Selection of green fluorescent proteins by in vitro compartmentalization using microbead-display libraries

In vitro compartmentalization (IVC) is a method to link genotype and phenotype by confining DNA and an in vitro gene expression system in cell-like compartments such as water-in-oil microdroplets. IVC provides a flexible platform for the selection and directed evolution of peptides, proteins, and RN...

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Published inBiochemical engineering journal Vol. 187; p. 108627
Main Authors Iizuka, Ryo, Tahara, Kentaro, Matsueda, Anna, Tsuda, Soichiro, Yoon, Dong Hyun, Sekiguchi, Tetsushi, Shoji, Shuichi, Funatsu, Takashi
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.11.2022
Subjects
directed evolution
DNA
DNA libraries
emulsions
fluorescence
gene expression
genotype
Green fluorescent protein
In vitro compartmentalization
Microbead display
microbeads
Microdroplet
peptides
phenotype
ribozymes
Microbead display
In vitro compartmentalization
Green fluorescent protein
Microdroplet
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Abstract In vitro compartmentalization (IVC) is a method to link genotype and phenotype by confining DNA and an in vitro gene expression system in cell-like compartments such as water-in-oil microdroplets. IVC provides a flexible platform for the selection and directed evolution of peptides, proteins, and RNAs with the desired catalytic, binding, and regulatory activities. However, in general, IVC requires confinement of a gene library in each compartment at the single-molecule level, resulting in the low expression level and activity of the protein and difficulty in recovering the DNA. To overcome the problems, we devised an alternative approach using microbeads displaying multiple copies of single genes prepared by on-bead emulsion PCR. We showed that this approach could increase the levels of protein synthesized compared with conventional IVC. Moreover, by employing this approach, we screened a library of green fluorescent protein (GFP) genes containing random sequences in the chromophore region and obtained genes encoding GFPs with different spectral characteristics in only a single round of screening. The result shows that our approach has great potential for practical applications in improving the properties or identifying new properties of enzymes, ribozymes, and their regulators. •An approach for a productive in vitro compartmentalization process is presented.•The approach uses microbeads displaying multiple copies of single genes.•The approach increased the levels of protein synthesized in microcompartments.•The approach enabled the acquisition of proteins with a desired property.
AbstractList In vitro compartmentalization (IVC) is a method to link genotype and phenotype by confining DNA and an in vitro gene expression system in cell-like compartments such as water-in-oil microdroplets. IVC provides a flexible platform for the selection and directed evolution of peptides, proteins, and RNAs with the desired catalytic, binding, and regulatory activities. However, in general, IVC requires confinement of a gene library in each compartment at the single-molecule level, resulting in the low expression level and activity of the protein and difficulty in recovering the DNA. To overcome the problems, we devised an alternative approach using microbeads displaying multiple copies of single genes prepared by on-bead emulsion PCR. We showed that this approach could increase the levels of protein synthesized compared with conventional IVC. Moreover, by employing this approach, we screened a library of green fluorescent protein (GFP) genes containing random sequences in the chromophore region and obtained genes encoding GFPs with different spectral characteristics in only a single round of screening. The result shows that our approach has great potential for practical applications in improving the properties or identifying new properties of enzymes, ribozymes, and their regulators.
In vitro compartmentalization (IVC) is a method to link genotype and phenotype by confining DNA and an in vitro gene expression system in cell-like compartments such as water-in-oil microdroplets. IVC provides a flexible platform for the selection and directed evolution of peptides, proteins, and RNAs with the desired catalytic, binding, and regulatory activities. However, in general, IVC requires confinement of a gene library in each compartment at the single-molecule level, resulting in the low expression level and activity of the protein and difficulty in recovering the DNA. To overcome the problems, we devised an alternative approach using microbeads displaying multiple copies of single genes prepared by on-bead emulsion PCR. We showed that this approach could increase the levels of protein synthesized compared with conventional IVC. Moreover, by employing this approach, we screened a library of green fluorescent protein (GFP) genes containing random sequences in the chromophore region and obtained genes encoding GFPs with different spectral characteristics in only a single round of screening. The result shows that our approach has great potential for practical applications in improving the properties or identifying new properties of enzymes, ribozymes, and their regulators. •An approach for a productive in vitro compartmentalization process is presented.•The approach uses microbeads displaying multiple copies of single genes.•The approach increased the levels of protein synthesized in microcompartments.•The approach enabled the acquisition of proteins with a desired property.
ArticleNumber 108627
Author Tahara, Kentaro
Sekiguchi, Tetsushi
Matsueda, Anna
Yoon, Dong Hyun
Tsuda, Soichiro
Iizuka, Ryo
Shoji, Shuichi
Funatsu, Takashi
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  givenname: Soichiro
  surname: Tsuda
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  givenname: Dong Hyun
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  givenname: Tetsushi
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  givenname: Shuichi
  surname: Shoji
  fullname: Shoji, Shuichi
  organization: Research Organization for Nano & Life Innovation, Waseda University, 513 Waseda Tsurumakicho, Shinjuku-ku, Tokyo 162-0041, Japan
– sequence: 8
  givenname: Takashi
  surname: Funatsu
  fullname: Funatsu, Takashi
  email: funatsu@mol.f.u-tokyo.ac.jp
  organization: Graduate School of Pharmaceutical Sciences, The University of Tokyo, 7-3-1 Hongo, Bunkyo-ku, Tokyo 113-0033, Japan
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Keywords Microbead display
In vitro compartmentalization
Green fluorescent protein
Microdroplet
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Snippet In vitro compartmentalization (IVC) is a method to link genotype and phenotype by confining DNA and an in vitro gene expression system in cell-like...
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SubjectTerms directed evolution
DNA
DNA libraries
emulsions
fluorescence
gene expression
genotype
Green fluorescent protein
In vitro compartmentalization
Microbead display
microbeads
Microdroplet
peptides
phenotype
ribozymes
Title Selection of green fluorescent proteins by in vitro compartmentalization using microbead-display libraries
URI https://dx.doi.org/10.1016/j.bej.2022.108627
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