The longer transmembrane helices of class I viral fusion proteins may facilitate viral fusion

The viral envelope-resident viral fusion proteins (VFPs) fuse the envelope with the host cell membrane, which allows virus entry into host cells. The homotrimeric class I VFPs (cI-VFPs) are anchored to the envelope by three single-pass transmembrane helices (spTMHs). It is generally accepted that the hydrophobic length of a TMH matches the thickness of the hydrophobic membrane core, and this reduces TMH dynamics by stabilizing both the TMHs and the membrane. However, to enable fusion, a cI-VFP undergoes a large conformational transition which includes the disassembly of the spTMHs from a pre-fusion trimer and their subsequent reassembly with the cI-VFP fusion peptides into a post-fusion complex. Given the potential functional relevance of the cI-VFP spTMH disassembly-reassembly dynamics, we hypothesized that these spTMH lengths may be mismatched with the thickness of biological membranes. Here, we examine the predicted lengths of a curated dataset of cI-VFP spTMHs and find that they are indeed about 10% longer than the hydrophobic thickness of model membranes. The cI-VFP spTMHs are on average also longer than the spTMHs of human fusion and human non-fusion proteins. Since our dataset contains cI-VFPs from diverse enveloped viruses, and viral proteins are fast evolving, we conclude that the longer spTMHs are functionally relevant and thus, preserved. Our observation that the spTMH lengths of retrovirus-derived human fusogenic proteins, syncytins, are similar to those of cI-VFPs, supports this conclusion. The longer spTMHs may facilitate the cI-VFP conformational change and perturb the fusing membrane, reducing the barrier to fusion.