Triterpenoids Manipulate a Broad Range of Virus-host Fusion Via Wrapping the HR2 Domain Prevalent in Viral Envelopes

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2018 Nov 27

PMID 30474060

Citations 39

Authors

Longlong Si

Kun Meng

Zhenyu Tian

Jiaqi Sun

Huiqiang Li

Ziwei Zhang

Veronica Soloveva

Haiwei Li

Ge Fu

Qing Xia

Sulong Xiao

Lihe Zhang

Demin Zhou

Affiliations

Soon will be listed here.

Abstract

A trimer-of-hairpins motif has been identified in triggering virus-cell fusion within a variety of viral envelopes. Chemically manipulating such a motif represents current repertoire of viral fusion inhibitors. Here, we report that triterpenoids, a class of natural products, antagonize this trimer-of-hairpins via its constitutive heptad repeat-2 (HR2), a prevalent α-helical coil in class I viral fusion proteins. Triterpenoids inhibit the entry of Ebola, Marburg, HIV, and influenza A viruses with distinct structure-activity relationships. Specifically, triterpenoid probes capture the viral envelope via photocrosslinking HR2. Profiling the Ebola HR2-triterpenoid interactions using amino acid substitution, surface plasmon resonance, and nuclear magnetic resonance revealed six residues accessible to triterpenoids, leading to wrapping of the hydrophobic helix and blocking of the HR1-HR2 interaction critical in the trimer-of-hairpins formation. This finding was also observed in the envelopes of HIV and influenza A viruses and might potentially extend to a broader variety of viruses, providing a mechanistic insight into triterpenoid-mediated modulation of viral fusion.

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