John Orban

Professor

Orban Group

Contact

Email: jorban@umd.edu

Call: (240) 314-6221

Education

  • Postdoctoral Fellow, Biomolecular NMR Spectroscopy, University of Washington, 1987-1990
  • CSIRO Postdoctoral Fellow, Biochemistry & Biophysics, McMaster University, 1985-1987
  • Ph.D., Chemistry, Australian National University, 1985
  • B.Sc. (Hons), Chemistry, University of Adelaide, Australia, 1981

Profile

Dr. Orban’s research interests focus on the area of protein structural biology and design, particularly in understanding how the malleability of protein folds relates to biological function. High field solution NMR spectroscopy and other biophysical and biochemical methods are employed in the laboratory.

CURRENT RESEARCH

Protein switches

Mutational tipping points for switching fold and function in a designed system.

While most globular proteins populate relatively homogeneous conformational ensembles under physiological conditions, significant exceptions continue to emerge. Many biological processes involve extensive re-modeling of protein conformation, including switches from disordered to ordered states. Some natural proteins can even undergo large-scale transitions from one ordered state to another, involving major shifts in secondary structure, repacking of the protein core, and exposure of new surfaces.

Such “metamorphic” proteins are capable of performing alternative functions triggered by binding interactions that stabilize latent conformational states. The ability of these proteins to completely change their fold topologies has implications in a number of important areas including computational and structural biology, protein evolution, human disease, and protein design. The Orban lab is working on the biophysical characterization of protein switches between a number of common fold topologies that occur through short mutational paths or in response to external stimuli.

Intrinsically disordered proteins (IDPs)

The proteins described above are typically on the margin of stability and can be tipped toward one fold or another through relatively subtle changes in sequence or environmental triggers. Intrinsically disordered proteins, on the other hand, have no stable 3D structure and their flexibility allows them to adopt many different conformations. Thus, their structures are characterized by conformational ensembles that are typically non-random coil. These conformational ensembles can be shifted, sometimes dramatically, in response to post-translational modifications or ligand binding. Conceptually, they are similar to metamorphic proteins, having the ability to adopt different structures with different binding partners, for example. The Orban lab is studying an IDP called prostate associated gene 4 (PAGE4) that plays an important role in prostate cancer using a range of biophysical tools including NMR and small angle X-ray scattering (SAXS). PAGE4 undergoes large changes in its conformational ensemble and cellular function depending on the level of phosphorylation. 

NMR spectra and assignment of a human T cell receptor ectodomain.

Multi-protein signaling complexes

The conformational changes described above are large amplitude. However, small structural changes can also play an important role in key biological processes. An example of this is
the interaction between peptide-MHC and T cell receptor (TCR) molecules. Although the 3D structures of pMHC, TCR, and pMHC-TCR are known, how this non-covalent binding interaction transmits information to distal TCR-associated CD3 molecules and triggers T cell signaling remains a mystery. The Orban lab is working on characterizing the binding interaction between TCR and CD3 molecules and also understanding how pMHC-binding to TCR leads to allosteric changes that affect the TCR-CD3 interaction.

 

Publications
2023
A single C-terminal residue controls SARS-CoV-2 spike trafficking and incorporation into VLPs.
Acquired resistance to KRAS G12C small-molecule inhibitors via genetic/nongenetic mechanisms in lung cancer.
Design and characterization of a protein fold switching network.
Reversible switching between two common protein folds in a designed system using only temperature.
2021
Engineering subtilisin proteases that specifically degrade active RAS.
2020
Peptide-MHC Binding Reveals Conserved Allosteric Sites in MHC Class I- and Class II-Restricted T Cell Receptors (TCRs).
A Non-genetic Mechanism Involving the Integrin β4/Paxillin Axis Contributes to Chemoresistance in Lung Cancer.
2019
The structural basis of T-cell receptor (TCR) activation: An enduring enigma.
Structural and Dynamical Order of a Disordered Protein: Molecular Insights into Conformational Switching of PAGE4 at the Systems Level.
2018
Structural metamorphism and polymorphism in proteins on the brink of thermodynamic stability.
Peptide-MHC (pMHC) binding to a human antiviral T cell receptor induces long-range allosteric communication between pMHC- and CD3-binding sites.
Prostate-Associated Gene 4 (PAGE4): Leveraging the Conformational Dynamics of a Dancing Protein Cloud as a Therapeutic Target.
PAGE4 and Conformational Switching: Insights from Molecular Dynamics Simulations and Implications for Prostate Cancer.
Phenotypic Plasticity, Bet-Hedging, and Androgen Independence in Prostate Cancer: Role of Non-Genetic Heterogeneity.
2017
Phosphorylation-induced conformational dynamics in an intrinsically disordered protein and potential role in phenotypic heterogeneity.
2016
Prostate-associated gene 4 (PAGE4), an intrinsically disordered cancer/testis antigen, is a novel therapeutic target for prostate cancer.
2015
Phosphorylation-induced Conformational Ensemble Switching in an Intrinsically Disordered Cancer/Testis Antigen.
Identification of the Docking Site for CD3 on the T Cell Receptor β Chain by Solution NMR.
Subdomain interactions foster the design of two protein pairs with ∼80% sequence identity but different folds.
2013
Implications of protein fold switching.