We report protein- and aptamer-based electrochemical biochips for low-cost, one-step, sensitive and accurate multiplex detection of SARS-CoV-2 spike (S) and nucleocapsid (N) proteins, and IgG antibody in unprocessed clinical samples,...
AS1411 aptamer can function as a recognition probe to detect the cell surface nucleolin overexpressed in cancer cells, however, little is known about their binding process. This study proposed a feasible binding mode for the first time and provided atomic-level descriptions for the high affinity and specific binding of AS1411. The binding pose predicted by docking was screened using knowledge-based criteria, and a microsecond molecular dynamics (MD) simulation showed the stable existence of the predicted structure in the solution. Structural analysis shows that the unique capping of the 5′ end of AS1411 provides the specific binding with RBD1, and the interactions of hydrogen bond, salt bridge, and water-mediated network between AS1411 and RBD1,2 stabilize the binding. The calculation of per-residue decomposition emphasizes the dominant contribution of van der Waals energy and critical residues are screened. Our study provides the molecular basis of this specific binding and can guide rational AS1411-based aptamers design. Further insights require tight collaborations between the experiments and in silico studies.
The viral entry process of the novel severe acute respiratory syndrome coronavirus 2
(SARS-CoV-2) requires heparin and heparan sulfates from the cell surface, functioning as
a cofactor for human angiotensin-converting enzyme 2 (ACE2) for recognizing the
receptor-binding domain (RBD) of the spike (S) protein on the surface of the virion. In
the present study, the binding poses of an oligosaccharide with four repeating units of
GlcNS6
S
-IdoA2
S
(octa) predicted by Vina-Carb in the
RBD binding site were employed in molecular dynamics (MD) simulations to provide atomic
details for studying the cofactor mechanism. The molecular model in the MD simulations
reproduced the length- and sequence-dependent behavior observed from the microarray
experiments and revealed an important planar U-turn shape for HP/HS binding to RBD. The
model for octa with this shape in the ACE2–RBD complex enhanced the interactions
in the binding interface. The comparisons with the ACE2–RBD complex suggested
that the presence of octa in the RBD binding site blocked the movements in a loop region
at the distal end of the RBD binding interface and promoted the contacts of this loop
region with the ACE2 N-terminus helix. This study shed light on the atomic and dynamic
details for HP/HS interacting with RBD and provided insights into their cofactor role in
the ACE2–RBD interactions.
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