University Of Delaware: Untapped Potential

Press release from the University of Delaware:

October 29, 2021

New hope for biodegrading plastics may lie in worm microbiome

Fresh hope for new ways to biodegrade plastics may lie in an unusual place … the gut of the yellow mealworm, according to University of Delaware researchers Kevin Solomon and Mark Blenner.

About an inch long and typically taken for fish food or a tasty treat for robins, wrens or woodpeckers, yellow mealworms are the larvae of the mealworm beetle.

The researchers will use a technique called phenoprofiling to search for microbes in the gut that are involved in plastics degradation.

“Basically, we’re baiting a chemical hook with plastic and when the microbes eat the plastic — and the hook — we will have a handle to pull out the microbes using a technique called fluorescence activated self-sorting so that we can study them,” Blenner said, chuckling. “It’s kind of funny, because what do we normally bait hooks with? Worms.”

The tagging technique was developed by the UD team’s collaborators Aaron Wright, a senior scientist, and Andrea Steiger, a chemist, at PNNL. It will help the researchers decode which microbe does what by enabling the team to see proteins, coded in parts of the microbe’s DNA, that are important for a particular aspect of breaking the plastic down.

"By looking at the chemistry of the plastics and the chemical processes required to degrade them, we can design small molecule probes that very selectively tag the proteins that play a role in degradation,” Steiger said. “These tags ‘light up’ the microbes that have those plastic-degrading proteins, and we can isolate and identify them. Not only do we plan to identify the microbes that eat the plastics- but also the biochemical mechanisms by which they do so. This is incredible information that we can use to build up microbial communities to address global challenges."

Microbes talk to each other by exchanging several small molecules, which may or may not be important for coordinating the expression of proteins and enzymes needed to efficiently degrade these materials and for handing off a part of the process to one microbe or another. Better understanding this process will help the research team learn to control and optimize communities of microbes to address various global challenges.

“For the first time, this will let us get a handle on the critical elements and how they must come together … what is the design, so that we can build them for a variety of different scenarios,” said Solomon.

The project will be further advanced via funding through the FICUS program, or Facilities Integrating Collaborations for User Science. Sponsored by BER, FICUS allows access to multiple user facilities, including the Joint Genome Institute and the Environmental Molecular Sciences Laboratory, through a single project proposal.

If successful, Solomon said it’s possible to imagine a world with plastic-degrading compost or specialized microbe mixtures for breaking down plastics in industrial bioreactors. Maybe the work could inform solutions for environmental issues such as microplastics, those pesky last bits of plastic that find their way into the water. For now, though, it’s about trying things out, gathering data and seeing how far they can take it.

In other work, funded through a $569,599 grant from DOE’s Office of Science, Solomon is studying how specific fungi found in the digestive tract of plant-eating ruminants, such as cattle, sheep and giraffes, help their host animals thrive on grasses. Degrading grasses is considered a harder part of breaking down cellulose for biofuels, and the microbes currently used for industrial biofuel production cannot convert plant biomass into its component sugars without prior help from heat and chemicals.

“A cow is not a pressure cooker, but these fungi have effective strategies for breaking through all the chemistry without tools like heat, acids and pressure,” he said.

These same processes can accelerate the conversion of cellulose in agricultural residues for biofuels. Solomon plans to develop genetic tools to identify and manipulate the enzymes that help these microbes do the heavy lifting in breaking apart renewable plant material in the natural world. This goal is to establish design principles to engineer new fungal strains with the capacity to do the job in industry, to help produce sustainable fuels, materials and other value-added compounds.

This press release was produced by the University of Delaware. The views expressed here are the author’s own.