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Optimizing the strain engineering process for industrial-scale production of bio-based molecules
Biomanufacturing could contribute as much as [Formula: see text] 30 trillion to the global economy by 2030. However, the success of the growing bioeconomy depends on our ability to manufacture high-performing strains in a time- and cost-effective manner. The Design–Build–Test–Learn (DBTL) framework...
| Autores principales: | , , , , , , , , , , , , , , , , , , , , , , , , , |
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| Formato: | Online Artículo Texto |
| Lenguaje: | English |
| Publicado: |
Oxford University Press
2023
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| Materias: | |
| Acceso en línea: | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10548853/ https://www.ncbi.nlm.nih.gov/pubmed/37656881 http://dx.doi.org/10.1093/jimb/kuad025 |
| _version_ | 1785115364959453184 |
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| author | Abbate, Eric Andrion, Jennifer Apel, Amanda Biggs, Matthew Chaves, Julie Cheung, Kristi Ciesla, Anthony Clark-ElSayed, Alia Clay, Michael Contridas, Riarose Fox, Richard Hein, Glenn Held, Dan Horwitz, Andrew Jenkins, Stefan Kalbarczyk, Karolina Krishnamurthy, Nandini Mirsiaghi, Mona Noon, Katherine Rowe, Mike Shepherd, Tyson Tarasava, Katia Tarasow, Theodore M Thacker, Drew Villa, Gladys Yerramsetty, Krishna |
| author_facet | Abbate, Eric Andrion, Jennifer Apel, Amanda Biggs, Matthew Chaves, Julie Cheung, Kristi Ciesla, Anthony Clark-ElSayed, Alia Clay, Michael Contridas, Riarose Fox, Richard Hein, Glenn Held, Dan Horwitz, Andrew Jenkins, Stefan Kalbarczyk, Karolina Krishnamurthy, Nandini Mirsiaghi, Mona Noon, Katherine Rowe, Mike Shepherd, Tyson Tarasava, Katia Tarasow, Theodore M Thacker, Drew Villa, Gladys Yerramsetty, Krishna |
| author_sort | Abbate, Eric |
| collection | PubMed |
| description | Biomanufacturing could contribute as much as [Formula: see text] 30 trillion to the global economy by 2030. However, the success of the growing bioeconomy depends on our ability to manufacture high-performing strains in a time- and cost-effective manner. The Design–Build–Test–Learn (DBTL) framework has proven to be an effective strain engineering approach. Significant improvements have been made in genome engineering, genotyping, and phenotyping throughput over the last couple of decades that have greatly accelerated the DBTL cycles. However, to achieve a radical reduction in strain development time and cost, we need to look at the strain engineering process through a lens of optimizing the whole cycle, as opposed to simply increasing throughput at each stage. We propose an approach that integrates all 4 stages of the DBTL cycle and takes advantage of the advances in computational design, high-throughput genome engineering, and phenotyping methods, as well as machine learning tools for making predictions about strain scale-up performance. In this perspective, we discuss the challenges of industrial strain engineering, outline the best approaches to overcoming these challenges, and showcase examples of successful strain engineering projects for production of heterologous proteins, amino acids, and small molecules, as well as improving tolerance, fitness, and de-risking the scale-up of industrial strains. |
| format | Online Article Text |
| id | pubmed-10548853 |
| institution | National Center for Biotechnology Information |
| language | English |
| publishDate | 2023 |
| publisher | Oxford University Press |
| record_format | MEDLINE/PubMed |
| spelling | pubmed-105488532023-10-05 Optimizing the strain engineering process for industrial-scale production of bio-based molecules Abbate, Eric Andrion, Jennifer Apel, Amanda Biggs, Matthew Chaves, Julie Cheung, Kristi Ciesla, Anthony Clark-ElSayed, Alia Clay, Michael Contridas, Riarose Fox, Richard Hein, Glenn Held, Dan Horwitz, Andrew Jenkins, Stefan Kalbarczyk, Karolina Krishnamurthy, Nandini Mirsiaghi, Mona Noon, Katherine Rowe, Mike Shepherd, Tyson Tarasava, Katia Tarasow, Theodore M Thacker, Drew Villa, Gladys Yerramsetty, Krishna J Ind Microbiol Biotechnol Metabolic Engineering and Synthetic Biology Biomanufacturing could contribute as much as [Formula: see text] 30 trillion to the global economy by 2030. However, the success of the growing bioeconomy depends on our ability to manufacture high-performing strains in a time- and cost-effective manner. The Design–Build–Test–Learn (DBTL) framework has proven to be an effective strain engineering approach. Significant improvements have been made in genome engineering, genotyping, and phenotyping throughput over the last couple of decades that have greatly accelerated the DBTL cycles. However, to achieve a radical reduction in strain development time and cost, we need to look at the strain engineering process through a lens of optimizing the whole cycle, as opposed to simply increasing throughput at each stage. We propose an approach that integrates all 4 stages of the DBTL cycle and takes advantage of the advances in computational design, high-throughput genome engineering, and phenotyping methods, as well as machine learning tools for making predictions about strain scale-up performance. In this perspective, we discuss the challenges of industrial strain engineering, outline the best approaches to overcoming these challenges, and showcase examples of successful strain engineering projects for production of heterologous proteins, amino acids, and small molecules, as well as improving tolerance, fitness, and de-risking the scale-up of industrial strains. Oxford University Press 2023-09-01 /pmc/articles/PMC10548853/ /pubmed/37656881 http://dx.doi.org/10.1093/jimb/kuad025 Text en © The Author(s) 2023. Published by Oxford University Press on behalf of Society of Industrial Microbiology and Biotechnology. https://creativecommons.org/licenses/by/4.0/This is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited. |
| spellingShingle | Metabolic Engineering and Synthetic Biology Abbate, Eric Andrion, Jennifer Apel, Amanda Biggs, Matthew Chaves, Julie Cheung, Kristi Ciesla, Anthony Clark-ElSayed, Alia Clay, Michael Contridas, Riarose Fox, Richard Hein, Glenn Held, Dan Horwitz, Andrew Jenkins, Stefan Kalbarczyk, Karolina Krishnamurthy, Nandini Mirsiaghi, Mona Noon, Katherine Rowe, Mike Shepherd, Tyson Tarasava, Katia Tarasow, Theodore M Thacker, Drew Villa, Gladys Yerramsetty, Krishna Optimizing the strain engineering process for industrial-scale production of bio-based molecules |
| title | Optimizing the strain engineering process for industrial-scale production of bio-based molecules |
| title_full | Optimizing the strain engineering process for industrial-scale production of bio-based molecules |
| title_fullStr | Optimizing the strain engineering process for industrial-scale production of bio-based molecules |
| title_full_unstemmed | Optimizing the strain engineering process for industrial-scale production of bio-based molecules |
| title_short | Optimizing the strain engineering process for industrial-scale production of bio-based molecules |
| title_sort | optimizing the strain engineering process for industrial-scale production of bio-based molecules |
| topic | Metabolic Engineering and Synthetic Biology |
| url | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10548853/ https://www.ncbi.nlm.nih.gov/pubmed/37656881 http://dx.doi.org/10.1093/jimb/kuad025 |
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