Your search keyword '"Sean C O'Neill"' showing total 4 results

1. 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

2. ‘Reverse’ Hofmeister effects on the sol–gel transition rates for an α-helical peptide–PEG bioconjugate

Author

Jacob A Weber, Sean C O'Neill, Raymond S. Tu, and Ankit D. Kanthe

Subjects

Anions, Bromides, Microrheology, Hofmeister series, Protein Conformation, Kinetics, General Physics and Astronomy, Viscoelastic Substances, 02 engineering and technology, Electrolyte, 01 natural sciences, Article, Phase Transition, Polyethylene Glycols, Hydrophobic effect, Chlorides, Spectroscopy, Fourier Transform Infrared, 0103 physical sciences, Amino Acid Sequence, Physical and Theoretical Chemistry, 010306 general physics, Aqueous solution, Chemistry, Water, Iodides, 021001 nanoscience & nanotechnology, Folding (chemistry), Chaotropic agent, Crystallography, Peptides, Rheology, 0210 nano-technology, Gels

Abstract

We examine the dynamics of the sol-gel transition for end-functionalized linear- and 4-arm-peptides bioconjugated to poly-ethylene glycol (PEG) in aqueous environments with increasingly chaotropic (Cl(-) < Br(-) < I(-)) anions. A 23-amino acid peptide sequence is rationally designed to self-assemble upon folding into the ordered α-helical conformation due to the hydrophobic effect. We use Attenuated Total Reflection - Fourier Transform Infrared Spectroscopy (ATR-FTIR) to quantify the ensemble average reversible secondary structure transitions as a function of electrolyte concentration and specific ion effects along the Hofmeister series. Subsequently, microrheology is used to quantify the kinetics of the gelation process, as it relates to folding and specific ion interactions. Our key findings were non-intuitive. We observe the faster evolution of the gel transitions in systems with more chaotropic anions. For our peptides in aqueous solution, “water-structuring” ions yield faster assembly behavior with a viscoelastic exponent, n, closer to unity representing self-assemblies that are Rouse-like. In contrast, ions that are “water-breaking” resulted in smaller viscoelastic exponents where self-assembly dynamics result in a viscoelastic exponent that suggests polymer entanglements.

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. Evolution of mechanics in α-helical peptide conjugated linear- and star-block PEG

Author

Z. H. Bhuiyan, Raymond S. Tu, and Sean C O'Neill

Subjects

Microrheology, chemistry.chemical_classification, Kinetics, Supramolecular chemistry, technology, industry, and agriculture, Peptide, 02 engineering and technology, General Chemistry, Conjugated system, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Article, 0104 chemical sciences, Folding (chemistry), chemistry, PEG ratio, Polymer chemistry, Biophysics, 0210 nano-technology, Peptide sequence

Abstract

We have designed a peptide conjugated poly-ethylene glycol (PEG) bioconjugate system that allows us to examine the intra- and inter-molecular dynamics of gelation. We measure the kinetics of gelation for end-functionalized linear- and star-architectures, and we correlate the gelation behavior with the molecular structure and self-association. The 23-amino acid peptide sequence is known to form a coiled-coil structure as a function of the solution's electrolyte concentration, and the two topologies of the PEG are peptide end-functionalized to examine formation of supramolecular assemblies. Subsequently, microrheology is used to evaluate the dynamics of self-assembly and the gelation time-scales. This study shows that the dynamics of peptide folding and assembly for linear-PEG conjugated systems yield a percolated network, but the star-PEG conjugated systems yield discrete assemblies and remain viscous. The results suggest that the degree of intra- and inter-molecular folding defines the critical gel behavior of the supramolecular system.

Published

2017