Dendrimer-like supramolecular assembly of proteins with a tunable size and valency through stepwise iterative growth

Bae, Jinho; Kim, Hong-Sik; Gijeong, Kim,; Song, Ji‐Joon; Kim, Kwang Ho

doi:10.1101/2021.06.23.449676

Cited by 2 publications

(2 citation statements)

References 38 publications

(35 reference statements)

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“…To arrive at sensitive viral antigen tests that at the same time fulfill the main POC requirements (fast, simple-to-use, homogeneous detection), the multivalent presentation of viral surface proteins can be exploited by constructing biosensors that bind to multiple, potentially different target proteins on the virus surface, which would allow a more specific detection of virus variants depending on the targeted HA and NA subtypes. Systems with higher valency could also be constructed by including multiple SpyCatcher and DogCatcher domains in the scaffold and mixing them with binders 39 . These sensors might even allow the direct detection of intact, infectious virus using simple readout in a homogeneous test at the point-of-care.…”

Section: Discussionmentioning

confidence: 99%

Bioluminescent detection of viral surface proteins using branched multivalent protein switches

Gräwe,

Spruit,

de Vries

et al. 2023

Preprint

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Fast and reliable virus diagnostics is key to prevent the spread of viruses in populations. A hallmark of viruses is the presence of multivalent surface proteins, a property that can be harnessed to control conformational switching in sensor proteins. Here, we introduce a new sensor platform (dark-LUX) for the detection of viral surface proteins consisting of a general bioluminescent framework that can be post-translationally functionalized with separately expressed binding domains. The platform relies on 1) plug-and-play bioconjugation of different binding proteins via SpyTag/SpyCatcher technology to create branched protein structures, 2) an optimized turn-on bioluminescent switch based on complementation of the split-luciferase NanoBiT upon target binding and 3) straightforward exploration of the protein linker space. The influenza A virus (IAV) surface proteins hemagglutinin (HA) and neuraminidase (NA) were used as relevant multivalent targets to establish proof of principle and optimize relevant parameters such as linker properties, choice of target binding domains and the optimal combination of the competing NanoBiT components SmBiT and DarkBiT. The sensor framework allows rapid conjugation and exchange of various binding domains including scFvs, nanobodies and de novo designed binders for a variety of targets, including the construction of a heterobivalent switch that targets the head and stem region of hemagglutinin. The modularity of the platform thus allows straightforward optimization of binding domains and scaffold properties for existing viral targets, and is well suited to quickly adapt bioluminescent sensor proteins to effectively detect newly evolving viral epitopes.

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Section: Discussionmentioning

confidence: 99%

Bioluminescent detection of viral surface proteins using branched multivalent protein switches

Gräwe,

Spruit,

de Vries

et al. 2023

Preprint

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“…The programmable assembly of protein nanoparticles could provide a route for the construction of innovative functional nanomaterials for potential applications in nanomedicine. Bae et al applied a bottom-up method to construct supramolecular assemblies of protein nanoparticles with programmable size and valency [104]. The protein was assembled into dendrimer-like nanostructures, called "protein dendrimers", using three genetic fusion proteins (one core and two building-block proteins) (Figure 7A).…”

Section: De Novo Design Of Protein-based Nanoparticles For Efficient ...mentioning

confidence: 99%

Tailored Functionalized Protein Nanocarriers for Cancer Therapy: Recent Developments and Prospects

Abdel‐Hamid

El-Hafeez

et al. 2023

Pharmaceutics

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Recently, the potential use of nanoparticles for the targeted delivery of therapeutic and diagnostic agents has garnered increased interest. Several nanoparticle drug delivery systems have been developed for cancer treatment. Typically, protein-based nanocarriers offer several advantages, including biodegradability and biocompatibility. Using genetic engineering or chemical conjugation approaches, well-known naturally occurring protein nanoparticles can be further prepared, engineered, and functionalized in their self-assembly to meet the demands of clinical production efficiency. Accordingly, promising protein nanoparticles have been developed with outstanding tumor-targeting capabilities, ultimately overcoming multidrug resistance issues, in vivo delivery barriers, and mimicking the tumor microenvironment. Bioinspired by natural nanoparticles, advanced computational techniques have been harnessed for the programmable design of highly homogenous protein nanoparticles, which could open new routes for the rational design of vaccines and drug formulations. The current review aims to present several significant advancements made in protein nanoparticle technology, and their use in cancer therapy. Additionally, tailored construction methods and therapeutic applications of engineered protein-based nanoparticles are discussed.

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Dendrimer-like supramolecular assembly of proteins with a tunable size and valency through stepwise iterative growth

Cited by 2 publications

References 38 publications

Bioluminescent detection of viral surface proteins using branched multivalent protein switches

Bioluminescent detection of viral surface proteins using branched multivalent protein switches

Tailored Functionalized Protein Nanocarriers for Cancer Therapy: Recent Developments and Prospects

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