Mutation and ACE2-induced Allosteric Network Rewiring in Delta and Omicron SARS-CoV-2 Spike Proteins

The spike protein of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) mediates viral entry by binding its receptor-binding domain (RBD) to the host receptor ACE2. Spike mutations in different variants have been experimentally shown to influence the rate of conformational transitions and alter viral infectivity. In parallel, both experimental and computational studies have reported the presence of long-range allosteric communication within the spike protein, suggesting that such mutations may also affect allosteric signaling pathways involved in viral function. A detailed understanding of the allosteric residue network is essential for rational antiviral drug design. In this study, we performed extensive atomistic molecular dynamics (MD) simulations of the spike proteins from the Delta and Omicron variants in both ACE2-bound and unbound states. By integrating linear mutual information (LMI) calculations and graph theory-based analysis, we delineated the long-range allosteric communication networks embedded within the spike protein. Betweenness centrality metrics enabled the identification of residues that act as key mediators of information flow. Notably, ACE2 binding markedly enhances allosteric coupling throughout the spike. We identified three key linkers, Link1 (NTD-RBD), Link2 (RBD-SD1), and Link3 (SD2-FP), as primary mediators of allosteric communication. Delta exhibits stronger signaling through Link1 and Link2, whereas Omicron redirects communication via Link3. While Delta maintains localized connectivity within the S1 domain but loses long-range contact with the S2 core, Omicron forms a broader yet weaker S1 network and establishes long-range coupling. We propose that the N856K and T547K mutations reshape the conformational landscape, reconfiguring allosteric communication pathways in Omicron. Furthermore, our analysis reveals distinct domain-level allosteric couplings in Delta and Omicron, pointing to variant-specific differences in fusogenicity and immune evasion. By mapping key allosteric sites and mutation-induced conformational shifts, our study may provide a framework for developing robust antiviral strategies resilient to future emerging SARS-CoV-2 variants.