posted on 2021-05-27, 01:22authored bySung Oh Woo, Myungkeun Oh, Lina Alhalhooly, Jasmin Farmakes, Arith J. Rajapakse, Zhongyu Yang, Philip G. Collins, Yongki Choi
Single-molecule
measurements of protein dynamics help unveil the
complex conformational changes and transitions that occur during ligand
binding and catalytic processes. Using high-resolution single-molecule
nanocircuit techniques, we have investigated differences in the conformational
dynamics and transitions of lysozyme interacting with three ligands:
peptidoglycan substrate, substrate-based chitin analogue, and indole
derivative inhibitors. While processing peptidoglycan, lysozyme followed
one of the two mechanistic pathways for the hydrolysis of the glycosidic
bonds: a concerted mechanism inducing direct conformational changes
from open to fully closed conformations or a nonconcerted mechanism
involving transient pauses in intermediate conformations between the
open and closed conformations. In the presence of either chitin or
an indole inhibitor, lysozyme was unable to access the fully closed
conformation where catalysis occurs. Instead, lysozymes’ conformational
closures terminated at slightly closed, “excited” conformations
that were approximately one-quarter of the full hinge-bending range.
With the indole inhibitor, lysozyme reached this excited conformation
in a single step without any evidence of rate-liming intermediates,
but the same conformational motions with chitin involved three hidden,
intermediate processes and features similar to the nonconcerted peptidoglycan
mechanism. The similarities suggest that these hidden processes involve
attempts to accommodate imperfectly aligned polysaccharides in the
active site. The results provide a detailed glimpse of the enzyme–ligand
interplay at the crux of molecular recognition, enzyme specificity,
and catalysis.