Sequence of the SARS-CoV-2 spike transmembrane domain makes it inherently dynamic

The homotrimeric SARS-CoV-2 spike protein enables viral infection by mediating the fusion of the viral envelope with the host membrane. The spike protein is anchored to the SARS-CoV-2 envelope by its transmembrane domain (TMD), which is composed of three TM helices, each contributed by one of the protomers of the homotrimeric spike. Although the TMD is important for SARS-CoV-2 viral fusion and is well-conserved across the Coronaviridae family, it is unclear whether it is a passive anchor of the spike or actively promotes viral fusion. Specifically, the nature of the TMD dynamics and how these dynamics couple to the large pre- to post-fusion conformational transition of the spike ectomembrane domains remains unknown. Here, we computationally study the SARS-CoV-2 spike TMD in both homogenous POPC and cholesterol containing membranes to characterize its structure, dynamics, and self-assembly. Different tools identify distinct segments of the spike sequence as its TM helix. Atomistic simulations of a spike protomer segment that includes the superset of the TM helix predictions show that the membrane-embedded TM sequence bobs, tilts and gains and loses helicity at the membrane edges. Coarse-grained multimerization simulations using representative TM helix structures from the atomistic simulations exhibit diverse trimer populations whose architecture depends on the structure of the TM helix protomer. Multiple overlapping and conflicting dimerization interfaces stabilized these trimeric populations. An asymmetric conformation is populated in addition to a symmetric conformation and several in-between trimeric conformations. While the symmetric conformation reflects the symmetry of the resting spike, the asymmetric TMD conformation could promote viral membrane fusion through the stabilization of a fusion intermediate. Together, our simulations demonstrate that the SARS-CoV-2 spike TM anchor sequence is inherently dynamic, trimerization does not abrogate these dynamics and the various observed TMD conformations may enable viral fusion.