Like every industry, modern farming relies heavily on plastics. Think plastic mulch lining vegetable beds, PVC pipes draining water from fields, polyethylene covering high tunnels, and plastic seed, fertilizer, and herbicide packaging, to name a few. In a new review article, University of Illinois Urbana-Champaign researchers say these plastics are now widely dispersed in agricultural soils in the form of microplastics and nanoplastics.
That’s not necessarily new; microplastics have been found in nearly every ecosystem and organism on Earth. The twist, according to the College of Agricultural, Consumer and Environmental Sciences (ACES) researchers, is that micro- and nanoplastics in agricultural soil could contribute to antibiotic resistant bacteria with a ready route into our food supply.
“Plastic itself may not be very toxic, but it can act as a vector for transmitting pathogenic and antimicrobial resistant bacteria into the food chain,” said study author Jayashree Nath, postdoctoral researcher in the Department of Food Science and Human Nutrition in ACES. “This phenomenon is not very well known to people, so we wanted to raise awareness.”
If the link between microplastics and antibiotic resistance is less than obvious, here’s how it works. First, plastics are an excellent adsorbent. That means chemical substances and microscopic organisms love to stick to plastic. Chemicals that would ordinarily move through soil quickly — things like pesticides and heavy metals — instead stick around and are concentrated when they encounter plastics. Similarly, bacteria and other microorganisms that occur naturally in soil preferentially congregate on the stable surfaces of microplastics, forming what are known as biofilms.
When bacteria encounter unusual chemical substances in their new home base, they activate stress response genes that incidentally help them resist other chemicals too, including, sometimes, antibiotics. And when groups of bacteria attach to the same surface, they have a habit of sharing these genes through a process called horizontal gene transfer. Nanoplastics, which can enter bacterial cells, present a different kind of stress, but that stress can have the same outcome.
“Bacteria have been evolving genetic mechanisms to cope with stress for millions of years. Plastic is a new material bacteria have never seen in nature, so they are now evoking these genetic tool sets to deal with that stress,” said co-author Pratik Banerjee, associate professor in FSHN and Illinois Extension specialist. “We have also shown bacteria may become more virulent in the presence of plastics, in addition to becoming more resistant to antimicrobials.”
Gene transfer between bacteria on microplastics has been documented in other environments, particularly water. So far, the phenomenon is only hypothetical in agricultural soil, but that doesn’t mean it’s not happening. Nath and Banerjee are currently running laboratory studies to document gene transfer.
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“Soil is an under-researched area in this field,” Banerjee said. “We have an obligation to understand what’s going on in soil, because what we suspect and what we fear is that the situation in soil could be even worse than in water.
“One of the technical problems is that soil is a very difficult medium to handle when it comes to fishing out microplastics. Water is so easy, because you can simply filter the microplastic out,” Banerjee added. “But we have made some good headway thanks to Jayashree and our collaboration with the Illinois Sustainable Technology Center.”
The authors point out many foodborne pathogens make it onto produce from their native home in the soil, but nanoplastics and antibiotic resistant bacteria could be small enough to enter roots and plant tissues — where they are impossible to wash away. While nanoplastics have been documented in and on crops, the field of study is still new and it’s not well known how often this occurs. Banerjee’s research group plans to tackle that question as well.
Ultimately, microplastics are here to stay. After all, they persist in the environment for centuries or longer. The authors say it’s time to understand their impacts in the soil and our food system, raise awareness, and push toward biodegradable plastic alternatives.
The study, “Interaction of microbes with microplastics and nanoplastics in the agroecosystems — impact on antimicrobial resistance,” is published in Pathogens. Authors include Jayashree Nath, Jayita De, Shantanu Sur, and Pratik Banerjee. The research was supported by the National Institute of Food and Agriculture of the USDA.