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1. Genome-scale and pathway engineering for the sustainable aviation fuel precursor isoprenol production in Pseudomonas putida

Author

Banerjee, Deepanwita, Yunus, Ian S, Wang, Xi, Kim, Jinho, Srinivasan, Aparajitha, Menchavez, Russel, Chen, Yan, Gin, Jennifer W, Petzold, Christopher J, Martin, Hector Garcia, Magnuson, Jon K, Adams, Paul D, Simmons, Blake A, Mukhopadhyay, Aindrila, Kim, Joonhoon, and Lee, Taek Soon

Subjects
Biological Sciences, Industrial Biotechnology, Bioengineering, Responsible Consumption and Production, Affordable and Clean Energy, Pseudomonas putida, Carbon, Metabolic Engineering, Sustainable aviation fuel, Isoprenol, Genome-scale metabolic model, Constrained minimal cut sets, OptKnock, Biotechnology, Biochemistry and cell biology, Industrial biotechnology
Abstract

Sustainable aviation fuel (SAF) will significantly impact global warming in the aviation sector, and important SAF targets are emerging. Isoprenol is a precursor for a promising SAF compound DMCO (1,4-dimethylcyclooctane) and has been produced in several engineered microorganisms. Recently, Pseudomonas putida has gained interest as a future host for isoprenol bioproduction as it can utilize carbon sources from inexpensive plant biomass. Here, we engineer metabolically versatile host P. putida for isoprenol production. We employ two computational modeling approaches (Bilevel optimization and Constrained Minimal Cut Sets) to predict gene knockout targets and optimize the "IPP-bypass" pathway in P. putida to maximize isoprenol production. Altogether, the highest isoprenol production titer from P. putida was achieved at 3.5 g/L under fed-batch conditions. This combination of computational modeling and strain engineering on P. putida for an advanced biofuels production has vital significance in enabling a bioproduction process that can use renewable carbon streams.

Published
2024

2. A miniaturized feedstocks-to-fuels pipeline for screening the efficiency of deconstruction and microbial conversion of lignocellulosic biomass

Author

Pidatala, Venkataramana R, Lei, Mengziang, Choudhary, Hemant, Petzold, Christopher J, Martin, Hector Garcia, Simmons, Blake A, Gladden, John M, and Rodriguez, Alberto

Subjects
Biological Sciences, Industrial Biotechnology, Affordable and Clean Energy, Lignin, Biomass, Biofuels, Sorghum, Ionic Liquids, General Science & Technology
Abstract

Sustainably grown biomass is a promising alternative to produce fuels and chemicals and reduce the dependency on fossil energy sources. However, the efficient conversion of lignocellulosic biomass into biofuels and bioproducts often requires extensive testing of components and reaction conditions used in the pretreatment, saccharification, and bioconversion steps. This restriction can result in a significant and unwieldy number of combinations of biomass types, solvents, microbial strains, and operational parameters that need to be characterized, turning these efforts into a daunting and time-consuming task. Here we developed a high-throughput feedstocks-to-fuels screening platform to address these challenges. The result is a miniaturized semi-automated platform that leverages the capabilities of a solid handling robot, a liquid handling robot, analytical instruments, and a centralized data repository, adapted to operate as an ionic-liquid-based biomass conversion pipeline. The pipeline was tested by using sorghum as feedstock, the biocompatible ionic liquid cholinium phosphate as pretreatment solvent, a "one-pot" process configuration that does not require ionic liquid removal after pretreatment, and an engineered strain of the yeast Rhodosporidium toruloides that produces the jet-fuel precursor bisabolene as a conversion microbe. By the simultaneous processing of 48 samples, we show that this configuration and reaction conditions result in sugar yields (~70%) and bisabolene titers (~1500 mg/L) that are comparable to the efficiencies observed at larger scales but require only a fraction of the time. We expect that this Feedstocks-to-Fuels pipeline will become an effective tool to screen thousands of bioenergy crop and feedstock samples and assist process optimization efforts and the development of predictive deconstruction approaches.

Published
2024

3. Guide RNA structure design enables combinatorial CRISPRa programs for biosynthetic profiling

Author

Fontana, Jason, Sparkman-Yager, David, Faulkner, Ian, Cardiff, Ryan, Kiattisewee, Cholpisit, Walls, Aria, Primo, Tommy G, Kinnunen, Patrick C, Garcia Martin, Hector, Zalatan, Jesse G, and Carothers, James M

Subjects
Biological Sciences, Bioinformatics and Computational Biology, Industrial Biotechnology, Genetics, Biotechnology, 1.1 Normal biological development and functioning, Infection, Escherichia coli, RNA, Guide, CRISPR-Cas Systems, CRISPR-Cas Systems, Metabolic Engineering, Biosynthetic Pathways, Promoter Regions, Genetic, Humans, Gene Expression Regulation, Bacterial, RNA Folding
Abstract

Engineering metabolism to efficiently produce chemicals from multi-step pathways requires optimizing multi-gene expression programs to achieve enzyme balance. CRISPR-Cas transcriptional control systems are emerging as important tools for programming multi-gene expression, but poor predictability of guide RNA folding can disrupt expression control. Here, we correlate efficacy of modified guide RNAs (scRNAs) for CRISPR activation (CRISPRa) in E. coli with a computational kinetic parameter describing scRNA folding rate into the active structure (rS = 0.8). This parameter also enables forward design of scRNAs, allowing us to design a system of three synthetic CRISPRa promoters that can orthogonally activate (>35-fold) expression of chosen outputs. Through combinatorial activation tuning, we profile a three-dimensional design space expressing two different biosynthetic pathways, demonstrating variable production of pteridine and human milk oligosaccharide products. This RNA design approach aids combinatorial optimization of metabolic pathways and may accelerate routine design of effective multi-gene regulation programs in bacterial hosts.

Published
2024

4. Perspectives for self-driving labs in synthetic biology

Author

Martin, Hector Garcia, Radivojevic, Tijana, Zucker, Jeremy, Bouchard, Kristofer, Sustarich, Jess, Peisert, Sean, Arnold, Dan, Hillson, Nathan, Babnigg, Gyorgy, Marti, Jose Manuel, Mungall, Christopher J., Beckham, Gregg T., Waldburger, Lucas, Carothers, James, Sundaram, ShivShankar, Agarwal, Deb, Simmons, Blake A., Backman, Tyler, Banerjee, Deepanwita, Tanjore, Deepti, Ramakrishnan, Lavanya, and Singh, Anup

Subjects
Quantitative Biology - Other Quantitative Biology
Abstract

Self-driving labs (SDLs) combine fully automated experiments with artificial intelligence (AI) that decides the next set of experiments. Taken to their ultimate expression, SDLs could usher a new paradigm of scientific research, where the world is probed, interpreted, and explained by machines for human benefit. While there are functioning SDLs in the fields of chemistry and materials science, we contend that synthetic biology provides a unique opportunity since the genome provides a single target for affecting the incredibly wide repertoire of biological cell behavior. However, the level of investment required for the creation of biological SDLs is only warranted if directed towards solving difficult and enabling biological questions. Here, we discuss challenges and opportunities in creating SDLs for synthetic biology., Comment: 17 pages, 3 figures. Submitted for publication in Current Opinion in Biotechnology. Updated figure 3 in this version

Published
2022

5. Perspectives for self-driving labs in synthetic biology

Author

Martin, Hector G, Radivojevic, Tijana, Zucker, Jeremy, Bouchard, Kristofer, Sustarich, Jess, Peisert, Sean, Arnold, Dan, Hillson, Nathan, Babnigg, Gyorgy, Marti, Jose M, Mungall, Christopher J, Beckham, Gregg T, Waldburger, Lucas, Carothers, James, Sundaram, ShivShankar, Agarwal, Deb, Simmons, Blake A, Backman, Tyler, Banerjee, Deepanwita, Tanjore, Deepti, Ramakrishnan, Lavanya, and Singh, Anup

Subjects
Biochemistry and Cell Biology, Biological Sciences, Bioengineering, Genetics, Biotechnology, Human Genome, Humans, Artificial Intelligence, Synthetic Biology, q-bio.OT, Engineering, Technology, Agricultural biotechnology, Industrial biotechnology, Medical biotechnology
Abstract

Self-driving labs (SDLs) combine fully automated experiments with artificial intelligence (AI) that decides the next set of experiments. Taken to their ultimate expression, SDLs could usher a new paradigm of scientific research, where the world is probed, interpreted, and explained by machines for human benefit. While there are functioning SDLs in the fields of chemistry and materials science, we contend that synthetic biology provides a unique opportunity since the genome provides a single target for affecting the incredibly wide repertoire of biological cell behavior. However, the level of investment required for the creation of biological SDLs is only warranted if directed toward solving difficult and enabling biological questions. Here, we discuss challenges and opportunities in creating SDLs for synthetic biology.

Published
2023

6. ClusterCAD 2.0: an updated computational platform for chimeric type I polyketide synthase and nonribosomal peptide synthetase design

Author

Tao, Xavier B, LaFrance, Sarah, Xing, Yifei, Nava, Alberto A, Martin, Hector Garcia, Keasling, Jay D, and Backman, Tyler WH

Subjects
Biological Sciences, Bioengineering, Biotechnology, Peptide Synthases, Polyketide Synthases, Software, Environmental Sciences, Information and Computing Sciences, Developmental Biology, Biological sciences, Chemical sciences, Environmental sciences
Abstract

Megasynthase enzymes such as type I modular polyketide synthases (PKSs) and nonribosomal peptide synthetases (NRPSs) play a central role in microbial chemical warfare because they can evolve rapidly by shuffling parts (catalytic domains) to produce novel chemicals. If we can understand the design rules to reshuffle these parts, PKSs and NRPSs will provide a systematic and modular way to synthesize millions of molecules including pharmaceuticals, biomaterials, and biofuels. However, PKS and NRPS engineering remains difficult due to a limited understanding of the determinants of PKS and NRPS fold and function. We developed ClusterCAD to streamline and simplify the process of designing and testing engineered PKS variants. Here, we present the highly improved ClusterCAD 2.0 release, available at https://clustercad.jbei.org. ClusterCAD 2.0 boasts support for PKS-NRPS hybrid and NRPS clusters in addition to PKS clusters; a vastly enlarged database of curated PKS, PKS-NRPS hybrid, and NRPS clusters; a diverse set of chemical 'starters' and loading modules; the new Domain Architecture Cluster Search Tool; and an offline Jupyter Notebook workspace, among other improvements. Together these features massively expand the chemical space that can be accessed by enzymes engineered with ClusterCAD.

Published
2023

7. BayFlux: A Bayesian method to quantify metabolic Fluxes and their uncertainty at the genome scale

Author

Backman, Tyler WH, Schenk, Christina, Radivojevic, Tijana, Ando, David, Singh, Jahnavi, Czajka, Jeffrey J, Costello, Zak, Keasling, Jay D, Tang, Yinjie, Akhmatskaya, Elena, and Martin, Hector Garcia

Subjects
Biological Sciences, Industrial Biotechnology, Bioengineering, Biotechnology, Bayes Theorem, Uncertainty, Metabolic Flux Analysis, Carbon Isotopes, Models, Biological, Mathematical Sciences, Information and Computing Sciences, Bioinformatics
Abstract

Metabolic fluxes, the number of metabolites traversing each biochemical reaction in a cell per unit time, are crucial for assessing and understanding cell function. 13C Metabolic Flux Analysis (13C MFA) is considered to be the gold standard for measuring metabolic fluxes. 13C MFA typically works by leveraging extracellular exchange fluxes as well as data from 13C labeling experiments to calculate the flux profile which best fit the data for a small, central carbon, metabolic model. However, the nonlinear nature of the 13C MFA fitting procedure means that several flux profiles fit the experimental data within the experimental error, and traditional optimization methods offer only a partial or skewed picture, especially in "non-gaussian" situations where multiple very distinct flux regions fit the data equally well. Here, we present a method for flux space sampling through Bayesian inference (BayFlux), that identifies the full distribution of fluxes compatible with experimental data for a comprehensive genome-scale model. This Bayesian approach allows us to accurately quantify uncertainty in calculated fluxes. We also find that, surprisingly, the genome-scale model of metabolism produces narrower flux distributions (reduced uncertainty) than the small core metabolic models traditionally used in 13C MFA. The different results for some reactions when using genome-scale models vs core metabolic models advise caution in assuming strong inferences from 13C MFA since the results may depend significantly on the completeness of the model used. Based on BayFlux, we developed and evaluated novel methods (P-13C MOMA and P-13C ROOM) to predict the biological results of a gene knockout, that improve on the traditional MOMA and ROOM methods by quantifying prediction uncertainty.

Published
2023

8. Beyond Low Earth Orbit: Biological Research, Artificial Intelligence, and Self-Driving Labs

Author

Sanders, Lauren M., Yang, Jason H., Scott, Ryan T., Qutub, Amina Ann, Martin, Hector Garcia, Berrios, Daniel C., Hastings, Jaden J. A., Rask, Jon, Mackintosh, Graham, Hoarfrost, Adrienne L., Chalk, Stuart, Kalantari, John, Khezeli, Kia, Antonsen, Erik L., Babdor, Joel, Barker, Richard, Baranzini, Sergio E., Beheshti, Afshin, Delgado-Aparicio, Guillermo M., Glicksberg, Benjamin S., Greene, Casey S., Haendel, Melissa, Hamid, Arif A., Heller, Philip, Jamieson, Daniel, Jarvis, Katelyn J., Komarova, Svetlana V., Komorowski, Matthieu, Kothiyal, Prachi, Mahabal, Ashish, Manor, Uri, Mason, Christopher E., Matar, Mona, Mias, George I., Miller, Jack, Myers Jr., Jerry G., Nelson, Charlotte, Oribello, Jonathan, Park, Seung-min, Parsons-Wingerter, Patricia, Prabhu, R. K., Reynolds, Robert J., Saravia-Butler, Amanda, Saria, Suchi, Sawyer, Aenor, Singh, Nitin Kumar, Soboczenski, Frank, Snyder, Michael, Soman, Karthik, Theriot, Corey A., Van Valen, David, Venkateswaran, Kasthuri, Warren, Liz, Worthey, Liz, Zitnik, Marinka, and Costes, Sylvain V.

Subjects
Quantitative Biology - Other Quantitative Biology, Computer Science - Machine Learning
Abstract

Space biology research aims to understand fundamental effects of spaceflight on organisms, develop foundational knowledge to support deep space exploration, and ultimately bioengineer spacecraft and habitats to stabilize the ecosystem of plants, crops, microbes, animals, and humans for sustained multi-planetary life. To advance these aims, the field leverages experiments, platforms, data, and model organisms from both spaceborne and ground-analog studies. As research is extended beyond low Earth orbit, experiments and platforms must be maximally autonomous, light, agile, and intelligent to expedite knowledge discovery. Here we present a summary of recommendations from a workshop organized by the National Aeronautics and Space Administration on artificial intelligence, machine learning, and modeling applications which offer key solutions toward these space biology challenges. In the next decade, the synthesis of artificial intelligence into the field of space biology will deepen the biological understanding of spaceflight effects, facilitate predictive modeling and analytics, support maximally autonomous and reproducible experiments, and efficiently manage spaceborne data and metadata, all with the goal to enable life to thrive in deep space., Comment: 28 pages, 4 figures

Published
2021

9. Beyond Low Earth Orbit: Biomonitoring, Artificial Intelligence, and Precision Space Health

Author

Scott, Ryan T., Antonsen, Erik L., Sanders, Lauren M., Hastings, Jaden J. A., Park, Seung-min, Mackintosh, Graham, Reynolds, Robert J., Hoarfrost, Adrienne L., Sawyer, Aenor, Greene, Casey S., Glicksberg, Benjamin S., Theriot, Corey A., Berrios, Daniel C., Miller, Jack, Babdor, Joel, Barker, Richard, Baranzini, Sergio E., Beheshti, Afshin, Chalk, Stuart, Delgado-Aparicio, Guillermo M., Haendel, Melissa, Hamid, Arif A., Heller, Philip, Jamieson, Daniel, Jarvis, Katelyn J., Kalantari, John, Khezeli, Kia, Komarova, Svetlana V., Komorowski, Matthieu, Kothiyal, Prachi, Mahabal, Ashish, Manor, Uri, Martin, Hector Garcia, Mason, Christopher E., Matar, Mona, Mias, George I., Myers, Jr., Jerry G., Nelson, Charlotte, Oribello, Jonathan, Parsons-Wingerter, Patricia, Prabhu, R. K., Qutub, Amina Ann, Rask, Jon, Saravia-Butler, Amanda, Saria, Suchi, Singh, Nitin Kumar, Soboczenski, Frank, Snyder, Michael, Soman, Karthik, Van Valen, David, Venkateswaran, Kasthuri, Warren, Liz, Worthey, Liz, Yang, Jason H., Zitnik, Marinka, and Costes, Sylvain V.

Subjects
Quantitative Biology - Other Quantitative Biology, Computer Science - Machine Learning
Abstract

Human space exploration beyond low Earth orbit will involve missions of significant distance and duration. To effectively mitigate myriad space health hazards, paradigm shifts in data and space health systems are necessary to enable Earth-independence, rather than Earth-reliance. Promising developments in the fields of artificial intelligence and machine learning for biology and health can address these needs. We propose an appropriately autonomous and intelligent Precision Space Health system that will monitor, aggregate, and assess biomedical statuses; analyze and predict personalized adverse health outcomes; adapt and respond to newly accumulated data; and provide preventive, actionable, and timely insights to individual deep space crew members and iterative decision support to their crew medical officer. Here we present a summary of recommendations from a workshop organized by the National Aeronautics and Space Administration, on future applications of artificial intelligence in space biology and health. In the next decade, biomonitoring technology, biomarker science, spacecraft hardware, intelligent software, and streamlined data management must mature and be woven together into a Precision Space Health system to enable humanity to thrive in deep space., Comment: 31 pages, 4 figures

Published
2021

11. MACAW: An Accessible Tool for Molecular Embedding and Inverse Molecular Design

Author

Blay, Vincent, Radivojevic, Tijana, Allen, Jonathan E, Hudson, Corey M, and Martin, Hector Garcia

Subjects
Medicinal and Biomolecular Chemistry, Chemical Sciences, Algorithms, Octanes, Protein Binding, Receptors, Histamine H1, Theoretical and Computational Chemistry, Computation Theory and Mathematics, Medicinal & Biomolecular Chemistry, Medicinal and biomolecular chemistry, Theoretical and computational chemistry
Abstract

The growing capabilities of synthetic biology and organic chemistry demand tools to guide syntheses toward useful molecules. Here, we present Molecular AutoenCoding Auto-Workaround (MACAW), a tool that uses a novel approach to generate molecules predicted to meet a desired property specification (e.g., a binding affinity of 50 nM or an octane number of 90). MACAW describes molecules by embedding them into a smooth multidimensional numerical space, avoiding uninformative dimensions that previous methods often introduce. The coordinates in this embedding provide a natural choice of features for accurately predicting molecular properties, which we demonstrate with examples for cetane and octane numbers, flash points, and histamine H1 receptor binding affinity. The approach is computationally efficient and well-suited to the small- and medium-size datasets commonly used in biosciences. We showcase the utility of MACAW for virtual screening by identifying molecules with high predicted binding affinity to the histamine H1 receptor and limited affinity to the muscarinic M2 receptor, which are targets of medicinal relevance. Combining these predictive capabilities with a novel generative algorithm for molecules allows us to recommend molecules with a desired property value (i.e., inverse molecular design). We demonstrate this capability by recommending molecules with predicted octane numbers of 40, 80, and 120, which is an important characteristic of biofuels. Thus, MACAW augments classical retrosynthesis tools by providing recommendations for molecules on specification.

Published
2022

12. Learning from learning machines: a new generation of AI technology to meet the needs of science

Author

Pion-Tonachini, Luca, Bouchard, Kristofer, Martin, Hector Garcia, Peisert, Sean, Holtz, W. Bradley, Aswani, Anil, Dwivedi, Dipankar, Wainwright, Haruko, Pilania, Ghanshyam, Nachman, Benjamin, Marrone, Babetta L., Falco, Nicola, Prabhat, Arnold, Daniel, Wolf-Yadlin, Alejandro, Powers, Sarah, Climer, Sharlee, Jackson, Quinn, Carlson, Ty, Sohn, Michael, Zwart, Petrus, Kumar, Neeraj, Justice, Amy, Tomlin, Claire, Jacobson, Daniel, Micklem, Gos, Gkoutos, Georgios V., Bickel, Peter J., Cazier, Jean-Baptiste, Müller, Juliane, Webb-Robertson, Bobbie-Jo, Stevens, Rick, Anderson, Mark, Kreutz-Delgado, Ken, Mahoney, Michael W., and Brown, James B.

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

We outline emerging opportunities and challenges to enhance the utility of AI for scientific discovery. The distinct goals of AI for industry versus the goals of AI for science create tension between identifying patterns in data versus discovering patterns in the world from data. If we address the fundamental challenges associated with "bridging the gap" between domain-driven scientific models and data-driven AI learning machines, then we expect that these AI models can transform hypothesis generation, scientific discovery, and the scientific process itself.

Published
2021

15. Frontiers and Opportunities in Bioenergy Crop Microbiome Research Networks

Author

Howe, The Inter-BRC Microbiome Workshop Consortium Adina, Bonito, Gregory, Chou, Ming-Yi, Cregger, Melissa A, Fedders, Anna, Field, John L, Martin, Hector Garcia, Labbé, Jesse L, Mechan-Llontop, Marco E, Northen, Trent R, Shade, Ashley, and Tschaplinski, Timothy J

Subjects
Affordable and Clean Energy, ecosystems, microbiome, plants
Abstract

Researchers from across the four United States Department of Energy Bioenergy Research Centers (BRCs) engaged in a microbiome workshop that focused on identifying challenges and collaboration opportunities to better understand bioenergy-relevant plant–microbe interactions. The virtual workshop included hands-on educational sessions and a keynote address on current best practices in microbiome science and community microbiome standards, as well as breakout sessions aimed at identifying microbiome-related data and measurements that should be prioritized, opportunities for and barriers to integrating plant metabolites to microbiome research, and strategies for more effectively integrating microbiome data and processes into existing models. Based on participant discussion, key findings of the workshop were the need to prioritize scaling data sharing across BRCs and the broader research community and securing collaborative infrastructure in the areas of microbiome-ecosystem modeling and molecular plant–microbe interactions. This workshop review highlights additional main findings from this event, to encourage cross-site and more holistic metaanalyses while promoting wide scientific community engagement across plant microbiome sciences.

Published
2022

16. Scalable and automated CRISPR-based strain engineering using droplet microfluidics

Author

Iwai, Kosuke, Wehrs, Maren, Garber, Megan, Sustarich, Jess, Washburn, Lauren, Costello, Zachary, Kim, Peter W, Ando, David, Gaillard, William R, Hillson, Nathan J, Adams, Paul D, Mukhopadhyay, Aindrila, Garcia Martin, Hector, and Singh, Anup K

Subjects
Fluid Mechanics and Thermal Engineering, Engineering, Genetics, Bioengineering, Biotechnology, Microfluidics
Abstract

We present a droplet-based microfluidic system that enables CRISPR-based gene editing and high-throughput screening on a chip. The microfluidic device contains a 10 × 10 element array, and each element contains sets of electrodes for two electric field-actuated operations: electrowetting for merging droplets to mix reagents and electroporation for transformation. This device can perform up to 100 genetic modification reactions in parallel, providing a scalable platform for generating the large number of engineered strains required for the combinatorial optimization of genetic pathways and predictable bioengineering. We demonstrate the system's capabilities through the CRISPR-based engineering of two test cases: (1) disruption of the function of the enzyme galactokinase (galK) in E. coli and (2) targeted engineering of the glutamine synthetase gene (glnA) and the blue-pigment synthetase gene (bpsA) to improve indigoidine production in E. coli.

Published
2022

18. Microbial production of advanced biofuels

Author

Keasling, Jay, Garcia Martin, Hector, Lee, Taek Soon, Mukhopadhyay, Aindrila, Singer, Steven W, and Sundstrom, Eric

Subjects
Biological Sciences, Industrial Biotechnology, Climate Action, Affordable and Clean Energy, Bacteria, Biofuels, Genetic Engineering, Genomics, Machine Learning, Microbiology, Medical Microbiology
Abstract

Concerns over climate change have necessitated a rethinking of our transportation infrastructure. One possible alternative to carbon-polluting fossil fuels is biofuels produced by engineered microorganisms that use a renewable carbon source. Two biofuels, ethanol and biodiesel, have made inroads in displacing petroleum-based fuels, but their uptake has been limited by the amounts that can be used in conventional engines and by their cost. Advanced biofuels that mimic petroleum-based fuels are not limited by the amounts that can be used in existing transportation infrastructure but have had limited uptake due to costs. In this Review, we discuss engineering metabolic pathways to produce advanced biofuels, challenges with substrate and product toxicity with regard to host microorganisms and methods to engineer tolerance, and the use of functional genomics and machine learning approaches to produce advanced biofuels and prospects for reducing their costs.

Published
2021

20. Biomonitoring and precision health in deep space supported by artificial intelligence

Author

Scott, Ryan T., Sanders, Lauren M., Antonsen, Erik L., Hastings, Jaden J. A., Park, Seung-min, Mackintosh, Graham, Reynolds, Robert J., Hoarfrost, Adrienne L., Sawyer, Aenor, Greene, Casey S., Glicksberg, Benjamin S., Theriot, Corey A., Berrios, Daniel C., Miller, Jack, Babdor, Joel, Barker, Richard, Baranzini, Sergio E., Beheshti, Afshin, Chalk, Stuart, Delgado-Aparicio, Guillermo M., Haendel, Melissa, Hamid, Arif A., Heller, Philip, Jamieson, Daniel, Jarvis, Katelyn J., Kalantari, John, Khezeli, Kia, Komarova, Svetlana V., Komorowski, Matthieu, Kothiyal, Prachi, Mahabal, Ashish, Manor, Uri, Garcia Martin, Hector, Mason, Christopher E., Matar, Mona, Mias, George I., Myers, Jr, Jerry G., Nelson, Charlotte, Oribello, Jonathan, Parsons-Wingerter, Patricia, Prabhu, R. K., Qutub, Amina Ann, Rask, Jon, Saravia-Butler, Amanda, Saria, Suchi, Singh, Nitin Kumar, Snyder, Michael, Soboczenski, Frank, Soman, Karthik, Van Valen, David, Venkateswaran, Kasthuri, Warren, Liz, Worthey, Liz, Yang, Jason H., Zitnik, Marinka, and Costes, Sylvain V.

Published
2023
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21. Biological research and self-driving labs in deep space supported by artificial intelligence

Author

Sanders, Lauren M., Scott, Ryan T., Yang, Jason H., Qutub, Amina Ann, Garcia Martin, Hector, Berrios, Daniel C., Hastings, Jaden J. A., Rask, Jon, Mackintosh, Graham, Hoarfrost, Adrienne L., Chalk, Stuart, Kalantari, John, Khezeli, Kia, Antonsen, Erik L., Babdor, Joel, Barker, Richard, Baranzini, Sergio E., Beheshti, Afshin, Delgado-Aparicio, Guillermo M., Glicksberg, Benjamin S., Greene, Casey S., Haendel, Melissa, Hamid, Arif A., Heller, Philip, Jamieson, Daniel, Jarvis, Katelyn J., Komarova, Svetlana V., Komorowski, Matthieu, Kothiyal, Prachi, Mahabal, Ashish, Manor, Uri, Mason, Christopher E., Matar, Mona, Mias, George I., Miller, Jack, Myers, Jr., Jerry G., Nelson, Charlotte, Oribello, Jonathan, Park, Seung-min, Parsons-Wingerter, Patricia, Prabhu, R. K., Reynolds, Robert J., Saravia-Butler, Amanda, Saria, Suchi, Sawyer, Aenor, Singh, Nitin Kumar, Snyder, Michael, Soboczenski, Frank, Soman, Karthik, Theriot, Corey A., Van Valen, David, Venkateswaran, Kasthuri, Warren, Liz, Worthey, Liz, Zitnik, Marinka, and Costes, Sylvain V.

Published
2023
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22. Multiomics Data Collection, Visualization, and Utilization for Guiding Metabolic Engineering

Author

Roy, Somtirtha, Radivojevic, Tijana, Forrer, Mark, Marti, Jose Manuel, Jonnalagadda, Vamshi, Backman, Tyler, Morrell, William, Plahar, Hector, Kim, Joonhoon, Hillson, Nathan, and Martin, Hector Garcia

Subjects
Biological Sciences, Industrial Biotechnology, Networking and Information Technology R&D (NITRD), Bioengineering, Machine Learning and Artificial Intelligence, Generic health relevance, machine learning, flux analysis, metabolic engineering, biofuels, synthetic biology, multiomics analysis, Other Biological Sciences, Biomedical Engineering, Medical Biotechnology, Industrial biotechnology, Medical biotechnology, Biomedical engineering
Abstract

Biology has changed radically in the past two decades, growing from a purely descriptive science into also a design science. The availability of tools that enable the precise modification of cells, as well as the ability to collect large amounts of multimodal data, open the possibility of sophisticated bioengineering to produce fuels, specialty and commodity chemicals, materials, and other renewable bioproducts. However, despite new tools and exponentially increasing data volumes, synthetic biology cannot yet fulfill its true potential due to our inability to predict the behavior of biological systems. Here, we showcase a set of computational tools that, combined, provide the ability to store, visualize, and leverage multiomics data to predict the outcome of bioengineering efforts. We show how to upload, visualize, and output multiomics data, as well as strain information, into online repositories for several isoprenol-producing strain designs. We then use these data to train machine learning algorithms that recommend new strain designs that are correctly predicted to improve isoprenol production by 23%. This demonstration is done by using synthetic data, as provided by a novel library, that can produce credible multiomics data for testing algorithms and computational tools. In short, this paper provides a step-by-step tutorial to leverage these computational tools to improve production in bioengineered strains.

Published
2021

23. Machine learning for metabolic engineering: A review

Author

Lawson, Christopher E, Martí, Jose Manuel, Radivojevic, Tijana, Jonnalagadda, Sai Vamshi R, Gentz, Reinhard, Hillson, Nathan J, Peisert, Sean, Kim, Joonhoon, Simmons, Blake A, Petzold, Christopher J, Singer, Steven W, Mukhopadhyay, Aindrila, Tanjore, Deepti, Dunn, Joshua G, and Garcia Martin, Hector

Subjects
Biological Sciences, Industrial Biotechnology, Machine Learning and Artificial Intelligence, Networking and Information Technology R&D (NITRD), Bioengineering, Algorithms, Gene Editing, Machine Learning, Metabolic Engineering, Synthetic Biology, Deep Learning, Biotechnology, Biochemistry and cell biology, Industrial biotechnology
Abstract

Machine learning provides researchers a unique opportunity to make metabolic engineering more predictable. In this review, we offer an introduction to this discipline in terms that are relatable to metabolic engineers, as well as providing in-depth illustrative examples leveraging omics data and improving production. We also include practical advice for the practitioner in terms of data management, algorithm libraries, computational resources, and important non-technical issues. A variety of applications ranging from pathway construction and optimization, to genetic editing optimization, cell factory testing, and production scale-up are discussed. Moreover, the promising relationship between machine learning and mechanistic models is thoroughly reviewed. Finally, the future perspectives and most promising directions for this combination of disciplines are examined.

Published
2021

24. ART: A machine learning Automated Recommendation Tool for synthetic biology

Author

Radivojević, Tijana, Costello, Zak, Workman, Kenneth, and Martin, Hector Garcia

Subjects
Quantitative Biology - Quantitative Methods, Statistics - Machine Learning
Abstract

Biology has changed radically in the last two decades, transitioning from a descriptive science into a design science. Synthetic biology allows us to bioengineer cells to synthesize novel valuable molecules such as renewable biofuels or anticancer drugs. However, traditional synthetic biology approaches involve ad-hoc engineering practices, which lead to long development times. Here, we present the Automated Recommendation Tool (ART), a tool that leverages machine learning and probabilistic modeling techniques to guide synthetic biology in a systematic fashion, without the need for a full mechanistic understanding of the biological system. Using sampling-based optimization, ART provides a set of recommended strains to be built in the next engineering cycle, alongside probabilistic predictions of their production levels. We demonstrate the capabilities of ART on simulated data sets, as well as experimental data from real metabolic engineering projects producing renewable biofuels, hoppy flavored beer without hops, and fatty acids. Finally, we discuss the limitations of this approach, and the practical consequences of the underlying assumptions failing.

Published
2019
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25. How to Hallucinate Functional Proteins

Author

Costello, Zak and Martin, Hector Garcia

Subjects
Quantitative Biology - Quantitative Methods
Abstract

Here we present a novel approach to protein design and phenotypic inference using a generative model for protein sequences. BioSeqVAE, a variational autoencoder variant, can hallucinate syntactically valid protein sequences that are likely to fold and function. BioSeqVAE is trained on the entire known protein sequence space and learns to generate valid examples of protein sequences in an unsupervised manner. The model is validated by showing that its latent feature space is useful and that it accurately reconstructs sequences. Its usefulness is demonstrated with a selection of relevant downstream design tasks. This work is intended to serve as a computational first step towards a general purpose structure free protein design tool.

Published
2019

26. Combining mechanistic and machine learning models for predictive engineering and optimization of tryptophan metabolism.

Author

Zhang, Jie, Petersen, Søren D, Radivojevic, Tijana, Ramirez, Andrés, Pérez-Manríquez, Andrés, Abeliuk, Eduardo, Sánchez, Benjamín J, Costello, Zak, Chen, Yu, Fero, Michael J, Martin, Hector Garcia, Nielsen, Jens, Keasling, Jay D, and Jensen, Michael K

Subjects
Saccharomyces cerevisiae, Amino Acids, Tryptophan, Biosensing Techniques, Biochemical Phenomena, Genotype, Phenotype, Algorithms, Models, Biological, Metabolic Networks and Pathways, Metabolic Engineering, Machine Learning, Models, Biological
Abstract

Through advanced mechanistic modeling and the generation of large high-quality datasets, machine learning is becoming an integral part of understanding and engineering living systems. Here we show that mechanistic and machine learning models can be combined to enable accurate genotype-to-phenotype predictions. We use a genome-scale model to pinpoint engineering targets, efficient library construction of metabolic pathway designs, and high-throughput biosensor-enabled screening for training diverse machine learning algorithms. From a single data-generation cycle, this enables successful forward engineering of complex aromatic amino acid metabolism in yeast, with the best machine learning-guided design recommendations improving tryptophan titer and productivity by up to 74 and 43%, respectively, compared to the best designs used for algorithm training. Thus, this study highlights the power of combining mechanistic and machine learning models to effectively direct metabolic engineering efforts.

Published
2020

27. A machine learning Automated Recommendation Tool for synthetic biology.

Author

Radivojević, Tijana, Costello, Zak, Workman, Kenneth, and Garcia Martin, Hector

Subjects
Escherichia coli, Saccharomyces cerevisiae, Dodecanol, Fatty Acids, Bayes Theorem, Beer, Biofuels, Synthetic Biology, Metabolic Engineering, Machine Learning
Abstract

Synthetic biology allows us to bioengineer cells to synthesize novel valuable molecules such as renewable biofuels or anticancer drugs. However, traditional synthetic biology approaches involve ad-hoc engineering practices, which lead to long development times. Here, we present the Automated Recommendation Tool (ART), a tool that leverages machine learning and probabilistic modeling techniques to guide synthetic biology in a systematic fashion, without the need for a full mechanistic understanding of the biological system. Using sampling-based optimization, ART provides a set of recommended strains to be built in the next engineering cycle, alongside probabilistic predictions of their production levels. We demonstrate the capabilities of ART on simulated data sets, as well as experimental data from real metabolic engineering projects producing renewable biofuels, hoppy flavored beer without hops, fatty acids, and tryptophan. Finally, we discuss the limitations of this approach, and the practical consequences of the underlying assumptions failing.

Published
2020

28. Chemoinformatic-Guided Engineering of Polyketide Synthases

Author

Zargar, Amin, Lal, Ravi, Valencia, Luis, Wang, Jessica, Backman, Tyler William H, Cruz-Morales, Pablo, Kothari, Ankita, Werts, Miranda, Wong, Andrew R, Bailey, Constance B, Loubat, Arthur, Liu, Yuzhong, Chen, Yan, Chang, Samantha, Benites, Veronica T, Hernández, Amanda C, Barajas, Jesus F, Thompson, Mitchell G, Barcelos, Carolina, Anayah, Rasha, Martin, Hector Garcia, Mukhopadhyay, Aindrila, Petzold, Christopher J, Baidoo, Edward EK, Katz, Leonard, and Keasling, Jay D

Subjects
Medicinal and Biomolecular Chemistry, Chemical Sciences, Bioengineering, Generic health relevance, Computational Biology, Molecular Structure, Polyketide Synthases, Protein Engineering, General Chemistry, Chemical sciences, Engineering
Abstract

Polyketide synthase (PKS) engineering is an attractive method to generate new molecules such as commodity, fine and specialty chemicals. A significant challenge is re-engineering a partially reductive PKS module to produce a saturated β-carbon through a reductive loop (RL) exchange. In this work, we sought to establish that chemoinformatics, a field traditionally used in drug discovery, offers a viable strategy for RL exchanges. We first introduced a set of donor RLs of diverse genetic origin and chemical substrates  into the first extension module of the lipomycin PKS (LipPKS1). Product titers of these engineered unimodular PKSs correlated with chemical structure similarity between the substrate of the donor RLs and recipient LipPKS1, reaching a titer of 165 mg/L of short-chain fatty acids produced by the host Streptomyces albus J1074. Expanding this method to larger intermediates that require bimodular communication, we introduced RLs of divergent chemosimilarity into LipPKS2 and determined triketide lactone production. Collectively, we observed a statistically significant correlation between atom pair chemosimilarity and production, establishing a new chemoinformatic method that may aid in the engineering of PKSs to produce desired, unnatural products.

Published
2020

29. Grit, Motivational Belief, Self-Regulated Learning (SRL), and Academic Achievement of Civil Engineering Students

Author

Martin, Hector, Craigwell, Renaldo, and Ramjarrie, Karrisa

Abstract

The influence of grit on engineering student's achievement has been understudied. The association between grit, self-regulated learning (SRL), and academic achievement in civil engineering students was investigated using correlation and regression analysis. One hundred and one civil engineering students from various nationalities completed a self-report questionnaire that contained the Grit 12-item scale and the forty-four questions on motivational beliefs and self-regulated learning practices (MSLQ). Four of the five SRL variables were predicted by perseverance of effort: intrinsic value, self-efficacy, cognitive strategy use, and self-regulation. Initially, perseverance of effort predicted the current grade point average (GPA), but it was no longer a predictor after including SRL indicators. Consistency of interest was a predictor of cognitive strategy usage, but it did not affect students' academic achievement. GPAs were also predicted by student self-efficacy and age. The connection between academic accomplishment and grit is mediated by SRL engagement. Students' perceived competency and confidence in completing their degree were shown to be major determinants of their GPA. Furthermore, motivational beliefs had a greater effect on students' GPAs than grit did. In the majority of the study's constructs, female students outperformed males. GPAs were higher among younger students than among their older peers.

Published
2022
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31. Identification, Characterization, and Application of a Highly Sensitive Lactam Biosensor from Pseudomonas putida

Author

Thompson, Mitchell G, Pearson, Allison N, Barajas, Jesus F, Cruz-Morales, Pablo, Sedaghatian, Nima, Costello, Zak, Garber, Megan E, Incha, Matthew R, Valencia, Luis E, Baidoo, Edward EK, Martin, Hector Garcia, Mukhopadhyay, Aindrila, and Keasling, Jay D

Subjects
Biological Sciences, Industrial Biotechnology, Biotechnology, Bioengineering, Biosensing Techniques, Caprolactam, Escherichia coli, Lactams, Ligands, Metabolic Engineering, Plasmids, Pseudomonas putida, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Biomedical Engineering, Biochemistry and cell biology, Bioinformatics and computational biology
Abstract

Caprolactam is an important polymer precursor to nylon traditionally derived from petroleum and produced on a scale of 5 million tons per year. Current biological pathways for the production of caprolactam are inefficient with titers not exceeding 2 mg/L, necessitating novel pathways for its production. As development of novel metabolic routes often require thousands of designs and result in low product titers, a highly sensitive biosensor for the final product has the potential to rapidly speed up development times. Here we report a highly sensitive biosensor for valerolactam and caprolactam from Pseudomonas putida KT2440 which is >1000× more sensitive to an exogenous ligand than previously reported sensors. Manipulating the expression of the sensor oplR (PP_3516) substantially altered the sensing parameters, with various vectors showing Kd values ranging from 700 nM (79.1 μg/L) to 1.2 mM (135.6 mg/L). Our most sensitive construct was able to detect in vivo production of caprolactam above background at ∼6 μg/L. The high sensitivity and range of OplR is a powerful tool toward the development of novel routes to the biological synthesis of caprolactam.

Published
2020

32. Lessons from Two Design–Build–Test–Learn Cycles of Dodecanol Production in Escherichia coli Aided by Machine Learning

Author

Opgenorth, Paul, Costello, Zak, Okada, Takuya, Goyal, Garima, Chen, Yan, Gin, Jennifer, Benites, Veronica, de Raad, Markus, Northen, Trent R, Deng, Kai, Deutsch, Samuel, Baidoo, Edward EK, Petzold, Christopher J, Hillson, Nathan J, Martin, Hector Garcia, and Beller, Harry R

Subjects
Biochemistry and Cell Biology, Biological Sciences, Industrial Biotechnology, Biotechnology, Bioengineering, Algorithms, Dodecanol, Escherichia coli, Machine Learning, Metabolic Engineering, Metabolic Networks and Pathways, Synthetic Biology, DBTL, machine learning, dodecanol, proteomics, synthetic biology, Medicinal and Biomolecular Chemistry, Biomedical Engineering, Biochemistry and cell biology, Bioinformatics and computational biology
Abstract

The Design-Build-Test-Learn (DBTL) cycle, facilitated by exponentially improving capabilities in synthetic biology, is an increasingly adopted metabolic engineering framework that represents a more systematic and efficient approach to strain development than historical efforts in biofuels and biobased products. Here, we report on implementation of two DBTL cycles to optimize 1-dodecanol production from glucose using 60 engineered Escherichia coli MG1655 strains. The first DBTL cycle employed a simple strategy to learn efficiently from a relatively small number of strains (36), wherein only the choice of ribosome-binding sites and an acyl-ACP/acyl-CoA reductase were modulated in a single pathway operon including genes encoding a thioesterase (UcFatB1), an acyl-ACP/acyl-CoA reductase (Maqu_2507, Maqu_2220, or Acr1), and an acyl-CoA synthetase (FadD). Measured variables included concentrations of dodecanol and all proteins in the engineered pathway. We used the data produced in the first DBTL cycle to train several machine-learning algorithms and to suggest protein profiles for the second DBTL cycle that would increase production. These strategies resulted in a 21% increase in dodecanol titer in Cycle 2 (up to 0.83 g/L, which is more than 6-fold greater than previously reported batch values for minimal medium). Beyond specific lessons learned about optimizing dodecanol titer in E. coli, this study had findings of broader relevance across synthetic biology applications, such as the importance of sequencing checks on plasmids in production strains as well as in cloning strains, and the critical need for more accurate protein expression predictive tools.

Published
2019

35. Validating the Relative Importance of Technology Diffusion Barriers– Exploring Modular Construction Design-Build Practices in the UK.

Author

Martin, Hector, Garner, Maia, Manewa, Anupa, and Chadee, Aaron

Subjects
*ADOPTIVE parents, *MODULAR construction, *TECHNOLOGY transfer, *INNOVATION adoption, *BID price
Abstract

This research investigates the low use of modular construction despite its recognized cost, time, quality, safety, and sustainability advantages. Using technology diffusion theory, this study seeks to identify and rank the characteristics that impede modular building adoption, such as relative advantage, compatibility, complexity, trialability, and observability. A survey of industry professionals in the United Kingdom was undertaken, and the results, validated by a one-sample t-test, showed that attitudes toward modular building, rather than technical difficulties, are the key impediments to broad adoption. The degree to which modular construction resonates with prospective adopters' current values, past experiences, and requirements determines its acceptance. Traditional mind-sets, the presence of traditional constructs, resistance to change, prior attitudes, bid prices, hesitation, and skepticism are all associated with non-adoption. Professional positions serve as a bridge between adopters and non-adapters. The research also emphasizes the importance of design-build project delivery systems and early supplier chain participation in accelerating the mainstream adoption of modular construction. [ABSTRACT FROM AUTHOR]

Published
2025
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36. CIRCE: The Canarias InfraRed Camera Experiment for the Gran Telescopio Canarias

Author

Eikenberry, Stephen S., Charcos, Miguel, Edwards, Michelle L., Garner, Alan, Lasso-Cabrera, Nestor, Stelter, Richard D., Marin-Franch, Antonio, Raines, S. Nicholas, Ackley, Kendall, Bennett, John G., Cenarro, Javier A., Chinn, Brian, Donoso, H. Veronica, Frommeyer, Raymond, Hanna, Kevin, Herlevich, Michael D., Julian, Jeff, Miller, Paola, Mullin, Scott, Murphey, Charles H., Packham, Chris, Varosi, Frank, Vega, Claudia, Warner, Craig, Ramaprakash, A. N., Burse, Mahesh, Punnadi, Sunjit, Chordia, Pravin, Gerarts, Andreas, Martín, Héctor de Paz, Calero, María Martín, Scarpa, Riccardo, Acosta, Sergio Fernandez, Sánchez, William Miguel Hernández, Siegel, Benjamin, Pérez, Francisco Francisco, Martín, Himar D. Viera, Losada, José A. Rodríguez, Nuñez, Agustín, Tejero, Álvaro, González, Carlos E. Martín, Rodríguez, César Cabrera, Sendra, Jordi Molgó, Rodriguez, J. Esteban, Cáceres, J. Israel Fernádez, García, Luis A. Rodríguez, Lopez, Manuel Huertas, Dominguez, Raul, Gaggstatter, Tim, Lavers, Antonio Cabrera, Geier, Stefan, Pessev, Peter, Sarajedini, Ata, and Castro-Tirado, A. J.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

The Canarias InfraRed Camera Experiment (CIRCE) is a near-infrared (1-2.5 micron) imager, polarimeter and low-resolution spectrograph operating as a visitor instrument for the Gran Telescopio Canarias 10.4-meter telescope. It was designed and built largely by graduate students and postdocs, with help from the UF astronomy engineering group, and is funded by the University of Florida and the U.S. National Science Foundation. CIRCE is intended to help fill the gap in near-infrared capabilities prior to the arrival of EMIR to the GTC, and will also provide the following scientific capabilities to compliment EMIR after its arrival: high-resolution imaging, narrowband imaging, high-time-resolution photometry, imaging polarimetry, low resolution spectroscopy. In this paper, we review the design, fabrication, integration, lab testing, and on-sky performance results for CIRCE. These include a novel approach to the opto-mechanical design, fabrication, and alignment., Comment: 41 pages, 18 figures

Published
2017

38. Machine learning framework for assessment of microbial factory performance.

Author

Oyetunde, Tolutola, Liu, Di, Martin, Hector Garcia, and Tang, Yinjie J

Subjects
Escherichia coli, Reproducibility of Results, Algorithms, Models, Biological, Computer Simulation, Databases, Factual, Metabolic Engineering, Machine Learning, Models, Biological, Databases, Factual, Bioengineering, Generic Health Relevance, MD Multidisciplinary, General Science & Technology
Abstract

Metabolic models can estimate intrinsic product yields for microbial factories, but such frameworks struggle to predict cell performance (including product titer or rate) under suboptimal metabolism and complex bioprocess conditions. On the other hand, machine learning, complementary to metabolic modeling necessitates large amounts of data. Building such a database for metabolic engineering designs requires significant manpower and is prone to human errors and bias. We propose an approach to integrate data-driven methods with genome scale metabolic model for assessment of microbial bio-production (yield, titer and rate). Using engineered E. coli as an example, we manually extracted and curated a data set comprising about 1200 experimentally realized cell factories from ~100 papers. We furthermore augmented the key design features (e.g., genetic modifications and bioprocess variables) extracted from literature with additional features derived from running the genome-scale metabolic model iML1515 simulations with constraints that match the experimental data. Then, data augmentation and ensemble learning (e.g., support vector machines, gradient boosted trees, and neural networks in a stacked regressor model) are employed to alleviate the challenges of sparse, non-standardized, and incomplete data sets, while multiple correspondence analysis/principal component analysis are used to rank influential factors on bio-production. The hybrid framework demonstrates a reasonably high cross-validation accuracy for prediction of E.coli factory performance metrics under presumed bioprocess and pathway conditions (Pearson correlation coefficients between 0.8 and 0.93 on new data not seen by the model).

Published
2019

39. Parallel Integration and Chromosomal Expansion of Metabolic Pathways

Author

Goyal, Garima, Costello, Zak, Alonso-Gutierrez, Jorge, Kang, Aram, Lee, Taek Soon, Martin, Hector Garcia, and Hillson, Nathan J

Subjects
Biological Sciences, Industrial Biotechnology, Chromosomes, Bacterial, DNA Copy Number Variations, DNA-Binding Proteins, Escherichia coli, Genetic Loci, Machine Learning, Metabolic Engineering, Metabolic Networks and Pathways, Pentanols, Plasmids, metabolic pathway, chromosomal integration, stabilization, copy number, statistical modeling, machine learning, optimization, isopentenol, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Biomedical Engineering, Biochemistry and cell biology, Bioinformatics and computational biology
Abstract

Robust fermentation of biomass-derived sugars into bioproducts demands the reliable microbial expression of metabolic pathways. Plasmid-based expression systems may suffer from instability and result in highly variable titers, rates, and yields. An established mitigation approach, chemical induced chromosomal expansion (CIChE), expands a singly integrated pathway to plasmid-like copy numbers while maintaining stability in the absence of antibiotic selection pressure. Here, we report parallel integration and chromosomal expansion (PIACE), extensions to CIChE that enable independent expansions of pathway components across multiple loci, use suicide vectors to achieve high-efficiency site-specific integration of sequence-validated multigene components, and introduce a heat-curable plasmid to obviate recA deletion post pathway expansion. We applied PIACE to stabilize an isopentenol pathway across three loci in E. coli DH1 and then generate libraries of pathway component copy number variants to screen for improved titers. Polynomial regressor statistical modeling of the production screening data suggests that increasing copy numbers of all isopentenol pathway components would further improve titers.

Published
2018

40. Leveraging knowledge engineering and machine learning for microbial bio-manufacturing

Author

Oyetunde, Tolutola, Bao, Forrest Sheng, Chen, Jiung-Wen, Martin, Hector Garcia, and Tang, Yinjie J

Subjects
Biological Sciences, Industrial Biotechnology, Biotechnology, Genetics, Human Genome, Machine Learning and Artificial Intelligence, Networking and Information Technology R&D (NITRD), Bioengineering, Generic health relevance, Bioreactors, Machine Learning, Metabolic Engineering, Models, Biological, Synthetic Biology, Deep learning, Design-build-test-learn, Genome scale modeling, Metabolic burdens, Engineering, Technology, Biological sciences
Abstract

Genome scale modeling (GSM) predicts the performance of microbial workhorses and helps identify beneficial gene targets. GSM integrated with intracellular flux dynamics, omics, and thermodynamics have shown remarkable progress in both elucidating complex cellular phenomena and computational strain design (CSD). Nonetheless, these models still show high uncertainty due to a poor understanding of innate pathway regulations, metabolic burdens, and other factors (such as stress tolerance and metabolite channeling). Besides, the engineered hosts may have genetic mutations or non-genetic variations in bioreactor conditions and thus CSD rarely foresees fermentation rate and titer. Metabolic models play important role in design-build-test-learn cycles for strain improvement, and machine learning (ML) may provide a viable complementary approach for driving strain design and deciphering cellular processes. In order to develop quality ML models, knowledge engineering leverages and standardizes the wealth of information in literature (e.g., genomic/phenomic data, synthetic biology strategies, and bioprocess variables). Data driven frameworks can offer new constraints for mechanistic models to describe cellular regulations, to design pathways, to search gene targets, and to estimate fermentation titer/rate/yield under specified growth conditions (e.g., mixing, nutrients, and O2). This review highlights the scope of information collections, database constructions, and machine learning techniques (such as deep learning and transfer learning), which may facilitate "Learn and Design" for strain development.

Published
2018

41. Industrial brewing yeast engineered for the production of primary flavor determinants in hopped beer.

Author

Denby, Charles M, Li, Rachel A, Vu, Van T, Costello, Zak, Lin, Weiyin, Chan, Leanne Jade G, Williams, Joseph, Donaldson, Bryan, Bamforth, Charles W, Petzold, Christopher J, Scheller, Henrik V, Martin, Hector Garcia, and Keasling, Jay D

Subjects
Saccharomyces cerevisiae, Monoterpenes, Hydro-Lyases, Plant Proteins, Pilot Projects, Genetic Engineering, Fermentation, Genes, Fungal, Beer, Genes, Fungal
Abstract

Flowers of the hop plant provide both bitterness and "hoppy" flavor to beer. Hops are, however, both a water and energy intensive crop and vary considerably in essential oil content, making it challenging to achieve a consistent hoppy taste in beer. Here, we report that brewer's yeast can be engineered to biosynthesize aromatic monoterpene molecules that impart hoppy flavor to beer by incorporating recombinant DNA derived from yeast, mint, and basil. Whereas metabolic engineering of biosynthetic pathways is commonly enlisted to maximize product titers, tuning expression of pathway enzymes to affect target production levels of multiple commercially important metabolites without major collateral metabolic changes represents a unique challenge. By applying state-of-the-art engineering techniques and a framework to guide iterative improvement, strains are generated with target performance characteristics. Beers produced using these strains are perceived as hoppier than traditionally hopped beers by a sensory panel in a double-blind tasting.

Published
2018

43. Current of interacting particles inside a channel of exponential cavities: Application of a modified Fick--Jacobs equation

Author

Suárez, Gonzalo, Hoyuelos, Miguel, and Mártin, Héctor

Subjects
Condensed Matter - Statistical Mechanics
Abstract

The Fick--Jacobs equation has been widely studied, because of its applications in the diffusion and transport of non-interacting particles in narrow channels. It is also known that a modified version of this equation can be used to describe the same system with particles interacting through a hard-core potential. In this work we present a system that can be exactly solved using the Fick--Jacobs equation. The exact results of the particle concentration profile along the channel $n$, the current, $J$, and the mobility, $\mu$, of particles as a function of an external force are contrasted with Monte Carlo simulations results of non-interacting particles. For interacting particles the behavior of $n$, $J$ and $\mu$, obtained from the modified Fick--Jacobs equation are in agreement with numerical simulations, where the hard-core interaction is taken into account. Even more, for interacting particles the modified Fick--Jacobs equation gives comparatively more accurate results of the current difference (when a force is applied in opposite directions) than the exact result for the non-interacting ones.

Published
2016
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44. Computational Requirements in Clean Energy and Manufacturing: Summary report of the virtual workshop held on June 28-29, 2021

Author

Sieger, Matt, primary, Turner, John, additional, Allu, Srikanth, additional, Ameen, Muhsin, additional, Chaudhuri, Santanu, additional, Chen, Jackie, additional, Chen, Yousu, additional, Dal Forno Chuahy, Flavio, additional, Finney, Charles, additional, Gururajan, Vyaas, additional, Huang, Henry, additional, Kaul, Brian, additional, Klippenstein, Stephen, additional, Martin, Hector, additional, Pal, Pinaki, additional, Peles, Slaven, additional, Plotkowski, Alex, additional, Sanyal, Jibonananda, additional, Sengupta, Manajit, additional, Som, Sibendu, additional, and Sprague, Michael, additional

Published
2023
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45. Automated Flow-Based/Digital Microfluidic Platform Integrated with Onsite Electroporation Process for Multiplex Genetic Engineering Applications

Author

Iwai, Kosuke, Ando, David, Kim, Peter W, Gach, Phillip C, Raje, Manasi, Duncomb, Todd A, Heinemann, Joshua V, Northen, Trent R, Martin, Hector Garcia, Hillson, Nathan J, Adams, Paul D, and Singh, Anup K

Subjects
Biological Sciences, Industrial Biotechnology, Bioengineering, Biotechnology, Genetics, 1.1 Normal biological development and functioning
Abstract

We present a novel automated flow-based/digital microfluidic platform integrated with onsite electroporation function. In addition to high-throughput arraying of microdroplets and mixing of DNA parts and cells, proposed platform is capable of multiplexed electroporation process and dual optical detection of expressed fluorescence on chip. Unlike conventional microtiter plate based reactions, our platform would allow completely automated and robust genetic engineering steps using drastically smaller amounts of reagents and can be useful for gene editing processes such as CRISPR/Cas9 for synthetic biology applications.

Published
2018

46. Two-Scale 13C Metabolic Flux Analysis for Metabolic Engineering

Author

Ando, David and Garcia Martin, Hector

Subjects
Biological Sciences, Industrial Biotechnology, Bioengineering, Carbon Isotopes, Computational Biology, Mass Spectrometry, Metabolic Engineering, Metabolic Flux Analysis, Metabolomics, Models, Biological, Software, Workflow, 13C Metabolic flux analysis, Flux analysis, Omics data, Predictive biology, Other Chemical Sciences, Biochemistry and Cell Biology, Developmental Biology, Biochemistry and cell biology, Medicinal and biomolecular chemistry
Abstract

Accelerating the Design-Build-Test-Learn (DBTL) cycle in synthetic biology is critical to achieving rapid and facile bioengineering of organisms for the production of, e.g., biofuels and other chemicals. The Learn phase involves using data obtained from the Test phase to inform the next Design phase. As part of the Learn phase, mathematical models of metabolic fluxes give a mechanistic level of comprehension to cellular metabolism, isolating the principle drivers of metabolic behavior from the peripheral ones, and directing future experimental designs and engineering methodologies. Furthermore, the measurement of intracellular metabolic fluxes is specifically noteworthy as providing a rapid and easy-to-understand picture of how carbon and energy flow throughout the cell. Here, we present a detailed guide to performing metabolic flux analysis in the Learn phase of the DBTL cycle, where we show how one can take the isotope labeling data from a 13C labeling experiment and immediately turn it into a determination of cellular fluxes that points in the direction of genetic engineering strategies that will advance the metabolic engineering process.For our modeling purposes we use the Joint BioEnergy Institute (JBEI) Quantitative Metabolic Modeling (jQMM) library, which provides an open-source, python-based framework for modeling internal metabolic fluxes and making actionable predictions on how to modify cellular metabolism for specific bioengineering goals. It presents a complete toolbox for performing different types of flux analysis such as Flux Balance Analysis, 13C Metabolic Flux Analysis, and it introduces the capability to use 13C labeling experimental data to constrain comprehensive genome-scale models through a technique called two-scale 13C Metabolic Flux Analysis (2S-13C MFA) [1]. In addition to several other capabilities, the jQMM is also able to predict the effects of knockouts using the MoMA and ROOM methodologies. The use of the jQMM library is illustrated through a step-by-step demonstration, which is also contained in a digital Jupyter Notebook format that enhances reproducibility and provides the capability to be adopted to the user's specific needs. As an open-source software project, users can modify and extend the code base and make improvements at will, providing a base for future modeling efforts.

Published
2018

47. A machine learning approach to predict metabolic pathway dynamics from time-series multiomics data

Author

Costello, Zak and Martin, Hector Garcia

Subjects
Biological Sciences, Bioinformatics and Computational Biology, Networking and Information Technology R&D (NITRD), Bioengineering, Machine Learning and Artificial Intelligence, Bioinformatics and computational biology
Abstract

New synthetic biology capabilities hold the promise of dramatically improving our ability to engineer biological systems. However, a fundamental hurdle in realizing this potential is our inability to accurately predict biological behavior after modifying the corresponding genotype. Kinetic models have traditionally been used to predict pathway dynamics in bioengineered systems, but they take significant time to develop, and rely heavily on domain expertise. Here, we show that the combination of machine learning and abundant multiomics data (proteomics and metabolomics) can be used to effectively predict pathway dynamics in an automated fashion. The new method outperforms a classical kinetic model, and produces qualitative and quantitative predictions that can be used to productively guide bioengineering efforts. This method systematically leverages arbitrary amounts of new data to improve predictions, and does not assume any particular interactions, but rather implicitly chooses the most predictive ones.

Published
2018

48. The Experiment Data Depot: A Web-Based Software Tool for Biological Experimental Data Storage, Sharing, and Visualization

Author

Morrell, William C, Birkel, Garrett W, Forrer, Mark, Lopez, Teresa, Backman, Tyler WH, Dussault, Michael, Petzold, Christopher J, Baidoo, Edward EK, Costello, Zak, Ando, David, Alonso-Gutierrez, Jorge, George, Kevin W, Mukhopadhyay, Aindrila, Vaino, Ian, Keasling, Jay D, Adams, Paul D, Hillson, Nathan J, and Martin, Hector Garcia

Subjects
Biochemistry and Cell Biology, Biological Sciences, Bioengineering, Generic health relevance, Information Storage and Retrieval, Metadata, Models, Biological, User-Computer Interface, database, -omics data, data standards, data mining, flux analysis, synthetic biology, Medicinal and Biomolecular Chemistry, Biomedical Engineering, Biochemistry and cell biology, Bioinformatics and computational biology
Abstract

Although recent advances in synthetic biology allow us to produce biological designs more efficiently than ever, our ability to predict the end result of these designs is still nascent. Predictive models require large amounts of high-quality data to be parametrized and tested, which are not generally available. Here, we present the Experiment Data Depot (EDD), an online tool designed as a repository of experimental data and metadata. EDD provides a convenient way to upload a variety of data types, visualize these data, and export them in a standardized fashion for use with predictive algorithms. In this paper, we describe EDD and showcase its utility for three different use cases: storage of characterized synthetic biology parts, leveraging proteomics data to improve biofuel yield, and the use of extracellular metabolite concentrations to predict intracellular metabolic fluxes.

Published
2017

49. Transport with hard-core interaction in a chain of asymmetric cavities

Author

Suárez, Gonzalo, Hoyuelos, Miguel, and Mártin, Héctor

Subjects
Condensed Matter - Statistical Mechanics
Abstract

In this paper we investigate the diffusion of particles inside a chain of asymmetric cavities. We are considering particles that interact through a hard--core potential and are driven by an external force. We show that the difference in the current when the force is applied to the left and to the right strongly depends on the concentration inside the cavity. We found that, when the concentration is high enough, the hard--core interaction vanishes and inverts the asymmetric effect of the cavity. We also introduce a new equation, a modification to the Fick--Jacobs equation, to describe this system analytically. Finally, we used numerical simulations to verify the analytic results, finding a good agreement between theory and simulations., Comment: XXVI IUPAP Conference on Computational Physics, CCP2014 August 11-14, 2014, Boston, Massachusetts, USA

Published
2015
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50. Machine learning for metabolic engineering: A review

Author

Lawson, Christopher E., Martí, Jose Manuel, Radivojevic, Tijana, Jonnalagadda, Sai Vamshi R., Gentz, Reinhard, Hillson, Nathan J., Peisert, Sean, Kim, Joonhoon, Simmons, Blake A., Petzold, Christopher J., Singer, Steven W., Mukhopadhyay, Aindrila, Tanjore, Deepti, Dunn, Joshua G., and Garcia Martin, Hector

Published
2021
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