Funder: Harvard Medical
School; doi: https://doi.org/10.13039/100006691Funder: Wyss Institute for Biologically Inspired EngineeringAbstract: Synthetic gene oscillators have the potential to control timed functions and periodic gene expression in engineered cells. Such oscillators have been refined in bacteria in vitro, however, these systems have lacked the robustness and precision necessary for applications in complex in vivo environments, such as the mammalian gut. Here, we demonstrate the implementation of a synthetic oscillator capable of keeping robust time in the mouse gut over periods of days. The oscillations provide a marker of bacterial growth at a single-cell level enabling quantification of bacterial dynamics in response to inflammation and underlying variations in the gut microbiota. Our work directly detects increased bacterial growth heterogeneity during disease and differences between spatial niches in the gut, demonstrating the deployment of a precise engineered genetic oscillator in real-life settings

Bakshi, S

Leoncini, E

Lyon, LG

Naydich, AD

Paulsson, J

Potvin-Trottier, L

Richmond, DL

Riglar, DT

Silver, PA

Verdegaal, AA

Synthetic gene oscillators have the potential to control timed functions and periodic gene expression in engineered cells. Such oscillators have been refined in bacteria in vitro, however, these systems have lacked the robustness and precision necessary for applications in complex in vivo environments, such as the mammalian gut. Here, we demonstrate the implementation of a synthetic oscillator capable of keeping robust time in the mouse gut over periods of days. The oscillations provide a marker of bacterial growth at a single-cell level enabling quantification of bacterial dynamics in response to inflammation and underlying variations in the gut microbiota. Our work directly detects increased bacterial growth heterogeneity during disease and differences between spatial niches in the gut, demonstrating the deployment of a precise engineered genetic oscillator in real-life settings

CUED - Cambridge University Engineering Department

Bacterial variability in the mammalian gut captured by a single-cell synthetic oscillator

Riglar, David T

Richmond, David L

Potvin-Trottier, Laurent

Verdegaal, Andrew A

Naydich, Alexander D

Bakshi, Somenath

Leoncini, Emanuele

Lyon, Lorena G

Paulsson, Johan

Silver, Pamela A

Apollo (Cambridge)

Bacterial variability in the mammalian gut captured by a single-cell synthetic oscillator.

Abstract: Synthetic gene oscillators have the potential to control timed functions and periodic gene expression in engineered cells. Such oscillators have been refined in bacteria in vitro, however, these systems have lacked the robustness and precision necessary for applications in complex in vivo environments, such as the mammalian gut. Here, we demonstrate the implementation of a synthetic oscillator capable of keeping robust time in the mouse gut over periods of days. The oscillations provide a marker of bacterial growth at a single-cell level enabling quantification of bacterial dynamics in response to inflammation and underlying variations in the gut microbiota. Our work directly detects increased bacterial growth heterogeneity during disease and differences between spatial niches in the gut, demonstrating the deployment of a precise engineered genetic oscillator in real-life settings

Riglar, David T.

Richmond, David L.

Verdegaal, Andrew A.

Naydich, Alexander D.

Lyon, Lorena G.

Silver, Pamela A.

English

A Correction to this paper has been published: https://doi.org/10.1038/s41467-021-22149-5</jats:p

Author Correction: Bacterial variability in themammalian gut captured by a single-cell syntheticoscillatorDavid T. Riglar , David L. Richmond , Laurent Potvin-Trottier , Andrew A. Verdegaal, Alexander D. Naydich,Somenath Bakshi , Emanuele Leoncini , Lorena G. Lyon, Johan Paulsson & Pamela A. SilverCorrection to: Nature Communications https://doi.org/10.1038/s41467-019-12638-z, published online 11 October 2019.In the original version of the Supplementary Information provided with this Article, Supplementary Table 1 incorrectly provided thedetails for strain LPT239 as “E. coli MC4100 + pLPT234 + pLPT145” and for strain LPT320 as “E. coli MC4100 + pLPT234 +pLPT41”. The details for strain LPT239 should be “E. coli MC4100 + pLPT234 + pLPT41” and for strain LPT320 should be “E. coliMC4100 + pLPT234 + pLPT145”. This has been corrected in the HMTL version of the article and the correct table appended below:OriginalSupplementary Table 1: Strains used in this study.Strain Source DetailsLPT239 This study E. coli MC4100 + pLPT234 + pLPT145LPT320 This study E. coli MC4100 + pLPT234 + pLPT41LPT322 This study E. coli MC4100 + pLPT234 + pLPT149PAS715 This study E. coli MG1655 DE(lacI) DE(motA) rpsL K42R + pLPT234 + pLPT145PAS716 This study S. Typhimurium LT2 + pLPT234 + pLPT145 (*streptomycin resistant through uncharacterized mutational selection).PAS717 This study E. coli Nissle 1917 DE(lacI) DE(motA) rpsL K42R + pLPT234 + pLPT145PAS718 This study E. coli MG1655 DE(lacI) DE(motA) rpsL K42R attTn7::pRNA1-mKate2 + pLPT234 + pLPT145Corrected:Supplementary Table 1: Strains used in this study.Strain Source DetailsLPT239 This study E. coli MC4100 + pLPT234 + pLPT41LPT320 This study E. coli MC4100 + pLPT234 + pLPT145LPT322 This study E. coli MC4100 + pLPT234 + pLPT149PAS715 This study E. coli MG1655 DE(lacI) DE(motA) rpsL K42R + pLPT234 + pLPT145PAS716 This study S. Typhimurium LT2 + pLPT234 + pLPT145 (*streptomycin resistant through uncharacterized mutational selection).PAS717 This study E. coli Nissle 1917 DE(lacI) DE(motA) rpsL K42R + pLPT234 + pLPT145PAS718 This study E. coli MG1655 DE(lacI) DE(motA) rpsL K42R attTn7::pRNA1-mKate2 + pLPT234 + pLPT145https://doi.org/10.1038/s41467-021-22149-5 OPENNATURE COMMUNICATIONS |         (2021) 12:1818 | https://doi.org/10.1038/s41467-021-22149-5 | www.nature.com/naturecommunications 11234567890():,;Additional informationSupplementary information The online version contains supplementary material available at https://doi.org/10.1038/s41467-021-22149-5.Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution andreproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license,and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a creditline to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use,you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.© The Author(s) 2021AUTHOR CORRECTION NATURE COMMUNICATIONS | https://doi.org/10.1038/s41467-021-22149-52 NATURE COMMUNICATIONS |         (2021) 12:1818 | https://doi.org/10.1038/s41467-021-22149-5 | www.nature.com/naturecommunications

Author Correction: Bacterial variability in the mammalian gut captured by a single-cell synthetic oscillator.

https://www.repository.cam.ac.uk/bitstream/handle/1810/299760/Bacterial%20variability%20in%20the%20mammalian%20gut%20captured%20by%20a%20single-cell%20synthetic%20oscillator.pdf?sequence=1&isAllowed=y

Bacterial variability in the mammalian gut captured by a single-cell synthetic oscillator

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