni di anfibi in un’area della piana fiorentina: Azioni di salvaguardia e tecniche di prevenzione. Rivista di Idrobiologia 40: 187197.Google Scholar
Stanback, M.T. (1998) Getting stuck: a cost of communal cavity roosting. Wilson Bulletin 110: 421423.Google Scholar
Stevens, C.E., Paszkowski, C.A. & Stringer, D. (2006) Occurrence of the western toad and its use of ‘borrow pits’ in West-Central Africa. Northwestern Naturalist 87: 107117.CrossRefGoogle Scholar
Stuart, S.N., Chanson, J.S., Cox, N.A., Young, B.E., Rodrigues, A.S., Fischman, D.L. & Waller, R.W. (2004) Status and trends of amphibian declines and extinctions worldwide. Science 306: 17831786.Google Scholar
ter Braak, C.J.F. & Smilauer, P. (2002) Canoco for Windows Version 4.5. Ithaca, NY, USA: Biometrics-Plant Research International.Google Scholar
Thorton, P.K., Jones, P.G., Owiyo, T., Kruska, R.L., Herrero, M., Orindi, V., Bhadwal, S., Kristjanson, P., Notenbaert, A., Bekele, N. & Omolo, A. (2008) Climate change and poverty in Africa: Mapping hotspots of vulnerability. African Journal of Agricultural and Resource Economics 2: 2444.Google Scholar
Tryjanowski, P., Sparks, T., Rybacki, M. & Berger, L. (2006) Is body size of the water frog Rana esculenta complex responding to climate change? Naturwissenschaften 93: 110113.Google Scholar
Turner, D.S. (2007) Amphibians and Reptiles of Sonoita Creek State Natural Area, Arizona. Sonoran Herpetologist 20: 3842.Google Scholar
Wang, I.J. (2009) Fine-scale population structure in a desert amphibian: landscape genetics of the black toad (Bufo exsul). Molecular Ecology 18: 38473856.Google Scholar
Ward, D. (2009) The Biology of Deserts. Oxford, UK: Oxford University Press.Google Scholar
Wilson, J.S. & Topham, S. (2009) The negative effects of barrier fencing on the desert tortoise (Gopherus agassizii) and non-target species: is there room for improvement? Contemporary Herpetology 2009 (3): 14.Google Scholar
Woinarski, J.C.Z., Armstrong, M., Brennan, K., Connors, G., Milne, D., McKenzie, G. & Edwards, K. (2000) A different fauna? Captures of vertebrates in a pipeline trench, compared with conventional survey techniques; and a consideration of mortality patterns in a pipeline trench. Australian Zoologist 31: 421431.CrossRefGoogle Scholar
Wolak, M.E., Gilchrist, G.W., Ruzicka, V.A., Nally, D.M. & Chambers, R.M. (2010) A contemporary, sex‐limited change in body size of an estuarine turtle in response to commercial fishing. Conservation Biology 24: 12681277.Google Scholar
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