Your search keyword '"Amethist S. Finch"' showing total 6 results

1. Genetically Engineered Peptides for Inorganics: Study of an Unconstrained Bacterial Display Technology and Bulk Aluminum Alloy

Author

Bryn L. Adams, Deborah A. Sarkes, Amethist S. Finch, Dimitra N. Stratis-Cullum, and Margaret M. Hurley

Subjects

chemistry.chemical_classification, Bacterial display, Materials science, Surface Properties, Mechanical Engineering, Nanotechnology, Peptide binding, Peptide, Biopanning, Combinatorial chemistry, Communications, Molecular dynamics, Residue (chemistry), Molecular recognition, chemistry, Mechanics of Materials, Peptide Library, Alloys, Escherichia coli, General Materials Science, Peptide library, Genetic Engineering, Peptides, Aluminum

Abstract

Biological systems have evolved the exquisite ability to spatially combine many weak, non-covalent chemical interactions to direct the molecular recognition and self-assembly of incredibly complex materials. The ability to control assembly at the molecular level has led to an interest in harnessing nature’s building blocks (e.g., polypeptides, DNA, etc.) to bind inorganic or synthetic compounds for multi-scale fabrication (nano-to macro) of advanced materials. The utility of this approach is evidenced by the large and growing body of research reports highlighting peptides generated through biopanning of surface display peptide libraries.1–5 Examples include a wide range of peptide binders to pure metals,6–10 metal oxides,11–13 metal alloys,14 metal salts,15 and semiconductors,16–18 as well as hydroxyapatite—the inorganic component of teeth and bone.19 Inorganic binding peptides, no matter the source, are widely recognized for their specificity and design control, and present a remarkable opportunity for advanced materials development.20 However, the rules governing this type of peptide binding are not fully understood.18, 20, 21 A variety of factors have been implicated in playing a role in peptide-inorganic surface interactions, including conformational effects,22–25 electrostatic effects,26, 27 relative residue placement in the sequence,28, 29 acid-base chemistry,30 and hydrogen bond formation.14, 21

Published

2013

2. Protein catalyzed capture agents with tailored performance for in vitro and in vivo applications

Author

Amethist S. Finch, Deborah A. Sarkes, Paul Kearney, Kenneth C. Fang, Candice Warner, Brandi L. Dorsey, Blake Farrow, Jeré A. Wilson, Sherri L. Candelario, Jacquie Malette, Dimitra N. Stratis-Cullum, Heather D. Agnew, Matthew B. Coppock, Bert T. Lai, Joshua A. Orlicki, Suresh M. Pitram, Scott M. Law, James R. Heath, and Rosemary D. Rohde

Subjects

0301 basic medicine, Male, Vascular Endothelial Growth Factor A, Peptide, Ligands, 01 natural sciences, Biochemistry, Mass Spectrometry, thermal stability, Mice, protective antigen, Chromatography, High Pressure Liquid, chemistry.chemical_classification, Bacterial display, Calorimetry, Differential Scanning, vascular endothelial growth factor, Circular Dichroism, General Medicine, Articles, biological stability, peptide, Synthetic antibody, Colonic Neoplasms, Injections, Intravenous, Click chemistry, Microsomes, Liver, Female, HT29 Cells, Injections, Intraperitoneal, Protein Binding, Proteases, Bacterial Toxins, Transplantation, Heterologous, Biophysics, Antibodies, Catalysis, Article, Biomaterials, 03 medical and health sciences, synthetic antibody, In vivo, Peptide Library, Animals, Humans, Amino Acid Sequence, Antigens, Bacterial, 010405 organic chemistry, Ligand, Organic Chemistry, protein catalyzed capture agent, In vitro, 0104 chemical sciences, 030104 developmental biology, chemistry, Click Chemistry, Peptides

Abstract

We report on peptide‐based ligands matured through the protein catalyzed capture (PCC) agent method to tailor molecular binders for in vitro sensing/diagnostics and in vivo pharmacokinetics parameters. A vascular endothelial growth factor (VEGF) binding peptide and a peptide against the protective antigen (PA) protein of Bacillus anthracis discovered through phage and bacterial display panning technologies, respectively, were modified with click handles and subjected to iterative in situ click chemistry screens using synthetic peptide libraries. Each azide‐alkyne cycloaddition iteration, promoted by the respective target proteins, yielded improvements in metrics for the application of interest. The anti‐VEGF PCC was explored as a stable in vivo imaging probe. It exhibited excellent stability against proteases and a mean elimination in vivo half‐life (T 1/2) of 36 min. Intraperitoneal injection of the reagent results in slow clearance from the peritoneal cavity and kidney retention at extended times, while intravenous injection translates to rapid renal clearance. The ligand competed with the commercial antibody for binding to VEGF in vivo. The anti‐PA ligand was developed for detection assays that perform in demanding physical environments. The matured anti‐PA PCC exhibited no solution aggregation, no fragmentation when heated to 100°C, and > 81% binding activity for PA after heating at 90°C for 1 h. We discuss the potential of the PCC agent screening process for the discovery and enrichment of next generation antibody alternatives.

Published

2016

3. Method for Discovery of Peptide Reagents Using a Commercial Magnetic Separation Platform and Bacterial Cell Surface Display Technology

Author

Deborah A. Sarkes, Dimitra N. Stratis-Cullum, Amethist S. Finch, and i L. Dorsey

Subjects

Streptavidin, chemistry.chemical_classification, Bacterial display, Phage display, Sorting, Peptide, Biopanning, Computational biology, Biology, Cell sorting, Combinatorial chemistry, chemistry.chemical_compound, Affinity Reagent, chemistry

Abstract

Biopanning by bacterial display has many advantages over yeast and phage display, including the speed to discovery of affinity reagents and direct amplification of bound cells without the need to elute and reinfect. However, widespread use is limited, in part due to poor performance achieved using manual Magnetic-Activated Cell Sorting (MACS) methods, and an absence of widely-available, low cost, high-performance sorting alternatives. Here, we have developed a methodology for bacterial cell sorting using the semi-automated autoMACS® Pro Separator for the first time, and have produced a complete method for sorting of bacteria displaying 15-mer peptides on their cell surface using this device, including downstream bioinformatic analysis of candidates for binding to a target of interest. Two autoMACS® programs designed for isolation of target cells with low frequency were evaluated and adapted to bacterial biopanning, using protective antigen (PA) of Bacillus anthracis as the model system. In contrast to manual MACS, the bacterial display library was preferentially enriched by autoMACS® sorting, yielding several promising candidates after only three rounds of biopanning and bioinformatic analysis. Individual candidates were evaluated for relative binding to fluorescently-labeled PA target or streptavidin negative control using Fluorescence-Activated Cell Sorting (FACS). The top thirteen peptide candidates from the autoMACS® sort demonstrate binding to PA with low cross-reactivity to streptavidin, while only two of eighteen candidates from the manual sort showed binding to PA, and both demonstrated greater cross-reactivity to streptavidin. Overall, the autoMACS® platform quickly harvested higher affinity peptide candidates with demonstrated specificity to the PA target. Peptide candidates produced with this method contained the previously reported PA consensus WXCFTC, further validating this method and the commercially available autoMACS® platform as the first low cost, semi-automated biopanning approach for bacterial display that is widely accessible and more reliable than the MACS/FACS standard protocol.

Published

2015

4. Biodiscovery of aluminum binding peptides

Author

Bryn L. Adams, Dimitra N. Stratis-Cullum, Amethist S. Finch, Margaret M. Hurley, and Deborah A. Sarkes

Subjects

chemistry.chemical_classification, Bacterial display, Affinity Reagent, Biochemistry, Chemistry, medicine, Peptide, Biopanning, medicine.disease_cause, Biosensor, Escherichia coli, Amino acid, Biofabrication

Abstract

Cell surface peptide display systems are large and diverse libraries of peptides (7-15 amino acids) which are presented by a display scaffold hosted by a phage (virus), bacteria, or yeast cell. This allows the selfsustaining peptide libraries to be rapidly screened for high affinity binders to a given target of interest, and those binders quickly identified. Peptide display systems have traditionally been utilized in conjunction with organic-based targets, such as protein toxins or carbon nanotubes. However, this technology has been expanded for use with inorganic targets, such as metals, for biofabrication, hybrid material assembly and corrosion prevention. While most current peptide display systems employ viruses to host the display scaffold, we have recently shown that a bacterial host, Escherichia coli, displaying peptides in the ubiquitous, membrane protein scaffold eCPX can also provide specific peptide binders to an organic target. We have, for the first time, extended the use of this bacterial peptide display system for the biodiscovery of aluminum binding 15mer peptides. We will present the process of biopanning with macroscopic inorganic targets, binder enrichment, and binder isolation and discovery.

Published

2013

5. Advances in synthetic peptides reagent discovery

Author

Amethist S. Finch, Deborah A. Sarkes, Dimitra N. Stratis-Cullum, and Bryn L. Adams

Subjects

Bacterial display, Protective antigen, Laboratory automation, Inorganic materials, Computational biology, Biocompatible material, Bioinformatics

Abstract

Bacterial display technology offers a number of advantages over competing display technologies (e.g, phage) for the rapid discovery and development of peptides with interaction targeted to materials ranging from biological hazards through inorganic metals. We have previously shown that discovery of synthetic peptide reagents utilizing bacterial display technology is relatively simple and rapid to make laboratory automation possible. This included extensive study of the protective antigen system of Bacillus anthracis, including development of discovery, characterization, and computational biology capabilities for in-silico optimization. Although the benefits towards CBD goals are evident, the impact is far-reaching due to our ability to understand and harness peptide interactions that are ultimately extendable to the hybrid biomaterials of the future. In this paper, we describe advances in peptide discovery including, new target systems (e.g. non-biological materials), advanced library development and clone analysis including integrated reporting.

Published

2013

6. Biomaterials: Genetically Engineered Peptides for Inorganics: Study of an Unconstrained Bacterial Display Technology and Bulk Aluminum Alloy (Adv. Mater. 33/2013)

Author

Amethist S. Finch, Bryn L. Adams, Deborah A. Sarkes, Margaret M. Hurley, and Dimitra N. Stratis-Cullum

Subjects

Bacterial display, Peptide display, Materials science, Mechanics of Materials, Genetically engineered, Mechanical Engineering, Alloy, engineering, General Materials Science, Nanotechnology, Biopanning, engineering.material, Biomineralization

Published

2013