TY - JOUR
KW - Sustainability
KW - Biofuels
KW - Rocket fuel
KW - Polyketide synthase
KW - Polycyclopropanated fatty acid
KW - Methyl esters
KW - POP-FAME
AU - Pablo Cruz-Morales
AU - Kevin Yin
AU - Alexander Landera
AU - John R Cort
AU - Robert P Young
AU - Jennifer E Kyle
AU - Robert Bertrand
AU - Anthony T Iavarone
AU - Suneil Acharya
AU - Aidan Cowan
AU - Yan Chen
AU - Jennifer W Gin
AU - Corinne D Scown
AU - Christopher J Petzold
AU - Carolina Araujo-Barcelos
AU - Eric R Sundstrom
AU - Anthe George
AU - Yuzhong Liu
AU - Sarah Klass
AU - Alberto A Nava
AU - Jay D Keasling
AB - <p>Cyclopropane-functionalized hydrocarbons are excellent fuels due their high&nbsp;<a class="topic-link" title="Learn more about energy density from ScienceDirect's AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/flux-density">energy density</a>. However, the organic synthesis of these molecules is challenging. In this work, we produced polycyclopropanated fatty acids in bacteria. These molecules can be converted into&nbsp;<a class="topic-link" title="Learn more about renewable fuels from ScienceDirect's AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/renewable-fuel">renewable fuels</a>&nbsp;for energy-demanding applications such as shipping, long-haul transport, aviation, and rocketry. We explored the chemical diversity encoded in thousands of bacterial genomes to identify and repurpose naturally occurring cyclopropanated molecules. We identified a set of candidate iterative&nbsp;<a class="topic-link" title="Learn more about polyketide from ScienceDirect's AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/polyketide">polyketide</a>&nbsp;synthases (iPKSs) predicted to produce polycyclopropanated fatty acids (POP-FAs), expressed them in&nbsp;<em>Streptomyces&nbsp;</em><em><a class="topic-link" title="Learn more about coelicolor from ScienceDirect's AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/coelicolor">coelicolor</a></em>, and produced POP-FAs. We determined the structure of the molecules and increased their production 22-fold. Finally, we produced polycyclopropanated&nbsp;<a class="topic-link" title="Learn more about fatty acid methyl esters from ScienceDirect's AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/fatty-acid-methyl-ester">fatty acid methyl esters</a>&nbsp;(POP-FAMEs). Our POP fuel candidates can have net&nbsp;<a class="topic-link" title="Learn more about heating values from ScienceDirect's AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/calorific-value">heating values</a>&nbsp;of more than 50&nbsp;MJ/L. Our research shows that the POP-FAMEs and other POPs have the energetic properties for energy-demanding applications for which sustainable alternatives are scarce.</p>
BT - Joule
DA - 07/2022
DO - 10.1016/j.joule.2022.05.011
IS - 7
LA - eng
N2 - <p>Cyclopropane-functionalized hydrocarbons are excellent fuels due their high&nbsp;<a class="topic-link" title="Learn more about energy density from ScienceDirect's AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/flux-density">energy density</a>. However, the organic synthesis of these molecules is challenging. In this work, we produced polycyclopropanated fatty acids in bacteria. These molecules can be converted into&nbsp;<a class="topic-link" title="Learn more about renewable fuels from ScienceDirect's AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/renewable-fuel">renewable fuels</a>&nbsp;for energy-demanding applications such as shipping, long-haul transport, aviation, and rocketry. We explored the chemical diversity encoded in thousands of bacterial genomes to identify and repurpose naturally occurring cyclopropanated molecules. We identified a set of candidate iterative&nbsp;<a class="topic-link" title="Learn more about polyketide from ScienceDirect's AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/polyketide">polyketide</a>&nbsp;synthases (iPKSs) predicted to produce polycyclopropanated fatty acids (POP-FAs), expressed them in&nbsp;<em>Streptomyces&nbsp;</em><em><a class="topic-link" title="Learn more about coelicolor from ScienceDirect's AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/coelicolor">coelicolor</a></em>, and produced POP-FAs. We determined the structure of the molecules and increased their production 22-fold. Finally, we produced polycyclopropanated&nbsp;<a class="topic-link" title="Learn more about fatty acid methyl esters from ScienceDirect's AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/fatty-acid-methyl-ester">fatty acid methyl esters</a>&nbsp;(POP-FAMEs). Our POP fuel candidates can have net&nbsp;<a class="topic-link" title="Learn more about heating values from ScienceDirect's AI-generated Topic Pages" href="https://www.sciencedirect.com/topics/engineering/calorific-value">heating values</a>&nbsp;of more than 50&nbsp;MJ/L. Our research shows that the POP-FAMEs and other POPs have the energetic properties for energy-demanding applications for which sustainable alternatives are scarce.</p>
PY - 2022
SP - 1590 
EP -  1605
ST - Joule
T2 - Joule
TI - Biosynthesis of polycyclopropanated high energy biofuels
UR - https://linkinghub.elsevier.com/retrieve/pii/S2542435122002380
VL - 6
SN - 25424351
ER -