Proteins are the central functional instruments that enable life, and the development of strategies for protein mimicry is a grand challenge for chemists. Artificial backbones with defined folding propensities, termed ?foldamers?, can offer biostable analogues of natural entities; however, challenges related to design create barriers to mimicking complex tertiary folds. Overcoming this barrier promises to open a new frontier and advance foldamers toward the functional versatility of proteins. With support from the initial award, a general method for creating foldamer tertiary structure was developed based on the systematic alteration of backbone covalent structure in natural sequences. An important gap remains in establishing the ability of these mimetics to reproduce and modulate functional properties of prototype proteins on which they are based. A long-term goal of the PI?s research program is to develop principles for the design of artificial backbones capable of reproducing the full panoply of protein folds and functions in nature and to apply these principles to control properties such as folded structure, folded stability, physiological stability, and dynamics. The overall objective of this renewal application is to demonstrate the scope of functions possible in heterogeneous-backbone foldamer tertiary structure mimetics. The central hypothesis guiding this work is that design principles developed in the initial award period can be applied to produce functional analogues of diverse prototype proteins and also used to tune functional characteristics of the native backbone. The rationale for pursuing the proposed research is that pushing beyond structural mimicry to functional mimicry in protein-inspired artificial scaffolds will hone design principles, create valuable bioactive agents, and shed new light on natural systems. In order to test the above central hypothesis, two specific aims will be pursued: (1) develop mimics of zinc finger proteins with native-like molecular recognition characteristics; (2) create mimics of disulfide-rich domains from insect and reptile venoms. In terms of expected outcomes, the proposed work will (1) expand the scope of foldamer tertiary structure mimicry (complex chain topologies, large multidomain proteins); (2) broaden the functional repertoire of these scaffolds (selective recognition of DNA, proteins, and biological membranes); (3) yield new insights into the dynamics of sequence-specific DNA binding by zinc finger proteins; and (4) provide a starting point toward bioactive agents with potential applications in the management of chronic pain and treatment of microbial infections. Collectively, realization of the goals of the project will lead to a vertical advance in the size, structural complexity, and functional diversity possible in synthetic protein mimetics.

Public Health Relevance

The proposed project seeks to develop technologies for the constriction of synthetic, biostable mimics of complex protein folds and functions. The public health relevance of this goal stems from the biomedical implications of protein mimicry in a broad sense as well as specific targets being addressed and their connection to the treatment of chronic pain and microbial infections.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM107161-07
Application #
9861247
Study Section
Synthetic and Biological Chemistry B Study Section (SBCB)
Program Officer
Fabian, Miles
Project Start
2013-07-01
Project End
2023-01-31
Budget Start
2020-02-01
Budget End
2021-01-31
Support Year
7
Fiscal Year
2020
Total Cost
Indirect Cost
Name
University of Pittsburgh
Department
Chemistry
Type
Schools of Arts and Sciences
DUNS #
004514360
City
Pittsburgh
State
PA
Country
United States
Zip Code
15213
George, Kelly L; Horne, W Seth (2018) Foldamer Tertiary Structure through Sequence-Guided Protein Backbone Alteration. Acc Chem Res 51:1220-1228
Kar, Karunakar; Baker, Matthew A; Lengyel, George A et al. (2017) Backbone Engineering within a Latent ?-Hairpin Structure to Design Inhibitors of Polyglutamine Amyloid Formation. J Mol Biol 429:308-323
Walters, Christopher R; Szantai-Kis, D Miklos; Zhang, Yitao et al. (2017) The effects of thioamide backbone substitution on protein stability: a study in ?-helical, ?-sheet, and polyproline II helical contexts. Chem Sci 8:2868-2877
George, Kelly L; Horne, W Seth (2017) Heterogeneous-Backbone Foldamer Mimics of Zinc Finger Tertiary Structure. J Am Chem Soc 139:7931-7938
Tavenor, Nathan A; Reinert, Zachary E; Lengyel, George A et al. (2016) Comparison of design strategies for ?-helix backbone modification in a protein tertiary fold. Chem Commun (Camb) 52:3789-92
Karnes, Megan A; Schettler, Shelby L; Werner, Halina M et al. (2016) Thermodynamic and Structural Impact of ?,?-Dialkylated Residue Incorporation in a ?-Hairpin Peptide. Org Lett 18:3902-5
Werner, Halina M; Cabalteja, Chino C; Horne, W Seth (2016) Peptide Backbone Composition and Protease Susceptibility: Impact of Modification Type, Position, and Tandem Substitution. Chembiochem 17:712-8
Werner, Halina M; Horne, W Seth (2015) Folding and function in ?/?-peptides: targets and therapeutic applications. Curr Opin Chem Biol 28:75-82
Lengyel, George A; Reinert, Zachary E; Griffith, Brian D et al. (2014) Comparison of backbone modification in protein ?-sheets by ??? residue replacement and ?-residue methylation. Org Biomol Chem 12:5375-81
Reinert, Zachary E; Horne, W Seth (2014) Protein backbone engineering as a strategy to advance foldamers toward the frontier of protein-like tertiary structure. Org Biomol Chem 12:8796-802

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