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12 - Biogeography of Cyclamen: an application of phyloclimatic modelling

from Section 3 - Biogeography, migration and ecological niche modelling

Published online by Cambridge University Press:  16 May 2011

By
C. Yesson  and
A. Culham
Edited by
Trevor R. Hodkinson ,
Michael B. Jones ,
Stephen Waldren  and
John A. N. Parnell
C. Yesson
Affiliation:
Institute of Zoology, Zoological Society of London, UK
A. Culham
Affiliation:
University of Reading, UK
Trevor R. Hodkinson
Affiliation:
Trinity College, Dublin
Michael B. Jones
Affiliation:
Trinity College, Dublin
Stephen Waldren
Affiliation:
Trinity College, Dublin
John A. N. Parnell
Affiliation:
Trinity College, Dublin
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Summary

Abstract

Cyclamen is a genus of popular garden plant, protected by Convention on International Trade in Endangered Species (CITES) legislation. Many of its species are morphologically and phenologically adapted to the seasonal climate of the Mediterranean region. Most species occur in geographic isolation and will readily hybridise with their sister species when brought together. We investigate the biogeography of Cyclamen and assess the impact of palaeogeography and palaeoclimate change on the distribution of the genus. We use techniques of phyloclimatic modelling (combining ecological niche modelling and phylogenetic character optimisation) to investigate the heritability of climatic preference and to reconstruct ancestral niches. Conventional and phyloclimatic approaches to biogeography are compared to provide an insight into the historic distribution of Cyclamen species and the potential impact of climate change on their future distribution. The predicted climate changes over the next century could see a northward shift of many species' climatic niches to places outside their current ranges. However, such distribution changes are unlikely to occur through natural ant-based dispersal, so conservation measures are likely to be required.

Introduction

Cyclamen: present-day status and distribution

Cyclamen L. is a genus of c. 20 species in the family Myrsinaceae. Its species are perennial herbs, having distinctive flowers with reflexed petals, that are often scented, and winter blooming. These characteristics make Cyclamen a popular garden plant. Its popularity has prompted many studies on the group, including cytology (Bennett and Grimshaw, 1991; Anderberg, 1994), hybridisation (Gielly et al., 2001; Grey-Wilson, 2003) and phenology (Debussche et al., 2004).

Type
Chapter
Information
Climate Change, Ecology and Systematics , pp. 265 - 279
Publisher: Cambridge University Press
Print publication year: 2011

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References

Ackerly, D. D. (2003). Community assembly, niche conservatism, and adaptive evolution in changing environments. International Journal of Plant Sciences, 164, S165–S184.CrossRefGoogle Scholar
Anderberg, A. A. (1994). Phylogeny and subgeneric classification of Cyclamen L. (Primulaceae). Kew Bulletin, 49, 455–467.CrossRefGoogle Scholar
Anderberg, A. A., Trift, I. and Källersjö, M. (2000). Phylogeny of Cyclamen L. (Primulaceae): evidence from morphology and sequence data from the internal transcribed spacers of nuclear ribosomal DNA. Plant Systematics and Evolution, 220, 147–160.CrossRefGoogle Scholar
Bennett, S. T. and Grimshaw, J. M. (1991). Cytological studies in Cyclamen subg. Cyclamen (Primulaceae). Plant Systematics and Evolution, 176, 135–143.CrossRefGoogle Scholar
Bonaccorso, E., Koch, I. and Peterson, A. T. (2006). Pleistocene fragmentation of Amazon species' ranges. Diversity and Distributions, 12, 157–164.CrossRefGoogle Scholar
Busby, J. R. (1991). BIOCLIM: a bioclimatic analysis and prediction system. In Nature Conservation: Cost Effective Biological Surveys and Data Analysis, ed. Margules, C. R. and Austin, M. P.. Melbourne: CSIRO, pp. 64–68.Google Scholar
Clennett, J. C. B. (2002). An analysis and revision of Cyclamen L. with emphasis on subgenus Gyrophoebe O. Schwarz. Botanical Journal of the Linnean Society, 138, 473–481.CrossRefGoogle Scholar
Compton, J. A., Clennett, J. C. B. and Culham, A. (2004). Nomenclature in the dock. Overclassification leads to instability: a case study in the horticulturally important genus Cyclamen (Myrsinaceae). Botanical Journal of the Linnean Society, 146, 339–349.CrossRefGoogle Scholar
Culham, A., Denney, M., Jope, M. and Moore, P. (2009). A new species of Cyclamen from Crete. Cyclamen, 33, 12–15.Google Scholar
Davis, M. B. and Shaw, R. G. (2001). Range shifts and adaptive responses to Quaternary climate change. Science, 292, 673–679.CrossRefGoogle ScholarPubMed
Debussche, M., Garnier, E. and Thompson, J. D. (2004). Exploring the causes of variation in phenology and morphology in Mediterranean geophytes: a genus-wide study of Cyclamen. Botanical Journal of the Linnean Society, 145, 469–484.CrossRefGoogle Scholar
Douady, C. J., Catzeflis, F., Raman, J., Springer, M. S. and Stanhope, M. J. (2003). The Sahara as a vicariant agent, and the role of the Miocene climatic events, in the diversification of the mammalian order Macroscelidae (elephant shrews). Proceedings of the National Academy of Sciences of the USA, 100, 8325–8330.CrossRefGoogle Scholar
Elith, J., Graham, C. H., Anderson, R. P. et al. (2006). Novel methods improve prediction of species' distributions from occurrence data. Ecography, 29, 129–151.CrossRefGoogle Scholar
Estabrook, G. F. (2001). Vicariance or dispersal: the use of natural historical data to test competing hypotheses of disjunction on the Tyrrhenian coast. Journal of Biography, 28, 95–103.CrossRefGoogle Scholar
Gielly, L., Debussche, M. and Thompson, J. D. (2001). Geographic isolation and evolution of Mediterranean endemic Cyclamen: insights from chloroplast trnL (UAA) intron sequence variation. Plant Systematics and Evolution, 230, 75–88.CrossRefGoogle Scholar
Graham, C. H., Ron, S. R., Santos, J. C., Schneider, C. J. and Moritz, C. (2004). Integrating phylogenetics and environmental niche models to explore speciation mechanisms in dendrobatid frogs. Evolution, 58, 1781–1793.CrossRefGoogle ScholarPubMed
Grey-Wilson, C. (2003). Cyclamen: a Guide for Gardeners, Horticulturalists and Botanists. London: Batsford.Google Scholar
Guisan, A. and Thuiller, W. (2005). Predicting species distribution: offering more than simple habitat models. Ecology Letters, 8, 993–1009.CrossRefGoogle Scholar
Guisan, A. and Zimmermann, N. E. (2000). Predictive habitat distribution models in ecology. Ecological Modelling, 135, 147–186.CrossRefGoogle Scholar
Hoffmann, M. H. (2005). Evolution of the realized climatic niche in the genus Arabidopsis (Brassicaceae). Evolution, 59, 1425–1436.Google Scholar
Hugall, A., Moritz, C., Moussalli, A. and Stanisic, J. (2002). Reconciling paleodistribution models and comparative phylogeography in the wet tropics rainforest land snail Gnarosophia bellendenkerensis(Brazier 1875). Proceedings of the National Academy of Sciences of the USA, 99, 6112–6117.CrossRefGoogle Scholar
Inouye, D. W. (2000). The ecological and evolutionary significance of frost in the context of climate change. Ecology Letters, 3, 457–463.CrossRefGoogle Scholar
Krijgsman, W. (2002). The Mediterranean: mare nostrum of earth sciences. Earth and Planetary Science Letters, 205, 1–12.CrossRefGoogle Scholar
Martínez-Meyer, E., Peterson, A. T. and Hargrove, W. W. (2004a). Ecological niches as stable distributional constraints on mammal species, with implications for Pleistocene extinctions and climate change projections for biodiversity. Global Ecology and Biogeography, 13, 305–314.CrossRefGoogle Scholar
Martínez-Meyer, E., Peterson, A. T. and Navarro-Siguenza, A. G. (2004b). Evolution of seasonal ecological niches in the passerina buntings (Aves: Cardinalidae). Proceedings of the Royal Society of London B, 271, 1151–1157.CrossRefGoogle Scholar
McLachlan, J. S., Clark, J. S. and Manos, P. S. (2005). Molecular indicators of tree migration capacity under rapid climate change. Ecology, 86, 2088–2098.CrossRefGoogle Scholar
Morrone, J. J. and Crisci, J. V. (1995). Historical biogeography: introduction to methods. Annual Review of Ecology and Systematics, 26, 373–401.CrossRefGoogle Scholar
Ness, J. H., Bronstein, J. L., Andersen, A. N. and Holland, J. N. (2004). Ant body size predicts dispersal distance of ant-adapted seeds: implications of small-ant invasions. Ecology, 85, 1244–1250.CrossRefGoogle Scholar
Nix, H. A. (1986). A biogeographic analysis of Australian elapid snakes. In Atlas of Elapid Snakes of Australia, ed. Longmore, R.. Canberra: Australian Government Publishing Service, pp. 4–15.Google Scholar
Oberprieler, C. (2005). Temporal and spatial diversification of circum-Mediterranean Compositae-Anthemideae. Taxon, 54, 951–966.CrossRefGoogle Scholar
Page, R. D. M. (1988). Quantitative cladistic biogeography constructing and comparing area cladograms. Systematic Zoology, 37, 254–270.CrossRefGoogle Scholar
Peterson, A. T. (2003). Predicting the geography of species' invasions via ecological niche modeling. Quarterly Review of Biology, 78, 419–433.CrossRefGoogle ScholarPubMed
Peterson, A. T., Soberón, J. and Sánchez-Cordero, V. (1999). Conservation of ecological niches in evolutionary time. Science, 285, 1265–1267.CrossRefGoogle Scholar
Peterson, A. T., Tian, H., Martínez-Meyer, E. et al. (2005). Modeling distributional shifts of individual species and biomes. In Climate Change and Biodiversity, ed. Lovejoy, T. E. and Hannah, L. J.. New Haven, CT: Yale University Press, pp. 211–229.Google Scholar
Phillips, S. J., Anderson, R. P. and Schapire, R. E. (2006). Maximum entropy modeling of species geographic distributions. Ecological Modelling, 190, 231–259.CrossRefGoogle Scholar
Piñeiro, R., Aguilar, J. F., Munt, D. D. and Feliner, G. N. (2007). Ecology matters: Atlantic–Mediterranean disjunction in the sand-dune shrub Armeria pungens (Plumbaginaceae). Molecular Ecology, 16, 2155–2171.CrossRefGoogle Scholar
Ree, R. H., Moore, B. R., Webb, C. O. and Donoghue, M. J. (2005). A likelihood framework for inferring the evolution of geographic range on phylogenetic trees. Evolution, 59, 2299–2311.CrossRefGoogle ScholarPubMed
Ricklefs, R. E. and Latham, R. E. (1992). Intercontinental correlation of geographical ranges suggests stasis in ecological traits of relict genera of temperate perennial herbs. American Naturalist, 139, 1305–1321.CrossRefGoogle Scholar
Ronquist, F. (1997). Dispersal–vicariance analysis: a new approach to the quantification of historical biogeography. Systematic Biology, 46, 195–203.CrossRefGoogle Scholar
Sanmartin, I. (2003). Dispersal vs. vicariance in the Mediterranean: historical biogeography of the Palearctic Pachydeminae (Coleoptera, Scarabaeoidea). Journal of Biogeography, 30, 1883–1897.CrossRefGoogle Scholar
Stace, C. (1997). New Flora of the British Isles, 2nd edn. Cambridge: Cambridge University Press.Google Scholar
Wiens, J. J. and Donoghue, M. J. (2004). Historical biogeography, ecology and species richness. Trends in Ecology and Evolution, 19, 639–644.CrossRefGoogle ScholarPubMed
Yesson, C. (2008). Investigating plant diversity in Mediterranean climates. Unpublished PhD thesis, University of Reading.
Yesson, C. and Culham, A. (2006a). Phyloclimatic modelling: combining phylogenetics and bioclimatic modelling. Systematic Biology, 55, 785–802.CrossRefGoogle Scholar
Yesson, C. and Culham, A. (2006b). A phyloclimatic study of Cyclamen. BMC Evolutionary Biology, 6, 72.CrossRefGoogle ScholarPubMed
Yesson, C., Toomey, N. H. and Culham, A. (2009). Cyclamen: time, sea and speciation biogeography using a temporally calibrated phylogeny. Journal of Biogeography, 36, 1234–1252.CrossRefGoogle Scholar

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