How Waste-eating Bacteria Digest Complex Carbons
New information could lead to bacteria-based platforms that recycle plastic and plant waste
A common environmental bacterium, Comamonas testosteroni, could someday become nature’s plastic recycling center. While most bacteria prefer to eat sugars, C. testosteroni, instead, has a natural appetite for complex waste from plants and plastics.
In a new Northwestern Engineering-led study, researchers have, for the first time, deciphered the metabolic mechanisms that enable C. testosteroni to digest the seemingly undigestible. This new information could potentially lead to novel biotechnology platforms that harness the bacteria to help recycle plastic waste.
The research was published February 6 in the journal Nature Chemical Biology.
Comamonas species are found nearly everywhere — including in soils and sewage sludge. C. testosteroni first caught researchers’ attention with its natural ability to digest synthetic laundry detergents. After further analysis, scientists discovered that this natural bacterium also breaks down compounds from plastic and lignin (fibrous, woody waste from plants).
Although other researchers have worked to engineer bacteria that can breakdown plastic waste, the McCormick School of Engineering’s Ludmilla Aristilde believes bacteria with natural abilities to digest plastics hold more promise for large-scale recycling applications
“Soil bacteria provide an untapped, underexplored, naturally occurring resource of biochemical reactions that could be exploited to help us deal with the accumulating waste on our planet,” Aristilde said. “We found that the metabolism of C. testosteroni is regulated on different levels, and those levels are integrated. The power of microbiology is amazing and could play an important role in establishing a circular economy.”
The study was led by Aristilde, an associate professor of civil and environmental engineering at the McCormick School of Engineering, and PhD student Rebecca Wilkes, who is the paper’s first author. The study included collaborators from University of Chicago, Oak Ridge National Laboratory, and Technical University of Denmark.
Kicking sugar
Most projects to engineer bacteria involve Escherichia Coli because it is the most well-studied bacterial model organism. But E. Coli, in its natural state, readily consumes various forms of sugar. As long as sugar is available, E. Coli will consume that — and leave the plastic chemicals behind.
“Engineering bacteria for different purposes is a laborious process,” Aristilde said. “It is important to note that C. testosteroni cannot use sugars, period. It has natural genetic limitations that prevent competition with sugars, making this bacterium an attractive platform.”
What C. testosteroni really wants, though, is a different source of carbon. And materials such as plastic and lignin contain compounds with a ring of tasty carbon atoms. While researchers have known that C. testosteroni can digest these compounds, Aristilde and her team wanted to know how.
“These are carbon compounds with complex bond chemistry,” Aristilde said. “Many bacteria have great difficulty breaking them apart.”
Combining different ‘omics’
To study how C. testosteroni degrades these complex forms of carbon, Aristilde and her team combined multiple forms of “omics”-based analyses: transcriptomics (study of RNA molecules); proteomics (study of proteins); metabolomics (study of metabolites); and fluxomics (study of metabolic reactions). Comprehensive “multi-omics” studies are massive undertakings that require a variety of different techniques. Aristilde leads one of few labs that carries out such comprehensive studies.
It is important to note that C. testosteroni cannot use sugars, period. It has natural genetic limitations that prevent competition with sugars, making this bacterium an attractive platform. Associate Professor of Civil and Environmental Engineering
By examining the relationship among transcriptomics, proteomics, metabolomics, and fluxomics, Aristilde and her team mapped the metabolic pathways that bacteria use to degrade plastic and lignin compounds into carbons for food. Ultimately, the team discovered that the bacteria first break down the ring of carbons in each compound. After breaking open the ring into a linear structure, the bacteria continue to degrade it into shorter fragments.
“We started with a plastic or lignin compound that has seven or eight carbons linked together through a core six-carbon circular shape forming the so-called benzene ring,” Aristilde explained. “Then, they break that apart into shorter chains that have three or four carbons. In the process, the bacteria feed those broken-down products into their natural metabolism, so they can make amino acids or DNA to help them grow.”
Upcycling plastic waste
Aristilde also discovered that C. testosteroni can direct carbon through different metabolic routes. These routes can lead to useful by-products that can be used for industrially relevant polymers such as plastics. Aristilde and her team are currently working on a project investigating the metabolism that triggers this polymer biosynthesis.
“These Comamonas species have the potential to make several polymers relevant to biotechnology,” Aristilde said. “This could lead to new platforms that generate plastic, decreasing our dependence on petroleum chemicals. One of my lab’s major goals is to use renewable resources, such as converting waste into plastic and recycling nutrients from wastes. Then, we won’t have to keep extracting petroleum chemicals to make plastics, for instance.”
The study, “Complex regulation in a Comamonas Platform for Diverse Aromatic Carbon Metabolism,” was supported by the National Science Foundation and the U.S. Department of Energy.