%0 Journal Article %1 pfenning_alternative_2008 %A Pfenning, Brenda %A Gerstner, Sabine %A Poethke, Hans Joachim %D 2008 %J Entomologia Experimentalis et Applicata %K Gerridae, Heteroptera, Phenotypic adaptation, bivoltine, constant, cycle, dimorphism life physiological plasticity, seasonal thermal time, univoltine, wing %N 3 %P 235--242 %R 10.1111/j.1570-7458.2008.00781.x %T Alternative life histories in the water strider Gerris lacustris: time constraint on wing morph and voltinism %U http://onlinelibrary.wiley.com/doi/10.1111/j.1570-7458.2008.00781.x/abstract %V 129 %X The wing dimorphic water strider Gerris lacustris L. (Heteroptera: Gerridae) switches to a bivoltine life cycle under favorable climatic conditions. The switch in voltinism is accompanied by a reduction of wing development in the directly reproducing midsummer generation, while the diapausing generation has a high fraction of long-winged individuals. We investigated whether the thermal energy (degree-days) available in natural habitats constrains the combination of developmental pathway and wing morph. Offspring of G. lacustris were reared under quasi-natural conditions at two temperature regimes to determine the thermal constant k required to complete adult development in either wing morph. The thermal constant for egg-to-adult development of the short-winged morph was about 20\% lower than of the long-winged morph. Based on the results from the outdoor laboratory experiment, we calculated the total degree-days necessary to complete the possible combinations of wing morph pattern and voltinism. Comparison of these estimates with the thermal energy actually available during the reproductive season of 2004 for various natural habitats (sun-exposed field ponds and shaded forest ponds) suggests that voltinism as well as wing morph pattern is strongly limited by the number of degree-days available in these habitats. On forest ponds, only univoltine life cycles were possible, whereas on field ponds temperature allowed bivoltine life cycles. However, only the eggs laid at the very beginning of the season had the potential to accumulate enough degree-days to complete a bivoltine life cycle with both generations long-winged. We conclude that thermal energy is the main environmental constraint limiting voltinism of populations in the two habitat types. Furthermore, the available thermal energy also seems to influence the determination of the seasonal wing pattern in G. lacustris.

@article{pfenning_alternative_2008, abstract = {The wing dimorphic water strider Gerris lacustris L. (Heteroptera: Gerridae) switches to a bivoltine life cycle under favorable climatic conditions. The switch in voltinism is accompanied by a reduction of wing development in the directly reproducing midsummer generation, while the diapausing generation has a high fraction of long-winged individuals. We investigated whether the thermal energy (degree-days) available in natural habitats constrains the combination of developmental pathway and wing morph. Offspring of G. lacustris were reared under quasi-natural conditions at two temperature regimes to determine the thermal constant k required to complete adult development in either wing morph. The thermal constant for egg-to-adult development of the short-winged morph was about 20\% lower than of the long-winged morph. Based on the results from the outdoor laboratory experiment, we calculated the total degree-days necessary to complete the possible combinations of wing morph pattern and voltinism. Comparison of these estimates with the thermal energy actually available during the reproductive season of 2004 for various natural habitats (sun-exposed field ponds and shaded forest ponds) suggests that voltinism as well as wing morph pattern is strongly limited by the number of degree-days available in these habitats. On forest ponds, only univoltine life cycles were possible, whereas on field ponds temperature allowed bivoltine life cycles. However, only the eggs laid at the very beginning of the season had the potential to accumulate enough degree-days to complete a bivoltine life cycle with both generations long-winged. We conclude that thermal energy is the main environmental constraint limiting voltinism of populations in the two habitat types. Furthermore, the available thermal energy also seems to influence the determination of the seasonal wing pattern in G. lacustris.}, added-at = {2016-09-26T15:45:29.000+0200}, author = {Pfenning, Brenda and Gerstner, Sabine and Poethke, Hans Joachim}, biburl = {https://www.bibsonomy.org/bibtex/2d8fd4760f67ed040401f99f329322b2c/teegroup}, doi = {10.1111/j.1570-7458.2008.00781.x}, file = {Full Text PDF:/media/thomas/USBArbeit/zotero/storage/SPTP7E7K/Pfenning et al. - 2008 - Alternative life histories in the water strider Ge.pdf:application/pdf;Snapshot:/media/thomas/USBArbeit/zotero/storage/JAXKFT42/abstract.html:text/html}, interhash = {172e506b58ea96125d22cf5c86dcaa11}, intrahash = {d8fd4760f67ed040401f99f329322b2c}, issn = {1570-7458}, journal = {Entomologia Experimentalis et Applicata}, keywords = {Gerridae, Heteroptera, Phenotypic adaptation, bivoltine, constant, cycle, dimorphism life physiological plasticity, seasonal thermal time, univoltine, wing}, language = {en}, month = dec, number = 3, pages = {235--242}, shorttitle = {Alternative life histories in the water strider {Gerris} lacustris}, timestamp = {2016-09-26T15:45:29.000+0200}, title = {Alternative life histories in the water strider {Gerris} lacustris: time constraint on wing morph and voltinism}, url = {http://onlinelibrary.wiley.com/doi/10.1111/j.1570-7458.2008.00781.x/abstract}, urldate = {2016-09-26}, volume = 129, year = 2008 }