maanantai 12. syyskuuta 2016

Beavers and beetles: studying how a wetland species influences forest beetles

Window traps are emptied out once a
 month so it is important to
attach them firmly to tree trunks. ©Mia Vehkaoja
My PhD research looks at how beavers affect forest beetle populations. I have several research questions: do beaver-induced flood zones have different beetle species assemblages than other areas, do the increased moisture and sunlight conditions in the flood zone affect species assemblage, and do beaver areas advance or hinder potential forest pests or protected species. I have also looked into the dead wood dynamics that beavers create at the flood zones, concluding that beavers are a primary disturbance agent of boreal wetlands. Their actions produce copious amounts of dead wood in boreal forests that are currently highly managed and have consequently become scarce in dead wood, which is necessary for many species of insects, fungi, birds, and even mammals. The dead wood created by beavers is also highly diverse, which therefore maximizes the number of deadwood-dependent species facilitated by beavers. The flooding caused by the species produce e.g. snags and deciduous dead wood, which are especially scarce in the boreal region.


My research combines a game species with widespread effects on its surroundings, and forest beetles, several species of which have become scarce and require protection. Beaver-induced flooding and the species’ habit of felling tree trunks may locally disturb forest owners, but my study is looking into whether beavers’ actions facilitate or disturb forest pests. Combining game and insect research is cool, and generates new information on which to base decision-making for future protection measures, beaver population management, and even for using beavers as a natural tool for restoring degraded wetlands and forests.

Window traps are good for collecting
forest invertebrates. ©Sari Holopainen
Studying insects is interesting yet challenging. Determining individuals to the species level nearly always requires capturing them first, although some species, such as the birch bark beetle (Scolytus ratzeburgi), can be identified by the unique pattern they leave on tree trunks. During the last three years I have used window traps to gather my insect data. The data have been collected from eight sites located at Evo and Isojärvi National Park. Beavers have previously been present at five of the sites, while three sites are controls that are unsuitable for beaver habitation due to certain environmental factors, e.g. not enough deciduous trees. I have a total of 120 traps spread out at the sites, so every summer I collect about 600 samples.

Window traps are widely used for determining the insect assemblages of sites. They are very simple to use: the trap is attached to a tree trunk or set to hang between two trees. Insects crawl or fly into the plastic plexiglas frame and then fall through the funnel into a liquid-filled container at the bottom. The container is filled halfway with water, dishwashing fluid, and salt. The dishwashing fluid prevents the insects from regaining flight, consequently drowning them. The salt helps preserve the insects until the trap is emptied out, which happens about once a month.


After the trap container has been emptied the gathered sample is sifted through using tweezers and a microscope, to separate the insect groups that I am interest in. Next the individuals are determined to the necessary level. Sometimes determining the family level is enough, but if making conservation decisions or gaining new information on certain species is the goal, it is usually necessary to determine individual insects to the species level. How this is done depends on the order in question, e.g. beetles are often recognized by their ankles and genitals. Species, genera, and families are determined using identification keys. The summer of 2016 was the last summer that I collected data for my PhD, so now I can focus on identifying the beetle samples. Once this is complete I can begin statistically analyzing the data. 

University of Helsinki PhD student Stella Thompson is a 2015 LBAYS grant recipient

perjantai 2. syyskuuta 2016

Thermal melanism in the Glanville fritillary butterfly (Melitaea cinxia)


Melanin production in animals has been associated to a number of advantages spanning from UV light protection to a better ability to camouflage or produce warning coloration patterns. The most commonly proposed hypothesis to explain such phenomenon is related to the better ability of darker individuals to absorb and retain heat, and is known as “thermal melanism”. The thermal melanism hypothesis is associated in particular to organisms with a limited ability to thermoregulate, as ectotherms, whose fitness is tightly dependent on climatic conditions. Ectotherms living in cold climates are expected to show a high degree of phenotypic plasticity in order to better adapt to stringent environmental conditions.

In insects, melanin is not only related to the pigmentation of the surface of body parts, but is also released in the hemolymph as a key component of immune response. In fact, when the insect cuticle is breached via wounding or parasitism the phenoloxidase enzymatic pathway is activated and melanin is produced in order to neutralize foreign bodies entering the hemolymph. The activation of insect immunity, and in particular melanin production, has been shown to be a costly process, hence trade-offs between investment in immunity and other fitness-related traits can be expected when the conditions are not optimal.

I wanted to test the thermal melanism hypothesis on the Glanville fritillary butterfly (Melitaea cinxia), for which the northernmost limit of its distribution range is located in the Åland islands. Adults of the Glanville fritillary are observed to fly actively in conditions of full sun and temperatures above 18-20°C. However, when temperatures are lower and the sun is absent they are incapable of moving and performing their activities. In addition, a great variation in the wing pigmentation has been described, hence they are expected to be plastic. To test the plasticity of wings, I have exposed pupae to either a cold or control treatment, took photographs of adult wings and measured their darkness in a series of experiments performed in the spring of 2015 and 2016 at the Lammi biological station.

Furthermore, I was also interested in the connection between melanin allocation to wing patterns and the ability to produce melanin in the hemolymph as a key component of immunity. In order to test this, I collected hemolymph samples of control and previously cold exposed adults and measured the activity of the phenoloxidase enzyme. Finally, to test the costs associated to melanin production I infected control and cold exposed butterflies with a bacterial solution, and assessed lifespan.

Preliminary data show that cold exposed pupae resulted in adults with darker wings, indicating that they are able to modulate melanin allocation to wings in response to thermal conditions. In addition, exposure of pupae to a milder cold treatment still resulted in darker adults, but only in females, which in standard conditions are paler than males. This indicates that wings of the Glanville fritillary are highly plastic, and potentially supports the thermal melanism hypothesis. Contrary to my expectations, the production of phenoloxidase in the hemolymph was higher in adults that had been exposed to the cold conditions, suggesting that there is no trade-off in the allocation of melanin between wing patterns and immune defense. Moreover, the condition of females seemed not to be affected by cold nor bacterial infection, since the lifespan data did not significantly differ among treatment groups. Males showed a similar response, except for the ones that experienced both cold exposure and bacterial infection, for which we observe a significantly lower lifespan. Based on these data, the upregulated phenoloxidase production of cold exposed individuals did not seem to improve the ability to survive or fight infections, but instead it seems associated to a lifespan cost in males.


In order to elucidate the adaptive value of darker butterflies, and demonstrate or reject the thermal melanism hypothesis, I carried out another experiment in a large outdoor enclosure at the Lammi biological station in summer 2016. I measured traits as heat absorption capacity with a thermal image camera, as well as flight ability and reproductive success of cold exposed butterflies to pinpoint potential advantages in terms of dispersal or fitness traits. I am looking forward to the exciting results!

Elena Rosa is a University of Helsinki PhD student and 2015 grant recipient