Abstract
Despite the availability of prophylactic vaccines the burden of human papillomavirus (HPV) associated malignancy remains high and there is a need to develop additional therapeutic strategies to complement vaccination. We have previously shown that the poorly characterised E5 oncoprotein forms a virus-coded ion channel or viroporin that was sensitive to the amantadine derivative rimantadine. We now demonstrate that alkylated imino sugars, which have antiviral activity against a number of viruses, inhibit E5 channel activity in vitro. Using molecular modelling we predict that imino sugars intercalate between E5 protomers to prevent channel oligomerisation. We explored the ability of these viroporin inhibitors to block E5-mediated activation of mitogenic signalling in keratinocytes. Treatment with either rimantadine or imino sugars prevented ERK-MAPK phosphorylation and reduced cyclin B1 expression in cells expressing E5 from a number of high-risk HPV types. Moreover, viroporin inhibitors also reduced ERK-MAPK activation and cyclin B1 expression in differentiating primary human keratinocytes containing high-risk HPV18. These observations provide evidence of a key role for E5 viroporin function during the HPV life cycle. Viroporin inhibitors could be utilised for stratified treatment of HPV associated tumours prior to virus integration, or as true antiviral therapies to eliminate virus prior to malignant transformation.
Highlights
Human papillomaviruses (HPV) are small non-enveloped doublestranded DNA viruses that infect squamous epithelial cells
Low-risk HPV types cause benign anogenital warts, whereas a limited number of highrisk HPV types cause the majority of anogenital cancers as well as a subset of oropharyngeal malignancies; HPV16 and HPV18 are responsible for the largest proportion of carcinomas
We previously demonstrated that HPV16 E5 forms a hexameric viroporin complex, with activity sensitive to the adamantane rimantadine, as well as novel unrelated scaffolds (Wetherill et al, 2012)
Summary
Human papillomaviruses (HPV) are small non-enveloped doublestranded DNA (dsDNA) viruses that infect squamous epithelial cells. They are sexually transmitted causing approximately 5 million new infections per year in the USA (Cates, 1999). Prophylactic vaccines are available, yet these protect against only a sub-set of HPV types with little impact upon pre-existing infections (Schiller and Müller, 2015). HPV vaccination programmes are poorly available in most developing countries where cervical cancer is more frequent (Bruni et al, 2016). Effective antiviral agents represent an alternative approach to treating HPV infections, yet no such drugs are currently available
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