Arren Bar-Even Explained

Arren Bar-Even
Birth Name:Arren Bar-Even
Birth Date:6 June 1980
Birth Place:Haifa, Israel
Occupation:Biochemist, synthetic biologist
Known For:Research on metabolic engineering, agricultural sustainability
Notable Works:Formate bioeconomy

Arren Bar-Even (6 June 1980 – 18 September 2020) was an Israeli biochemist and synthetic biologist. In his research, Bar-Even made pioneering advances in the design and implementation of novel pathways for improved CO2 fixation.[1] and formate utilisation.[2]

Education and career

Bar-Even was born on 6 June 1980 in Haifa, Israel.[3] He obtained his bachelor's degree in the excellence program from the Faculty of Biology from Technion, the Israeli Institute of Technology in 2002. He then completed his master's degree in Bioinformatics at the Weizmann Institute of Science in 2005. After working as a consultant in the biotech industry for some years, he returned to academia to complete a PhD degree in biochemistry at the Weizmann Institute of Science in 2012. In his work with Ron Milo as his supervisor, he specialized in the design principles of cellular metabolism. From 2015, Bar-Even became junior research group leader of the “Systems and Synthetic Metabolism” lab at the Max Planck Institute of Molecular Plant Physiology.[4]

Research

Already in his PhD at the Weizmann Institute, Bar-Even made advances in metabolic engineering. He extended our basic understanding of the general features of enzymes and metabolic pathways, in a series of insightful meta-analyses of key design principles of metabolism. This deep grasp of the fundamentals of how metabolism operates and evolves was a basis for his advances in metabolic engineering. These included the invention of a multitude of novel pathways for synthetic carbon fixation,[1] formate assimilation,[5] photorespiration bypasses,[6] and significant contributions to the establishment of the predominant CO2 fixation cycle – the Calvin-Benson cycle – in E. coli.[7]

Based on formate, Bar-Even established the idea of a formate bio-economy[8] with the potential to revolutionize food- and feedstock production[9] among other biotechnological sectors for a circular carbon economy. In the formate bio-economy, formate is produced from CO2 physiochemically using renewable energy sources and subsequently fed as sole carbon source to engineered microbes to produce a myriad of products, such as fuels, other value-added chemicals, food and feedstock.

After starting his own lab at the Max Planck Institute of Molecular Plant Physiology, Bar-Even worked among other projects on the biological realisation of the formate bio-economy.[10] This mainly consisted of engineering model organisms (e.g. E. coli, S. cerevisiae, etc.) towards formatotrophic growth – the ability to grow on formate as a sole carbon source. In 2020, this goal was achieved with the demonstration of the first synthetic formatotrophic E. coli cells growing via the reductive glycine pathway,[11] a synthetic pathway designed by Bar-Even and only later found to operate in nature.[12] Notably, the engineered cells could also grow on methanol as sole carbon source, which had been a long-standing goal of synthetic biology.

External links

Notes and References

  1. Bar-Even . Arren . Noor . Elad . Lewis . Nathan E. . Milo . Ron . 2010-05-11 . Design and analysis of synthetic carbon fixation pathways . Proceedings of the National Academy of Sciences . en . 107 . 19 . 8889–8894 . 10.1073/pnas.0907176107 . 0027-8424 . 2889323 . 20410460. 2010PNAS..107.8889B . free .
  2. Bar-Even . Arren . Noor . Elad . Flamholz . Avi . Milo . Ron . 2013-08-01 . Design and analysis of metabolic pathways supporting formatotrophic growth for electricity-dependent cultivation of microbes . Biochimica et Biophysica Acta (BBA) - Bioenergetics . Metals in Bioenergetics and Biomimetics Systems . en . 1827 . 8 . 1039–1047 . 10.1016/j.bbabio.2012.10.013 . 23123556 . 0005-2728. free .
  3. Web site: Arren Bar-Even - 1980-2020 : Arren Bar-Even's Tribute Lifestories . 2023-04-13 . In memory of Arren Bar-Even, 1980 - 2020 . en-GB.
  4. Web site: Arren Bar-Even . 2022-07-09 . www.mpimp-golm.mpg.de . en.
  5. Bar-Even . Arren . 2016-07-05 . Formate Assimilation: The Metabolic Architecture of Natural and Synthetic Pathways . Biochemistry . 55 . 28 . 3851–3863 . 10.1021/acs.biochem.6b00495 . 27348189 . 0006-2960.
  6. Bar-Even . Arren . August 2018 . Daring metabolic designs for enhanced plant carbon fixation . Plant Science . 273 . 71–83 . 10.1016/j.plantsci.2017.12.007 . 29907311 . 49223106 . 0168-9452. free . 2018PlnSc.273...71B .
  7. Gleizer . Shmuel . Ben-Nissan . Roee . Bar-On . Yinon M. . Antonovsky . Niv . Noor . Elad . Zohar . Yehudit . Jona . Ghil . Krieger . Eyal . Shamshoum . Melina . Bar-Even . Arren . Milo . Ron . 2019-11-27 . Conversion of Escherichia coli to Generate All Biomass Carbon from CO2 . Cell . English . 179 . 6 . 1255–1263.e12 . 10.1016/j.cell.2019.11.009 . 0092-8674 . 6904909 . 31778652.
  8. Yishai . Oren . Lindner . Steffen N . Gonzalez de la Cruz . Jorge . Tenenboim . Hezi . Bar-Even . Arren . December 2016 . The formate bio-economy . Current Opinion in Chemical Biology . en . 35 . 1–9 . 10.1016/j.cbpa.2016.07.005. 27459678 .
  9. Web site: 2021-06-21 . Microbes and solar power 'could produce 10 times more food than plants' . 2022-08-03 . The Guardian . en.
  10. Web site: Park . Potsdam Science . 2020-08-28 . Potsdam Science Park Game Changer – "Everything we'll need to make new stuff is CO2 and renewable energy" . 2023-05-24 . Potsdam Science Park . en-US.
  11. Kim . Seohyoung . Lindner . Steffen N. . Aslan . Selçuk . Yishai . Oren . Wenk . Sebastian . Schann . Karin . Bar-Even . Arren . May 2020 . Growth of E. coli on formate and methanol via the reductive glycine pathway . Nature Chemical Biology . en . 16 . 5 . 538–545 . 10.1038/s41589-020-0473-5 . 32042198 . 211074951 . 1552-4469.
  12. Sánchez-Andrea . Irene . Guedes . Iame Alves . Hornung . Bastian . Boeren . Sjef . Lawson . Christopher E. . Sousa . Diana Z. . Bar-Even . Arren . Claassens . Nico J. . Stams . Alfons J. M. . 2020-10-09 . The reductive glycine pathway allows autotrophic growth of Desulfovibrio desulfuricans . Nature Communications . en . 11 . 1 . 5090 . 10.1038/s41467-020-18906-7 . 33037220 . 7547702 . 2020NatCo..11.5090S . 2041-1723.