1.  Tracking Agricultural Antibiotic Resistance (AgAR).  Regardless of whether resistance occurs naturally or is the result of human activities, we need to better determine how to mitigate potential health risks from environmental bacteria and genes. This includes gathering information on how they move within food production systems, what conditions encourages them to die or persist in soil, air and water, and how they move between urban and rural environments.  Image from Durso and Cook, 2014.  Impacts of antibiotic use in agriculture: what are the benefits and risks?  Curr Opinion Microbiol 19:37-44. 

2. Profile Naturally Occurring Antibiotic Resistance.  Antibiotic resistant bacteria and their genes are ubiquitous in the environment.  This often goes unnoticed, since most environmental bacteria do not make people sick.  In order to determine the impacts that specific farming or human waste management practices have on environmental resistance, we need to know what kinds and amounts of resistance occurs naturally.  Studies performed at Nine-Mile Prairie in southeast Nebraska, pictured above, help us know what kinds and amounts of antibiotic resistant bacteria and antibiotic resistance genes occur naturally in Nebraskan soils.  Since over 90% of the land in Nebraska is devoted to agricultural production, these native prairie sites give us an important insight into how specific farming practices have impacted soils over time. 

3. Fighting Foodborne Pathogens.  Foodborne pathogens that come from farm animals (zoonotic pathogens) live primarily in two main habitats.  They usually grow in the lower intestines of warm blooded animals (including humans and farm animals).  Once they are excreted from the animal via feces, they must survive or grow in water, soil, and sediment until they find a new host, or they die.  I collect information on how well the pathogens survive in the environment, and how different agronomic practices like buffer strips or manure incorporation influence their survival.  I am also collecting information on how long specific serotypes of Shiga-toxigenic E. coli (STEC) survive in water and soil.  My lab has expertise in finding and isolating STEC from environmental sources, and I work with human public-health labs to help them isolate STEC in outbreaks associated with agricultural events such as fairs and ag-expos. 

4. Uncover Links Between Microbial Community Structure and Soil Organic Carbon Storage.  ARS Scientists and technicians collect deep soil cores from long-term (30-+ year) switchgrass plots.  There is intense interest in the agricultural and biogeochemical communities for high-resolution microbial community data from the soils that support cropping systems and are linked to long-term management data.  This project pairs high resolution taxonomic and functional information on bacterial and fungal communities with our unit’s existing comprehensive collection of soil physical and chemical data.  Additionally, decades of information on agronomic and management outcomes is available for these sample plots, providing valuable phenotyping and metadata that can be leveraged to provide a deep and thorough understanding of the role of microbes in C and N cycling.  There is interest in these outcomes from both basic and applied scientists.