Soo hyun Kwon scite author profile

The introduction of a stimulus-responsive property is an effective way to increase the applicability of functional materials in the field of nanobiotechnology. Herein, a peptide platform is devised for constructing elastin-like peptide amphiphiles (ELPAs) that exhibit a temperature-responsiveness that can be easily tuned via a single N-terminal amino acid substitution at the final step of peptide synthesis. Due to the modular property of peptides, the platform based on a miniaturized elastin-like peptide (MELP) can be conjugated with various bioactive peptide sequences in diverse macromolecular topologies. First, the MELP platform is coupled with a short linear RGD peptide. The ELPAs of the peptide conjugates exhibit rapid aggregation (coacervation) and retard disaggregation in response to heating and cooling, respectively. Second, the platform is grafted with an α-helical guest peptide in a lariattype structure, which forms ELPAs that undergo faster disassembly than the ELPAs without the guest peptide in response to temperature increases. Interestingly, the critical temperatures for the thermoresponsive behaviors are commonly dependent on the hydrophobic and aromatic properties of the N-terminal amino acid residues. These results suggest that this peptide platform possesses great potential for use in the development of smart materials in wide-ranging applications related to temperature change.

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3D² Self‐Assembling Janus Peptide Dendrimers with Tailorable Supermultivalency

Choi

Kwon

Lim

2019

Adv Funct Materials

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The self-assembly of peptides enables the construction of self-assembled peptide nanostructures (SPNs) with chemical composition similar to those of natural proteins; however, the structural complexity and functional properties of SPNs are far beneath those of natural proteins. One of the most fundamental challenges in fabricating more elaborate SPNs lies in developing building blocks that are simultaneously more complex and relatively easy to synthesize. Here, the development of self-assembling Janus peptide dendrimers (JPDs) is reported, which have fully 3D structures similar to those of globular proteins. For the reliable and convenient synthesis of JPDs, a solid-phase bifurcation synthesis method is devised. The self-assembly behavior of JPDs is unique because only the dendrimer generation and not the weight fraction dictates the morphology of SPNs. The coassembly of two JPD building blocks provides an opportunity not only to enlarge the morphological repertoire in a predictable manner but also to discover SPNs with unusual and interesting morphologies. Because JPD assemblies have dual multivalency, i.e., supramolecular and unimolecular multivalency, the JPD system enables the statistical selection of materials with high avidity for the desired cell types and possibly any target receptors.

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Structural control of self-assembled peptide nanostructures to develop peptide vesicles for photodynamic therapy of cancer

Kwon¹,

Lee²,

Kim³

et al. 2022

Materials Today Bio

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Fabrication of Multicomponent Multivesicular Peptidoliposomes and Their Directed Cytoplasmic Delivery

Kwon

Lim

2017

ACS Macro Lett.

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A novel self-assembly strategy for the formation of multicomponent and multicompartment vesicles via the hierarchical assembly of the cyclic peptide and lipid building blocks is reported. The primary driving force underlying the formation of dual-component (i.e., peptide and lipid) heteromultivesicular vesicles (hMVVs) is the differential thermostability between the supramolecular building blocks. Furthermore, the combination of the differential thermostability and charge-based separation further enables the fabrication of the hMVVs that incorporate up to four different components (i.e., two different building blocks and two different encapsulated molecules). The quadruple-component hMVVs consist of cyclic peptides, lipids, negatively charged green fluorescent probes (GFPr), and positively charged red fluorescent probes (RFPr). Intracellular delivery study shows that cellular localization of hMVVs is directed by the function of hMVV envelopes, and the nuclear localization signal (NLS) of peptide vesicles appears to use different cellular pathways depending on the site of action (i.e., extracellular space or cytoplasm). This study provides the hierarchical peptide-based hMVVs with sophisticated architectures and cell delivery characteristics, thus making a step toward artificial cells or viruses.

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Nanomorphological Diversity of Self-Assembled Cyclopeptisomes Investigated via Thermodynamic and Kinetic Controls

et al. 2016

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The physicochemical and biological characteristics of vesicles are dependent on the type of self-assembly building blocks and methods of preparation. In this report, we designed a vesicle-forming linear and cyclic peptide building blocks and investigated the effect of molecular topology and thermodynamic and kinetic controls on the stability and morphological features of the self-assembled vesicles. Comparison of topological effect on self-assembly revealed that the strong association of the aromatic hydrophobic segments is observed only in the cyclic peptide, which is most likely the results of constrained structure along with the restriction in the molecular degree of freedom. Consequently, the formation of stable vesicles could be observed only with the cyclic peptide. Further investigation with cyclic peptide building blocks revealed that depending on the control methods, vesicles with a variety of structural features, such as polygonal, wrinkled, round, round-patched, and round-fused vesicles, could be fabricated. Our results demonstrate that existing vesicle structures constitute only a fraction of the possible structural diversity and that macrocyclic peptides can provide a wealth of opportunities in vesicle engineering.

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Soo hyun Kwon

Modular Self‐Assembling Peptide Platform with a Tunable Thermoresponsiveness via a Single Amino Acid Substitution

3D² Self‐Assembling Janus Peptide Dendrimers with Tailorable Supermultivalency

Structural control of self-assembled peptide nanostructures to develop peptide vesicles for photodynamic therapy of cancer

Fabrication of Multicomponent Multivesicular Peptidoliposomes and Their Directed Cytoplasmic Delivery

Nanomorphological Diversity of Self-Assembled Cyclopeptisomes Investigated via Thermodynamic and Kinetic Controls

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Soo hyun Kwon

Modular Self‐Assembling Peptide Platform with a Tunable Thermoresponsiveness via a Single Amino Acid Substitution

3D2 Self‐Assembling Janus Peptide Dendrimers with Tailorable Supermultivalency

Structural control of self-assembled peptide nanostructures to develop peptide vesicles for photodynamic therapy of cancer

Fabrication of Multicomponent Multivesicular Peptidoliposomes and Their Directed Cytoplasmic Delivery

Nanomorphological Diversity of Self-Assembled Cyclopeptisomes Investigated via Thermodynamic and Kinetic Controls

Contact Info

Product

Resources

About

3D² Self‐Assembling Janus Peptide Dendrimers with Tailorable Supermultivalency