Browsing by Author "Nordling, Emilia"

During the last century increased emissions of greenhouse gases have caused global climate warming. While the temperatures are still rising, the largest increases have been observed in spring-time temperatures. This may affect the phenology of multiple species. If the increase in temperature affects different species differently, then the lifecycles of various species may become unsynchronized. For interacting species, a disturbance like this may be catastrophic: for example, if the phenology of host plants is drastically altered, then many herbivores may be left without food. Previous research on the effects of climate change on interspecific interactions has focused on bitrophic interactions. My research expands this past emphasis to a tritrophic level: to interactions between plants (penduculate oak, Quercus robur), herbivorous insects (moths: Tischeria ekebladella, Phyllonorycter quercifoliella and P. harrisella) and parasitoids (wasps in the family Eulophidae). Since bud burst in oaks varies significantly among individuals, I also investigated how host genotype may affect the synchrony between species. My hypotheses were that higher spring-time temperatures will disrupt the synchrony between species, and that this disturbance will affect the growth and reproduction of species at higher trophic levels. I also posited that the effects will vary with the genotype of the host. I tested these hypotheses in a field experiment running from April to September 2009. To manipulate temperatures I used a greenhouse, transplanting multiple oak-specific moth and parasitoid species to oaks of different genotypes growing inside and outside of the greenhouse. During the field experiment, the temperature differed by 3.19°C between the interior and the outside of the greenhouse. As a result, the phenology of all species was advanced in the greenhouse interior as compared to ambient conditions. Interspecific synchrony was affected differently in different species pairs: Inside of the greenhouse, the synchrony between oaks and Phyllonorycter moths and between oaks and parasitoids was decreased. The synchrony between oaks and the moth T. ekebladella remained unaffected. Likewise, the synchrony between moths and parasitoids was left intact. The larvae of T. ekebladella grew bigger inside of the greenhouse than outside of it. In addition, a second generation of T. ekebladella occurred inside of the greenhouse, but not under ambient temperatures. Host plant phenology had a significant effect on associated insects: moth larvae of T. ekebladella grew bigger on oaks sprouting leaves early in the season. This increase in performance suggests that moth larvae prefer old leaves. In summary, my study shows that climate change may affect different species and different interspecific interactions in highly different ways. My study also upsets the previous view that mature oak foliage would offer food of inferior quality to moth larvae. In addition, it depicts host plant genotype as a less prominent determinant of insect performance than has been previously assumed.