Unraveling the Allosteric Communication Mechanisms
in T‑Cell Receptor–Peptide-Loaded Major Histocompatibility
Complex Dynamics Using Molecular Dynamics Simulations: An Approach
Based on Dynamic Cross Correlation Maps and Residue Interaction Energy
Calculations
Antigen presentation by major histocompatibility
complex (MHC)
proteins to T-cell receptors (TCRs) plays a crucial role in triggering
the adaptive immune response. Most of our knowledge on TCR–peptide-loaded
major histocompatibility complex (pMHC) interaction stemmed from experiments
yielding static structures, yet the dynamic aspects of this molecular
interaction are equally important to understand the underlying molecular
mechanisms and to develop treatment strategies against diseases such
as cancer and autoimmune diseases. To this end, computational biophysics
studies including all-atom molecular dynamics simulations have provided
useful insights; however, we still lack a basic understanding of an
overall allosteric mechanism that results in conformational changes
in the TCR and subsequent T-cell activation. Previous hydrogen–deuterium
exchange and nuclear magnetic resonance studies provided clues regarding
these molecular mechanisms, including global rigidification and allosteric
effects on the constant domain of TCRs away from the pMHC interaction
site. Here, we show that molecular dynamics simulations can be used
to identify how this overall rigidification may be related to the
allosteric communication within TCRs upon pMHC interaction via essential
dynamics and nonbonded residue–residue interaction energy analyses.
The residues taking part in the rigidification effect are highlighted
with an intricate analysis on residue interaction changes, which lead
to a detailed outline of the complex formation event. Our results
indicate that residues of the Cβ domain of TCRs show significant
differences in their nonbonded interactions upon complex formation.
Moreover, the dynamic cross correlations between these residues are
also increased, in line with their nonbonded interaction energy changes.
Altogether, our approach may be valuable for elucidating intramolecular
allosteric changes in the TCR structure upon pMHC interaction in molecular
dynamics simulations.