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Lythrum salicaria, or purple loosestrife, at U of T's Koffler Scientific Reserve (photo by Rob Colautti)

Invasive plant thrives by adapting quickly to local climates

Natural selection enables purple loosestrife to invade northern Ontario

߲ݴý research has found that purple loosestrife – an invasive species that competes with native plants for light and nutrients and can degrade habitats for wildlife – has evolved extremely rapidly, flowering about three weeks earlier as it has spread to northern Ontario.

This has allowed populations of the species to thrive in the colder climate with a more than 30-fold increase in seed production.

“The ability of invasive species to rapidly adapt to local climate has not generally been considered to be an important factor affecting spread,” said Rob Colautti, who conducted the research as a PhD student in U of T’s Department of Ecology & Evolutionary Biology under the supervision of Professor Spencer Barrett.

“Instead, factors such as escape from natural enemies including herbivores, predators, pathogens or parasites were thought to explain how species become invasive," Colautti said. "We found that the evolution of local adaptation to climate in purple loosestrife increased reproduction as much as or more than escaping natural enemies.

"Understanding that species can evolve rapidly to local climates is important for predicting how invasive species spread and how native and non-native species alike will respond to climate change.”

The research team included more than 30 U of T undergraduate students and part of the research was conducted at the ߲ݴý’s Koffler Scientific Reserve (pictured right).

To determine whether populations have evolved local adaptation, the scientists collected seeds from three different climatic regions (north, south and intermediate latitudes in eastern N. America) and then grew them at three sites spanning the distribution of the species to see if there were differences in survival and reproduction, i.e. fitness. They found that 'home' plants collected from latitudes most similar to each common garden location always had higher fitness than the 'away' plants. For example, plants collected from northern latitudes had the highest fitness when grown at the northern site in Timmins, Ontario but the lowest fitness when grown at a southern site in northern Virginia relative to plants collected from southern latitudes.

The team’s previous work showed that northern populations flower about 20 days earlier but at half the size of southern populations when both were grown in the same ‘common garden’ experiment. They wondered whether these genetic differences could account for the observation of locally adapted populations. So in the next phase of the research, they directly measured Darwinian natural selection on flowering time at each of the common garden sites.

They found that early flowering was adaptive at the most northern site, because early-flowering plants produced the most offspring while plants with delayed flowering began reproduction near the end of the growing season, when pollinators were scarce and flowers were prone to frost damage. But later flowering was favoured by natural selection at more southern sites because delayed reproduction allowed plants to grow larger and produce more seeds when the growing season is longer.

Remarkably, these differences have evolved over the past 50 years as the species moved northwards, following its initial introduction to the east coast of the USA.

The research was funded by grants from the Natural Sciences and Engineering Research Council of Canada. The paper “Rapid adaptation to climate facilitates range expansion in an invasive plant” will appear in Science October 18.

Kim Luke is a writer with the Faculty of Arts & Science at the ߲ݴý.
 

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