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The U.S. Department of Agriculture announced its strengthened commitment to advancing research and programmatic priorities that support pollinator health by soliciting nominations for members to serve on its newly formed USDA National Pollinator Subcommittee. The Pollinator Subcommittee will provide input on annual USDA strategic pollinator priorities and goals and will make pollinator health-related recommendations to strengthen USDA pollinator research efforts. USDA is both a major funder and conductor of pollinator research, with research initiatives spanning across five USDA mission areas.

On May 14, Director Reilly signed a Memorandum of Agreement with the Department of the Navy and the U.S. Fish and Wildlife Service. The MOA provides for continuity of operations for the USFWS and the USGS with construction of new office and lab facilities on the Guam National Wildlife Refuge in conjunction with DOD’s construction of a Marine Corps firing range. "The USGS has a long history of collaborating with the Department of Defense in support of U.S. facilities and force readiness in the INDOPACOM Area of Responsibility. One of our signature efforts ongoing today is a collaboration with DOD, the U.S. Fish and Wildlife Service, and the local government in minimizing the impacts of the invasive Brown Treesnakes (BTS) and improving BTS controls on military lands on Guam," said Jim Reilly, director of the USGS.

A new study shows that vaccination may reduce the impact of white-nose syndrome in bats, marking a milestone in the international fight against one of the most destructive wildlife diseases in modern times. "This is a significant step forward in developing control mechanisms to combat the devastating spread of white-nose syndrome in our important bat populations," said USGS Director Jim Reilly. "Being able to deliver an oral vaccine during hibernation could be a game changer in our ability to combat one of the deadliest wildlife diseases in modern times." White-nose syndrome is caused by a fungus called Pseudogymnoascus destructans, or Pd, and has killed millions of North American bats since 2006. The disease is spreading rapidly and there is no cure.

A novel control strategy could be in store for spotted wing drosophila, an invasive vinegar fly species from Asia that attacks more than 100 fruit crops, including blueberry, cherry, blackberry, and grape. Two- to three-millimeters long, the spotted wing drosophila fly first drew attention in 2008 in California. Before long, it had spread to other western states, inflicting losses of 50 to 100 percent in berry crops there. Two years later, it had spread to the eastern United States, wreaking similar havoc and forcing growers to retaliate with intensive insecticide spraying. Researchers, meanwhile, began learning all they could about the invader. One such scientist is Blair Sampson, an Agricultural Research Service (ARS) entomologist who specializes in integrated pest management approaches for small-fruit crops. Sampson is with the ARS Thad Cochran Southern Horticultural Laboratory in Poplarville, Mississippi.

Virginia Tech entomologist Muni Muniappan has warned of Tuta absoluta’s likely arrival into the United States since he began monitoring the pest's spread throughout Africa in 2012. Thanks to a joint grant from the U.S. Department of Agriculture, Muniappan's team and collaborators will be able to model the pest's entry into the United States — protecting the country's billion-dollar tomato industry — before irreparable damage is caused. Tuta absoluta is a tomato pest native to South America. If left unmitigated, it has the potential to destroy 100 percent of tomato crops. In 2016, the pest caused a "tomato emergency" in such countries as Nigeria, where tomatoes are a lifeline for many smallholder farmers. With the U.S. as one of the world's leaders in tomato production, the pest's impact would be severe if nothing is done to stop it. The USDA's Food and Agriculture Cyberinformatics Tools Initiative awarded the University of Virginia's Biocomplexity Institute and Virginia Tech the four-year, $500,000 grant to project the pest's movement and rate of spread into the U.S. The model, to be developed by the Biocomplexity Institute, will map the spread of invasive species over time, accounting for factors such as climate, biology, and demographic information.

The Mississippi River Delta is home to the world’s largest contiguous swath of Phragmites australis, or more commonly known as the common reed. But the plant that can grow to nearly 20 ft. and has been a critical component in stabilizing the state’s coastal erosion is not actually native to Louisiana—well, not entirely. There are multiple P. australis genotypes. P. australis subspecies (ssp.) americanus is the native subspecies in the U.S. and Canada. However, Phragmites australis ssp. australis originated in central Europe and was subsequently introduced to the U.S. where it is now considered to be one of the most problematic invasive species in North America. "Novel genome characteristics contribute to the invasiveness of Phragmites australis (common reed)" in Molecular Ecology and recently featured in an edition of The Scientist, LSU researchers collaborated with Tulane University and the U.S. Geological Survey to study the genomic bases of P. australis and to investigate what exactly makes the invasive reed grass subspecies thrive in wetlands, in comparison to its native counterpart.

A chance discovery in an Ohio woodland has turned into a multi-disciplinary, multi-agency, and multi-national effort to piece together a puzzle and understand a scourge that is killing trees by the thousands in northern states east of the Great Plains. The leaves of young beech trees are failing somehow. Scientists have figured out what causes the malady; it’s the 'how' that has them scratching their heads. Beech trees are one of the most common trees in America's northern and northeastern forests. Their nut crop feeds birds and other animals, and its wood is prized for bentwood furniture. The symptoms of beech leaf disease were plain to see – sunken dark spots on the leaves, which eventually died – but opinions differed on the cause. Was it bacterial, fungal, or viral? Then, a plant pathologist working for the State of Ohio noticed wiggly things in the leaf lesions. They turned out to be nematodes, microscopic worms that live in the soil, that had somehow managed to make it to the tree canopy 40-50 feet above ground. Nematode samples were sent to Beltsville, MD, for analysis and identification at the Agricultural Research Service (ARS) Mycology and Nematology Genetic Diversity and Biology Laboratory in Beltsville, MD. The nematode, Litylenchus crenatae, turned out to be native to Japan – the first population of L. crenatae found in the Western Hemisphere. The curious thing is that it's not a tree-killer in Japan.

White-nose syndrome has killed over 90% of northern long-eared, little brown and tri-colored bat populations in fewer than 10 years, according to a new study published in Conservation Biology. Researchers also noted declines in Indiana bat and big brown bat populations. The findings, detailed in "The scope and severity of white-nose syndrome on hibernating bats in North America," underscore the devastating impacts of the deadly fungal disease. The research tapped into the most comprehensive data set on North American bat populations to date, which includes data from over 200 locations in 27 states and two Canadian provinces.

Provides a collation of best available research literature, research gaps, and a summary of published researchfor wildland fire and invasive species issues. NISC staff searched Google Scholar, USGS publications warehouse, USDA, FS TreeSearch, and AGRICOLA using keywords “invasive species”, “invasive species and fire”, “invasive species and wildfire” from 2000 to 2024. Most of the existing research explores the relationship between invasive plants, particularly grass species, and wildfire risk, fire regimes, impacts to native plant communities, and loss of wildlife habitats. These are living documents and will be updated on a regular basis.

In California's San Joaquin Valley, scientists from the Agricultural Research Service (ARS) have a sharpshooter, and the pathogen it spreads, in their crosshairs. ARS Scientists in California are devising strategies to combat pests that cause over $100 million in damage to the grape industry.
See also: Down on the Farm archives