Automation assisted anaerobic phenotyping for metabolic engineering

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Automation assisted anaerobic phenotyping for metabolic engineering. / Raj, Kaushik; Venayak, Naveen; Diep, Patrick et al.
Yn: Microbial cell factories, Cyfrol 20, Rhif 1, 23.09.2021, t. 184.

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

HarvardHarvard

Raj, K, Venayak, N, Diep, P, Golla, SA, Yakunin, AF & Mahadevan, R 2021, 'Automation assisted anaerobic phenotyping for metabolic engineering', Microbial cell factories, cyfrol. 20, rhif 1, tt. 184. https://doi.org/10.1186/s12934-021-01675-3

APA

Raj, K., Venayak, N., Diep, P., Golla, S. A., Yakunin, A. F., & Mahadevan, R. (2021). Automation assisted anaerobic phenotyping for metabolic engineering. Microbial cell factories, 20(1), 184. https://doi.org/10.1186/s12934-021-01675-3

CBE

Raj K, Venayak N, Diep P, Golla SA, Yakunin AF, Mahadevan R. 2021. Automation assisted anaerobic phenotyping for metabolic engineering. Microbial cell factories. 20(1):184. https://doi.org/10.1186/s12934-021-01675-3

MLA

VancouverVancouver

Raj K, Venayak N, Diep P, Golla SA, Yakunin AF, Mahadevan R. Automation assisted anaerobic phenotyping for metabolic engineering. Microbial cell factories. 2021 Medi 23;20(1):184. doi: 10.1186/s12934-021-01675-3

Author

Raj, Kaushik ; Venayak, Naveen ; Diep, Patrick et al. / Automation assisted anaerobic phenotyping for metabolic engineering. Yn: Microbial cell factories. 2021 ; Cyfrol 20, Rhif 1. tt. 184.

RIS

TY - JOUR

T1 - Automation assisted anaerobic phenotyping for metabolic engineering

AU - Raj, Kaushik

AU - Venayak, Naveen

AU - Diep, Patrick

AU - Golla, Sai Akhil

AU - Yakunin, Alexander F

AU - Mahadevan, Radhakrishnan

N1 - © 2021. The Author(s).

PY - 2021/9/23

Y1 - 2021/9/23

N2 - BACKGROUND: Microorganisms can be metabolically engineered to produce a wide range of commercially important chemicals. Advancements in computational strategies for strain design and synthetic biological techniques to construct the designed strains have facilitated the generation of large libraries of potential candidates for chemical production. Consequently, there is a need for high-throughput laboratory scale techniques to characterize and screen these candidates to select strains for further investigation in large scale fermentation processes. Several small-scale fermentation techniques, in conjunction with laboratory automation have enhanced the throughput of enzyme and strain phenotyping experiments. However, such high throughput experimentation typically entails large operational costs and generate massive amounts of laboratory plastic waste.RESULTS: In this work, we develop an eco-friendly automation workflow that effectively calibrates and decontaminates fixed-tip liquid handling systems to reduce tip waste. We also investigate inexpensive methods to establish anaerobic conditions in microplates for high-throughput anaerobic phenotyping. To validate our phenotyping platform, we perform two case studies-an anaerobic enzyme screen, and a microbial phenotypic screen. We used our automation platform to investigate conditions under which several strains of E. coli exhibit the same phenotypes in 0.5 L bioreactors and in our scaled-down fermentation platform. We also propose the use of dimensionality reduction through t-distributed stochastic neighbours embedding (t-SNE) in conjunction with our phenotyping platform to effectively cluster similarly performing strains at the bioreactor scale.CONCLUSIONS: Fixed-tip liquid handling systems can significantly reduce the amount of plastic waste generated in biological laboratories and our decontamination and calibration protocols could facilitate the widespread adoption of such systems. Further, the use of t-SNE in conjunction with our automation platform could serve as an effective scale-down model for bioreactor fermentations. Finally, by integrating an in-house data-analysis pipeline, we were able to accelerate the 'test' phase of the design-build-test-learn cycle of metabolic engineering.

AB - BACKGROUND: Microorganisms can be metabolically engineered to produce a wide range of commercially important chemicals. Advancements in computational strategies for strain design and synthetic biological techniques to construct the designed strains have facilitated the generation of large libraries of potential candidates for chemical production. Consequently, there is a need for high-throughput laboratory scale techniques to characterize and screen these candidates to select strains for further investigation in large scale fermentation processes. Several small-scale fermentation techniques, in conjunction with laboratory automation have enhanced the throughput of enzyme and strain phenotyping experiments. However, such high throughput experimentation typically entails large operational costs and generate massive amounts of laboratory plastic waste.RESULTS: In this work, we develop an eco-friendly automation workflow that effectively calibrates and decontaminates fixed-tip liquid handling systems to reduce tip waste. We also investigate inexpensive methods to establish anaerobic conditions in microplates for high-throughput anaerobic phenotyping. To validate our phenotyping platform, we perform two case studies-an anaerobic enzyme screen, and a microbial phenotypic screen. We used our automation platform to investigate conditions under which several strains of E. coli exhibit the same phenotypes in 0.5 L bioreactors and in our scaled-down fermentation platform. We also propose the use of dimensionality reduction through t-distributed stochastic neighbours embedding (t-SNE) in conjunction with our phenotyping platform to effectively cluster similarly performing strains at the bioreactor scale.CONCLUSIONS: Fixed-tip liquid handling systems can significantly reduce the amount of plastic waste generated in biological laboratories and our decontamination and calibration protocols could facilitate the widespread adoption of such systems. Further, the use of t-SNE in conjunction with our automation platform could serve as an effective scale-down model for bioreactor fermentations. Finally, by integrating an in-house data-analysis pipeline, we were able to accelerate the 'test' phase of the design-build-test-learn cycle of metabolic engineering.

KW - Anaerobiosis

KW - Automation, Laboratory/methods

KW - Escherichia coli/genetics

KW - Fermentation

KW - High-Throughput Screening Assays/instrumentation

KW - Metabolic Engineering/instrumentation

U2 - 10.1186/s12934-021-01675-3

DO - 10.1186/s12934-021-01675-3

M3 - Article

C2 - 34556155

VL - 20

SP - 184

JO - Microbial cell factories

JF - Microbial cell factories

SN - 1475-2859

IS - 1

ER -