Your search keyword '"Annelise E, Barron"' showing total 6 results

1. Commentary progress in the de novo design of structured peptoid protein mimics

Author

Annelise E. Barron and Modi Wetzler

Subjects

Biomaterials, chemistry.chemical_compound, chemistry, Peptidomimetic, Research community, Organic Chemistry, Biophysics, Nanotechnology, Peptoid, General Medicine, Biology, Biochemistry

Abstract

Significant progress has been made in recent years toward creating interesting, unique, and in some cases, predictable oligopeptoid/polypeptoid secondary, tertiary, and in one case, quaternary structures. This article describes this progress, identifies a few of the many remaining challenges, and discusses potentially interesting or fruitful strategies for the peptoid biomimetics research community. © 2011 Wiley Periodicals, Inc. Biopolymers (Pept Sci) 96: 556–560, 2011.

Published

2011

2. NMEGylation: A novel modification to enhance the bioavailability of therapeutic peptides

Author

Annelise E. Barron, Theodore S. Jardetzky, and Minyoung Park

Subjects

Serum, Chemistry, Pharmaceutical, Biophysics, Peptide, Peptide binding, Biochemistry, Article, Biomaterials, Inhibitory Concentration 50, chemistry.chemical_compound, Drug Stability, Humans, Solubility, chemistry.chemical_classification, Organic Chemistry, General Medicine, Combinatorial chemistry, Bioavailability, Monomer, chemistry, N-substituted Glycines, lipids (amino acids, peptides, and proteins), Target protein, Peptides, Hydrophobic and Hydrophilic Interactions, Linker, Conjugate

Abstract

We have evaluated "NMEGylation"--the covalent attachment of an oligo-N-methoxyethylglycine (NMEG) chain--as a new form of peptide/protein modification to enhance the bioavailability of short peptides. OligoNMEGs are hydrophilic polyethylene glycol-like molecules made by solid-phase synthesis, typically up to 40 monomers in length. They have been studied as nonfouling surface coatings and as monodisperse mobility modifiers for free-solution conjugate capillary electrophoresis. However, polyNMEGs have not been demonstrated before this work as modifiers of therapeutic proteins. In prior published work, we identified a short peptide, "C20," as a potential extracellular inhibitor of the fusion of human respiratory syncytial virus with mammalian cells. The present study was aimed at improving the C20 peptide's stability and solubility. To this end, we synthesized and studied a series of NMEGylated C20 peptide-peptoid bioconjugates comprising different numbers of NMEGs at either the N- or C-terminus of C20. NMEGylation was found to greatly improve this peptide's solubility and serum stability; however, longer polyNMEGs (n > 3) deleteriously affected peptide binding to the target protein. By incorporating just one NMEG monomer, along with a glycine monomer as a flexible spacer, at C20's N-terminus (NMEG-Gly-C20), we increased both solubility and serum stability greatly, while recovering a binding affinity comparable to that of unmodified C20 peptide. Our results suggest that NMEGylation with an optimized number of NMEG monomers and a proper linker could be useful, more broadly, as a novel modification to enhance bioavailability and efficacy of therapeutic peptides.

Published

2011

3. A chemically synthesized peptoid-based drag-tag enhances free-solution DNA sequencing by capillary electrophoresis

Author

Robert J. Meagher, Russell D. Haynes, and Annelise E. Barron

Subjects

Streptavidin, Glycine, Biophysics, Biochemistry, Article, DNA sequencing, Polyethylene Glycols, Biomaterials, Peptoids, chemistry.chemical_compound, Capillary electrophoresis, chemistry.chemical_classification, Molar mass, Chromatography, Molecular Structure, Organic Chemistry, Electrophoresis, Capillary, Peptoid, DNA, Sequence Analysis, DNA, General Medicine, Polymer, Solutions, Electrophoresis, Monomer, chemistry

Abstract

We report a capillary-based DNA sequencing read length of 100 bases in 16 min using end-labeled free-solution conjugate electrophoresis (FSCE) with a monodisperse poly-N-substituted glycine (polypeptoid) as a synthetic drag-tag. FSCE enabled rapid separation of single-stranded (ss) DNA sequencing fragments with single-base resolution without the need for a viscous DNA separation matrix. Protein-based drag-tags previously used for FSCE sequencing, for example, streptavidin, are heterogeneous in molar mass (polydisperse); the resultant band-broadening can make it difficult to obtain the single-base resolution necessary for DNA sequencing. In this study, we synthesized and HPLC-purified a 70mer poly-N-(methoxyethyl)glycine (NMEG) drag-tag with a molar mass of - 11 kDa. The NMEG monomers that comprise this peptoid drag-tag are interesting for bioanalytical applications, because the methoxyethyl side chain's chemical structure is reminiscent of the basic monomer unit of polyethylene glycol, a highly biocompatible commercially available polymer, which, however, is not available in monodisperse preparation at an - 11 kDa molar mass. This is the first report of ssDNA separation and of four-color, base-by-base DNA sequencing by FSCE through the use of a chemically synthesized drag-tag. These results show that high-molar mass, chemically synthesized drag-tags based on the polyNMEG structure, if obtained in monodisperse preparation, would serve as ideal drag-tags and could help FSCE reach the commercially relevant read lengths of 100 bases or more.

Published

2011

4. Close mimicry of lung surfactant protein B by 'clicked' dimers of helical, cationic peptoids

Author

Michelle T. Dohm, Annelise E. Barron, Ronald N. Zuckermann, Jiwon Seo, and Shannon L. Seurynck-Servoss

Subjects

chemistry.chemical_classification, Stereochemistry, Dimer, Organic Chemistry, Biophysics, Cationic polymerization, Peptide, Peptoid, General Medicine, Biochemistry, Biomaterials, chemistry.chemical_compound, Monomer, chemistry, Pulmonary surfactant, Amphiphile, Organic chemistry, Linker

Abstract

A family of peptoid dimers developed to mimic SP-B is presented, where two amphipathic, cationic helices are linked by an achiral octameric chain. SP-B is a vital therapeutic protein in lung surfactant replacement therapy, but its large-scale isolation or chemical synthesis is impractical. Enhanced biomimicry of SP-B’s disulfide-bonded structure has been previously attempted via disulfide-mediated dimerization of SP-B1-25 and other peptide mimics, which improved surface activity relative to the monomers. Herein, the effects of disulfide- or ‘click’-mediated (1,3-dipolar cycloaddition) dimerization, as well as linker chemistry, on the lipid-associated surfactant activity of a peptoid monomer are described. Results revealed that the ‘clicked’ peptoid dimer enhanced in vitro surface activity in a DPPC:POPG:PA lipid film relative to its disulfide-bonded and monomeric counterparts in both surface balance and pulsating bubble surfactometry studies. On the pulsating bubble surfactometer, the film containing the ‘clicked’ peptoid dimer outperformed all presented peptoid monomers and dimers, and two SP-B derived peptides, attaining an adsorbed surface tension of 22 mN m −1 , and maximum and minimum cycling values of 42 mN m −1 and near-zero, respectively.

Published

2009

5. Progress in the de novo design of structured peptoid protein mimics

Author

Modi, Wetzler and Annelise E, Barron

Subjects

Peptoids, Molecular Structure, Drug Design, Humans, Computer Simulation, Peptidomimetics, Protein Structure, Secondary

Abstract

Significant progress has been made in recent years toward creating interesting, unique, and in some cases, predictable oligopeptoid/polypeptoid secondary, tertiary, and in one case, quaternary structures. This article describes this progress, identifies a few of the many remaining challenges, and discusses potentially interesting or fruitful strategies for the peptoid biomimetics research community.

Published

2011

6. Extreme stability of helices formed by water-soluble poly-N-substituted glycines (polypeptoids) with alpha-chiral side chains

Author

Tracy J. Sanborn, Ronald N. Zuckermann, Annelise E. Barron, and Cindy W. Wu

Subjects

Steric effects, Stereochemistry, Biophysics, Glycine, Biochemistry, Oligomer, Protein Structure, Secondary, Biomaterials, chemistry.chemical_compound, Peptoids, Biopolymers, Drug Stability, Amphiphile, Side chain, Urea, Denaturation (biochemistry), Aqueous solution, Circular Dichroism, Organic Chemistry, Temperature, Water, Peptoid, General Medicine, chemistry, Solubility, Solvents, Salts, Chirality (chemistry), Oligopeptides

Abstract

Poly-N-substituted glycines or “peptoids” are protease-stable peptide mimics. Although the peptoid backbone is achiral and lacks hydrogen-bond donors, substitution with α-chiral side chains can drive the formation of stable helices that give rise to intense CD spectra. To systematically study the solution properties and stability of water-soluble peptoid helices with α-chiral side chains, we have synthesized and characterized an amphipathic, 36-residue N-substituted glycine oligomer. CD was used to investigate effects of concentration and solvent environment on this helical peptoid. We saw no significant dependence of helical structure on concentration. Intense, “α-helix-like” CD spectra were observed for the 36-mer in aqueous, 2,2,2-trifluorethanol (TFE), and methanol solution, proving a relative insensitivity of peptoid helical structure to solvent environment. While CD spectra taken in these different solvents were fundamentally similar in shape, we did observe some interesting differences in the intensities of particular CD bands in the various solvents. For example, the addition of TFE to an aqueous solvent increases the degree of peptoid helicity, as is observed for polypeptide α-helices. Moreover, the helical structure of peptoids appears to be virtually unaffected by heat, even in an aqueous buffer containing 8 M urea. The extraordinary resistance of these peptoid helices to denaturation is consistent with a dominant role of steric forces in their structural stabilization. The structured polypeptoids studied here may have potential as robust mimics of helical polypeptides of therapeutic interest. © 2002 John Wiley & Sons, Inc. Biopolymers 63: 12–20, 2002

Published

2002