Rising temperature and development in dragonfly populations at different latitudes

  1. IDA FLENNER1,2,3,
  2. OTTO RICHTER1,
  3. FRANK SUHLING1

Article first published online: 16 AUG 2009

DOI: 10.1111/j.1365-2427.2009.02289.x

Issue

Freshwater Biology

Freshwater Biology

Volume 55, Issue 2, pages 397–410, February 2010

Additional Information

How to Cite

FLENNER, I., RICHTER, O. and SUHLING, F. (2010), Rising temperature and development in dragonfly populations at different latitudes. Freshwater Biology, 55: 397–410. doi: 10.1111/j.1365-2427.2009.02289.x

Author Information

  1. 1

    Institut für Geoökologie, Technische Universität Braunschweig, Braunschweig, Germany

  2. 2

    Ecology and Environmental Sciences, Halmstad University, Halmstad, Sweden

  3. 3

    Department of Animal Ecology, Uppsala University, Uppsala, Sweden

*Ida Flenner, Ecology and Environmental Sciences, Halmstad University, PO Box 823, SE-30118 Halmstad, Sweden. E-mail: ida.flenner@hh.se

Publication History

  1. Issue published online: 13 JAN 2010
  2. Article first published online: 16 AUG 2009
  3. (Manuscript accepted 4 July 2009)

SEARCH

SEARCH BY CITATION

ARTICLE TOOLS

View Full Article (HTML) Get PDF (521K)

Keywords:

  • climate change;
  • growth rate;
  • Odonata;
  • seasonal regulation;
  • voltinism pattern

Summary

1. For modelling the future ecological responses to climate change, data on individual species and on variation within and between populations from different latitudes are required.

2. We examined life cycle regulation and growth responses to temperature in Mediterranean and temperate populations of a widespread European odonate, Orthetrum cancellatum. In an experiment, offspring from individual females from different parts of the range were kept separately to elucidate differences between families.

3. The experiment was run outdoors at 52°N at a natural photoperiod for almost a year. We used four temperature regimes, ambient (i.e. following local air temperature) and ambient temperature increased by 2, 4 and 6 °C, to mimic future temperature rise. A mathematical model was used to categorise the type of seasonal regulation and estimate parameters of the temperature response curve.

4. Growth rate varied significantly with temperature sum, survival and geographic origin, as well as with family. Offspring of all females from the temperate part of the range had a life cycle with a 12 h day-length threshold necessary to induce diapause (i.e. diapause was induced once day length fell below 12 h). By contrast, Mediterranean families had a 10 h threshold or had an unregulated life cycle allowing winter growth. The temperature response did not significantly differ between populations, but varied between families with a greater variation in the optimum temperature for growth in the Mediterranean population.

5. The variation in seasonal regulation leads to a diversity in voltinism patterns within species, ranging from bivoltine to semivoltine along a latitudinal gradient. Given that the type of seasonal regulation is genetically fixed, rising temperatures will not allow faster than univoltine development in temperate populations. We discuss the consequences of our results in the light of rising temperature in central Europe.

View Full Article (HTML) Get PDF (521K)