Abstract
Rhinoviruses (RVs) are the main cause of recurrent infections with rather mild symptoms characteristic of the common cold. Nevertheless, RVs give rise to enormous numbers of absences from work and school and may become life-threatening in particular settings. Vaccination is jeopardised by the large number of serotypes eliciting only poorly cross-neutralising antibodies. Conversely, antivirals developed over the years failed FDA approval because of a low efficacy and/or side effects. RV species A, B, and C are now included in the fifteen species of the genus Enteroviruses based upon the high similarity of their genome sequences. As a result of their comparably low pathogenicity, RVs have become a handy model for other, more dangerous members of this genus, e.g., poliovirus and enterovirus 71. We provide a short overview of viral proteins that are considered potential drug targets and their corresponding drug candidates. We briefly mention more recently identified cellular enzymes whose inhibition impacts on RVs and comment novel approaches to interfere with infection via aggregation, virus trapping, or preventing viral access to the cell receptor. Finally, we devote a large part of this article to adding the viral RNA genome to the list of potential drug targets by dwelling on its structure, folding, and the still debated way of its exit from the capsid. Finally, we discuss the recent finding that G-quadruplex stabilising compounds impact on RNA egress possibly via obfuscating the unravelling of stable secondary structural elements.
Highlights
The common cold symptoms caused by rhinoviruses (RVs) differ very much from the severe symptoms associated with infections by some select representatives of other
Encapsidation might be initiated by VPg and 50 -proximal RNA sequences binding to pentamers; replicating poliovirus ss(+)RNA could be UV-crosslinked to pentamers, and Pfister and colleagues saw ‘capsid-like structures’ upon a negative stain electron microscopy of poliovirus replication complexes [165]
At least part of it might stem from interactions with the receptor (ICAM-1) at a low pH, as observed for RV-B14; these lead to a rearrangement of the RNA
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. It should be kept in mind that one of RVs’ most distinct physicochemical properties is their inactivation at a slightly acidic pH, which was originally taken as a basis for classification [2] This instability at a low pH even led to considering acid-buffered saline as anti-RV nose drops [3]. This fact is enormously complicating the development of a ‘pan- Enterovirus’, or, at least, a ‘pan-rhinovirus’ inhibitor. These strategies have recently been expanded onto small molecules, forming filaments ‘catching’ the virus particles, similar to the otherwise completely unrelated neutrophil extracellular traps [25]
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