Human serotine transporter (hSERT)
is one of the most influential
drug targets, and its allosteric modulators (e.g., escitalopram) have
emerged to be the next-generation medication for psychiatric disorders.
However, the molecular mechanism underlying the allosteric modulation
of hSERT is still elusive. Here, the simulation strategies of conventional
(cMD) and steered (SMD) molecular dynamics were applied to investigate
this molecular mechanism from distinct perspectives. First, cMD simulations
revealed that escitalopram’s binding to hSERT’s allosteric
site simultaneously enhanced its binding to the orthosteric site.
Then, SMD simulation identified that the occupation of hSERT’s
allosteric site by escitalopram could also block its dissociation
from the orthosteric site. Finally, by comparing the simulated structures
of two hSERT–escitalopram complexes with and without allosteric
modulation, a new conformational coupling between an extracellular
(Arg104-Glu494) and an intracellular (Lys490-Glu494) salt bridge was
identified. In summary, this study explored the mechanism underlying
the allosteric modulation of hSERT by collectively applying two MD
simulation strategies, which could facilitate our understanding of
the allosteric modulations of not only hSERT but also other clinically
important therapeutic targets.