Current understanding of the mechanism of HPV infection

Abstract HPVs (human papillomaviruses) and other papillomaviruses have a unique mechanism of infection that has likely evolved to limit infection to the basal cells of stratified epithelium, the only tissue in which they replicate. Recent studies in a mouse cervicovaginal challenge model indicate that, surprisingly, the virus cannot initially bind to keratinocytes in vivo. Rather it must first bind via its L1 major capsid protein to heparan sulfate proteoglycans (HSPGs) on segments of the basement membrane (BM) exposed after epithelial trauma and undergo a conformational change that exposes the N-terminus of L2 minor capsid protein to furin cleavage. L2 proteolysis exposes a previously occluded surface of L1 that binds an as yet undetermined cell surface receptor on keratinocytes that have migrated over the BM to close the wound. Papillomaviruses are the only viruses that are known to initiate their infectious process at an extracellular site. In contrast to the in vivo situation, the virions can bind directly to many cultured cell lines through cell surface HSPGs and then undergo a similar conformational change and L2 cleavage. Transfer to the secondary receptor leads to internalization, uncoating in late endosomes, escape from the endosome by an L2-dependent mechanism, and eventual trafficking of an L2–genome complex to specific subnuclear domains designated ND10 bodies, where viral gene transcription is initiated. The infectious process is remarkably slow and asynchronous both in vivo and in cultured cells, taking 12–24 h for initiation of transcription. The extended exposure of antibody neutralizing determinants while the virions reside on the BM and cell surfaces might, in part, account for the remarkable effectiveness of vaccines based on neutralizing antibodies to L1 virus-like particles or the domain of L2 exposed after furin cleavage.