An evolutionary optimization of a rhodopsin-based phototrophic metabolism in Escherichia coli

An evolutionary optimization of a rhodopsin-based phototrophic metabolism in Escherichia coli

Abstract Background The expression of the Gloeobacter rhodopsin (GR) in a chemotrophic Escherichia coli enables the light-driven phototrophic energy generation. Adaptive laboratory evolution has been used for acquiring desired phenotype of microbial cells and for the elucidation of basic mechanism o...

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Main Authors: Hyun Aaron Kim, Hyun Ju Kim, Jihoon Park, Ah Reum Choi, Kyoo Heo, Haeyoung Jeong, Kwang-Hwan Jung, Yeong-Jae Seok, Pil Kim, Sang Jun Lee
Format: Article
Language:English
Published: BMC 2017-06-01
Series:Microbial Cell Factories
Subjects:
Adaptive laboratory evolution
Strain optimization
Chemotroph
Phototroph
Rhodopsin
Proton pumping
Online Access:http://link.springer.com/article/10.1186/s12934-017-0725-6
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spelling doaj-c63f73b507514799957c4e6b01d0e3c42020-11-24T21:04:43ZengBMCMicrobial Cell Factories1475-28592017-06-011611910.1186/s12934-017-0725-6An evolutionary optimization of a rhodopsin-based phototrophic metabolism in Escherichia coliHyun Aaron Kim0Hyun Ju Kim1Jihoon Park2Ah Reum Choi3Kyoo Heo4Haeyoung Jeong5Kwang-Hwan Jung6Yeong-Jae Seok7Pil Kim8Sang Jun Lee9Hana Academy SeoulDepartment of Systems Biotechnology, Chung-Ang UniversityDepartment of Biotechnology, The Catholic University of KoreaDepartment of Life Sciences, Sogang UniversityDepartment of Biological Sciences, Seoul National UniversityInfectious Disease Research Center, Korea Research Institute of Bioscience and Biotechnology (KRIBB)Department of Life Sciences, Sogang UniversityDepartment of Biological Sciences, Seoul National UniversityDepartment of Biotechnology, The Catholic University of KoreaDepartment of Systems Biotechnology, Chung-Ang UniversityAbstract Background The expression of the Gloeobacter rhodopsin (GR) in a chemotrophic Escherichia coli enables the light-driven phototrophic energy generation. Adaptive laboratory evolution has been used for acquiring desired phenotype of microbial cells and for the elucidation of basic mechanism of molecular evolution. To develop an optimized strain for the artificially acquired phototrophic metabolism, an ancestral E. coli expressing GR was adaptively evolved in a chemostat reactor with constant illumination and limited glucose conditions. This study was emphasized at an unexpected genomic mutation contributed to the improvement of microbial performance. Results During the chemostat culture, increase of cell size was observed, which were distinguished from that of the typical rod-shaped ancestral cells. A descendant ET5 strain was randomly isolated from the chemostat culture at 88-days. The phototrophic growth and the light-induced proton pumping of the ET5 strain were twofold and eightfold greater, respectively, than those of the ancestral E. coli strain. Single point mutation of C1082A at dgcQ gene (encoding diguanylate cyclase, also known as the yedQ gene) in the chromosome of ET5 strain was identified from whole genome sequencing analysis. An ancestral E. coli complemented with the same dgcQ mutation from the ET5 was repeated the subsequently enhancements of light-driven phototrophic growth and proton pumping. Intracellular c-di-GMP, the product of the diguanylate cyclase (dgcQ), of the descendant ET5 strain was suddenly increased while that of the ancestral strain was negligible. Conclusions Newly acquired phototrophic metabolism of E. coli was further improved via adaptive laboratory evolution by the rise of a point mutation on a transmembrane cell signaling protein followed by increase of signal molecule that eventually led an increase proton pumping and phototrophic growth.http://link.springer.com/article/10.1186/s12934-017-0725-6Adaptive laboratory evolutionStrain optimizationChemotrophPhototrophRhodopsinProton pumping
collection DOAJ
language English
format Article
sources DOAJ
author Hyun Aaron Kim
Hyun Ju Kim
Jihoon Park
Ah Reum Choi
Kyoo Heo
Haeyoung Jeong
Kwang-Hwan Jung
Yeong-Jae Seok
Pil Kim
Sang Jun Lee
spellingShingle Hyun Aaron Kim
Hyun Ju Kim
Jihoon Park
Ah Reum Choi
Kyoo Heo
Haeyoung Jeong
Kwang-Hwan Jung
Yeong-Jae Seok
Pil Kim
Sang Jun Lee
An evolutionary optimization of a rhodopsin-based phototrophic metabolism in Escherichia coli
Microbial Cell Factories
Adaptive laboratory evolution
Strain optimization
Chemotroph
Phototroph
Rhodopsin
Proton pumping
author_facet Hyun Aaron Kim
Hyun Ju Kim
Jihoon Park
Ah Reum Choi
Kyoo Heo
Haeyoung Jeong
Kwang-Hwan Jung
Yeong-Jae Seok
Pil Kim
Sang Jun Lee
author_sort Hyun Aaron Kim
title An evolutionary optimization of a rhodopsin-based phototrophic metabolism in Escherichia coli
title_short An evolutionary optimization of a rhodopsin-based phototrophic metabolism in Escherichia coli
title_full An evolutionary optimization of a rhodopsin-based phototrophic metabolism in Escherichia coli
title_fullStr An evolutionary optimization of a rhodopsin-based phototrophic metabolism in Escherichia coli
title_full_unstemmed An evolutionary optimization of a rhodopsin-based phototrophic metabolism in Escherichia coli
title_sort evolutionary optimization of a rhodopsin-based phototrophic metabolism in escherichia coli
publisher BMC
series Microbial Cell Factories
issn 1475-2859
publishDate 2017-06-01
description Abstract Background The expression of the Gloeobacter rhodopsin (GR) in a chemotrophic Escherichia coli enables the light-driven phototrophic energy generation. Adaptive laboratory evolution has been used for acquiring desired phenotype of microbial cells and for the elucidation of basic mechanism of molecular evolution. To develop an optimized strain for the artificially acquired phototrophic metabolism, an ancestral E. coli expressing GR was adaptively evolved in a chemostat reactor with constant illumination and limited glucose conditions. This study was emphasized at an unexpected genomic mutation contributed to the improvement of microbial performance. Results During the chemostat culture, increase of cell size was observed, which were distinguished from that of the typical rod-shaped ancestral cells. A descendant ET5 strain was randomly isolated from the chemostat culture at 88-days. The phototrophic growth and the light-induced proton pumping of the ET5 strain were twofold and eightfold greater, respectively, than those of the ancestral E. coli strain. Single point mutation of C1082A at dgcQ gene (encoding diguanylate cyclase, also known as the yedQ gene) in the chromosome of ET5 strain was identified from whole genome sequencing analysis. An ancestral E. coli complemented with the same dgcQ mutation from the ET5 was repeated the subsequently enhancements of light-driven phototrophic growth and proton pumping. Intracellular c-di-GMP, the product of the diguanylate cyclase (dgcQ), of the descendant ET5 strain was suddenly increased while that of the ancestral strain was negligible. Conclusions Newly acquired phototrophic metabolism of E. coli was further improved via adaptive laboratory evolution by the rise of a point mutation on a transmembrane cell signaling protein followed by increase of signal molecule that eventually led an increase proton pumping and phototrophic growth.
topic Adaptive laboratory evolution
Strain optimization
Chemotroph
Phototroph
Rhodopsin
Proton pumping
url http://link.springer.com/article/10.1186/s12934-017-0725-6
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