It has been a wild year with lots of challenges, but MAISRC is still here and working as hard as ever to develop research-based solutions to reduce the impacts of aquatic invasive species in Minnesota. MAISRC hopes the research highlights included in the report will surprise, inspire, and give you hope.
Invasive Species Resources
Displaying 1 to 5 of 5Search Help
University of Minnesota. Minnesota Aquatic Invasive Species Research Center.
University of Texas at Austin.
The cactus moth has a wingspan of only about an inch, but this invasive insect has the potential to cause largescale agricultural and ecological devastation in Texas, according to the first study of cactus moths in Texas. Researchers at The University of Texas at Austin's Invasive Species Project based at Brackenridge Field Laboratory in Austin have found that four native species of prickly pear cactus — and the species that rely on them — face a serious health threat from the moth.
University of Montana. Flathead Lake Biological Station.
Invasive species cause biodiversity loss and about $120 billion in annual damages in the U.S. alone. Despite plentiful evidence showing that invasive species can change food webs, how invaders disrupt food webs and native species through time has remained unclear. Now, thanks to a collaborative study conducted by researchers representing the University of Montana's Flathead Lake Biological Station (FLBS), U.S. Geological Survey (USGS), and Montana Fish, Wildlife & Parks, there is new insight into how invasive species progressively affect native food webs.
Texas A&M University. AgriLife Extension Service.
USDA NIFA research investment in Texas A&M AgriLife leads to breakthrough in fighting agricultural plant diseases. Researchers have made a discovery that will help combat fastidious pathogens, which cost U.S. agriculture alone billions of dollars annually.
University of Minnesota.
New research from the University of Minnesota’s Minnesota Invasive Terrestrial Plants and Pests Center (MITPPC) shows a possible path forward in controlling the invasive pest, the emerald ash borer (EAB), that threatens Minnesota’s nearly one billion ash trees.
In a recent study published in Fungal Biology, MITPPC researchers identified various fungi living in EAB-infested trees — a critical first step in finding fungi that may be harnessed to control the spread of EAB, and ultimately, prevent ash tree death.