Building a toolbox of protein scaffolds for future immobilization of biocatalysts

Biological materials that are genetically encoded and can self-assemble offer great potential as immobilization platforms in industrial biocatalysis. Protein-based scaffolds can be used for the spatial organization of enzymes, to stabilize the catalysts and provide optimal microenvironments for reac...

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Bibliographic Details
Published in:Applied microbiology and biotechnology 2018-10, Vol.102 (19), p.8373-8388
Main Authors: Schmidt-Dannert, Sarah, Zhang, Guoqiang, Johnston, Timothy, Quin, Maureen B., Schmidt-Dannert, Claudia
Format: Article
Language:English
Subjects:
Analysis
Assembling
Biocatalysts
Biological materials
Biomedical and Life Sciences
Biotechnologically Relevant Enzymes and Proteins
Biotechnology
Catalysis
Catalysts
Coding
E coli
Enzymes
Filaments
Genetic code
Homology
Immobilization
Life Sciences
Localization
Microbial Genetics and Genomics
Microbiology
Microenvironments
Microorganisms
Nanotechnology
Nanotubes
Phylogeny
Properties
Protein synthesis
Proteins
Salmonella
Scaffolds
Self-assembly
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Summary:Biological materials that are genetically encoded and can self-assemble offer great potential as immobilization platforms in industrial biocatalysis. Protein-based scaffolds can be used for the spatial organization of enzymes, to stabilize the catalysts and provide optimal microenvironments for reaction sequences. In our previous work, we created a protein scaffold for enzyme localization by engineering the bacterial microcompartment shell protein EutM from Salmonella enterica . Here, we sought to expand this work by developing a toolbox of EutM proteins with different properties, with the potential to be used for future immobilization of enzymes. We describe the bioinformatic identification of hundreds of homologs of EutM from diverse microorganisms. We specifically select 13 EutM homologs from extremophiles for characterization, based on phylogenetic analyses. We synthesize genes encoding the novel proteins, clone and express them in E. coli , and purify the proteins. In vitro characterization shows that the proteins self-assemble into robust nano- and micron-scale architectures including protein nanotubes, filaments, and scaffolds. We explore the self-assembly characteristics from a sequence-based approach and create a synthetic biology platform for the coexpression of different EutM homologs as hybrid scaffolds with integrated enzyme attachment points. This work represents a step towards our goal of generating a modular toolbox for the rapid production of self-assembling protein-based materials for enzyme immobilization.
ISSN:0175-7598
1432-0614
DOI:10.1007/s00253-018-9252-6