Structural Insights into Immature Dengue Virus-Like Particles Revealed by Cryo-EM and Molecular Dynamics Simulations

The lack of efficacious vaccines against dengue (DENV) infections imposes an enormous burden on global health and the economy. Virus-like particles (VLPs), such as mature DENV VLPs (mDVLPs), have been shown to induce broadly neutralizing antibodies, making them promising next-generation vaccine candidates. However, the limited structural details have restricted efforts to engineer VLPs to attain the desired biophysical and immunological properties. In the current work, we present the cryo-electron microscopy (cryo-EM) structure of immature dengue serotype 2 VLP (imD2VLPs), revealing an architecture composed of a glycoprotein layer with prominent spikes in a T=1 arrangement. These spikes, composed of envelope (E) and precursor membrane (prM) protein heterodimers capped by pr domains, closely resemble immature flavivirus particles. Complementing the static structural details, we performed multiscale molecular dynamics (MD) simulations to elucidate the functional dynamics of imD2VLPs in the context of different lipid envelope compositions. Additionally, MD simulations uncovered the transition pathway between our previously solved mature VLP structure and immature VLP from this work. Here we show that VLP maturation involves a simple sliding-rotating motion without any clashes between E proteins. Our results also indicated that lipid composition plays a critical role in VLP stability, with phospholipid-dominant environments providing greater stability than diacylglycerol-rich vesicles. In addition, we demonstrated enhanced production efficiency of VLPs by generating a stable mammalian cell line using CHO-K1 cells. These findings enabled us not only to predict and manipulate the immunogenic properties of dengue VLPs but also underscored the potential of VLPs as a simplified and manageable model for investigating the structural basis of the dengue virus more effectively.