Soomin Eom scite author profile

Protein cage nanoparticles have a unique spherical hollow structure that provides a modifiable interior space and an exterior surface. For full application, it is desirable to utilize both the interior space and the exterior surface simultaneously with two different functionalities in a well-combined way. Here, we genetically engineered encapsulin protein cage nanoparticles (Encap) as modular nanoplatforms by introducing a split-C-intein (IntC) fragment and SpyTag into the interior and exterior surfaces, respectively. A complementary split-N-intein (IntN) was fused to various protein cargoes, such as NanoLuc luciferase (Nluc), enhanced green fluorescent protein (eGFP), and Nluc-miniSOG, individually, which led to their successful encapsulation into Encaps to form Cargo@Encap through split intein-mediated protein ligation during protein coexpression and cage assembly in bacteria. Conversely, the SpyCatcher protein was fused to various protein ligands, such as a glutathione binder (GST-SC), dimerizing ligands (FKBP12-SC and FRB-SC), and a cancer-targeting affibody (SC-EGFRAfb); subsequently, they were displayed on Cargo@Encaps through SpyTag/SpyCatcher ligation to form Cargo@Encap/Ligands in a mix-and-match manner. Nluc@Encap/glutathione-S-transferase (GST) was effectively immobilized on glutathione (GSH)-coated solid supports exhibiting repetitive and long-term usage of the encapsulated luciferases. We also established luciferase-embedded layer-by-layer (LbL) nanostructures by alternately depositing Nluc@Encap/FKBP12 and Nluc@Encap/FRB in the presence of rapamycin and applied enhanced green fluorescent protein (eGFP)@Encap/EGFRAfb as a target-specific fluorescent imaging probe to visualize specific cancer cells selectively. Modular functionalization of the interior space and the exterior surface of a protein cage nanoparticle may offer the opportunity to develop new protein-based nanostructured devices and nanomedical tools.

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Highly sensitive pregnancy test kit via oriented antibody conjugation on brush-type ligand-coated quantum beads

Kim

Ahn

Bae

et al. 2022

Biosensors and Bioelectronics

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HRP-conjugated plug-and-playable IgG-binding nanobodies as secondary antibody mimics in immunoassays

Bae

Jang

Eom

et al. 2020

Sensors and Actuators B: Chemical

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Development of Recombinant Immunoglobulin G-Binding Luciferase-Based Signal Amplifiers in Immunoassays

et al. 2020

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In general immunoassays, secondary antibodies are covalently linked with enzymes and bind to the Fc region of target-bound primary antibodies to amplify signals of low-abundant target molecules. The antibodies themselves are obtained from large mammals and are further modified with enzymes. In this study, we developed novel recombinant immunoglobulin G (IgG)-binding luciferase-based signal amplifiers (rILSAs) by genetically fusing luciferase (Nluc) with antimouse IgG1 nanobody (MG1Nb) and antibody-binding domain (ABD), individually or together, in a mix-and-match manner. We obtained three different highly pure rILSAs in large quantities using a bacterial overexpression system and one-step purification. Mouse-specific rILSA, MG1Nb-Nluc, and rabbit-specific rILSA, Nluc-ABD, selectively bound to target-molecule-bound mouse IgG1 and rabbit IgG primary antibodies, whereas the bispecific rILSA, MG1Nb-Nluc-ABD, mutually bound to both mouse IgG1 and rabbit IgG primary antibodies. All rILSAs exhibited an outstanding signal-amplifying capability comparable to those of conventional horseradish-peroxidase-conjugated secondary antibodies, regardless of the target molecules, in various immunoassay formats, such as enzyme-linked immunosorbent assay, Western blot, and lateral flow assays. Each rILSA was selected for its own individual purpose and applied to various types of target analytes, in combination with a variety of target-specific primary antibodies, effectively minimizing the use of animals as well as reducing the costs and time associated with the production and chemical conjugation of signal-amplifying enzymes.

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Lactate oxidase/vSIRPα conjugates efficiently consume tumor-produced lactates and locally produce tumor-necrotic H2O2 to suppress tumor growth

Kang

Yeo

Choi

et al. 2023

International Journal of Biological Macromolecules

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Soomin Eom

Load and Display: Engineering Encapsulin as a Modular Nanoplatform for Protein-Cargo Encapsulation and Protein-Ligand Decoration Using Split Intein and SpyTag/SpyCatcher

Highly sensitive pregnancy test kit via oriented antibody conjugation on brush-type ligand-coated quantum beads

HRP-conjugated plug-and-playable IgG-binding nanobodies as secondary antibody mimics in immunoassays

Development of Recombinant Immunoglobulin G-Binding Luciferase-Based Signal Amplifiers in Immunoassays

Lactate oxidase/vSIRPα conjugates efficiently consume tumor-produced lactates and locally produce tumor-necrotic H2O2 to suppress tumor growth

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