Raw materials from CO

A synthetic key enzyme enables the conversion of CO₂ into formic acid

Max-Planck-Gesellschaft

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High-throughput devices can dramatically accelerate research. Here, 96 samples are tested at once for the enzymatic conversion of formate to formaldehyde—recognizable by the yellow color change.

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Credit: MPI f. Terrestrial Microbiology/ Franka Eiche

For a carbon-neutral bioeconomy, processes are needed that can efficiently capture CO2 and convert it into valuable products. Formic acid, or more specifically its salt, formate, is considered a promising candidate as it can be produced from CO₂ using renewable electricity. It is also easy to transport, non-toxic and versatile. Research is focusing, among other things, on microorganisms that are 'fed' formic acid made from CO₂ and use it to produce basic chemicals or fuels.

A team led by Maren Nattermann at the Max Planck Institute for Terrestrial Microbiology has developed a synthetic enzyme designed to perform the central conversion step with precision and stability in a single enzymatic process. This builds on previous research in which the team established a fully synthetic formyl phosphate pathway was established in bacteria.

Synthetic metabolic pathway

Until now, only certain bacteria have been able to utilize formic acid. Natural metabolic pathways bypass the intermediate product formaldehyde, which is an important starting point for integrating CO₂ into cellular metabolism. The researchers constructed an artificial bridge in the form of a synthetic formyl phosphate metabolic pathway, which they incorporated into living E. coli bacteria. Cooperation partner Sebastian Wenk (Project leader, University of Groningen) explains: 'Our work showed that a synthetic metabolic pathway for processing formate works in living organisms — a significant step towards developing biotechnologically useful microorganisms that can use formate obtained from CO₂ to produce food, fuels and materials.' The formaldehyde is immediately processed by the cell and does not accumulate.

However, the connection to cellular metabolism must be robust — after all, it is competing with well-established natural metabolism that has evolved over millions of years. Until now, researchers have only been able to develop complex, fragile, multi-step enzymatic cascades that release sensitive intermediate products, such as formyl phosphate or formyl-CoA, which are prone to breaking down or entering undesirable side reactions.  From a biotechnological perspective, the goal is a 'full formate diet' in which bacteria grow exclusively on formic acid, without the need for costly additives.

Tailor-made enzyme

Recently, the group achieved a decisive breakthrough with a tailor-made formate reductase enzyme that can convert formic acid to formaldehyde precisely and robustly. This enzyme, known as FAR (formate reductase), is based on a carboxylic acid reductase (CAR) found in the bacterium Mycobacteroides abscessus. This enzyme was modified through targeted mutagenesis and high-throughput screening to preferentially select small molecules such as formate. "With FAR, we now have a single, robust enzyme that reliably reduces formate to formaldehyde — exactly where many biotechnological pathways begin," explains Nattermann. 'This provides us with a missing building block for future bioconversions based directly on CO₂-based raw materials.'

'The most important thing is that our enzyme tolerates high concentrations of formate, whereas previous systems failed completely under these conditions,' adds Philipp Wichmann, the study's first author. It is precisely this stability that makes FAR attractive for industrial processes in which formate is produced electrochemically in very high concentrations. Without the use of high-throughput methods, this result would not have been achievable in such a short time. ‘After screening around 4,000 variants, we achieved a fivefold increase in formaldehyde production,’ explains Nattermann.

FAR is now an enzyme that can be used in both living cells and cell-free systems, as well as in electrobiochemical production lines. In the future, basic chemicals, bioplastics or fuels could be produced from CO₂-based formate. The researchers are already planning to combine FAR with other synthetic metabolic pathways, for example, to produce energy-rich molecules.

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Journal

ACS Catalysis

Article Title

Engineering a Formic Acid Reductase

Review article | Towards a Global Ground-Based Earth Observatory (GGBEO): Leveraging existing systems and networks

Big Earth Data

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Current and Future States of Observation Systems

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Credit: Big Earth Data

A new peer-reviewed article published in Big Earth Data presents a comprehensive roadmap for building an integrated Global Ground-Based Earth Observatory (GGBEO) to better tackle the escalating planetary environmental and climate crisis. The study argues that unifying existing ground-based, in situ, remote sensing, marine, and airborne observation networks is crucial for meeting the United Nations’ Sustainable Development Goals (SDGs) and for advancing climate science and societal resilience.

Citation
Lappalainen, H. K., Baklanov, A., Bäck, J., Arvanitidis, C., Basart, S., Bernier, N., … Kulmala, M. (2025). Towards a Global Ground-Based Earth Observatory (GGBEO): Leveraging existing systems and networks. Big Earth Data, 1–36. https://doi.org/10.1080/20964471.2025.2574174

Abstract

To tackle the planetary environmental and climate crisis and meet the United Nations’ Sustainable Development Goals (SDGs), we must fully leverage the potential of Earth observations (EO). This involves integrating globally sourced data on the atmosphere, hydrosphere, cryosphere, lithosphere, along with ecological and socio-economic information. By harmonizing and integrating these diverse data sources, we can more effectively incorporate observational data into multi-scale modeling and artificial intelligence (AI) frameworks. This paper is based on discussions from the “Towards Global Earth Observatory” workshop held from May 8–10, 2023, organized by the World Meteorological Organization (WMO) and the Atmosphere and Climate Competence Center (ACCC), in collaboration with the Institute for Atmospheric and Earth System Research (INAR) at the University of Helsinki. The current state of EO and data repositories is fragmented, highlighting the need for a more integrated approach to establish a new global Ground-Based Earth Observatory (GGBEO). Here, we summarize the current status of selected in-situ and ground-based remote sensing observation systems and outline future actions and recommendations to meet scientific, societal, and economic needs. In addition, we identify key steps to create a coordinated and comprehensive GGBEO system that leverages existing investments, networks, and infrastructures. This system would integrate regional and global ground-based in situ and remote sensing systems, marine, and airborne observational data. An integrated approach should aim for seamless coordination, interoperable and harmonized data repositories, easily searchable and accessible data, and sustainable long-term funding.

Keywords

SDGs; PEEX; climate; FAIR; TRUST; geoscience; remotesensing; earthobervation; environment; atmosphere

Big Earth Data is an interdisciplinary Open Access journal which aims to provide an efficient and high-quality platform for promoting the sharing, processing and analyses of Earth-related big data, thereby revolutionizing the cognition of the Earth’s systems. The journal publishes a wide range of content, including Research Articles, Review Articles, Data Notes, Technical Notes, and Perspectives. It is now included in ESCI (IF=3.8, Q1), Scopus (CiteScore=9.0, Q1), Ei Compendex, GEOBASE, and Inspec. Starting from 2023, Big Earth Data has announced a new award series for authors: Best and Outstanding Paper Awards.

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Journal

Big Earth Data

DOI

10.1080/20964471.2025.2583505 

Method of Research

Literature review

Subject of Research

Not applicable

Article Title

Towards a Global Ground-Based Earth Observatory (GGBEO): Leveraging existing systems and networks

Most peer reviewers now use AI, and publishing policy must keep pace

Frontiers

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A new whitepaper from Frontiers shows that AI has rapidly become part of everyday peer review, with 53% of reviewers now using AI tools. The findings in Unlocking AI’s untapped potential: responsible innovation in research and publishing point to a pivotal moment for research publishing. Adoption is accelerating and the opportunity now is to translate this momentum into stronger, more transparent, and more equitable research practices as demonstrated in Frontiers’ policy outlines.

Drawing on insights from 1,645 active researchers worldwide, the whitepaper identifies a global community eager to use AI confidently and responsibly. While many reviewers currently rely on AI for drafting reports or summarizing findings, the report highlights significant untapped potential for AI to support rigor, reproducibility, and deeper methodological insight.

Elena Vicario, Director of Research Integrity at Frontiers, said:

“AI is already improving efficiency and clarity in peer review, but its greatest value lies ahead. With the right governance, transparency, and training, AI can become a powerful partner in strengthening research quality and increasing trust in the scientific record.”

The study shows broad enthusiasm for using AI more effectively, especially among early-career researchers (87% adoption) and in rapidly growing research regions such as China (77%) and Africa (66%). Researchers in all regions see clear benefits, from reducing workload to improving communication, and many express a desire for clear, consistent policy recommendations that would enable more advanced use.

In response, Frontiers has set out a series of evidence-based policy recommendations for publishers, institutions, funders, and tool developers. These include:

• mandating transparency around AI use

• embedding AI literacy and competency training across the research system

• strengthening integrity and oversight standards

• improving data provenance and auditability

• and ensuring equitable access to trustworthy AI tools.

Together, these recommendations provide a practical roadmap for aligning publishing policy with how researchers are already using AI and for unlocking its full potential to strengthen scientific rigor and trust.

Kamila Markram, CEO and Co-founder of Frontiers, said:

“AI is transforming how science is written and reviewed, opening new possibilities for quality, collaboration, and global participation. This whitepaper is a call to action for the whole research ecosystem to embrace that potential. With aligned policies and responsible governance, AI will strengthen the integrity of science and accelerate discovery.”

The report encourages publishers, institutions, and policymakers to collaborate on sector-wide policy development, training pathways, and transparent communication to support responsible and innovative AI use across the research cycle.

About the report

Unlocking AI’s untapped potential: responsible innovation in research and publishing is based on a global survey of 1,645 active researchers, conducted in May and June 2025. It is the first large-scale study to examine AI adoption, trust, training, and governance within authoring, reviewing, and editorial workflows.

Heavy is the head that wears the crown: Study finds dominant baboons miss out on restful nights

Study finds higher-ranking baboons get less and more fragmented rest at night than their lower-ranked troop mates.

Swansea University

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A baboon sitting upright with its eyes closed

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Credit: Nick Dale Photography

Dominant baboons rule the troop by day, but at night, they may pay a hidden cost. A new study led by Swansea University has found that higher-ranking baboons get less and more fragmented rest at night than their lower-ranked troop mates.

In animals that sleep in groups, communal sleeping can offer protection, but – much like in humans –close neighbours can disturb one another, affecting both the quality and quantity of sleep. Despite its importance, this social aspect of sleep has rarely been studied in the wild.

Using GPS and accelerometer collars, researchers tracked the daytime and night-time activity of a troop of chacma baboons in South Africa, a species with a strong hierarchical social structure.

“We expected dominant baboons to get better rest at night, perhaps because they could choose the most comfortable or sheltered spots,” said Swansea University PhD student Marco Fele, lead author of the study. “But we found the opposite – dominant baboons had less and more interrupted rest.”

The team discovered that baboons are in sync at night, with individuals resting and waking together. However, because higher-ranked baboons have more nearby group members, this leads them to exert greater influence on each other’s night-time behaviour compared to lower-ranked individuals – and so dominant baboons are more likely to wake each other up.

The study, published in Current Biology, is the first to find social hierarchies may impact sleep in wild primates. It suggests that daytime leadership and influence may come with a night-time cost.

“Just like in humans, sleep is essential for health and decision-making,” said Professor Andrew King, co-author of the study. “If dominant individuals are resting less at night, it could affect their performance and wellbeing. Equally, it may be that baboons get enough rest overall, so the costs would be minimal. Future work now needs to test the consequences of these night-time disruptions.”

The findings highlight how social bonds and dominance shape both individual and group behaviour, even during periods of rest – insights made possible by advances in tracking technology and data analysis and opening the door to new discoveries about social life in the wild.

 

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A baboon walking at dusk

Credit

Nick Dale Photography

Journal

Current Biology

DOI

10.1016/j.cub.2025.10.028 

Method of Research

Observational study

Subject of Research

Animals

Article Title

Dominant baboons experience more interrupted and less rest at night

Article Publication Date

12-Dec-2025