Your search keyword '"Keasling, Jay D"' showing total 578 results

1. Systematic engineering for production of anti-aging sunscreen compound in Pseudomonas putida

Author

Yunus, Ian S, Yunus, Ian S, Hudson, Graham A, Chen, Yan, Gin, Jennifer W, Kim, Joonhoon, Baidoo, EdwardEK, Petzold, Christopher J, Adams, Paul D, Simmons, Blake A, Mukhopadhyay, Aindrila, Keasling, Jay D, Lee, Taek Soon, Yunus, Ian S, Yunus, Ian S, Hudson, Graham A, Chen, Yan, Gin, Jennifer W, Kim, Joonhoon, Baidoo, EdwardEK, Petzold, Christopher J, Adams, Paul D, Simmons, Blake A, Mukhopadhyay, Aindrila, Keasling, Jay D, and Lee, Taek Soon

Abstract

Sunscreen has been used for thousands of years to protect skin from ultraviolet radiation. However, the use of modern commercial sunscreen containing oxybenzone, ZnO, and TiO2 has raised concerns due to their negative effects on human health and the environment. In this study, we aim to establish an efficient microbial platform for production of shinorine, a UV light absorbing compound with anti-aging properties. First, we methodically selected an appropriate host for shinorine production by analyzing central carbon flux distribution data from prior studies alongside predictions from genome-scale metabolic models (GEMs). We enhanced shinorine productivity through CRISPRi-mediated downregulation and utilized shotgun proteomics to pinpoint potential competing pathways. Simultaneously, we improved the shinorine biosynthetic pathway by refining its design, optimizing promoter usage, and altering the strength of ribosome binding sites. Finally, we conducted amino acid feeding experiments under various conditions to identify the key limiting factors in shinorine production. The study combines meta-analysis of 13C-metabolic flux analysis, GEMs, synthetic biology, CRISPRi-mediated gene downregulation, and omics analysis to improve shinorine production, demonstrating the potential of Pseudomonas putida KT2440 as platform for shinorine production.

Published

2024

2. Development of Corynebacterium glutamicum as a monoterpene production platform

Author

Luckie, Bridget A, Luckie, Bridget A, Kashyap, Meera, Pearson, Allison N, Chen, Yan, Liu, Yuzhong, Valencia, Luis E, Carrillo Romero, Alexander, Hudson, Graham A, Tao, Xavier B, Wu, Bryan, Petzold, Christopher J, Keasling, Jay D, Luckie, Bridget A, Luckie, Bridget A, Kashyap, Meera, Pearson, Allison N, Chen, Yan, Liu, Yuzhong, Valencia, Luis E, Carrillo Romero, Alexander, Hudson, Graham A, Tao, Xavier B, Wu, Bryan, Petzold, Christopher J, and Keasling, Jay D

Abstract

Monoterpenes are commonly known for their role in the flavors and fragrances industry and are also gaining attention for other uses like insect repellant and as potential renewable fuels for aviation. Corynebacterium glutamicum, a Generally Recognized as Safe microbe, has been a choice organism in industry for the annual million ton-scale bioproduction of amino acids for more than 50 years; however, efforts to produce monoterpenes in C. glutamicum have remained relatively limited. In this study, we report a further expansion of the C. glutamicum biosynthetic repertoire through the development and optimization of a mevalonate-based monoterpene platform. In the course of our plasmid design iterations, we increased flux through the mevalonate-based bypass pathway, measuring isoprenol production as a proxy for monoterpene precursor abundance and demonstrating the highest reported titers in C. glutamicum to date at 1504.6 mg/L. Our designs also evaluated the effects of backbone, promoter, and GPP synthase homolog origin on monoterpene product titers. Monoterpene production was further improved by disrupting competing pathways for isoprenoid precursor supply and by implementing a biphasic production system to prevent volatilization. With this platform, we achieved 321.1 mg/L of geranoids, 723.6 mg/L of 1,8-cineole, and 227.8 mg/L of linalool. Furthermore, we determined that C. glutamicum first oxidizes geraniol through an aldehyde intermediate before it is asymmetrically reduced to citronellol. Additionally, we demonstrate that the aldehyde reductase, AdhC, possesses additional substrate promiscuity for acyclic monoterpene aldehydes.

Published

2024

3. Advances in Engineering Nucleotide Sugar Metabolism for Natural Product Glycosylation in Saccharomyces cerevisiae

Author

Crowe, Samantha A, Crowe, Samantha A, Liu, Yuzhong, Zhao, Xixi, Scheller, Henrik V, Keasling, Jay D, Crowe, Samantha A, Crowe, Samantha A, Liu, Yuzhong, Zhao, Xixi, Scheller, Henrik V, and Keasling, Jay D

Abstract

Glycosylation is a ubiquitous modification present across all of biology, affecting many things such as physicochemical properties, cellular recognition, subcellular localization, and immunogenicity. Nucleotide sugars are important precursors needed to study glycosylation and produce glycosylated products. Saccharomyces cerevisiae is a potentially powerful platform for producing glycosylated biomolecules, but it lacks nucleotide sugar diversity. Nucleotide sugar metabolism is complex, and understanding how to engineer it will be necessary to both access and study heterologous glycosylations found across biology. This review overviews the potential challenges with engineering nucleotide sugar metabolism in yeast from the salvage pathways that convert free sugars to their associated UDP-sugars to de novo synthesis where nucleotide sugars are interconverted through a complex metabolic network with governing feedback mechanisms. Finally, recent examples of engineering complex glycosylation of small molecules in S. cerevisiae are explored and assessed.

Published

2024

4. Verazine Biosynthesis from Simple Sugars in Engineered Saccharomyces cerevisiae

Author

Winegar, Peter H, Winegar, Peter H, Hudson, Graham A, Dell, Luisa B, Astolfi, Maria CT, Reed, James, Payet, Rocky D, Ombredane, Hugo CJ, Iavarone, Anthony T, Chen, Yan, Gin, Jennifer W, Petzold, Christopher J, Osbourn, Anne E, Keasling, Jay D, Winegar, Peter H, Winegar, Peter H, Hudson, Graham A, Dell, Luisa B, Astolfi, Maria CT, Reed, James, Payet, Rocky D, Ombredane, Hugo CJ, Iavarone, Anthony T, Chen, Yan, Gin, Jennifer W, Petzold, Christopher J, Osbourn, Anne E, and Keasling, Jay D

Abstract

Steroidal alkaloids are FDA-approved drugs (e.g., Zytiga) and promising drug candidates/leads (e.g., cyclopamine); yet many of the ≥ 697 known steroidal alkaloid natural products remain underutilized as drugs because it can be challenging to scale their biosynthesis in their producing organisms. Cyclopamine is a steroidal alkaloid produced by corn lily (Veratrum spp.) plants, and it is an inhibitor of the Hedgehog (Hh) signaling pathway. Therefore, cyclopamine is an important drug candidate/lead to treat human diseases that are associated with dysregulated Hh signaling, such as basal cell carcinoma and acute myeloid leukemia. Cyclopamine and its semi-synthetic derivatives have been studied in (pre)clinical trials as Hh inhibitor-based drugs. However, challenges in scaling the production of cyclopamine have slowed efforts to improve its efficacy and safety profile through (bio)synthetic derivatization, often limiting drug development to synthetic analogs of cyclopamine such as the FDA-approved drugs Odomzo, Daurismo, and Erivedge. If a platform for the scalable and sustainable production of cyclopamine were established, then its (bio)synthetic derivatization, clinical development, and, ultimately, widespread distribution could be accelerated. Ongoing efforts to achieve this goal include the biosynthesis of cyclopamine in Veratrum plant cell culture and the semi-/total chemical synthesis of cyclopamine. Herein, this work advances efforts towards a promising future approach: the biosynthesis of cyclopamine in engineered microorganisms. We completed the heterologous microbial production of verazine (biosynthetic precursor to cyclopamine) from simple sugars (i.e., glucose and galactose) in engineered Saccharomyces cerevisiae (S. cerevisiae) through the inducible upregulation of the native yeast mevalonate and lanosterol biosynthetic pathways, diversion of biosynthetic flux from ergosterol (i.e., native sterol in S. cerevisiae) to cholesterol (i.e., biosynthetic precursor

Published

2024

5. Development of Corynebacterium glutamicum as a monoterpene production platform

Author

Luckie, Bridget A., Kashyap, Meera, Pearson, Allison N., Chen, Yan, Liu, Yuzhong, Valencia, Luis E., Romero, Alexander Carrillo, Hudson, Graham A., Tao, Xavier B., Wu, Bryan, Petzold, Christopher J., Keasling, Jay D., Luckie, Bridget A., Kashyap, Meera, Pearson, Allison N., Chen, Yan, Liu, Yuzhong, Valencia, Luis E., Romero, Alexander Carrillo, Hudson, Graham A., Tao, Xavier B., Wu, Bryan, Petzold, Christopher J., and Keasling, Jay D.

Abstract

Monoterpenes are commonly known for their role in the flavors and fragrances industry and are also gaining attention for other uses like insect repellant and as potential renewable fuels for aviation. Corynebacterium glutamicum, a Generally Recognized as Safe microbe, has been a choice organism in industry for the annual million ton-scale bioproduction of amino acids for more than 50 years; however, efforts to produce monoterpenes in C. glutamicum have remained relatively limited. In this study, we report a further expansion of the C. glutamicum biosynthetic repertoire through the development and optimization of a mevalonate-based monoterpene platform. In the course of our plasmid design iterations, we increased flux through the mevalonate-based bypass pathway, measuring isoprenol production as a proxy for monoterpene precursor abundance and demonstrating the highest reported titers in C. glutamicum to date at 1504.6 mg/L. Our designs also evaluated the effects of backbone, promoter, and GPP synthase homolog origin on monoterpene product titers. Monoterpene production was further improved by disrupting competing pathways for isoprenoid precursor supply and by implementing a biphasic production system to prevent volatilization. With this platform, we achieved 321.1 mg/L of geranoids, 723.6 mg/L of 1,8-cineole, and 227.8 mg/L of linalool. Furthermore, we determined that C. glutamicum first oxidizes geraniol through an aldehyde intermediate before it is asymmetrically reduced to citronellol. Additionally, we demonstrate that the aldehyde reductase, AdhC, possesses additional substrate promiscuity for acyclic monoterpene aldehydes.

Published

2024

6. Metabolic engineering of yeast for the production of carbohydrate-derived foods and chemicals from C1–3 molecules

Author

Tang, Hongting, Tang, Hongting, Wu, Lianghuan, Guo, Shuyuan, Cao, Wenbing, Ma, Wenhui, Wang, Xiang, Shen, Junfeng, Wang, Menglin, Zhang, Qiannan, Huang, Mingtao, Luo, Xiaozhou, Zeng, Jie, Keasling, Jay D, Yu, Tao, Tang, Hongting, Tang, Hongting, Wu, Lianghuan, Guo, Shuyuan, Cao, Wenbing, Ma, Wenhui, Wang, Xiang, Shen, Junfeng, Wang, Menglin, Zhang, Qiannan, Huang, Mingtao, Luo, Xiaozhou, Zeng, Jie, Keasling, Jay D, and Yu, Tao

Abstract

The increase in population-related and environmental issues has emphasized the need for more efficient and sustainable production strategies for foods and chemicals. Carbohydrates are macronutrients sourced from crops and undergone transformation into various products ranging from foods to chemicals. Continuous efforts have led to the identification of a promising hybrid system that couples the electrochemical reduction of CO2 to intermediates containing one to three carbons (C1–3) with the transformation of the intermediates using engineered microorganisms into valuable products. Here we use yeast to transform C1–3 substrates into glucose and structurally tailored glucose derivatives, such as the sugar alcohol myo-inositol, the amino monosaccharide glucosamine, the disaccharide sucrose and the polysaccharide starch. By metabolic rewiring and mitigation of glucose repression, the titre of glucose and sucrose reached dozens of grams per litre. These results provide directions for microbial sugar-derived foods and chemicals production from renewable reduced CO2-based feedstocks. [Figure not available: see fulltext.].

Published

2024

7. Complete biosynthesis of the potent vaccine adjuvant QS-21

Author

Martin, Laetitia BB, Martin, Laetitia BB, Kikuchi, Shingo, Rejzek, Martin, Owen, Charlotte, Reed, James, Orme, Anastasia, Misra, Rajesh C, El-Demerdash, Amr, Hill, Lionel, Hodgson, Hannah, Liu, Yuzhong, Keasling, Jay D, Field, Robert A, Truman, Andrew W, Osbourn, Anne, Martin, Laetitia BB, Martin, Laetitia BB, Kikuchi, Shingo, Rejzek, Martin, Owen, Charlotte, Reed, James, Orme, Anastasia, Misra, Rajesh C, El-Demerdash, Amr, Hill, Lionel, Hodgson, Hannah, Liu, Yuzhong, Keasling, Jay D, Field, Robert A, Truman, Andrew W, and Osbourn, Anne

Abstract

QS-21 is a potent vaccine adjuvant currently sourced by extraction from the Chilean soapbark tree. It is a key component of human vaccines for shingles, malaria, coronavirus disease 2019 and others under development. The structure of QS-21 consists of a glycosylated triterpene scaffold coupled to a complex glycosylated 18-carbon acyl chain that is critical for immunostimulant activity. We previously identified the early pathway steps needed to make the triterpene glycoside scaffold; however, the biosynthetic route to the acyl chain, which is needed for stimulation of T cell proliferation, was unknown. Here, we report the biogenic origin of the acyl chain, characterize the series of enzymes required for its synthesis and addition and reconstitute the entire 20-step pathway in tobacco, thereby demonstrating the production of QS-21 in a heterologous expression system. This advance opens up unprecedented opportunities for bioengineering of vaccine adjuvants, investigating structure-activity relationships and understanding the mechanisms by which these compounds promote the human immune response.

Published

2024

8. Edible mycelium bioengineered for enhanced nutritional value and sensory appeal using a modular synthetic biology toolkit

Author

Maini Rekdal, Vayu, van der Luijt, Casper R.B., Chen, Yan, Kakumanu, Ramu, Baidoo, Edward E.K., Petzold, Christopher J., Cruz-Morales, Pablo, Keasling, Jay D., Maini Rekdal, Vayu, van der Luijt, Casper R.B., Chen, Yan, Kakumanu, Ramu, Baidoo, Edward E.K., Petzold, Christopher J., Cruz-Morales, Pablo, and Keasling, Jay D.

Abstract

Filamentous fungi are critical in the transition to a more sustainable food system. While genetic modification of these organisms has promise for enhancing the nutritional value, sensory appeal, and scalability of fungal foods, genetic tools and demonstrated use cases for bioengineered food production by edible strains are lacking. Here, we develop a modular synthetic biology toolkit for Aspergillus oryzae, an edible fungus used in fermented foods, protein production, and meat alternatives. Our toolkit includes a CRISPR-Cas9 method for gene integration, neutral loci, and tunable promoters. We use these tools to elevate intracellular levels of the nutraceutical ergothioneine and the flavor-and color molecule heme in the edible biomass. The strain overproducing heme is red in color and is readily formulated into imitation meat patties with minimal processing. These findings highlight the promise of synthetic biology to enhance fungal foods and provide useful genetic tools for applications in food production and beyond.

Published

2024

9. Edible mycelium bioengineered for enhanced nutritional value and sensory appeal using a modular synthetic biology toolkit

Author

Maini Rekdal, Vayu, van der Luijt, Casper R.B., Chen, Yan, Kakumanu, Ramu, Baidoo, Edward E.K., Petzold, Christopher J., Cruz-Morales, Pablo, Keasling, Jay D., Maini Rekdal, Vayu, van der Luijt, Casper R.B., Chen, Yan, Kakumanu, Ramu, Baidoo, Edward E.K., Petzold, Christopher J., Cruz-Morales, Pablo, and Keasling, Jay D.

Abstract

Filamentous fungi are critical in the transition to a more sustainable food system. While genetic modification of these organisms has promise for enhancing the nutritional value, sensory appeal, and scalability of fungal foods, genetic tools and demonstrated use cases for bioengineered food production by edible strains are lacking. Here, we develop a modular synthetic biology toolkit for Aspergillus oryzae, an edible fungus used in fermented foods, protein production, and meat alternatives. Our toolkit includes a CRISPR-Cas9 method for gene integration, neutral loci, and tunable promoters. We use these tools to elevate intracellular levels of the nutraceutical ergothioneine and the flavor-and color molecule heme in the edible biomass. The strain overproducing heme is red in color and is readily formulated into imitation meat patties with minimal processing. These findings highlight the promise of synthetic biology to enhance fungal foods and provide useful genetic tools for applications in food production and beyond.

Published

2024

10. Foldy:An open-source web application for interactive protein structure analysis

Author

Roberts, Jacob B., Nava, Alberto A., Pearson, Allison N., Incha, Matthew R., Valencia, Luis E., Ma, Melody, Rao, Abhay, Keasling, Jay D., Roberts, Jacob B., Nava, Alberto A., Pearson, Allison N., Incha, Matthew R., Valencia, Luis E., Ma, Melody, Rao, Abhay, and Keasling, Jay D.

Abstract

Foldy is a cloud-based application that allows non-computational biologists to easily utilize advanced AI-based structural biology tools, including AlphaFold and DiffDock. With many deployment options, it can be employed by individuals, labs, universities, and companies in the cloud without requiring hardware resources, but it can also be configured to utilize locally available computers. Foldy enables scientists to predict the structure of proteins and complexes up to 6000 amino acids with AlphaFold, visualize Pfam annotations, and dock ligands with AutoDock Vina and DiffDock. In our manuscript, we detail Foldy’s interface design, deployment strategies, and optimization for various user scenarios. We demonstrate its application through case studies including rational enzyme design and analyzing proteins with domains of unknown function. Furthermore, we compare Foldy’s interface and management capabilities with other open and closed source tools in the field, illustrating its practicality in managing complex data and computation tasks. Our manuscript underlines the benefits of Foldy as a day-to-day tool for life science researchers, and shows how Foldy can make modern tools more accessible and efficient.

Published

2024

11. Pathway Evolution Through a Bottlenecking-Debottlenecking Strategy and Machine Learning-Aided Flux Balancing

Author

Deng, Huaxiang, Yu, Han, Deng, Yanwu, Qiu, Yulan, Li, Feifei, Wang, Xinran, He, Jiahui, Liang, Weiyue, Lan, Yunquan, Qiao, Longjiang, Zhang, Zhiyu, Zhang, Yunfeng, Keasling, Jay D., Luo, Xiaozhou, Deng, Huaxiang, Yu, Han, Deng, Yanwu, Qiu, Yulan, Li, Feifei, Wang, Xinran, He, Jiahui, Liang, Weiyue, Lan, Yunquan, Qiao, Longjiang, Zhang, Zhiyu, Zhang, Yunfeng, Keasling, Jay D., and Luo, Xiaozhou

Abstract

The evolution of pathway enzymes enhances the biosynthesis of high-value chemicals, crucial for pharmaceutical, and agrochemical applications. However, unpredictable evolutionary landscapes of pathway genes often hinder successful evolution. Here, the presence of complex epistasis is identifued within the representative naringenin biosynthetic pathway enzymes, hampering straightforward directed evolution. Subsequently, a biofoundry-assisted strategy is developed for pathway bottlenecking and debottlenecking, enabling the parallel evolution of all pathway enzymes along a predictable evolutionary trajectory in six weeks. This study then utilizes a machine learning model, ProEnsemble, to further balance the pathway by optimizing the transcription of individual genes. The broad applicability of this strategy is demonstrated by constructing an Escherichia coli chassis with evolved and balanced pathway genes, resulting in 3.65 g L−1 naringenin. The optimized naringenin chassis also demonstrates enhanced production of other flavonoids. This approach can be readily adapted for any given number of enzymes in the specific metabolic pathway, paving the way for automated chassis construction in contemporary biofoundries.

Published

2024

12. Complete biosynthesis of the potent vaccine adjuvant QS-21

Author

Martin, Laetitia B.B., Kikuchi, Shingo, Rejzek, Martin, Owen, Charlotte, Reed, James, Orme, Anastasia, Misra, Rajesh C., El-Demerdash, Amr, Hill, Lionel, Hodgson, Hannah, Liu, Yuzhong, Keasling, Jay D., Field, Robert A., Truman, Andrew W., Osbourn, Anne, Martin, Laetitia B.B., Kikuchi, Shingo, Rejzek, Martin, Owen, Charlotte, Reed, James, Orme, Anastasia, Misra, Rajesh C., El-Demerdash, Amr, Hill, Lionel, Hodgson, Hannah, Liu, Yuzhong, Keasling, Jay D., Field, Robert A., Truman, Andrew W., and Osbourn, Anne

Abstract

QS-21 is a potent vaccine adjuvant currently sourced by extraction from the Chilean soapbark tree. It is a key component of human vaccines for shingles, malaria, coronavirus disease 2019 and others under development. The structure of QS-21 consists of a glycosylated triterpene scaffold coupled to a complex glycosylated 18-carbon acyl chain that is critical for immunostimulant activity. We previously identified the early pathway steps needed to make the triterpene glycoside scaffold; however, the biosynthetic route to the acyl chain, which is needed for stimulation of T cell proliferation, was unknown. Here, we report the biogenic origin of the acyl chain, characterize the series of enzymes required for its synthesis and addition and reconstitute the entire 20-step pathway in tobacco, thereby demonstrating the production of QS-21 in a heterologous expression system. This advance opens up unprecedented opportunities for bioengineering of vaccine adjuvants, investigating structure–activity relationships and understanding the mechanisms by which these compounds promote the human immune response. (Figure presented.)

Published

2024

13. Edible mycelium bioengineered for enhanced nutritional value and sensory appeal using a modular synthetic biology toolkit

Author

Maini Rekdal, Vayu, van der Luijt, Casper R.B., Chen, Yan, Kakumanu, Ramu, Baidoo, Edward E.K., Petzold, Christopher J., Cruz-Morales, Pablo, Keasling, Jay D., Maini Rekdal, Vayu, van der Luijt, Casper R.B., Chen, Yan, Kakumanu, Ramu, Baidoo, Edward E.K., Petzold, Christopher J., Cruz-Morales, Pablo, and Keasling, Jay D.

Abstract

Filamentous fungi are critical in the transition to a more sustainable food system. While genetic modification of these organisms has promise for enhancing the nutritional value, sensory appeal, and scalability of fungal foods, genetic tools and demonstrated use cases for bioengineered food production by edible strains are lacking. Here, we develop a modular synthetic biology toolkit for Aspergillus oryzae, an edible fungus used in fermented foods, protein production, and meat alternatives. Our toolkit includes a CRISPR-Cas9 method for gene integration, neutral loci, and tunable promoters. We use these tools to elevate intracellular levels of the nutraceutical ergothioneine and the flavor-and color molecule heme in the edible biomass. The strain overproducing heme is red in color and is readily formulated into imitation meat patties with minimal processing. These findings highlight the promise of synthetic biology to enhance fungal foods and provide useful genetic tools for applications in food production and beyond.

Published

2024

14. Heterologous production of polycyclopropanated fatty acids and their methyl esters in Streptomyces.

Author

Yin, Kevin, Yin, Kevin, Cruz-Morales, Pablo, Whitford, Christopher M, Keasling, Jay D, Yin, Kevin, Yin, Kevin, Cruz-Morales, Pablo, Whitford, Christopher M, and Keasling, Jay D

Abstract

Polycyclopropanated (POP) compounds show promise as fuels as their energy density can be greater than jet and rocket fuels in current use, but realizing their full potential requires significant development. This protocol guides the production of polycyclopropanated fatty acids in Streptomyces; POP production in another host remains to be demonstrated. This method can serve as a baseline for further development of POP as well as other polyketide products. For complete details on the use and execution of this protocol, please refer to Cruz-Morales et al. (2022).1.

Published

2023

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

Author

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

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

16. The pGinger Family of Expression Plasmids.

Author

Pearson, Allison N, Bond, Daniel R1, Pearson, Allison N, Thompson, Mitchell G, Kirkpatrick, Liam D, Ho, Cindy, Vuu, Khanh M, Waldburger, Lucas M, Keasling, Jay D, Shih, Patrick M, Pearson, Allison N, Bond, Daniel R1, Pearson, Allison N, Thompson, Mitchell G, Kirkpatrick, Liam D, Ho, Cindy, Vuu, Khanh M, Waldburger, Lucas M, Keasling, Jay D, and Shih, Patrick M

Abstract

The pGinger suite of expression plasmids comprises 43 plasmids that will enable precise constitutive and inducible gene expression in a wide range of Gram-negative bacterial species. Constitutive vectors are composed of 16 synthetic constitutive promoters upstream of red fluorescent protein (RFP), with a broad-host-range BBR1 origin and a kanamycin resistance marker. The family also has seven inducible systems (Jungle Express, Psal/NahR, Pm/XylS, Prha/RhaS, LacO1/LacI, LacUV5/LacI, and Ptet/TetR) controlling RFP expression on BBR1/kanamycin plasmid backbones. For four of these inducible systems (Jungle Express, Psal/NahR, LacO1/LacI, and Ptet/TetR), we created variants that utilize the RK2 origin and spectinomycin or gentamicin selection. Relevant RFP expression and growth data have been collected in the model bacterium Escherichia coli as well as Pseudomonas putida. All pGinger vectors are available via the Joint BioEnergy Institute (JBEI) Public Registry. IMPORTANCE Metabolic engineering and synthetic biology are predicated on the precise control of gene expression. As synthetic biology expands beyond model organisms, more tools will be required that function robustly in a wide range of bacterial hosts. The pGinger family of plasmids constitutes 43 plasmids that will enable both constitutive and inducible gene expression in a wide range of nonmodel Proteobacteria.

Published

2023

17. Biosensor Guided Polyketide Synthases Engineering for Optimization of Domain Exchange Boundaries

Author

Englund, Elias, Schmidt, Matthias, Nava, Alberto A., Klass, Sarah, Keiser, Leah, Dan, Qingyun, Katz, Leonard, Yuzawa, Satoshi, Keasling, Jay D., Englund, Elias, Schmidt, Matthias, Nava, Alberto A., Klass, Sarah, Keiser, Leah, Dan, Qingyun, Katz, Leonard, Yuzawa, Satoshi, and Keasling, Jay D.

Abstract

Type I modular polyketide synthases (PKSs) are multi-domain enzymes functioning like assembly lines. Many engineering attempts have been made for the last three decades to replace, delete and insert new functional domains into PKSs to produce novel molecules. However, inserting heterologous domains often destabilize PKSs, causing loss of activity and protein misfolding. To address this challenge, here we develop a fluorescence-based solubility biosensor that can quickly identify engineered PKSs variants with minimal structural disruptions. Using this biosensor, we screen a library of acyltransferase (AT)-exchanged PKS hybrids with randomly assigned domain boundaries, and we identify variants that maintain wild type production levels. We then probe each position in the AT linker region to determine how domain boundaries influence structural integrity and identify a set of optimized domain boundaries. Overall, we have successfully developed an experimentally validated, high-throughput method for making hybrid PKSs that produce novel molecules., QC 20230830

Published

2023

18. Expanding Extender Substrate Selection for Unnatural Polyketide Biosynthesis by Acyltransferase Domain Exchange within a Modular Polyketide Synthase

Author

Englund, Elias, Schmidt, Matthias, Nava, Alberto A., Lechner, Anna, Deng, Kai, Jocic, Renee, Lin, Yingxin, Roberts, Jacob, Benites, Veronica T., Kakumanu, Ramu, Gin, Jennifer W., Chen, Yan, Liu, Yuzhong, Petzold, Christopher J., Baidoo, Edward E. K., Northen, Trent R., Adams, Paul D., Katz, Leonard, Yuzawa, Satoshi, Keasling, Jay D., Englund, Elias, Schmidt, Matthias, Nava, Alberto A., Lechner, Anna, Deng, Kai, Jocic, Renee, Lin, Yingxin, Roberts, Jacob, Benites, Veronica T., Kakumanu, Ramu, Gin, Jennifer W., Chen, Yan, Liu, Yuzhong, Petzold, Christopher J., Baidoo, Edward E. K., Northen, Trent R., Adams, Paul D., Katz, Leonard, Yuzawa, Satoshi, and Keasling, Jay D.

Abstract

Modular polyketide synthases (PKSs) are poly-merases that employ alpha-carboxyacyl-CoAs as extender substrates. This enzyme family contains several catalytic modules, where each module is responsible for a single round of polyketide chain extension. Although PKS modules typically use malonyl-CoA or methylmalonyl-CoA for chain elongation, many other malonyl-CoA analogues are used to diversify polyketide structures in nature. Previously, we developed a method to alter an extension substrate of a given module by exchanging an acyltransferase (AT) domain while maintaining protein folding. Here, we report in vitro polyketide biosynthesis by 13 PKSs (the wild-type PKS and 12 AT-exchanged PKSs with unusual ATs) and 14 extender substrates. Our similar to 200 in vitro reactions resulted in 13 structurally different polyketides, including several polyketides that have not been reported. In some cases, AT-exchanged PKSs produced target polyketides by >100-fold compared to the wild-type PKS. These data also indicate that most unusual AT domains do not incorporate malonyl-CoA and methylmalonyl-CoA but incorporate various rare extender substrates that are equal to in size or slightly larger than natural substrates. We developed a computational workflow to predict the approximate AT substrate range based on active site volumes to support the selection of ATs. These results greatly enhance our understanding of rare AT domains and demonstrate the benefit of using the proposed PKS engineering strategy to produce novel chemicals in vitro., QC 20230515

Published

2023

19. Improved polyketide production in C. glutamicum by preventing propionate-induced growth inhibition.

Author

Zhan, Chunjun, Zhan, Chunjun, Lee, Namil, Lan, Guangxu, Dan, Qingyun, Cowan, Aidan, Wang, Zilong, Baidoo, Edward EK, Kakumanu, Ramu, Luckie, Bridget, Kuo, Rita C, McCauley, Joshua, Liu, Yuzhong, Valencia, Luis, Haushalter, Robert W, Keasling, Jay D, Zhan, Chunjun, Zhan, Chunjun, Lee, Namil, Lan, Guangxu, Dan, Qingyun, Cowan, Aidan, Wang, Zilong, Baidoo, Edward EK, Kakumanu, Ramu, Luckie, Bridget, Kuo, Rita C, McCauley, Joshua, Liu, Yuzhong, Valencia, Luis, Haushalter, Robert W, and Keasling, Jay D

Abstract

Corynebacterium glutamicum is a promising host for production of valuable polyketides. Propionate addition, a strategy known to increase polyketide production by increasing intracellular methylmalonyl-CoA availability, causes growth inhibition in C. glutamicum. The mechanism of this inhibition was unclear before our work. Here we provide evidence that accumulation of propionyl-CoA and methylmalonyl-CoA induces growth inhibition in C. glutamicum. We then show that growth inhibition can be relieved by introducing methylmalonyl-CoA-dependent polyketide synthases. With germicidin as an example, we used adaptive laboratory evolution to leverage the fitness advantage of polyketide production in the presence of propionate to evolve improved germicidin production. Whole-genome sequencing revealed mutations in germicidin synthase, which improved germicidin titer, as well as mutations in citrate synthase, which effectively evolved the native glyoxylate pathway to a new methylcitrate pathway. Together, our results show that C. glutamicum is a capable host for polyketide production and we can take advantage of propionate growth inhibition to drive titers higher using laboratory evolution or to screen for production of polyketides.

Published

2023

20. Deciphering triterpenoid saponin biosynthesis by leveraging transcriptome response to methyl jasmonate elicitation in Saponaria vaccaria

Author

Chen, Xiaoyue, Chen, Xiaoyue, Hudson, Graham A, Mineo, Charlotte, Amer, Bashar, Baidoo, Edward EK, Crowe, Samantha A, Liu, Yuzhong, Keasling, Jay D, Scheller, Henrik V, Chen, Xiaoyue, Chen, Xiaoyue, Hudson, Graham A, Mineo, Charlotte, Amer, Bashar, Baidoo, Edward EK, Crowe, Samantha A, Liu, Yuzhong, Keasling, Jay D, and Scheller, Henrik V

Abstract

Methyl jasmonate (MeJA) is a known elicitor of plant specialized metabolism, including triterpenoid saponins. Saponaria vaccaria is an annual herb used in traditional Chinese medicine, containing large quantities of oleanane-type triterpenoid saponins with anticancer properties and structural similarities to the vaccine adjuvant QS-21. Leveraging the MeJA-elicited saponin biosynthesis, we identify multiple enzymes catalyzing the oxidation and glycosylation of triterpenoids in S. vaccaria. This exploration is aided by Pacbio full-length transcriptome sequencing and gene expression analysis. A cellulose synthase-like enzyme can not only glucuronidate triterpenoid aglycones but also alter the product profile of a cytochrome P450 monooxygenase via preference for the aldehyde intermediate. Furthermore, the discovery of a UDP-glucose 4,6-dehydratase and a UDP-4-keto-6-deoxy-glucose reductase reveals the biosynthetic pathway for the rare nucleotide sugar UDP-D-fucose, a likely sugar donor for fucosylation of plant natural products. Our work enables the production and optimization of high-value saponins in microorganisms and plants through synthetic biology approaches.

Published

2023

21. Methods for producing monoterpene indole alkaloids

Author

Jensen, Michael Krogh, Hansen, Lea Gram, Zhang, Jie, Keasling, Jay D, Bradley, Samuel Alan, D'Ambrosio, Vasil, Marcussen, Nils Emil Junge, Jensen, Michael Krogh, Hansen, Lea Gram, Zhang, Jie, Keasling, Jay D, Bradley, Samuel Alan, D'Ambrosio, Vasil, and Marcussen, Nils Emil Junge

Abstract

The present invention relates to microorganisms for producing monoterpene indole al-kaloids (MIAs) and derivatives thereof de novo, including halogenated MIAs and halo-genated derivatives thereof. Also provided herein are methods for producing MIAs and derivatives thereof de novo, in particular halogenated MIAs and derivatives thereof, in a 5 microorganism, as well as useful nucleic acids, vectors and host cells for performing the present methods.

Published

2023

22. From lab to table:Expanding gastronomic possibilities with fermentation using the edible fungus Neurospora intermedia

Author

Rekdal, Vayu Maini, Rodriguez-Valeron, Nabila, Olaizola Garcia, Mikel, Vásquez, Diego Prado, Sörensen, Pia M., Munk, Rasmus, Keasling, Jay D., Rekdal, Vayu Maini, Rodriguez-Valeron, Nabila, Olaizola Garcia, Mikel, Vásquez, Diego Prado, Sörensen, Pia M., Munk, Rasmus, and Keasling, Jay D.

Abstract

Fermentation is a powerful tool for enhancing flavor, improving sustainability, and expanding creative possibilities in the kitchen. However, most fermentations done in gastronomic contexts are restricted to a small set of readily available microbial species. Expanding beyond this limited biological diversity holds promise to unlock new gastronomic innovation. Here, we explore novel culinary applications of Neurospora intermedia, an edible fungus traditionally used in Java, Indonesia to produce the fermented food oncom. Our work demonstrates that N. intermedia can be readily used in the production of oncom-like meat alternatives with non-traditional substrates, as well as in the production of enzymes for starch-to-sugar conversion. As an example, we harness secreted N. intermedia starch-degrading enzymes to produce an amazake that has a distinct volatile aroma composition compared to traditional amazake produced with Aspergillus oryzae. In addition to providing texture and flavor, N. intermedia can be used to add an orange color to dishes due to the development of brightly colored spores and aerial mycelia. This property, along with its secreted enzymes, was utilized to create a dish for fine-dining restaurant Alchemist in Copenhagen, Denmark. Overall, the novel foods produced in this study were rated favorably in consumer trials, indicating a broad sensory appeal of N. intermedia across different culinary applications and cultural contexts. The protocols and approaches presented in this study represent a new addition to the chef's toolbox that hold promise to expand gastronomic possibilities with fermentation in restaurants and beyond.

Published

2023

23. Automated Platform for the Plasmid Construction Process

Author

Nava, Alberto A., Fear, Anna Lisa, Lee, Namil, Mellinger, Peter, Lan, Guangxu, McCauley, Joshua, Tan, Stephen, Kaplan, Nurgul, Goyal, Garima, Coates, R. Cameron, Roberts, Jacob, Johnson, Zahmiria, Hu, Romina, Wu, Bryan, Ahn, Jared, Kim, Woojoo E., Wan, Yao, Yin, Kevin, Hillson, Nathan, Haushalter, Robert W., Keasling, Jay D., Nava, Alberto A., Fear, Anna Lisa, Lee, Namil, Mellinger, Peter, Lan, Guangxu, McCauley, Joshua, Tan, Stephen, Kaplan, Nurgul, Goyal, Garima, Coates, R. Cameron, Roberts, Jacob, Johnson, Zahmiria, Hu, Romina, Wu, Bryan, Ahn, Jared, Kim, Woojoo E., Wan, Yao, Yin, Kevin, Hillson, Nathan, Haushalter, Robert W., and Keasling, Jay D.

Abstract

There is a growing need for applications capable of handling large synthesis biology experiments. At the core of synthetic biology is the process of cloning and manipulating DNA as plasmids. Here, we report the development of an application named DNAda capable of writing automation instructions for any given DNA construct design generated by the J5 DNA assembly program. We also describe the automation pipeline and several useful features. The pipeline is particularly useful for the construction of combinatorial DNA assemblies. Furthermore, we demonstrate the platform by constructing a library of polyketide synthase parts, which includes 120 plasmids ranging in size from 7 to 14 kb from 4 to 7 DNA fragments.

Published

2023

24. Biosynthesis of natural and halogenated plant monoterpene indole alkaloids in yeast

Author

Bradley, Samuel A., Lehka, Beata J., Hansson, Frederik G., Adhikari, Khem B., Rago, Daniela, Rubaszka, Paulina, Haidar, Ahmad K., Chen, Ling, Hansen, Lea G., Gudich, Olga, Giannakou, Konstantina, Lengger, Bettina, Gill, Ryan T., Nakamura, Yoko, de Bernonville, Thomas Dugé, Koudounas, Konstantinos, Romero-Suarez, David, Ding, Ling, Qiao, Yijun, Frimurer, Thomas M., Petersen, Anja A., Besseau, Sébastien, Kumar, Sandeep, Gautron, Nicolas, Melin, Celine, Marc, Jillian, Jeanneau, Remi, O’Connor, Sarah E., Courdavault, Vincent, Keasling, Jay D., Zhang, Jie, Jensen, Michael K., Bradley, Samuel A., Lehka, Beata J., Hansson, Frederik G., Adhikari, Khem B., Rago, Daniela, Rubaszka, Paulina, Haidar, Ahmad K., Chen, Ling, Hansen, Lea G., Gudich, Olga, Giannakou, Konstantina, Lengger, Bettina, Gill, Ryan T., Nakamura, Yoko, de Bernonville, Thomas Dugé, Koudounas, Konstantinos, Romero-Suarez, David, Ding, Ling, Qiao, Yijun, Frimurer, Thomas M., Petersen, Anja A., Besseau, Sébastien, Kumar, Sandeep, Gautron, Nicolas, Melin, Celine, Marc, Jillian, Jeanneau, Remi, O’Connor, Sarah E., Courdavault, Vincent, Keasling, Jay D., Zhang, Jie, and Jensen, Michael K.

Abstract

Monoterpenoid indole alkaloids (MIAs) represent a large class of plant natural products with marketed pharmaceutical activities against a wide range of indications, including cancer, malaria and hypertension. Halogenated MIAs have shown improved pharmaceutical properties; however, synthesis of new-to-nature halogenated MIAs remains a challenge. Here we demonstrate a platform for de novo biosynthesis of two MIAs, serpentine and alstonine, in baker’s yeast Saccharomyces cerevisiae and deploy it to systematically explore the biocatalytic potential of refactored MIA pathways for the production of halogenated MIAs. From this, we demonstrate conversion of individual haloindole derivatives to a total of 19 different new-to-nature haloserpentine and haloalstonine analogs. Furthermore, by process optimization and heterologous expression of a modified halogenase in the microbial MIA platform, we document de novo halogenation and biosynthesis of chloroalstonine. Together, this study highlights a microbial platform for enzymatic exploration and production of complex natural and new-to-nature MIAs with therapeutic potential.

Published

2023

25. Biosensor Guided Polyketide Synthases Engineering for Optimization of Domain Exchange Boundaries

Author

Englund, Elias, Schmidt, Matthias, Nava, Alberto A., Klass, Sarah, Keiser, Leah, Dan, Qingyun, Katz, Leonard, Yuzawa, Satoshi, Keasling, Jay D., Englund, Elias, Schmidt, Matthias, Nava, Alberto A., Klass, Sarah, Keiser, Leah, Dan, Qingyun, Katz, Leonard, Yuzawa, Satoshi, and Keasling, Jay D.

Abstract

Type I modular polyketide synthases (PKSs) are multi-domain enzymes functioning like assembly lines. Many engineering attempts have been made for the last three decades to replace, delete and insert new functional domains into PKSs to produce novel molecules. However, inserting heterologous domains often destabilize PKSs, causing loss of activity and protein misfolding. To address this challenge, here we develop a fluorescence-based solubility biosensor that can quickly identify engineered PKSs variants with minimal structural disruptions. Using this biosensor, we screen a library of acyltransferase (AT)-exchanged PKS hybrids with randomly assigned domain boundaries, and we identify variants that maintain wild type production levels. We then probe each position in the AT linker region to determine how domain boundaries influence structural integrity and identify a set of optimized domain boundaries. Overall, we have successfully developed an experimentally validated, high-throughput method for making hybrid PKSs that produce novel molecules.

Published

2023

26. Heterologous production of polycyclopropanated fatty acids and their methyl esters in Streptomyces

Author

Yin, Kevin, Cruz-Morales, Pablo, Whitford, Christopher M., Keasling, Jay D., Yin, Kevin, Cruz-Morales, Pablo, Whitford, Christopher M., and Keasling, Jay D.

Abstract

Polycyclopropanated (POP) compounds show promise as fuels as their energy density can be greater than jet and rocket fuels in current use, but realizing their full potential requires significant development. This protocol guides the production of polycyclopropanated fatty acids in Streptomyces; POP production in another host remains to be demonstrated. This method can serve as a baseline for further development of POP as well as other polyketide products. For complete details on the use and execution of this protocol, please refer to Cruz-Morales et al. (2022).1

Published

2023

27. Maximizing Heterologous Expression of Engineered Type I Polyketide Synthases:Investigating Codon Optimization Strategies

Author

Schmidt, Matthias, Lee, Namil, Zhan, Chunjun, Roberts, Jacob B., Nava, Alberto A., Keiser, Leah S., Vilchez, Aaron A., Chen, Yan, Petzold, Christopher J., Haushalter, Robert W., Blank, Lars M., Keasling, Jay D., Schmidt, Matthias, Lee, Namil, Zhan, Chunjun, Roberts, Jacob B., Nava, Alberto A., Keiser, Leah S., Vilchez, Aaron A., Chen, Yan, Petzold, Christopher J., Haushalter, Robert W., Blank, Lars M., and Keasling, Jay D.

Abstract

Type I polyketide synthases (T1PKSs) hold enormous potential as a rational production platform for the biosynthesis of specialty chemicals. However, despite great progress in this field, the heterologous expression of PKSs remains a major challenge. One of the first measures to improve heterologous gene expression can be codon optimization. Although controversial, choosing the wrong codon optimization strategy can have detrimental effects on the protein and product levels. In this study, we analyzed 11 different codon variants of an engineered T1PKS and investigated in a systematic approach their influence on heterologous expression in Corynebacterium glutamicum, Escherichia coli, and Pseudomonas putida. Our best performing codon variants exhibited a minimum 50-fold increase in PKS protein levels, which also enabled the production of an unnatural polyketide in each of these hosts. Furthermore, we developed a free online tool (https://basebuddy.lbl.gov) that offers transparent and highly customizable codon optimization with up-to-date codon usage tables. In this work, we not only highlight the significance of codon optimization but also establish the groundwork for the high-throughput assembly and characterization of PKS pathways in alternative hosts.

Published

2023

28. Module-Based Polyketide Synthase Engineering for de Novo Polyketide Biosynthesis

Author

Nava, Alberto A., Roberts, Jacob, Haushalter, Robert W., Wang, Zilong, Keasling, Jay D., Nava, Alberto A., Roberts, Jacob, Haushalter, Robert W., Wang, Zilong, and Keasling, Jay D.

Abstract

Polyketide retrobiosynthesis, where the biosynthetic pathway of a given polyketide can be reversibly engineered due to the colinearity of the polyketide synthase (PKS) structure and function, has the potential to produce millions of organic molecules. Mixing and matching modules from natural PKSs is one of the routes to produce many of these molecules. Evolutionary analysis of PKSs suggests that traditionally used module boundaries may not lead to the most productive hybrid PKSs and that new boundaries around and within the ketosynthase domain may be more active when constructing hybrid PKSs. As this is still a nascent area of research, the generality of these design principles based on existing engineering efforts remains inconclusive. Recent advances in structural modeling and synthetic biology present an opportunity to accelerate PKS engineering by re-evaluating insights gained from previous engineering efforts with cutting edge tools.

Published

2023

29. Maximizing microbial bioproduction from sustainable carbon sources using iterative systems engineering

Author

Eng, Thomas, Banerjee, Deepanwita, Menasalvas, Javier, Chen, Yan, Gin, Jennifer, Choudhary, Hemant, Baidoo, Edward, Chen, Jian Hua, Ekman, Axel, Kakumanu, Ramu, Diercks, Yuzhong Liu, Codik, Alex, Larabell, Carolyn, Gladden, John, Simmons, Blake A., Keasling, Jay D., Petzold, Christopher J., Mukhopadhyay, Aindrila, Eng, Thomas, Banerjee, Deepanwita, Menasalvas, Javier, Chen, Yan, Gin, Jennifer, Choudhary, Hemant, Baidoo, Edward, Chen, Jian Hua, Ekman, Axel, Kakumanu, Ramu, Diercks, Yuzhong Liu, Codik, Alex, Larabell, Carolyn, Gladden, John, Simmons, Blake A., Keasling, Jay D., Petzold, Christopher J., and Mukhopadhyay, Aindrila

Abstract

Maximizing the production of heterologous biomolecules is a complex problem that can be addressed with a systems-level understanding of cellular metabolism and regulation. Specifically, growth-coupling approaches can increase product titers and yields and also enhance production rates. However, implementing these methods for non-canonical carbon streams is challenging due to gaps in metabolic models. Over four design-build-test-learn cycles, we rewire Pseudomonas putida KT2440 for growth-coupled production of indigoidine from para-coumarate. We explore 4,114 potential growth-coupling solutions and refine one design through laboratory evolution and ensemble data-driven methods. The final growth-coupled strain produces 7.3 g/L indigoidine at 77% maximum theoretical yield in para-coumarate minimal medium. The iterative use of growth-coupling designs and functional genomics with experimental validation was highly effective and agnostic to specific hosts, carbon streams, and final products and thus generalizable across many systems.

Published

2023

30. Deciphering triterpenoid saponin biosynthesis by leveraging transcriptome response to methyl jasmonate elicitation in Saponaria vaccaria

Author

Chen, Xiaoyue, Hudson, Graham A., Mineo, Charlotte, Amer, Bashar, Baidoo, Edward E. K., Crowe, Samantha A., Liu, Yuzhong, Keasling, Jay D., Scheller, Henrik V., Chen, Xiaoyue, Hudson, Graham A., Mineo, Charlotte, Amer, Bashar, Baidoo, Edward E. K., Crowe, Samantha A., Liu, Yuzhong, Keasling, Jay D., and Scheller, Henrik V.

Abstract

Methyl jasmonate (MeJA) is a known elicitor of plant specialized metabolism, including triterpenoid saponins. Saponaria vaccaria is an annual herb used in traditional Chinese medicine, containing large quantities of oleanane-type triterpenoid saponins with anticancer properties and structural similarities to the vaccine adjuvant QS-21. Leveraging the MeJA-elicited saponin biosynthesis, we identify multiple enzymes catalyzing the oxidation and glycosylation of triterpenoids in S. vaccaria. This exploration is aided by Pacbio full-length transcriptome sequencing and gene expression analysis. A cellulose synthase-like enzyme can not only glucuronidate triterpenoid aglycones but also alter the product profile of a cytochrome P450 monooxygenase via preference for the aldehyde intermediate. Furthermore, the discovery of a UDP-glucose 4,6-dehydratase and a UDP-4-keto-6-deoxy-glucose reductase reveals the biosynthetic pathway for the rare nucleotide sugar UDP-d-fucose, a likely sugar donor for fucosylation of plant natural products. Our work enables the production and optimization of high-value saponins in microorganisms and plants through synthetic biology approaches.

Published

2023

31. Transcriptome architecture of the three main lineages of agrobacteria

Author

Waldburger, Lucas, Thompson, Mitchell G., Weisberg, Alexandra J., Lee, Namil, Chang, Jeff H. H., Keasling, Jay D., Shih, Patrick M. M., Waldburger, Lucas, Thompson, Mitchell G., Weisberg, Alexandra J., Lee, Namil, Chang, Jeff H. H., Keasling, Jay D., and Shih, Patrick M. M.

Abstract

Transcription start sites (TSSs) are fundamental for understanding gene expression and regulation. Agrobacteria, a group of prokaryotes with the ability to transfer DNA into the genomes of host plants, are widely used in plant biotechnology. However, the genome-wide transcriptional regulation of agrobacteria is not well understood, especially in less-studied lineages. Differential RNA-seq and an optimized algorithm enabled identification of thousands of TSSs with nucleotide resolution for representatives of each lineage. The results of this study provide a framework for elucidating the mechanistic basis and evolution of pathology across the three main lineages of agrobacteria. The optimized algorithm also highlights the importance of parameter optimization in genome-wide TSS identification and genomics at large. Agrobacteria are a diverse, polyphyletic group of prokaryotes with multipartite genomes capable of transferring DNA into the genomes of host plants, making them an essential tool in plant biotechnology. Despite their utility in plant transformation, genome-wide transcriptional regulation is not well understood across the three main lineages of agrobacteria. Transcription start sites (TSSs) are a necessary component of gene expression and regulation. In this study, we used differential RNA-seq and a TSS identification algorithm optimized on manually annotated TSS, then validated with existing TSS to identify thousands of TSS with nucleotide resolution for representatives of each lineage. We extend upon the 356 TSSs previously reported in Agrobacterium fabrum C58 by identifying 1,916 TSSs. In addition, we completed genomes and phenotyping of Rhizobium rhizogenes C16/80 and Allorhizobium vitis T60/94, identifying 2,650 and 2,432 TSSs, respectively. Parameter optimization was crucial for an accurate, high-resolution view of genome and transcriptional dynamics, highlighting the importance of algorithm optimization in genome-wide TSS identific

Published

2023

32. The pGinger Family of Expression Plasmids

Author

Pearson, Allison N., Thompson, Mitchell G., Kirkpatrick, Liam D., Ho, Cindy, Vuu, Khanh M., Waldburger, Lucas M., Keasling, Jay D., Shih, Patrick M., Pearson, Allison N., Thompson, Mitchell G., Kirkpatrick, Liam D., Ho, Cindy, Vuu, Khanh M., Waldburger, Lucas M., Keasling, Jay D., and Shih, Patrick M.

Abstract

The pGinger suite of expression plasmids comprises 43 plasmids that will enable precise constitutive and inducible gene expression in a wide range of Gram-negative bacterial species. Constitutive vectors are composed of 16 synthetic constitutive promoters upstream of red fluorescent protein (RFP), with a broad-host-range BBR1 origin and a kanamycin resistance marker. The family also has seven inducible systems (Jungle Express, Psal/NahR, Pm/XylS, Prha/RhaS, LacO1/LacI, LacUV5/LacI, and Ptet/TetR) controlling RFP expression on BBR1/kanamycin plasmid backbones. For four of these inducible systems (Jungle Express, Psal/NahR, LacO1/LacI, and Ptet/TetR), we created variants that utilize the RK2 origin and spectinomycin or gentamicin selection. Relevant RFP expression and growth data have been collected in the model bacterium Escherichia coli as well as Pseudomonas putida. All pGinger vectors are available via the Joint BioEnergy Institute (JBEI) Public Registry.IMPORTANCE Metabolic engineering and synthetic biology are predicated on the precise control of gene expression. As synthetic biology expands beyond model organisms, more tools will be required that function robustly in a wide range of bacterial hosts. The pGinger family of plasmids constitutes 43 plasmids that will enable both constitutive and inducible gene expression in a wide range of nonmodel Proteobacteria. Metabolic engineering and synthetic biology are predicated on the precise control of gene expression. As synthetic biology expands beyond model organisms, more tools will be required that function robustly in a wide range of bacterial hosts. The pGinger family of plasmids constitutes 43 plasmids that will enable both constitutive and inducible gene expression in a wide range of nonmodel Proteobacteria.

Published

2023

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

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 . 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

34. Microbial production of fuels, commodity chemicals, and materials from sustainable sources of carbon and energy

Author

Cowan, Aidan E, Cowan, Aidan E, Klass, Sarah H, Winegar, Peter H, Keasling, Jay D, Cowan, Aidan E, Cowan, Aidan E, Klass, Sarah H, Winegar, Peter H, and Keasling, Jay D

Abstract

Anthropogenic carbon emissions are driving rapid changes to the earth's climate, disrupting whole ecosystems and endangering the stability of human society. Innovations in engineered microbial fermentation enable the fossil resource-free production of fuels, commodity chemicals, and materials, thereby reducing the carbon emissions associated with these products. Microorganisms have been engineered to catabolize sustainable sources of carbon and energy (i.e., plant biomass, plastic waste, and one-carbon feedstocks) and biosynthesize carbon-neutral or carbon-negative products. These engineering efforts exploit and optimize natural biological pathways or generate unnatural pathways which can biosynthesize chemicals that have not yet been accessed using synthetic chemistry. Recent advances in microbial fermentation seek not only to maximize the titer, rate, and yield of desired products, but also to tailor microbial catabolism to utilize inexpensive feedstocks. Ultimately, these advances aim to lower the cost of bioproduction so that microorganism-derived chemicals can be economically competitive with fossil-derived chemicals.

Published

2023

35. Biosynthesis of natural and halogenated plant monoterpene indole alkaloids in yeast

Author

Bradley, Samuel A., Lehka, Beata J., Hansson, Frederik G., Adhikari, Khem B., Rago, Daniela, Rubaszka, Paulina, Haidar, Ahmad K., Chen, Ling, Hansen, Lea G., Gudich, Olga, Giannakou, Konstantina, Lengger, Bettina, Gill, Ryan T., Nakamura, Yoko, de Bernonville, Thomas Dugé, Koudounas, Konstantinos, Romero-Suarez, David, Ding, Ling, Qiao, Yijun, Frimurer, Thomas M., Petersen, Anja A., Besseau, Sébastien, Kumar, Sandeep, Gautron, Nicolas, Melin, Celine, Marc, Jillian, Jeanneau, Remi, O’Connor, Sarah E., Courdavault, Vincent, Keasling, Jay D., Zhang, Jie, Jensen, Michael K., Bradley, Samuel A., Lehka, Beata J., Hansson, Frederik G., Adhikari, Khem B., Rago, Daniela, Rubaszka, Paulina, Haidar, Ahmad K., Chen, Ling, Hansen, Lea G., Gudich, Olga, Giannakou, Konstantina, Lengger, Bettina, Gill, Ryan T., Nakamura, Yoko, de Bernonville, Thomas Dugé, Koudounas, Konstantinos, Romero-Suarez, David, Ding, Ling, Qiao, Yijun, Frimurer, Thomas M., Petersen, Anja A., Besseau, Sébastien, Kumar, Sandeep, Gautron, Nicolas, Melin, Celine, Marc, Jillian, Jeanneau, Remi, O’Connor, Sarah E., Courdavault, Vincent, Keasling, Jay D., Zhang, Jie, and Jensen, Michael K.

Abstract

Monoterpenoid indole alkaloids (MIAs) represent a large class of plant natural products with marketed pharmaceutical activities against a wide range of indications, including cancer, malaria and hypertension. Halogenated MIAs have shown improved pharmaceutical properties; however, synthesis of new-to-nature halogenated MIAs remains a challenge. Here we demonstrate a platform for de novo biosynthesis of two MIAs, serpentine and alstonine, in baker’s yeast Saccharomyces cerevisiae and deploy it to systematically explore the biocatalytic potential of refactored MIA pathways for the production of halogenated MIAs. From this, we demonstrate conversion of individual haloindole derivatives to a total of 19 different new-to-nature haloserpentine and haloalstonine analogs. Furthermore, by process optimization and heterologous expression of a modified halogenase in the microbial MIA platform, we document de novo halogenation and biosynthesis of chloroalstonine. Together, this study highlights a microbial platform for enzymatic exploration and production of complex natural and new-to-nature MIAs with therapeutic potential.

Published

2023

36. Biosynthesis of natural and halogenated plant monoterpene indole alkaloids in yeast

Author

Bradley, Samuel A., Lehka, Beata J., Hansson, Frederik G., Adhikari, Khem B., Rago, Daniela, Rubaszka, Paulina, Haidar, Ahmad K., Chen, Ling, Hansen, Lea G., Gudich, Olga, Giannakou, Konstantina, Lengger, Bettina, Gill, Ryan T., Nakamura, Yoko, de Bernonville, Thomas Dugé, Koudounas, Konstantinos, Romero-Suarez, David, Ding, Ling, Qiao, Yijun, Frimurer, Thomas M., Petersen, Anja A., Besseau, Sébastien, Kumar, Sandeep, Gautron, Nicolas, Melin, Celine, Marc, Jillian, Jeanneau, Remi, O’Connor, Sarah E., Courdavault, Vincent, Keasling, Jay D., Zhang, Jie, Jensen, Michael K., Bradley, Samuel A., Lehka, Beata J., Hansson, Frederik G., Adhikari, Khem B., Rago, Daniela, Rubaszka, Paulina, Haidar, Ahmad K., Chen, Ling, Hansen, Lea G., Gudich, Olga, Giannakou, Konstantina, Lengger, Bettina, Gill, Ryan T., Nakamura, Yoko, de Bernonville, Thomas Dugé, Koudounas, Konstantinos, Romero-Suarez, David, Ding, Ling, Qiao, Yijun, Frimurer, Thomas M., Petersen, Anja A., Besseau, Sébastien, Kumar, Sandeep, Gautron, Nicolas, Melin, Celine, Marc, Jillian, Jeanneau, Remi, O’Connor, Sarah E., Courdavault, Vincent, Keasling, Jay D., Zhang, Jie, and Jensen, Michael K.

Abstract

Monoterpenoid indole alkaloids (MIAs) represent a large class of plant natural products with marketed pharmaceutical activities against a wide range of indications, including cancer, malaria and hypertension. Halogenated MIAs have shown improved pharmaceutical properties; however, synthesis of new-to-nature halogenated MIAs remains a challenge. Here we demonstrate a platform for de novo biosynthesis of two MIAs, serpentine and alstonine, in baker’s yeast Saccharomyces cerevisiae and deploy it to systematically explore the biocatalytic potential of refactored MIA pathways for the production of halogenated MIAs. From this, we demonstrate conversion of individual haloindole derivatives to a total of 19 different new-to-nature haloserpentine and haloalstonine analogs. Furthermore, by process optimization and heterologous expression of a modified halogenase in the microbial MIA platform, we document de novo halogenation and biosynthesis of chloroalstonine. Together, this study highlights a microbial platform for enzymatic exploration and production of complex natural and new-to-nature MIAs with therapeutic potential.

Published

2023

37. UniKP:a unified framework for the prediction of enzyme kinetic parameters

Author

Yu, Han, Deng, Huaxiang, He, Jiahui, Keasling, Jay D., Luo, Xiaozhou, Yu, Han, Deng, Huaxiang, He, Jiahui, Keasling, Jay D., and Luo, Xiaozhou

Abstract

Prediction of enzyme kinetic parameters is essential for designing and optimizing enzymes for various biotechnological and industrial applications, but the limited performance of current prediction tools on diverse tasks hinders their practical applications. Here, we introduce UniKP, a unified framework based on pretrained language models for the prediction of enzyme kinetic parameters, including enzyme turnover number (k cat), Michaelis constant (K m), and catalytic efficiency (k cat / K m), from protein sequences and substrate structures. A two-layer framework derived from UniKP (EF-UniKP) has also been proposed to allow robust k cat prediction in considering environmental factors, including pH and temperature. In addition, four representative re-weighting methods are systematically explored to successfully reduce the prediction error in high-value prediction tasks. We have demonstrated the application of UniKP and EF-UniKP in several enzyme discovery and directed evolution tasks, leading to the identification of new enzymes and enzyme mutants with higher activity. UniKP is a valuable tool for deciphering the mechanisms of enzyme kinetics and enables novel insights into enzyme engineering and their industrial applications.

Published

2023

38. A FAIR-compliant parts catalogue for genome engineering and expression control in Saccharomyces cerevisiae.

Author

D'Ambrosio, Vasil, D'Ambrosio, Vasil, Hansen, Lea G, Zhang, Jie, Jensen, Emil D, Arsovska, Dushica, Laloux, Marcos, Jakočiūnas, Tadas, Hjort, Pernille, De Lucrezia, Davide, Marletta, Serena, Keasling, Jay D, Jensen, Michael K, D'Ambrosio, Vasil, D'Ambrosio, Vasil, Hansen, Lea G, Zhang, Jie, Jensen, Emil D, Arsovska, Dushica, Laloux, Marcos, Jakočiūnas, Tadas, Hjort, Pernille, De Lucrezia, Davide, Marletta, Serena, Keasling, Jay D, and Jensen, Michael K

Abstract

The synthetic biology toolkit for baker's yeast, Saccharomyces cerevisiae, includes extensive genome engineering toolkits and parts repositories. However, with the increasing complexity of engineering tasks and versatile applications of this model eukaryote, there is a continued interest to expand and diversify the rational engineering capabilities in this chassis by FAIR (findable, accessible, interoperable, and reproducible) compliance. In this study, we designed and characterised 41 synthetic guide RNA sequences to expand the CRISPR-based genome engineering capabilities for easy and efficient replacement of genomically encoded elements. Moreover, we characterize in high temporal resolution 20 native promoters and 18 terminators using fluorescein and LUDOX CL-X as references for GFP expression and OD600 measurements, respectively. Additionally, all data and reported analysis is provided in a publicly accessible jupyter notebook providing a tool for researchers with low-coding skills to further explore the generated data as well as a template for researchers to write their own scripts. We expect the data, parts, and databases associated with this study to support a FAIR-compliant resource for further advancing the engineering of yeasts.

Published

2022

39. Enhancing Terminal Deoxynucleotidyl Transferase Activity on Substrates with 3′ Terminal Structures for Enzymatic De Novo DNA Synthesis

Author

Barthel, Sebastian, Palluk, Sebastian, Hillson, Nathan J., Keasling, Jay D., Arlow, Daniel H., Barthel, Sebastian, Palluk, Sebastian, Hillson, Nathan J., Keasling, Jay D., and Arlow, Daniel H.

Abstract

Enzymatic oligonucleotide synthesis methods based on the template-independent polymerase terminal deoxynucleotidyl transferase (TdT) promise to enable the de novo synthesis of long oligonucleotides under mild, aqueous conditions. Intermediates with a 30 terminal structure (hairpins) will inevitably arise during synthesis, but TdT has poor activity on these structured substrates, limiting its usefulness for oligonucleotide synthesis. Here, we described two parallel efforts to improve the activity of TdT on hairpins: (1) optimization of the concentrations of the divalent cation cofactors and (2) engineering TdT for enhanced thermostability, enabling reactions at elevated temperatures. By combining both of these improvements, we obtained a ~10-fold increase in the elongation rate of a guanine-cytosine hairpin.

Published

2022

40. Enhancing Terminal Deoxynucleotidyl Transferase Activity on Substrates with 3′ Terminal Structures for Enzymatic De Novo DNA Synthesis

Author

Barthel, Sebastian, Palluk, Sebastian, Hillson, Nathan J., Keasling, Jay D., Arlow, Daniel H., Barthel, Sebastian, Palluk, Sebastian, Hillson, Nathan J., Keasling, Jay D., and Arlow, Daniel H.

Abstract

Enzymatic oligonucleotide synthesis methods based on the template-independent polymerase terminal deoxynucleotidyl transferase (TdT) promise to enable the de novo synthesis of long oligonucleotides under mild, aqueous conditions. Intermediates with a 30 terminal structure (hairpins) will inevitably arise during synthesis, but TdT has poor activity on these structured substrates, limiting its usefulness for oligonucleotide synthesis. Here, we described two parallel efforts to improve the activity of TdT on hairpins: (1) optimization of the concentrations of the divalent cation cofactors and (2) engineering TdT for enhanced thermostability, enabling reactions at elevated temperatures. By combining both of these improvements, we obtained a ~10-fold increase in the elongation rate of a guanine-cytosine hairpin.

Published

2022

41. Circularity in mixed-plastic chemical recycling enabled by variable rates of polydiketoenamine hydrolysis.

Author

Demarteau, Jeremy, Demarteau, Jeremy, Epstein, Alexander R, Christensen, Peter R, Abubekerov, Mark, Wang, Hai, Teat, Simon J, Seguin, Trevor J, Chan, Christopher W, Scown, Corinne D, Russell, Thomas P, Keasling, Jay D, Persson, Kristin A, Helms, Brett A, Demarteau, Jeremy, Demarteau, Jeremy, Epstein, Alexander R, Christensen, Peter R, Abubekerov, Mark, Wang, Hai, Teat, Simon J, Seguin, Trevor J, Chan, Christopher W, Scown, Corinne D, Russell, Thomas P, Keasling, Jay D, Persson, Kristin A, and Helms, Brett A

Abstract

Footwear, carpet, automotive interiors, and multilayer packaging are examples of products manufactured from several types of polymers whose inextricability poses substantial challenges for recycling at the end of life. Here, we show that chemical circularity in mixed-polymer recycling becomes possible by controlling the rates of depolymerization of polydiketoenamines (PDK) over several orders of magnitude through molecular engineering. Stepwise deconstruction of mixed-PDK composites, laminates, and assemblies is chemospecific, allowing a prescribed subset of monomers, fillers, and additives to be recovered under pristine condition at each stage of the recycling process. We provide a theoretical framework to understand PDK depolymerization via acid-catalyzed hydrolysis and experimentally validate trends predicted for the rate-limiting step. The control achieved by PDK resins in managing chemical and material entropy points to wide-ranging opportunities for pairing circular design with sustainable manufacturing.

Published

2022

42. Advanced one-pot deconstruction and valorization of lignocellulosic biomass into triacetic acid lactone using Rhodosporidium toruloides.

Author

Otoupal, Peter B, Otoupal, Peter B, Geiselman, Gina M, Oka, Asun M, Barcelos, Carolina A, Choudhary, Hemant, Dinh, Duy, Zhong, Wenqing, Hwang, HeeJin, Keasling, Jay D, Mukhopadhyay, Aindrila, Sundstrom, Eric, Haushalter, Robert W, Sun, Ning, Simmons, Blake A, Gladden, John M, Otoupal, Peter B, Otoupal, Peter B, Geiselman, Gina M, Oka, Asun M, Barcelos, Carolina A, Choudhary, Hemant, Dinh, Duy, Zhong, Wenqing, Hwang, HeeJin, Keasling, Jay D, Mukhopadhyay, Aindrila, Sundstrom, Eric, Haushalter, Robert W, Sun, Ning, Simmons, Blake A, and Gladden, John M

Abstract

BackgroundRhodosporidium toruloides is capable of co-utilization of complex carbon sources and robust growth from lignocellulosic hydrolysates. This oleaginous yeast is therefore an attractive host for heterologous production of valuable bioproducts at high titers from low-cost, deconstructed biomass in an economically and environmentally sustainable manner. Here we demonstrate this by engineering R. toruloides to produce the polyketide triacetic acid lactone (TAL) directly from unfiltered hydrolysate deconstructed from biomass with minimal unit process operations.ResultsIntroduction of the 2-pyrone synthase gene into R. toruloides enabled the organism to produce 2.4 g/L TAL from simple media or 2.0 g/L from hydrolysate produced from sorghum biomass. Both of these titers are on par with titers from other better-studied microbial hosts after they had been heavily engineered. We next demonstrate that filtered hydrolysates produced from ensiled sorghum are superior to those derived from dried sorghum for TAL production, likely due to the substantial organic acids produced during ensiling. We also demonstrate that the organic acids found in ensiled biomass can be used for direct synthesis of ionic liquids within the biomass pretreatment process, enabling consolidation of unit operations of in-situ ionic liquid synthesis, pretreatment, saccharification, and fermentation into a one-pot, separations-free process. Finally, we demonstrate this consolidation in a 2 L bioreactor using unfiltered hydrolysate, producing 3.9 g/L TAL.ConclusionMany steps involved in deconstructing biomass into fermentable substrate can be combined into a distinct operation, and directly fed to cultures of engineered R. toruloides cultures for subsequent valorization into gram per liter titers of TAL in a cost-effective manner.

Published

2022

43. A FAIR-compliant parts catalogue for genome engineering and expression control in Saccharomyces cerevisiae.

Author

D'Ambrosio, Vasil, D'Ambrosio, Vasil, Hansen, Lea G, Zhang, Jie, Jensen, Emil D, Arsovska, Dushica, Laloux, Marcos, Jakočiūnas, Tadas, Hjort, Pernille, De Lucrezia, Davide, Marletta, Serena, Keasling, Jay D, Jensen, Michael K, D'Ambrosio, Vasil, D'Ambrosio, Vasil, Hansen, Lea G, Zhang, Jie, Jensen, Emil D, Arsovska, Dushica, Laloux, Marcos, Jakočiūnas, Tadas, Hjort, Pernille, De Lucrezia, Davide, Marletta, Serena, Keasling, Jay D, and Jensen, Michael K

Abstract

The synthetic biology toolkit for baker's yeast, Saccharomyces cerevisiae, includes extensive genome engineering toolkits and parts repositories. However, with the increasing complexity of engineering tasks and versatile applications of this model eukaryote, there is a continued interest to expand and diversify the rational engineering capabilities in this chassis by FAIR (findable, accessible, interoperable, and reproducible) compliance. In this study, we designed and characterised 41 synthetic guide RNA sequences to expand the CRISPR-based genome engineering capabilities for easy and efficient replacement of genomically encoded elements. Moreover, we characterize in high temporal resolution 20 native promoters and 18 terminators using fluorescein and LUDOX CL-X as references for GFP expression and OD600 measurements, respectively. Additionally, all data and reported analysis is provided in a publicly accessible jupyter notebook providing a tool for researchers with low-coding skills to further explore the generated data as well as a template for researchers to write their own scripts. We expect the data, parts, and databases associated with this study to support a FAIR-compliant resource for further advancing the engineering of yeasts.

Published

2022

44. Circularity in mixed-plastic chemical recycling enabled by variable rates of polydiketoenamine hydrolysis.

Author

Demarteau, Jeremy, Demarteau, Jeremy, Epstein, Alexander R, Christensen, Peter R, Abubekerov, Mark, Wang, Hai, Teat, Simon J, Seguin, Trevor J, Chan, Christopher W, Scown, Corinne D, Russell, Thomas P, Keasling, Jay D, Persson, Kristin A, Helms, Brett A, Demarteau, Jeremy, Demarteau, Jeremy, Epstein, Alexander R, Christensen, Peter R, Abubekerov, Mark, Wang, Hai, Teat, Simon J, Seguin, Trevor J, Chan, Christopher W, Scown, Corinne D, Russell, Thomas P, Keasling, Jay D, Persson, Kristin A, and Helms, Brett A

Abstract

Footwear, carpet, automotive interiors, and multilayer packaging are examples of products manufactured from several types of polymers whose inextricability poses substantial challenges for recycling at the end of life. Here, we show that chemical circularity in mixed-polymer recycling becomes possible by controlling the rates of depolymerization of polydiketoenamines (PDK) over several orders of magnitude through molecular engineering. Stepwise deconstruction of mixed-PDK composites, laminates, and assemblies is chemospecific, allowing a prescribed subset of monomers, fillers, and additives to be recovered under pristine condition at each stage of the recycling process. We provide a theoretical framework to understand PDK depolymerization via acid-catalyzed hydrolysis and experimentally validate trends predicted for the rate-limiting step. The control achieved by PDK resins in managing chemical and material entropy points to wide-ranging opportunities for pairing circular design with sustainable manufacturing.

Published

2022

45. Nitrogen Metabolism in Pseudomonas putida: Functional Analysis Using Random Barcode Transposon Sequencing.

Author

Schmidt, Matthias, Zhou, Ning-Yi1, Schmidt, Matthias, Pearson, Allison N, Incha, Matthew R, Thompson, Mitchell G, Baidoo, Edward EK, Kakumanu, Ramu, Mukhopadhyay, Aindrila, Shih, Patrick M, Deutschbauer, Adam M, Blank, Lars M, Keasling, Jay D, Schmidt, Matthias, Zhou, Ning-Yi1, Schmidt, Matthias, Pearson, Allison N, Incha, Matthew R, Thompson, Mitchell G, Baidoo, Edward EK, Kakumanu, Ramu, Mukhopadhyay, Aindrila, Shih, Patrick M, Deutschbauer, Adam M, Blank, Lars M, and Keasling, Jay D

Abstract

Pseudomonas putida KT2440 has long been studied for its diverse and robust metabolisms, yet many genes and proteins imparting these growth capacities remain uncharacterized. Using pooled mutant fitness assays, we identified genes and proteins involved in the assimilation of 52 different nitrogen containing compounds. To assay amino acid biosynthesis, 19 amino acid drop-out conditions were also tested. From these 71 conditions, significant fitness phenotypes were elicited in 672 different genes including 100 transcriptional regulators and 112 transport-related proteins. We divide these conditions into 6 classes, and propose assimilatory pathways for the compounds based on this wealth of genetic data. To complement these data, we characterize the substrate range of three promiscuous aminotransferases relevant to metabolic engineering efforts in vitro. Furthermore, we examine the specificity of five transcriptional regulators, explaining some fitness data results and exploring their potential to be developed into useful synthetic biology tools. In addition, we use manifold learning to create an interactive visualization tool for interpreting our BarSeq data, which will improve the accessibility and utility of this work to other researchers. IMPORTANCE Understanding the genetic basis of P. putida's diverse metabolism is imperative for us to reach its full potential as a host for metabolic engineering. Many target molecules of the bioeconomy and their precursors contain nitrogen. This study provides functional evidence linking hundreds of genes to their roles in the metabolism of nitrogenous compounds, and provides an interactive tool for visualizing these data. We further characterize several aminotransferases, lactamases, and regulators, which are of particular interest for metabolic engineering.

Published

2022

46. A microbial supply chain for production of the anti-cancer drug vinblastine.

Author

Zhang, Jie, Zhang, Jie, Hansen, Lea G, Gudich, Olga, Viehrig, Konrad, Lassen, Lærke MM, Schrübbers, Lars, Adhikari, Khem B, Rubaszka, Paulina, Carrasquer-Alvarez, Elena, Chen, Ling, D'Ambrosio, Vasil, Lehka, Beata, Haidar, Ahmad K, Nallapareddy, Saranya, Giannakou, Konstantina, Laloux, Marcos, Arsovska, Dushica, Jørgensen, Marcus AK, Chan, Leanne Jade G, Kristensen, Mette, Christensen, Hanne B, Sudarsan, Suresh, Stander, Emily A, Baidoo, Edward, Petzold, Christopher J, Wulff, Tune, O'Connor, Sarah E, Courdavault, Vincent, Jensen, Michael K, Keasling, Jay D, Zhang, Jie, Zhang, Jie, Hansen, Lea G, Gudich, Olga, Viehrig, Konrad, Lassen, Lærke MM, Schrübbers, Lars, Adhikari, Khem B, Rubaszka, Paulina, Carrasquer-Alvarez, Elena, Chen, Ling, D'Ambrosio, Vasil, Lehka, Beata, Haidar, Ahmad K, Nallapareddy, Saranya, Giannakou, Konstantina, Laloux, Marcos, Arsovska, Dushica, Jørgensen, Marcus AK, Chan, Leanne Jade G, Kristensen, Mette, Christensen, Hanne B, Sudarsan, Suresh, Stander, Emily A, Baidoo, Edward, Petzold, Christopher J, Wulff, Tune, O'Connor, Sarah E, Courdavault, Vincent, Jensen, Michael K, and Keasling, Jay D

Abstract

Monoterpene indole alkaloids (MIAs) are a diverse family of complex plant secondary metabolites with many medicinal properties, including the essential anti-cancer therapeutics vinblastine and vincristine1. As MIAs are difficult to chemically synthesize, the world's supply chain for vinblastine relies on low-yielding extraction and purification of the precursors vindoline and catharanthine from the plant Catharanthus roseus, which is then followed by simple in vitro chemical coupling and reduction to form vinblastine at an industrial scale2,3. Here, we demonstrate the de novo microbial biosynthesis of vindoline and catharanthine using a highly engineered yeast, and in vitro chemical coupling to vinblastine. The study showcases a very long biosynthetic pathway refactored into a microbial cell factory, including 30 enzymatic steps beyond the yeast native metabolites geranyl pyrophosphate and tryptophan to catharanthine and vindoline. In total, 56 genetic edits were performed, including expression of 34 heterologous genes from plants, as well as deletions, knock-downs and overexpression of ten yeast genes to improve precursor supplies towards de novo production of catharanthine and vindoline, from which semisynthesis to vinblastine occurs. As the vinblastine pathway is one of the longest MIA biosynthetic pathways, this study positions yeast as a scalable platform to produce more than 3,000 natural MIAs and a virtually infinite number of new-to-nature analogues.

Published

2022

47. Enhancing Terminal Deoxynucleotidyl Transferase Activity on Substrates with 3′ Terminal Structures for Enzymatic De Novo DNA Synthesis

Author

Barthel, Sebastian, Palluk, Sebastian, Hillson, Nathan J., Keasling, Jay D., Arlow, Daniel H., Barthel, Sebastian, Palluk, Sebastian, Hillson, Nathan J., Keasling, Jay D., and Arlow, Daniel H.

Abstract

Enzymatic oligonucleotide synthesis methods based on the template-independent polymerase terminal deoxynucleotidyl transferase (TdT) promise to enable the de novo synthesis of long oligonucleotides under mild, aqueous conditions. Intermediates with a 30 terminal structure (hairpins) will inevitably arise during synthesis, but TdT has poor activity on these structured substrates, limiting its usefulness for oligonucleotide synthesis. Here, we described two parallel efforts to improve the activity of TdT on hairpins: (1) optimization of the concentrations of the divalent cation cofactors and (2) engineering TdT for enhanced thermostability, enabling reactions at elevated temperatures. By combining both of these improvements, we obtained a ~10-fold increase in the elongation rate of a guanine-cytosine hairpin.

Published

2022

48. Engineering Pseudomonas putida KT2440 for chain length tailored free fatty acid and oleochemical production.

Author

Valencia, Luis E, Valencia, Luis E, Incha, Matthew R, Schmidt, Matthias, Pearson, Allison N, Thompson, Mitchell G, Roberts, Jacob B, Mehling, Marina, Yin, Kevin, Sun, Ning, Oka, Asun, Shih, Patrick M, Blank, Lars M, Gladden, John, Keasling, Jay D, Valencia, Luis E, Valencia, Luis E, Incha, Matthew R, Schmidt, Matthias, Pearson, Allison N, Thompson, Mitchell G, Roberts, Jacob B, Mehling, Marina, Yin, Kevin, Sun, Ning, Oka, Asun, Shih, Patrick M, Blank, Lars M, Gladden, John, and Keasling, Jay D

Abstract

Despite advances in understanding the metabolism of Pseudomonas putida KT2440, a promising bacterial host for producing valuable chemicals from plant-derived feedstocks, a strain capable of producing free fatty acid-derived chemicals has not been developed. Guided by functional genomics, we engineered P. putida to produce medium- and long-chain free fatty acids (FFAs) to titers of up to 670 mg/L. Additionally, by taking advantage of the varying substrate preferences of paralogous native fatty acyl-CoA ligases, we employed a strategy to control FFA chain length that resulted in a P. putida strain specialized in producing medium-chain FFAs. Finally, we demonstrate the production of oleochemicals in these strains by synthesizing medium-chain fatty acid methyl esters, compounds useful as biodiesel blending agents, in various media including sorghum hydrolysate at titers greater than 300 mg/L. This work paves the road to produce high-value oleochemicals and biofuels from cheap feedstocks, such as plant biomass, using this host.

Published

2022

49. Assembly and Evolution of Artificial Metalloenzymes within E. coli Nissle 1917 for Enantioselective and Site-Selective Functionalization of CH and CC Bonds

Author

Liu, Zhennan, Liu, Zhennan, Huang, Jing, Gu, Yang, Clark, Douglas S, Mukhopadhyay, Aindrila, Keasling, Jay D, Hartwig, John F, Liu, Zhennan, Liu, Zhennan, Huang, Jing, Gu, Yang, Clark, Douglas S, Mukhopadhyay, Aindrila, Keasling, Jay D, and Hartwig, John F

Abstract

The potential applications afforded by the generation and reactivity of artificial metalloenzymes (ArMs) in microorganisms are vast. We show that a non-pathogenic E. coli strain, Nissle 1917 (EcN), is a suitable host for the creation of ArMs from cytochrome P450s and artificial heme cofactors. An outer-membrane receptor in EcN transports an iridium porphyrin into the cell, and the Ir-CYP119 (CYP119 containing iridium porphyrin) assembled in vivo catalyzes carbene insertions into benzylic C-H bonds enantioselectively and site-selectively. The application of EcN as a whole-cell screening platform eliminates the need for laborious processing procedures, drastically increases the ease and throughput of screening, and accelerates the development of Ir-CYP119 with improved catalytic properties. Studies to identify the transport machinery suggest that a transporter different from the previously assumed ChuA receptor serves to usher the iridium porphyrin into the cytoplasm.

Published

2022

50. Permeability-Engineered Compartmentalization Enables In Vitro Reconstitution of Sustained Synthetic Biology Systems.

Author

Li, Luyao, Li, Luyao, Zhang, Rong, Chen, Long, Tian, Xintong, Li, Ting, Pu, Bingchun, Ma, Conghui, Ji, Xiangyang, Ba, Fang, Xiong, Chenwei, Shi, Yunfeng, Mi, Xianqiang, Li, Jian, Keasling, Jay D, Zhang, Jingwei, Liu, Yifan, Li, Luyao, Li, Luyao, Zhang, Rong, Chen, Long, Tian, Xintong, Li, Ting, Pu, Bingchun, Ma, Conghui, Ji, Xiangyang, Ba, Fang, Xiong, Chenwei, Shi, Yunfeng, Mi, Xianqiang, Li, Jian, Keasling, Jay D, Zhang, Jingwei, and Liu, Yifan

Abstract

In nature, biological compartments such as cells rely on dynamically controlled permeability for matter exchange and complex cellular activities. Likewise, the ability to engineer compartment permeability is crucial for in vitro systems to gain sustainability, robustness, and complexity. However, rendering in vitro compartments such a capability is challenging. Here, a facile strategy is presented to build permeability-configurable compartments, and marked advantages of such compartmentalization are shown in reconstituting sustained synthetic biology systems in vitro. Through microfluidics, the strategy produces micrometer-sized layered microgels whose shell layer serves as a sieving structure for biomolecules and particles. In this configuration, the transport of DNAs, proteins, and bacteriophages across the compartments can be controlled an guided by a physical model. Through permeability engineering, a compartmentalized cell-free protein synthesis system sustains multicycle protein production; ≈100 000 compartments are repeatedly used in a five-cycle synthesis, featuring a yield of 2.2 mg mL-1 . Further, the engineered bacteria-enclosing compartments possess near-perfect phage resistance and enhanced environmental fitness. In a complex river silt environment, compartmentalized whole-cell biosensors show maintained activity throughout the 32 h pollutant monitoring. It is anticipated that permeability-engineered compartmentalization should pave the way for practical synthetic biology applications such as green bioproduction, environmental sensing, and bacteria-based therapeutics.

Published

2022