Methane eating microbes could help turn a powerful greenhouse gas into everyday products like animal feed, green plastics, and cleaner fuels, according to a new scientific review of fast moving research on these unusual bacteria. The study highlights how methane consuming communities, known as methanotrophs, are emerging as biological "gatekeepers" that can both curb climate warming emissions and convert waste gases into valuable resources.
"Our work shows that methanotrophs are no longer just a curiosity of environmental microbiology, they are a strategic biological tool for a low carbon future," said lead author Jingrui Deng of Shandong University. "If we can understand and control these microbial communities, we can simultaneously cut greenhouse gases and manufacture useful products from the same processes."
Methane is a potent greenhouse gas with a global warming impact roughly 28 times higher than carbon dioxide over 100 years, yet much of the world's methane still escapes from landfills, farms, mines, and wastewater systems into the air. Methanotrophs naturally thrive in many of these places, including rice paddies, wetlands, lakes, forest soils, and even hot springs, using methane as both their carbon source and their fuel. The review explains that these microbes carry a specialized set of enzymes that oxidize methane step by step into methanol, formaldehyde, formate, and finally carbon dioxide, all under mild, low energy conditions.
Scientists are now learning how to harness these natural abilities at scale. The article describes a wave of new engineering solutions that seed methanotrophs into real world systems, from bio covers placed on landfill surfaces to biofilters that strip methane from exhaust streams at biogas plants and mines. In one example, spraying ultrafine water mists containing methane oxidizing bacteria in mining operations has been shown to reduce methane levels in the air and lower explosion risks. In wastewater treatment, methanotrophs can remove dissolved methane and nitrite at the same time, offering a way to cut both greenhouse gases and water pollutants.
However, the climate story is not simple. The authors point out that methane removal by these microbes can sometimes be accompanied by emissions of nitrous oxide, another greenhouse gas with an even higher warming impact than methane. Some methanotrophs compete with denitrifying bacteria for key metals, which can unintentionally boost nitrous oxide release, while other newly discovered strains are able to fully reduce nitrate to harmless nitrogen gas without producing nitrous oxide at all. "Designing future systems means choosing the right microbial partners so that we reduce both methane and nitrous oxide rather than trading one gas for another," Deng said.
Beyond emissions control, the review emphasizes the growing potential to use methanotrophs as miniature cell factories. By steering carbon through different metabolic routes, these microbes can produce a range of higher value products, including methanol, single cell protein used as animal feed, and biodegradable polyhydroxyalkanoate plastics. Early pilot systems have shown that immobilizing methanotrophs on materials such as coconut coir, ion exchange resins, or modified chitosan can boost methanol yields many times over, especially when methane is blended with carbon dioxide or hydrogen. Other mixed cultures convert biogas into microbial protein rich in essential amino acids, opening a pathway to turn waste gas into feed ingredients.
Biodegradable plastics represent another promising application. Certain methanotrophs are able to store carbon as internal polyester like granules that can later be recovered and processed into materials similar in performance to conventional plastics. Under optimized conditions, communities dominated by type II methanotrophs such as Methylocystis can accumulate more than half of their cell mass as these polymers, particularly when methane rich gas is supplied under carefully controlled nutrient limitation.
To unlock the full promise of these systems, the authors say, researchers must learn to tune the "wiring" of methanotroph metabolism. For methanol production, that means partially slowing down the enzymes that normally push methanol toward complete oxidation, while still supplying enough energy for cells to function. For single cell protein, it requires keeping nitrogen levels and gas ratios in a range that favors fast growth rather than storage compounds. For bioplastics, it involves selecting communities and operating conditions that push carbon into polymer storage during key growth stages.
The review also highlights a suite of cutting edge tools that are accelerating progress, from high throughput Raman activated cell sorting that can pull out top performing strains from complex environmental samples to synthetic biology approaches that delete or re route specific metabolic steps. These advances are helping scientists move from simply observing methane consuming communities in nature to actively designing microbial consortia for targeted climate and manufacturing goals.
"Looking ahead, methanotrophs sit at the crossroads of climate mitigation, waste management, and green manufacturing," said senior author Qigui Niu. "By integrating strain engineering, smart bioreactor design, and rigorous life cycle assessment, we can turn methane from a liability into a cornerstone of sustainable biomanufacturing." The authors argue that such integrated, biology driven approaches will be essential if the world is to scale negative carbon technologies and move closer to long term carbon neutrality.
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Journal reference: Deng J, Qiao J, Ye S, Lin F, Li YY, et al. 2026. Advances in high-value resource recovery of greenhouse gases driven by methanotrophic communities. Energy & Environment Nexus 2: e002 doi: 10.48130/een-0025-0018
https://www.maxapress.com/article/doi/10.48130/een-0025-0018
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About Energy & Environment Nexus :
Energy & Environment Nexus (e-ISSN 3070-0582) is an open-access journal publishing high-quality research on the interplay between energy systems and environmental sustainability, including renewable energy, carbon mitigation, and green technologies.
