Researcher Portfolio

 
   

Bar-Even, A.

External Organizations, Systems and Synthetic Metabolism, Max Planck Research Groups, Max Planck Institute of Molecular Plant Physiology, Max Planck Society  

 

Researcher Profile

 
Position: Systems and Synthetic Metabolism, Max Planck Research Groups, Max Planck Institute of Molecular Plant Physiology, Max Planck Society
Position: External Organizations
Additional IDs: ORCID: https://orcid.org/0000-0002-1039-4328
Researcher ID: https://pure.mpg.de/cone/persons/resource/persons132110

External references

 
WorldCat Search for Bar-Even, A.
Google Scholar Search for Bar-Even, A.

Publications

 
  (1 - 25 of 93)
 : Wenk, S., Rainaldi, V., Schann, K., He, H., Bouzon, M., Döring, V., Lindner, S. N., & Bar-Even, A. (2025). Evolution-assisted engineering of E. coli enables growth on formic acid at ambient CO2 via the Serine Threonine Cycle. Metabolic Engineering, 88, 14-24. doi:10.1016/j.ymben.2024.10.007. [PubMan] : Dronsella, B., Orsi, E., Schulz-Mirbach, H., Benito-Vaquerizo, S., Yilmaz, S., Glatter, T., Bar-Even, A., Erb, T. J., & Claassens, N. J. (2025). One-carbon fixation via the synthetic reductive glycine pathway exceeds yield of the Calvin cycle. Nature Microbiology, 10, 646-653. doi:10.1038/s41564-025-01941-9. [PubMan] : Wenk, S., Rainaldi, V., Schann, K., He, H., Bouzon, M., Döring, V., Lindner, S. N., & Bar-Even, A. (2025). Evolution-assisted engineering of E. coli enables growth on formic acid at ambient CO2 via the Serine Threonine Cycle. Metabolic Engineering, 88, 14-24. doi:10.1016/j.ymben.2024.10.007. [PubMan] : Orsi, E., Schulz-Mirbach, H., Cotton, C. A. R., Satanowski, A., Petri, H. M., Arnold, S. L., Grabarczyk, N., Verbakel, R., Jensen, K. S., Donati, S., Paczia, N., Glatter, T., Küffner, A. M., Chotel, T., Schillmüller, F., De Maria, A., He, H., Lindner, S. N., Noor, E., Bar-Even, A., Erb, T. J., & Nikel, P. I. (2025). Computation-aided designs enable developing auxotrophic metabolic sensors for wide-range glyoxylate and glycolate detection. Nature Communications, 16(1): 2168. doi:10.1038/s41467-025-57407-3. [PubMan] : Schann, K., Bakker, J., Boinot, M., Kuschel, P., He, H., Nattermann, M., Paczia, N., Erb, T., Bar-Even, A., & Wenk, S. (2024). Design, construction and optimization of formaldehyde growth biosensors with broad application in biotechnology. Microbial Biotechnology, 17(7): e14527. doi:10.1111/1751-7915.14527. [PubMan] : Schulz-Mirbach, H. A. M., Kruesemann, J. L., Andreadaki, T., Nerlich, J. N., Mavrothalassiti, E., Boecker, S., Schneider, P., Weresow, M., Abdelwahab, O., Paczia, N., Dronsella, B., Erb, T. J., Bar-Even, A., Klamt, S., & Lindner, S. N. (2024). Engineering new-to-nature biochemical conversions by combining fermentative metabolism with respiratory modules. Nature Communications, 15(1): 6725. doi:10.1038/s41467-024-51029-x. [PubMan] : Bysani, V. R., Alam, A. S., Bar-Even, A., & Machens, F. (2023). Engineering and evolution of the complete Reductive Glycine Pathway in Saccharomyces cerevisiae for formate and CO2 assimilation. Metabolic Engineering, 81, 167-181. doi:10.1016/j.ymben.2023.11.007. [PubMan] : Schada v. Borzyskowsi, L., Schulz-Mirbach, H., Troncoso Castellanos, M., Severi, F., Gomez Coronado, P. A., Paczia, N., Glatter, T., Bar-Even, A., Lindner, S. N., & Erb, T. J. (2023). Implementation of the β-hydroxyaspartate cycle increases growth performance of Pseudomonas putida on the PET monomer ethylene glycol. Metabolic Engineering, 76, 97-109. doi:10.1016/j.ymben.2023.01.011. [PubMan] : Schada von Borzyskowski, L., Schulz-Mirbach, H., Troncoso Castellanos, M., Severi, F., Gomez Coronado, P. A., Paczia, N., Glatter, T., Bar-Even, A., Lindner, S. N., & Erb, T. (2023). Implementation of the β-hydroxyaspartate cycle increases growth performance of Pseudomonas putida on the PET monomer ethylene glycol. Metabolic Engineering, 76, 97-109. doi:10.1016/j.ymben.2023.01.011. [PubMan] : Kim, S., Giraldo, N., Rainaldi, V., Machens, F., Collas, F., Kubis, A., Kensy, F., Bar-Even, A., & Lindner, S. N. (2023). Optimizing E. coli as a formatotrophic platform for bioproduction via the reductive glycine pathway. Frontiers in Bioengineering and Biotechnology, 11: 1091899. doi:10.3389/fbioe.2023.1091899. [PubMan] : Wu, T., Gomez Coronado, P. A., Kubis, A., Lindner, S. N., Marlière, P., Erb, T., Bar-Even, A., & He, H. (2023). Engineering a synthetic energy-efficient formaldehyde assimilation cycle in Escherichia coli. Nature Communications, 14: 8490. doi:10.1038/s41467-023-44247-2. [PubMan] : Schulz-Mirbach, H., Mueller, A., Wu, T., Pfister, P., Aslan, S., Schada von Borzyskowski, L., Erb, T., Bar-Even, A., & Lindner, S. N. (2022). On the flexibility of the cellular amination network in E. coli. eLife, 11: e77492. doi:10.7554/eLife.77492. [PubMan] : Iacometti, C., Marx, K., Hönick, M., Biletskaia, V., Schulz-Mirbach, H., Dronsella, B., Satanowski, A., Delmas, V., Berger, A., Dubois, I., Bouzon, M., Döring, V., Noor, E., Bar-Even, A., & Lindner, S. N. (2022). Activating Silent Glycolysis Bypasses in Escherichia coli. BioDesign Research, 2022: 9859643. doi:10.34133/2022/9859643. [PubMan] : Kirst, H., Ferlez, B., Lindner, S. N., Cotton, C. A. R., Bar-Even, A., & Kerfeld, C. (2022). Toward a glycyl radical enzyme containing synthetic bacterial microcompartment to produce pyruvate from formate and acetate. Proceedings of the National Academy of Sciences of the United States of America, 119(8): e2116871119. doi:10.1073/pnas.2116871119. [PubMan] : Bouzon, M., Döring, V., Dubois, I., Berger, A., Stoffel, G., Ramirez, L. C., Meyer, S., Fouré, M., Roche, D., Perret, A., Erb, T., Bar-Even, A., & Lindner, S. N. (2021). Change in cofactor specificity of oxidoreductases by adaptive evolution of an escherichia coli nadph-auxotrophic strain. mBio, 12(4): e00329-21. doi:10.1128/mBio.00329-21. [PubMan] : Scheffen, M., Marchal, D. G., Beneyton, T., Schuller, S., Klose, M., Diehl, C., Lehmann, J., Pfister, P., Carillo, M., He, H., Aslan, S., Cortina, N. S., Claus, P., Bollschweiler, D., Baret, J.-C., Schuller, J., Zarzycki, J., Bar-Even, A., & Erb, T. J. (2021). A new-to-nature carboxylation module to improve natural and synthetic CO2 fixation. Nature Catalysis, 4, 105-115. doi:10.1038/s41929-020-00557-y. [PubMan] : Leger, D., Matassa, S., Noor, E., Shepon, A., Milo, R., & Bar-Even, A. (2021). Photovoltaic-driven microbial protein production can use land and sunlight more efficiently than conventional crops. Proceedings of the National Academy of Sciences of the United States of America, 118(26): e2015025118. doi:10.1073/pnas.2015025118. [PubMan] : Scheffen, M., Marchal, D., Beneyton, T., Schuller, S., Klose, M., Diehl, C., Lehmann, J., Pfister, P., Carrillo, M., He, H., Aslan, S., Cortina, N., Claus, P., Bollschweiler, D., Baret, J.-C., Schuller, J., Zarzycki, J., Bar-Even, A., & Erb, T. (2021). A new-to-nature carboxylation module to improve natural and synthetic CO2 fixation. Nature Catalysis, 4, 105-115. doi:10.1038/s41929-020-00557-y. [PubMan] : Satanowski, A., Dronsella, B., Noor, E., Vögeli, B., He, H., Wichmann, P., Erb, T. J., Lindner, S. N., & Bar-Even, A. (2020). Awakening a latent carbon fixation cycle in Escherichia coli. NATURE COMMUNICATIONS, 11(1): 5812. doi:10.1038/s41467-020-19564-5. [PubMan] : Cotton, C. A. R., Bernhardsgrütter, I., He, H., Burgener, S., Schulz, L., Paczia, N., Dronsella, B., Erban, A., Toman, S., Dempfle, M., De Maria, A., Kopka, J., Lindner, S. N., Erb, T. J., & Bar-Even, A. (2020). Underground isoleucine biosynthesis pathways in E. coli. ELIFE, 9: e54207. doi:10.7554/eLife.54207. [PubMan] : Cotton, C. A. R., Bernhardsgrütter, I., He, H., Burgener, S., Schulz, L., Paczia, N., Dronsella, B., Erban, A., Toman, S., Dempfle, M., de Maria, A., Kopka, J., Lindner, S. N., Erb, T. J., & Bar-Even, A. (2020). Underground isoleucine biosynthesis pathways in E. coli. eLife, 9: e54207. doi:10.7554/eLife.54207. [PubMan] : Ramirez, L. C., Calvo Tusell, C., Stoffel, G. M. M., Lindner, S. N., Osuna, S., Erb, T. J., Garcia-Borràs, M., Bar-Even, A., & Acevedo-Rocha, C. G. (2020). In vivo selection for formate dehydrogenases with high efficiency and specificity towards NADP+. ACS Catalysis, 10, 7512-7525. doi:10.1021/acscatal.0c01487. [PubMan] : Claassens, N. J., Bordanaba-Florit, G., Cotton, C. A. R., de Maria, A., Finger-Bou, M., Friedeheim, L., Giner-Laguarda, N., Munar-Palmer, M., Newell, W., Scarinci, G., Verbunt, J., de Vries, S., Yilmaz, S., & Bar-Even, A. (2020). Replacing the Calvin cycle with the reductive glycine pathway in Cupriavidus necator. Metabolic Engineering, 62, 30-41. doi:10.1016/j.ymben.2020.08.004. [PubMan] : Flamholz, A., Dugan, E., Blikstad, C., Gleizer, S., Ben-Nissan, R., Amram, S., Antonovsky, N., Ravishankar, S., Noor, E., Bar-Even, A., Milo, R., & Savage, D. (2020). Functional reconstitution of a bacterial co2 concentrating mechanism in E. coli. eLife, 9: e59882, pp. 1-57. doi:10.7554/eLife.59882. [PubMan] : Kim, S., Lindner, S. N., Aslan, S., Yishai, O., Wenk, S., Schann, K., & Bar-Even, A. (2020). Growth of E. coli on formate and methanol via the reductive glycine pathway. Nature Chemical Biology, 16(5), 538-545. doi:10.1038/s41589-020-0473-5. [PubMan]