Your search keyword '"Garg, Shivani"' showing total 3 results

1. In vitro prototyping and rapid optimization of biosynthetic enzymes for cell design.

Author

Karim AS, Dudley QM, Juminaga A, Yuan Y, Crowe SA, Heggestad JT, Garg S, Abdalla T, Grubbe WS, Rasor BJ, Coar DN, Torculas M, Krein M, Liew FE, Quattlebaum A, Jensen RO, Stuart JA, Simpson SD, Köpke M, and Jewett MC

Subjects

Biosynthetic Pathways drug effects, Biotechnology methods, Cell-Free System metabolism, Metabolic Networks and Pathways physiology, Protein Biosynthesis genetics, Protein Biosynthesis physiology, Biosynthetic Pathways physiology, Metabolic Engineering methods, Synthetic Biology methods

Abstract

The design and optimization of biosynthetic pathways for industrially relevant, non-model organisms is challenging due to transformation idiosyncrasies, reduced numbers of validated genetic parts and a lack of high-throughput workflows. Here we describe a platform for in vitro prototyping and rapid optimization of biosynthetic enzymes (iPROBE) to accelerate this process. In iPROBE, cell lysates are enriched with biosynthetic enzymes by cell-free protein synthesis and then metabolic pathways are assembled in a mix-and-match fashion to assess pathway performance. We demonstrate iPROBE by screening 54 different cell-free pathways for 3-hydroxybutyrate production and optimizing a six-step butanol pathway across 205 permutations using data-driven design. Observing a strong correlation (r = 0.79) between cell-free and cellular performance, we then scaled up our highest-performing pathway, which improved in vivo 3-HB production in Clostridium by 20-fold to 14.63 ± 0.48 g l -1 . We expect iPROBE to accelerate design-build-test cycles for industrial biotechnology.

Published

2020

2. Modular cell-free expression plasmids to accelerate biological design in cells.

Author

Karim, Ashty S, Liew, Fungmin (Eric), Garg, Shivani, Vögeli, Bastian, Rasor, Blake J, Gonnot, Aislinn, Pavan, Marilene, Juminaga, Alex, Simpson, Séan D, Köpke, Michael, and Jewett, Michael C

Subjects

PLASMIDS, ESCHERICHIA coli, BIOMASS energy, DNA synthesis, SYNTHETIC biology

Abstract

Industrial biotechnology aims to produce high-value products from renewable resources. This can be challenging because model microorganisms—organisms that are easy to use like Escherichia coli —often lack the machinery required to utilize desired feedstocks like lignocellulosic biomass or syngas. Non-model organisms, such as Clostridium , are industrially proven and have desirable metabolic features but have several hurdles to mainstream use. Namely, these species grow more slowly than conventional laboratory microbes, and genetic tools for engineering them are far less prevalent. To address these hurdles for accelerating cellular design, cell-free synthetic biology has matured as an approach for characterizing non-model organisms and rapidly testing metabolic pathways in vitro. Unfortunately, cell-free systems can require specialized DNA architectures with minimal regulation that are not compatible with cellular expression. In this work, we develop a modular vector system that allows for T7 expression of desired enzymes for cell-free expression and direct Golden Gate assembly into Clostridium expression vectors. Utilizing the Joint Genome Institute's DNA Synthesis Community Science Program, we designed and synthesized these plasmids and genes required for our projects allowing us to shuttle DNA easily between our in vitro and in vivo experiments. We next validated that these vectors were sufficient for cell-free expression of functional enzymes, performing on par with the previous state-of-the-art. Lastly, we demonstrated automated six-part DNA assemblies for Clostridium autoethanogenum expression with efficiencies ranging from 68% to 90%. We anticipate this system of plasmids will enable a framework for facile testing of biosynthetic pathways in vitro and in vivo by shortening development cycles. [ABSTRACT FROM AUTHOR]

Published

2020

3. A modular approach for high-flux lactic acid production from methane in an industrial medium using engineered Methylomicrobium buryatense 5GB1.

Author

Garg, Shivani, Clomburg, James M., and Gonzalez, Ramon

Subjects

*LACTIC acid, *METHANE, *METHANOTROPHS, *NATURAL gas, *SYNTHETIC biology

Abstract

Convergence of market drivers such as abundant availability of inexpensive natural gas and increasing awareness of its global warming effects have created new opportunities for the development of small-scale gas-to-liquid (GTL) conversion technologies that can efficiently utilize methane, the primary component of natural gas. Leveraging the unique ability of methanotrophs that use methane as carbon and energy source, biological GTL platforms can be envisioned that are readily deployable at remote petroleum drilling sites where large chemical GTL infrastructure is uneconomical to set-up. Methylomicrobium buryatense, an obligate methanotroph, has gained traction as a potential industrial methanotrophic host because of availability of genetic tools and recent advances in its metabolic engineering. However, progress is impeded by low strain performance and lack of an industrial medium. In this study, we first established a small-scale cultivation platform using Hungate tubes for growth of M. buryatense at medium-to-high-throughput that also enabled 2X faster growth compared to that obtained in traditional glass serum bottles. Then, employing a synthetic biology approach we engineered M. buryatense with varying promoter (inducible and constitutive) and ribosome-binding site combinations, and obtained a strain capable of producing L-lactate from methane at a flux 14-fold higher than previously reported. Finally, we demonstrated L-lactate production in an industrial medium by replacing nitrate with less-expensive ammonium as the nitrogen source. Under these conditions, L-lactate was synthesized at a flux approximately 50-fold higher than that reported previously in a bioreactor system while achieving a titer of 0.6 g/L. These findings position M. buryatense closer to becoming an industrial host strain of choice, and pave new avenues for accelerating methane-to-chemical conversion using synthetic biology. [ABSTRACT FROM AUTHOR]

Published

2018