DNA-methods reveal the web of life

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Bats (here Daubenton’s bat, Myotis daubentonii) illustrate the many secretive species the diet of which can be accurately revealed only by DNA-based techniques. Credit: Risto Lindstedt

Modern DNA-based methods provide entirely new insight into the interaction between different species in nature. Researchers can finally reveal the details of who is eating whom, who pollinates what flower and who lives on whose skin or feathers. A special issue of the scientific top journal Molecular Ecology now provides an overview of the state of the art in this field.


Just like the microscope and the telescope opened up new vistas some centuries ago, DNA-based are now making it possible to discover whole new worlds. These methods are particularly important for revealing associations between species that are difficult to study by traditional methods, because they are too small, too secretive or too difficult to recognize.

Bats provide a vivid example. Since they hunt at night, it is basically impossible to observe what they are capturing. In the past, researchers had to guess at what they ate as based on small insect fragments in their droppings.

“Today we can easily achieve the same and more by sequencing the DNA present in the droppings. These approaches have helped us realize that such different animals as bats, birds and dragonflies actually share the same prey,” says Eero Vesterinen, a Finnish researcher now working at the Swedish University of Agricultural Sciences (SLU).

Understanding how different species are woven together in nature’s food webs is not only fascinating. The knowledge of how species interact with each other is also of applied importance, e.g. in conservation and in developing new methods for plant protection.

“For those of us who deal with on crops, DNA methods are among the best thing that ever happened,” says Mattias Jonsson, also a researcher at SLU. “The methods help us identify what predators keep insect pests in check.”

Three of the studies included in the special issue were done by SLU professor Tomas Roslin and his team. Using innovative methods, these researchers have identified what insects live in the edible that we pick for food, what insects pollinate the flowers of the Arctic, and how affects the actual top predators among arctic arthropods – the wolf spiders.

“Our most hilarious moments probably occurred during the mushroom study. We took the whole fungus and drove it through a regular kitchen blender, then used molecular methods to identify the insect DNA from the resulting mushroom soup. By this approach, we can establish what insects are causing the greatest damage to the mushroom yield, explore how specialized different insects are in terms of their mushroom diet, and study how the age and structure of forests affect the insect contents of mushroom,” says Tomas Roslin.

When they studied the insect visitors of artic flowers, they used sticky flower mimics which look like mountain avens.

“No entomologist alive could have identified the 30,000 individual insects that we caught. We, on the other hand, simply used the DNA of the insects to tell what they were. This way, we were able to describe trans-arctic patterns among the plant pollinators of the Arctic,” says Tomas Roslin.

New insights into how are connected is also important for predicting the consequences of a warming climate.

“The wolf spiders are the real rulers of the Arctic. They can be extremely numerous, and any animal smaller than them has reason to tremble. We used the mountain slopes of Northeast Greenland to understand how climate affects the wolf spiders’ diet. We realized that they maintain a preference for e.g. some fly prey regardless of climate, but that the climate affects how many flies are there for the spiders to eat,” says Tomas Roslin.


Explore further:
Researchers discover what is on the menu for dragonflies

More information:
Tomas Roslin et al. Introduction: Special issue on species interactions, ecological networks and community dynamics – Untangling the entangled bank using molecular techniques, Molecular Ecology (2018). DOI: 10.1111/mec.14974

Journal reference:
Molecular Ecology

Provided by:
Swedish University of Agricultural Sciences



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