Disruption of the HIV-1 Envelope allosteric network blocks CD4-induced rearrangements
Rory Henderson, Maolin Lu, Ye Zhou, Zekun Mu, Robert Parks, Qifeng Han, Allen L. Hsu, Elizabeth Carter, Scott C. Blanchard, RJ Edwards, Kevin Wiehe, Kevin O. Saunders, Mario J. Borgnia, Alberto Bartesaghi, Walther Mothes, Barton F. Haynes, Priyamvada Acharya, S. Munir Alam
Received Date: 15th October 19
The trimeric HIV-1 Envelope protein (Env) mediates viral-host cell fusion via a network of conformational transitions, with allosteric elements in each protomer orchestrating host receptor-induced exposure of the co-receptor binding site and fusion elements. To understand the molecular details of this allostery, we introduced Env mutations aimed to prevent CD4-induced rearrangements in the HIV-1 BG505 Env trimer. Binding analysis performed on the soluble ectodomain BG505 SOSIP Env trimers, cell-surface expressed BG505 full-length trimers and single-molecule Förster Resonance Energy Transfer (smFRET) performed on the full-length virion-bound Env confirmed that these mutations prevented CD4-induced transitions of the HIV-1 Env. Structural analysis by single-particle cryo-electron microscopy performed on the BG505 SOSIP mutant Env proteins revealed rearrangements in the gp120 topological layer contacts with gp41. Specifically, a conserved tryptophan at position 571 (W571) was displaced from its typical pocket at the interface of gp120 topological layers 1 and 2 by lysine 567, disrupting key gp120-gp41 contacts and rendering the Env insensitive to CD4 binding. Vector based analysis of closed Env SOSIP structures revealed the newly designed trimers exhibited a quaternary structure distinct from that typical of SOSIPs and residing near a cluster of Env trimers bound to vaccine-induced fusion peptide-directed antibodies (vFP Mabs). These results reveal the critical function of W571 as a conformational switch in Env allostery and receptor-mediated viral entry and provide insights on Env conformation that are relevant for vaccine design.
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This is an abstract of a preprint hosted on an independent third party site. It has not been peer reviewed but is currently under consideration at Nature Communications.