Your search keyword '"Raymond S. Tu"' showing total 6 results

1. Design Strategies to Tune the Structural and Mechanical Properties of Synthetic Collagen Hydrogels

Author

Jinyuan Hu, Fei Xu, Xiaonan Zhu, Vikas Nanda, Jie Wang, and Raymond S. Tu

Subjects

Polymers and Plastics, Tissue Engineering, Chemistry, Protein primary structure, Biomaterial, Bioengineering, Sequence (biology), Biocompatible Materials, Hydrogels, Biomaterials, Tissue engineering, Heterotrimeric G protein, Self-healing hydrogels, Materials Chemistry, Biophysics, Cell Adhesion, Collagen, Cell adhesion, Triple helix

Abstract

As an important component of biomaterials, collagen provides three-dimensional scaffolds and biological cues for cell adhesion and proliferation in tissue engineering. Recombinant collagen-like proteins, which were initially discovered in Streptococcus pyogenes and produced in heterologous hosts, have been chemically and genetically engineered for biomaterial applications. However, existing collagen-like proteins do not form gels, limiting their utility as biomaterials. Here, we present a series of rationally designed collagen-like proteins composed of a trimerization domain, triple-helical domains with various lengths, and a pair of heterotrimeric coiled-coil sequences attached to the N- and C-termini as adhesive ends. These designed proteins fold into triple helices and form self-supporting gels. As the triple-helical domains are lengthened, the gels become less stiff, pore sizes increase, and structural anisotropy decreases. Moreover, cell-culture assay confirms that the designed proteins are noncytotoxic. This study provides a design strategy for collagen-based biomaterials. The sequence variations reveal a relationship between the protein primary structure and material properties, where variations in the cross-linking density and association energies define the gelation of the protein network.

Published

2021

2. Protein Engineered Triblock Polymers Composed of Two SADs: Enhanced Mechanical Properties and Binding Abilities

Author

Ruipeng Li, Jennifer S. Haghpanah, Matthew B. Kubilius, Yao Wang, Priya Katyal, Nicole L. Schnabel, Navjot Singh, Sean C O'Neill, Andrew J. Olsen, Jin Kim Montclare, Raymond S. Tu, and Min Dai

Subjects

0301 basic medicine, Polymers and Plastics, Amino Acid Motifs, Protein domain, Bioengineering, Plasma protein binding, Cartilage Oligomeric Matrix Protein, 010402 general chemistry, 01 natural sciences, Micelle, Biomaterials, 03 medical and health sciences, Protein Domains, Materials Chemistry, Copolymer, Micelles, chemistry.chemical_classification, Cartilage oligomeric matrix protein, biology, Polymer, Small molecule, Elasticity, Elastin, 0104 chemical sciences, 030104 developmental biology, chemistry, cardiovascular system, biology.protein, Biophysics, Stress, Mechanical, Small molecule binding, Protein Binding

Abstract

Recombinant methods have been used to engineer artificial protein triblock polymers composed of two different self-assembling domains (SADs) bearing one elastin (E) flanked by two cartilage oligomeric matrix protein coiled-coil (C) domains to generate CEC. To understand how the two C domains improve small molecule recognition and the mechanical integrity of CEC, we have constructed CL44AECL44A, which bears an impaired CL44A domain that is unstructured as a negative control. The CEC triblock polymer demonstrates increased small molecule binding and ideal elastic behavior for hydrogel formation. The negative control CL44AECL44A does not exhibit binding to small molecule and is inelastic at lower temperatures, affirming the favorable role of C domain and its helical conformation. While both CEC and CL44AECL44A assemble into micelles, CEC is more densely packed with C domains on the surface enabling the development of networks leading to hydrogel formation. Such protein engineered triblock copolymers capable ...

Published

2018

3. Thermoresponsive Protein-Engineered Coiled-Coil Hydrogel for Sustained Small Molecule Release

Author

P. Douglas Renfrew, Lindsay K. Hill, Richard Bonneau, Jin Kim Montclare, Sean C O'Neill, Che Fu Liu, Michael Meleties, Xuan Xie, Raymond S. Tu, Priya Katyal, Erika Delgado-Fukushima, Youssef Zaim Wadghiri, and Teeba Jihad

Subjects

Polymers and Plastics, Polymers, Protein domain, Bioengineering, 02 engineering and technology, 010402 general chemistry, Protein Engineering, 01 natural sciences, Biomaterials, Protein Domains, Upper critical solution temperature, Materials Chemistry, Thermostability, Coiled coil, Drug Carriers, Chemistry, technology, industry, and agriculture, Temperature, Proteins, Hydrogels, Protein engineering, 021001 nanoscience & nanotechnology, Small molecule, 0104 chemical sciences, Nanofiber, Delayed-Action Preparations, Self-healing hydrogels, Biophysics, 0210 nano-technology, Hydrophobic and Hydrophilic Interactions

Abstract

Thermoresponsive hydrogels are used for an array of biomedical applications. Lower critical solution temperature-type hydrogels have been observed in nature and extensively studied in comparison to upper critical solution temperature (UCST)-type hydrogels. Of the limited protein-based UCST-type hydrogels reported, none have been composed of a single coiled-coil domain. Here, we describe a biosynthesized homopentameric coiled-coil protein capable of demonstrating a UCST. Microscopy and structural analysis reveal that the hydrogel is stabilized by molecular entanglement of protein nanofibers, creating a porous matrix capable of binding the small hydrophobic molecule, curcumin. Curcumin binding increases the α-helical structure, fiber entanglement, mechanical integrity, and thermostability, resulting in sustained drug release at physiological temperature. This work provides the first example of a thermoresponsive hydrogel comprised of a single coiled-coil protein domain that can be used as a vehicle for sustained release and, by demonstrating UCST-type behavior, shows promise in forging a relationship between coiled-coil protein-phase behavior and that of synthetic polymer systems.

Published

2019

4. Bionanocomposites: Differential Effects of Cellulose Nanocrystals on Protein Diblock Copolymers

Author

Sandra M. Da Silva, Christoph Weder, Deng Yan, E. Johan Foster, Raymond S. Tu, J.W. Gilman, Iulia Sacui, Jin Kim Montclare, Silvana Mueller, and Jennifer S. Haghpanah

Subjects

Polymers and Plastics, Surface Properties, Mechanical integrity, Biocompatible Materials, Bioengineering, 02 engineering and technology, Cartilage Oligomeric Matrix Protein, 010402 general chemistry, 01 natural sciences, Protein Structure, Secondary, Nanocomposites, Biomaterials, Colloid, Elastic Modulus, Materials Testing, Polymer chemistry, Materials Chemistry, Copolymer, Animals, Colloids, Urochordata, Cellulose, Cartilage oligomeric matrix protein, Aqueous solution, biology, Chemistry, 021001 nanoscience & nanotechnology, Differential effects, Peptide Fragments, Elastin, 0104 chemical sciences, Cellulose nanocrystals, Chemical engineering, biology.protein, Nanoparticles, 0210 nano-technology, Hydrophobic and Hydrophilic Interactions

Abstract

We investigate the effects of mixing a colloidal suspension of tunicate-derived cellulose nanocrystals (t-CNCs) with aqueous colloidal suspensions of two protein diblock copolymers, EC and CE, which bear two different self-assembling domains (SADs) derived from elastin (E) and the coiled-coil region of cartilage oligomeric matrix protein (C). The resulting aqueous mixtures reveal improved mechanical integrity for the CE+t-CNC mixture, which exhibits an elastic gel network. This is in contrast to EC+t-CNC, which does not form a gel, indicating that block orientation influences the ability to interact with t-CNCs. Surface analysis and interfacial characterization indicate that the differential mechanical properties of the two samples are due to the prevalent display of the E domain by CE, which interacts more with t-CNCs leading to a stronger network with t-CNCs. On the other hand, EC, which is predominantly C-rich on its surface, does not interact as much with t-CNCs. This suggests that the surface characteristics of the protein polymers, due to folding and self-assembly, are important factors for the interactions with t-CNCs, and a significant influence on the overall mechanical properties. These results have interesting implications for the understanding of cellulose hydrophobic interactions, natural biomaterials and the development of artificially assembled bionanocomposites.

Published

2013

5. Engineering of an Environmentally Responsive Beta Roll Peptide for Use As a Calcium-Dependent Cross-Linking Domain for Peptide Hydrogel Formation

Author

Hoang D. Lu, Raymond S. Tu, Kevin Dooley, Yang Hee Kim, and Scott Banta

Subjects

Models, Molecular, chemistry.chemical_classification, Circular dichroism, Leucine zipper, Polymers and Plastics, Macromolecular Substances, Chemistry, Stereochemistry, Beta helix, Bioengineering, Peptide, Leucine-rich repeat, Protein Engineering, Hydrogel, Polyethylene Glycol Dimethacrylate, Protein Structure, Secondary, Biomaterials, Cross-Linking Reagents, Leucine, Helix, Self-healing hydrogels, Materials Chemistry, Calcium, Peptides, Protein secondary structure

Abstract

We have created a set of rationally designed peptides that form calcium-dependent hydrogels based on the beta roll peptide domain. In the absence of calcium, the beta roll domain is intrinsically disordered. Upon the addition of calcium, the peptide forms a beta helix secondary structure. We have designed two variations of our beta roll domain. First, we have mutated one face of the beta roll domain to contain leucine residues so that the calcium-dependent structural formation leads to dimerization through hydrophobic interactions. Second, an α-helical leucine zipper domain is appended to the engineered beta roll domain as an additional means of forming intermolecular cross-links. This full peptide construct forms a hydrogel only in calcium-rich environments. The resulting structural and mechanical properties of the supramolecular assemblies are compared with the wild-type domain using several biophysical techniques including circular dichroism, FRET, bis-ANS binding and microrheology. The calcium responsiveness and rheological properties of the leucine beta roll containing construct confirm the potential of this allosterically regulated scaffold to serve as a cross-linking domain for stimulus-responsive biomaterials development.

Published

2012

6. Artificial Protein Block Polymer Libraries Bearing Two SADs: Effects of Elastin Domain Repeats

Author

Raymond S. Tu, Jin Kim Montclare, Jennifer S. Haghpanah, Min Dai, Eric W. Roth, Alice Liang, and Navjot Singh

Subjects

Curcumin, Polymers and Plastics, Polymers, Protein Conformation, Nanoparticle, Bioengineering, Viscoelastic Substances, Protein Structure, Secondary, Biomaterials, Drug Delivery Systems, Protein structure, Peptide Library, Polymer chemistry, Materials Chemistry, Matrilin Proteins, Peptide library, Glycoproteins, chemistry.chemical_classification, Cartilage oligomeric matrix protein, Extracellular Matrix Proteins, Tissue Engineering, biology, Viscosity, Transition temperature, Temperature, Proteins, Polymer, Small molecule, Elastin, Crystallography, chemistry, biology.protein, Nanoparticles, Gels

Abstract

We have generated protein block polymer E(n)C and CE(n) libraries composed of two different self-assembling domains (SADs) derived from elastin (E) and the cartilage oligomeric matrix protein coiled-coil (C). As the E domain is shortened, the polymers exhibit an increase in inverse transition temperature (T(t)); however, the range of temperature change differs dramatically between the E(n)C and CE(n) library. Whereas all polymers assemble into nanoparticles, the bulk mechanical properties of the E(n)C are very different from CE(n). The E(n)C members demonstrate viscolelastic behavior under ambient conditions and assemble into elastic soft gels above their T(t) values. By contrast, the CE(n) members are predominantly viscous at all temperatures. All library members demonstrate binding to curcumin. The differential thermoresponsive behaviors of the E(n)C and CE(n) libraries in addition to their small molecule recognition abilities make them suitable for potential use in tissue engineering and drug delivery.

Published

2011