The Role of Synthetic Biology in Atmospheric Greenhouse Gas Reduction: Prospects and Challenges

Charles DeLisi; Aristides Patrinos; Michael MacCracken; Dan Drell; George Annas; Adam Arkin; George Church; Robert Cook-Deegan; Henry Jacoby; Mary Lidstrom; Jerry Melillo; Ron Milo; Keith Paustian; John Reilly; Richard J. Roberts; Daniel Segrè; Susan Solomon; Dominic Woolf; Stan D. Wullschleger; Xiaohan Yang

doi:10.34133/2020/1016207

The Role of Synthetic Biology in Atmospheric Greenhouse Gas Reduction: Prospects and Challenges

Charles DeLisi, Aristides Patrinos, Michael MacCracken, Dan Drell, George Annas, Adam Arkin, George Church, Robert Cook-Deegan, Henry Jacoby, Mary Lidstrom, Jerry Melillo, Ron Milo, Keith Paustian, John Reilly, Richard J. Roberts, Daniel Segrè, Susan Solomon, Dominic Woolf, Stan D. Wullschleger, Xiaohan Yang

Future of Innovation in Society, School for the (SFIS)

Research output: Contribution to journal › Review article › peer-review

16 Scopus citations

Abstract

The long atmospheric residence time of CO₂ creates an urgent need to add atmospheric carbon drawdown to CO₂ regulatory strategies. Synthetic and systems biology (SSB), which enables manipulation of cellular phenotypes, offers a powerful approach to amplifying and adding new possibilities to current land management practices aimed at reducing atmospheric carbon. The participants (in attendance: Christina Agapakis, George Annas, Adam Arkin, George Church, Robert Cook-Deegan, Charles DeLisi, Dan Drell, Sheldon Glashow, Steve Hamburg, Henry Jacoby, Henry Kelly, Mark Kon, Todd Kuiken, Mary Lidstrom, Mike MacCracken, June Medford, Jerry Melillo, Ron Milo, Pilar Ossorio, Ari Patrinos, Keith Paustian, Kristala Jones Prather, Kent Redford, David Resnik, John Reilly, Richard J. Roberts, Daniel Segre, Susan Solomon, Elizabeth Strychalski, Chris Voigt, Dominic Woolf, Stan Wullschleger, and Xiaohan Yang) identified a range of possibilities by which SSB might help reduce greenhouse gas concentrations and which might also contribute to environmental sustainability and adaptation. These include, among other possibilities, engineering plants to convert CO₂ produced by respiration into a stable carbonate, designing plants with an increased root-to-shoot ratio, and creating plants with the ability to self-fertilize. A number of serious ecological and societal challenges must, however, be confronted and resolved before any such application can be fully assessed, realized, and deployed.

Original language	English (US)
Article number	1016207
Journal	BioDesign Research
Volume	2020
DOIs	https://doi.org/10.34133/2020/1016207
State	Published - 2020

ASJC Scopus subject areas

Biochemistry, Genetics and Molecular Biology (miscellaneous)
Agricultural and Biological Sciences (miscellaneous)
Biotechnology
Cell Biology

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10.34133/2020/1016207

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DeLisi, C., Patrinos, A., MacCracken, M., Drell, D., Annas, G., Arkin, A., Church, G., Cook-Deegan, R., Jacoby, H., Lidstrom, M., Melillo, J., Milo, R., Paustian, K., Reilly, J., Roberts, R. J., Segrè, D., Solomon, S., Woolf, D., Wullschleger, S. D., & Yang, X. (2020). The Role of Synthetic Biology in Atmospheric Greenhouse Gas Reduction: Prospects and Challenges. BioDesign Research, 2020, Article 1016207. https://doi.org/10.34133/2020/1016207

DeLisi, C, Patrinos, A, MacCracken, M, Drell, D, Annas, G, Arkin, A, Church, G, Cook-Deegan, R, Jacoby, H, Lidstrom, M, Melillo, J, Milo, R, Paustian, K, Reilly, J, Roberts, RJ, Segrè, D, Solomon, S, Woolf, D, Wullschleger, SD & Yang, X 2020, 'The Role of Synthetic Biology in Atmospheric Greenhouse Gas Reduction: Prospects and Challenges', BioDesign Research, vol. 2020, 1016207. https://doi.org/10.34133/2020/1016207

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title = "The Role of Synthetic Biology in Atmospheric Greenhouse Gas Reduction: Prospects and Challenges",

abstract = "The long atmospheric residence time of CO2 creates an urgent need to add atmospheric carbon drawdown to CO2 regulatory strategies. Synthetic and systems biology (SSB), which enables manipulation of cellular phenotypes, offers a powerful approach to amplifying and adding new possibilities to current land management practices aimed at reducing atmospheric carbon. The participants (in attendance: Christina Agapakis, George Annas, Adam Arkin, George Church, Robert Cook-Deegan, Charles DeLisi, Dan Drell, Sheldon Glashow, Steve Hamburg, Henry Jacoby, Henry Kelly, Mark Kon, Todd Kuiken, Mary Lidstrom, Mike MacCracken, June Medford, Jerry Melillo, Ron Milo, Pilar Ossorio, Ari Patrinos, Keith Paustian, Kristala Jones Prather, Kent Redford, David Resnik, John Reilly, Richard J. Roberts, Daniel Segre, Susan Solomon, Elizabeth Strychalski, Chris Voigt, Dominic Woolf, Stan Wullschleger, and Xiaohan Yang) identified a range of possibilities by which SSB might help reduce greenhouse gas concentrations and which might also contribute to environmental sustainability and adaptation. These include, among other possibilities, engineering plants to convert CO2 produced by respiration into a stable carbonate, designing plants with an increased root-to-shoot ratio, and creating plants with the ability to self-fertilize. A number of serious ecological and societal challenges must, however, be confronted and resolved before any such application can be fully assessed, realized, and deployed.",

author = "Charles DeLisi and Aristides Patrinos and Michael MacCracken and Dan Drell and George Annas and Adam Arkin and George Church and Robert Cook-Deegan and Henry Jacoby and Mary Lidstrom and Jerry Melillo and Ron Milo and Keith Paustian and John Reilly and Roberts, {Richard J.} and Daniel Segr{\`e} and Susan Solomon and Dominic Woolf and Wullschleger, {Stan D.} and Xiaohan Yang",

note = "Funding Information: The authors thank Drs. Steven Hamburg, Todd Kuiken, June Medford, Kent Redford, and David Resnik for formal presentations and for reading, commenting on, and editing the manuscript; Professors Kristila Prather, Chris Voigt, and Christina Agapakis for presenting their research on biological production of small molecules, self-fertilizing plants, and art and synthetic biology, respectively; and Dr. Elizabeth Strychalski for summarizing the synthetic biology session. The workshop was supported by a grant from the Alfred P. Sloan Foundation, by the Boston University (BU) Program in Bioinformatics and Systems Biology, and by the BU College of Engineering. Publisher Copyright: Copyright {\textcopyright} 2020 Charles DeLisi et al.",

year = "2020",

doi = "10.34133/2020/1016207",

language = "English (US)",

volume = "2020",

journal = "BioDesign Research",

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AU - DeLisi, Charles

AU - Patrinos, Aristides

AU - MacCracken, Michael

AU - Drell, Dan

AU - Annas, George

AU - Arkin, Adam

AU - Church, George

AU - Cook-Deegan, Robert

AU - Jacoby, Henry

AU - Lidstrom, Mary

AU - Melillo, Jerry

AU - Milo, Ron

AU - Paustian, Keith

AU - Reilly, John

AU - Roberts, Richard J.

AU - Segrè, Daniel

AU - Solomon, Susan

AU - Woolf, Dominic

AU - Wullschleger, Stan D.

AU - Yang, Xiaohan

N1 - Funding Information: The authors thank Drs. Steven Hamburg, Todd Kuiken, June Medford, Kent Redford, and David Resnik for formal presentations and for reading, commenting on, and editing the manuscript; Professors Kristila Prather, Chris Voigt, and Christina Agapakis for presenting their research on biological production of small molecules, self-fertilizing plants, and art and synthetic biology, respectively; and Dr. Elizabeth Strychalski for summarizing the synthetic biology session. The workshop was supported by a grant from the Alfred P. Sloan Foundation, by the Boston University (BU) Program in Bioinformatics and Systems Biology, and by the BU College of Engineering. Publisher Copyright: Copyright © 2020 Charles DeLisi et al.

PY - 2020

Y1 - 2020

N2 - The long atmospheric residence time of CO2 creates an urgent need to add atmospheric carbon drawdown to CO2 regulatory strategies. Synthetic and systems biology (SSB), which enables manipulation of cellular phenotypes, offers a powerful approach to amplifying and adding new possibilities to current land management practices aimed at reducing atmospheric carbon. The participants (in attendance: Christina Agapakis, George Annas, Adam Arkin, George Church, Robert Cook-Deegan, Charles DeLisi, Dan Drell, Sheldon Glashow, Steve Hamburg, Henry Jacoby, Henry Kelly, Mark Kon, Todd Kuiken, Mary Lidstrom, Mike MacCracken, June Medford, Jerry Melillo, Ron Milo, Pilar Ossorio, Ari Patrinos, Keith Paustian, Kristala Jones Prather, Kent Redford, David Resnik, John Reilly, Richard J. Roberts, Daniel Segre, Susan Solomon, Elizabeth Strychalski, Chris Voigt, Dominic Woolf, Stan Wullschleger, and Xiaohan Yang) identified a range of possibilities by which SSB might help reduce greenhouse gas concentrations and which might also contribute to environmental sustainability and adaptation. These include, among other possibilities, engineering plants to convert CO2 produced by respiration into a stable carbonate, designing plants with an increased root-to-shoot ratio, and creating plants with the ability to self-fertilize. A number of serious ecological and societal challenges must, however, be confronted and resolved before any such application can be fully assessed, realized, and deployed.

AB - The long atmospheric residence time of CO2 creates an urgent need to add atmospheric carbon drawdown to CO2 regulatory strategies. Synthetic and systems biology (SSB), which enables manipulation of cellular phenotypes, offers a powerful approach to amplifying and adding new possibilities to current land management practices aimed at reducing atmospheric carbon. The participants (in attendance: Christina Agapakis, George Annas, Adam Arkin, George Church, Robert Cook-Deegan, Charles DeLisi, Dan Drell, Sheldon Glashow, Steve Hamburg, Henry Jacoby, Henry Kelly, Mark Kon, Todd Kuiken, Mary Lidstrom, Mike MacCracken, June Medford, Jerry Melillo, Ron Milo, Pilar Ossorio, Ari Patrinos, Keith Paustian, Kristala Jones Prather, Kent Redford, David Resnik, John Reilly, Richard J. Roberts, Daniel Segre, Susan Solomon, Elizabeth Strychalski, Chris Voigt, Dominic Woolf, Stan Wullschleger, and Xiaohan Yang) identified a range of possibilities by which SSB might help reduce greenhouse gas concentrations and which might also contribute to environmental sustainability and adaptation. These include, among other possibilities, engineering plants to convert CO2 produced by respiration into a stable carbonate, designing plants with an increased root-to-shoot ratio, and creating plants with the ability to self-fertilize. A number of serious ecological and societal challenges must, however, be confronted and resolved before any such application can be fully assessed, realized, and deployed.

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The Role of Synthetic Biology in Atmospheric Greenhouse Gas Reduction: Prospects and Challenges

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ASJC Scopus subject areas

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