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06.02.2026 15:40

Taxiing through the Gut: Formic Acid in the Microbiome

Dr. Markus Bernards Public Relations und Kommunikation
Goethe-Universität Frankfurt am Main

Researchers at Goethe University Frankfurt have discovered a surprising role for formic acid in the human gut: The small molecule acts as a kind of “taxi” for electrons – both within bacteria and, likely, also between different microorganisms. The gut bacterium Blautia luti produces formic acid as part of a metabolic trick that allows it to respond flexibly to what is available in the gut. In addition to carbohydrates, the bacterium can also metabolize toxic carbon monoxide derived from the body’s own hemoglobin degradation.

FRANKFURT. Among the many trillions of microorganisms in the human gut is Blautia luti. Like many gut bacteria, it metabolizes indigestible dietary components, such as fiber in the form of carbohydrates. This process produces, among other things, acetic acid (acetate), an important energy source for our intestinal cells and a signaling molecule that can even influence our well-being via the gut-brain axis.

Taxis for electron transport
B. luti lives in the gut without oxygen and cannot respire, but only ferment. During this process, carbohydrates are converted into lactate, succinate, ethanol, carbon dioxide, and hydrogen, which are excreted as metabolic end products. Too much hydrogen in the gut is unhealthy because it inhibits further fermentation. Therefore, small single-celled organisms known as archaea consume the hydrogen, convert it into methane, and thus regulate hydrogen levels in the gut. Hydrogen thus acts, so to speak, as an electron taxi within a bacterium and between different bacteria. However, this process involves a substantial loss of energy and is therefore disadvantageous for the bacteria.

B. luti has an additional, better option. Raphael Trischler and Prof. Volker Müller, Chair of Molecular Microbiology and Bioenergetics at Goethe University Frankfurt, found that B. luti produces formic acid (formate) instead of carbon dioxide (CO₂) and hydrogen, with hydrogen bound to CO₂. In this case, formic acid is the electron taxi, allowing the energetically costly production of hydrogen to be bypassed.

Formic acid as an electron store
To produce formic acid, B. luti uses the enzyme pyruvate formate lyase. This enzyme is rather unusual in acetogenic bacteria. “The electrons are essentially stored in the formic acid,” explains Trischler. However, formic acid is also unhealthy at high concentrations.

B. luti detoxifies formic acid together with CO₂ via a special metabolic pathway, the Wood-Ljungdahl pathway (WLP), converting it into acetate. In the WLP, CO₂ is transformed via two different “branches” and ultimately assembled into acetic acid. In the first branch, CO₂ is normally converted into formic acid by a specific enzyme – formate dehydrogenase – using hydrogen. “But B. luti completely lacks formate dehydrogenase,” explains Raphael Trischler, who studied the bacterium for his doctoral thesis. Instead, B. luti uses formic acid directly. Sugar breakdown on one side and acetic acid production on the other are thus linked via formic acid – a clever strategy that gives the bacterium an energetic advantage.

Useful side effects
In the laboratory culture studied, B. luti excretes formic acid. In the complex food web of the gut, however, the situation is different, and formic acid does not accumulate there. Methane-producing archaea can convert formic acid into methane, but B. luti has another trick up its sleeve. Reducing formic acid in the WLP requires electrons that originate from carbohydrate fermentation. But B. luti can also use gases produced by other bacteria for this purpose. “In the presence of hydrogen, the formic acid disappears completely,” reports Trischler.

Particularly remarkable is B. luti’s ability to utilize carbon monoxide. This highly toxic gas is produced in the human body during the natural breakdown of hemoglobin, the red blood pigment. “Bacteria like B. luti can thus detoxify carbon monoxide produced by the body itself using formic acid,” explains Müller. This also explains why so many gut microbes possess the enzyme carbon monoxide dehydrogenase.

B. luti has yet another property beneficial to humans: In addition to acetate, it produces succinate (succinic acid). Succinate promotes the growth of other beneficial gut bacteria, stimulates the immune system, and is also an industrially valuable raw material for biotechnological applications.

The study highlights how diverse metabolic strategies in the gut are. “Even within related groups of bacteria, there are fascinating differences,” says Müller. “Understanding this helps us better decipher the interactions between different gut bacteria and their role in human well-being.”

Picture download:
https://www.uni-frankfurt.de/183002483


Caption:
1) Interspecies formate transfer. Formate is produced by various bacteria and taken up by B. luti, which converts it into acetate. B. luti can also produce formate itself. Image: Raphael Trischler, Goethe-Universität Frankfurt/AI

2) In the lab: Raphael Trischler (seated) and Volker Müller in the laboratory at an anaerobic chamber. The chamber contains no oxygen but nitrogen, allowing oxygen-sensitive bacteria such as B. luti to be handled safely. Photo: Jennifer Roth, Goethe-Universität Frankfurt

3) Formate as a taxi for electrons. Top: During interspecies formate transfer, B. luti consumes carbohydrates and produces short-chain fatty acids such as lactate, acetate, or succinate, but also formate. The short-chain fatty acids are then absorbed by the intestine. Formate is absorbed by other intestinal microbes and converted into short-chain fatty acids and methane (not shown). Below: During intraspecies formate transfer, B. luti metabolizes the formate with carbon monoxide (CO) or hydrogen (not shown) to produce short-chain fatty acids such as acetate. Short-chain fatty acids contribute to intestinal health. Image: Volker Müller, Goethe-University Frankfurt

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Wissenschaftliche Ansprechpartner:

Professor Volker Müller
Molecular Microbiology and Bioenergetics
Institute for Molecular Biosciences
Goethe University Frankfurt
Tel: +49 (0)69 798-29507
vmueller@bio.uni-frankfurt.de
https://www.mikrobiologie-frankfurt.de/
http://acinetobacter.de

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Originalpublikation:

Raphael Trischler, Volker Müller: Formate as electron carrier in the gut acetogen Blautia luti: a model for electron transfer in the gut microbiome. Gut Microbes (2026) https://doi.org/10.1080/19490976.2025.2609406

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Interspecies formate transfer. Formate is produced by various bacteria and taken up by B. luti, whic ...
Quelle: Raphael Trischler/AI
Copyright: Goethe University Frankfurt

<
In the lab: Raphael Trischler (seated) and Volker Müller in the laboratory at an anaerobic chamber. ...
Quelle: Jennifer Roth
Copyright: Goethe University Frankfurt

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