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INFORMATION FOR

    Corey O'Hern, PhD

    Professor
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    Additional Titles

    Assoc Prof Dept of Mechanical Engineering & Materials Science and Physics

    Associate Professor

    About

    Titles

    Professor

    Assoc Prof Dept of Mechanical Engineering & Materials Science and Physics; Associate Professor

    Biography

    Prof. O'Hern is a Professor of Mechanical Engineering & Materials Science and Physics, co-founder of the Integrated Graduate Program in Physical and Engineering Biology, and Director of the Program in Physics, Engineering, and Biology. His research employs theoretical and computational methods (e.g. all-atom and coarse-grained molecular dynamics simulations) to tackle a broad range of fundamental questions in soft matter and biological physics. Current projects include the dynamics of protein folding, unfolding, and aggregation, the binding and self-assembly of proteins, and the structural
    and mechanical properties of cells and tissues in the context of collective cell motion and wound healing.

    Departments & Organizations

    Education & Training

    Postdoctoral Research Associate
    University of Chicago (2002)
    Postdoctoral Research Associate
    University of California, Los Angeles (2002)
    PhD
    University of Pennsylvania, Physics (1999)
    BS
    Duke University, Physics (1994)

    Research

    Overview

    My research effort in biological physics employs both theoretical and computational approaches, including statistical mechanics descriptions
    and coarse-grained and atomistic molecular dynamics simulations, to study
    important biological problems ranging from determining the
    mechanical properties of skin cancer cells to understanding protein
    misfolding and aggregation. All of the projects described below involve close collaborations with experimental biologists.

    1. Smart, designer, protein-based nanogels: We design, create, and characterize new classes of
    stimuli-responsive biomaterials. A distinguishing feature of these
    materials is the incorporation of tetratricopeptide (TPR) modules of
    defined structure and stability and cross-linkers between TPRs to
    create a scaffold with structural integrity. Cross-linking in these
    novel materials is governed by specific TPR-peptide
    interactions. We are able to design and manipulate the
    microscopic components and their interactions with unprecedented
    control in these materials. We combine experimental measurements
    with coarse-grained computer simulations to understand and define the
    macroscopic consequences of particular designs. This coordinated process will lead to a new generation of
    active biomaterials with unprecedented, highly-specific molecular
    recognition capabilities and response to external stimuli. Collaborators
    on this project include Profs. Eric Dufresne (Mechanical Engineering,
    Chemical Engineering, Cell Biology, and Physics) and Lynne Regan (Molecular Biophysics & Biochemistry, Chemistry).

    2. Understanding the structural and mechanical properties of epithelial cells:
    The goal of this project is to first determine the structural
    properties (cell size and shape) and mechanical constraints
    (intercellular forces and packing geometry) of normal epithelial
    tissue and then identify how these properties evolve during cancer
    progression and wound healing. This work is based on the hypothesis that tumor

    formation and cell motion during wound healing can be directly linked
    to changes in the mechanical properties of the tissue. We will address three
    fundamental open questions in this project: 1) Does the structure,
    packing geometry, and force-bearing properties of cells and tissues
    change during tumorigenesis? 2) Is there a feedback effect, in which
    these changes promote the progression of tumorigenesis? and 3) To what extent can wound healing be modeled by mechanical response without biochemical signaling?
    Collaborators on this project include Profs. Eric Dufresne (Mechanical Engineering & Materials Science,
    Chemical Engineering, Cell Biology) and Valerie
    Horsley (MCDB).

    4. Nanoscale approaches to screening small molecule inhibitors of
    toxic amyloid species in neurodegenerative disease:
    Single molecule measurements are uniquely capable of characterizing
    the dynamic set of molecular species that are populated during amyloid
    aggregation. We will combine experimental single molecule
    fluorescence methods with computer simulations to develop a novel
    approach to determine how soluble amyloid species interact with small
    organic molecules. We will develop our methods using the Parkinson's
    Disease associated protein, alpha-synuclein, and the Alzheimer's
    Disease associated protein, tau. Using small molecules that have been
    identified for their ability to perturb aggregation of these proteins, we will study their effects on protein conformational dynamics and
    oligomerization process. We will specifically address two questions: (1) how do small molecules affect monomer structures and
    their dynamics and (2) what is the effect of small molecules on
    oligomerization. The results of these investigations will provide an
    ultrasensitive, robust assay for screening small molecules that
    perturb soluble pre-fibrillar amyloid species. Thus, if successful,

    our proposed research will lead to a transformative change in the way
    small-molecule drugs are screened, the ultimate outcome of which is
    the development of drugs to treat or prevent Parkinson's, Alzheimer's,
    and other amyloid diseases. This work will be performed
    in collaboration with Prof. Elizabeth Rhoades (MB&B, Physics).

    1. Prediction of the Binding Affinity for Hydrophobic Protein-Protein Interactions
    2. Modeling the Conformational Dynamics of the Intrinsically Disordered Proteins alpha-synuclein and tau.
    3. Modeling the Collective Motion of Epithelial Cells in Response to Wounding
    4. Modeling Changes in the Structural and Mechanical Properties of Epithelial Cells during Tumor Formation

    Medical Research Interests

    Cell Shape; Protein Conformation; Protein Folding; Thermodynamics

    Research at a Glance

    Yale Co-Authors

    Frequent collaborators of Corey O'Hern's published research.

    Publications

    2024

    Academic Achievements & Community Involvement

    • activity

      Jamming and glass transitions in disordered solids

    • activity

      American Physical Society

    • honor

      NSF Cyber-Enabled Discovery and Innovation Award

    • honor

      NSF Faculty Early Career Development Award

    • honor

      Graduated Summa Cum Laude

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