Prophylactic treatment with the nucleoside analogue 2'-C-methylcytidine completely prevents transmission of norovirus.

OBJECTIVES: Norovirus outbreaks of acute gastroenteritis are highly prevalent, extensive and can disturb the functioning of health institutions, leading to the closure of hospital wards and causing life-threatening infections in long-term care facilities. There is no vaccine available; hence there is a pressing need for antivirals for the treatment (in immunodeficient patients) and prophylaxis of norovirus infections. We explored in a mouse model whether an inhibitor of norovirus replication can prevent/reduce transmission of the virus. METHODS: We reported recently that the viral polymerase inhibitor 2'-C-methylcytidine (2CMC) efficiently protects against murine norovirus (MNV)-induced diarrhoea and mortality in mice. Here, we established an MNV-transmission model, determined the 50% infectious dose and assessed the ability of an antiviral molecule to prevent or reduce transmission of (murine) norovirus when given either to the infected (seeder) mice or to the uninfected (sentinel) mice. RESULTS: A robust norovirus transmission model was established using genogroup V (murine) norovirus in AG129 mice. The 50% infectious dose was determined to be ∼ 270 CCID50 (50% cell culture infectious dose). Treatment of infected mice with 2CMC reduced viral shedding and markedly reduced transmission to uninfected sentinels. Also, prophylactic treatment of sentinels with 2CMC resulted in protection against infection with MNV. CONCLUSIONS: These findings constitute an important first step towards developing an efficient prophylaxis for the control of norovirus outbreaks.

The enterovirus protease inhibitor rupintrivir exerts cross-genotypic anti-norovirus activity and clears cells from the norovirus replicon.

Potent and safe inhibitors of norovirus replication are needed for the treatment and prophylaxis of norovirus infections. We here report that the in vitro anti-norovirus activity of the protease inhibitor rupintrivir is extended to murine noroviruses and that rupintrivir clears human cells from their Norwalk replicon after only two passages of antiviral pressure. In addition, we demonstrate that rupintrivir inhibits the human norovirus (genogroup II [GII]) protease and further explain the inhibitory effect of the molecule by means of molecular modeling on the basis of the crystal structure of the Norwalk virus protease. The combination of rupintrivir with the RNA-dependent RNA polymerase inhibitors 2'-C-methylcytidine and favipiravir (T-705) resulted in a merely additive antiviral effect. The fact that rupintrivir is active against noroviruses belonging to genogroup I (Norwalk virus), genogroup V (murine norovirus), and the recombinant 3C-like protease of a GII norovirus suggests that the drug exerts cross-genotypic anti-norovirus activity and will thus most likely be effective against the clinically relevant human norovirus strains. The design of antiviral molecules targeting the norovirus protease could be a valuable approach for the treatment and/or prophylaxis of norovirus infections.

Inhibition of norovirus replication by the nucleoside analogue 2'-C-methylcytidine.

We here report on the activity of 2'-C-methylcytidine (2CMC) [a nucleoside polymerase inhibitor of the hepatitis C virus (HCV)] on the in vitro replication of (murine) norovirus (MNV). 2CMC inhibits (i) virus-induced CPE formation, (ii) viral RNA synthesis and (iii) infectious progeny formation with EC(50) values of ∼2µM. 2CMC acts at a time-point that coincides with the onset of viral RNA synthesis. Even following 30 passages of selective pressure no MNV-resistant virus was selected, which is in line with the high barrier to resistance of the nucleoside analogue for HCV. When combined with the broad-spectrum RNA virus inhibitor ribavirin, a marked antagonistic activity was observed indicating that these molecules should not be combined for the treatment of norovirus infections. Our results suggest that 2'-C-methyl nucleoside analogues should be further explored for the treatment and prophylaxis of norovirus infections.

Favipiravir (T-705) inhibits in vitro norovirus replication.

Human noroviruses are the primary cause of foodborne gastroenteritis. Potent and safe inhibitors are needed for the treatment/prophylaxis of norovirus infections. We demonstrate that Favipiravir [T-705, a drug in advanced clinical development for the treatment of infections with the influenza virus] inhibits in vitro murine norovirus replication. Time-of-drug addition studies reveal that T-705 exerts its activity at a time-point that coincides with onset of viral RNA synthesis, which is in line with the viral polymerase as the presumed target.

Outbreak of acute gastroenteritis caused by adenovirus type 41 in a kindergarten.

In response to an alert due to epidemic gastroenteritis in children in a kindergarten, an outbreak investigation was carried out in a Portuguese municipality. The objectives were to establish an aetiological diagnosis, assess vaccine efficacy if possible, and to take corrective measures if necessary. The warden at the kindergarten was interviewed, and we visited the premises. The overall attack rate was 11·4% and most cases were mild. Stool samples from three symptomatic children were collected and screened for the presence of noroviruses, rotaviruses and adenoviruses. High vaccination coverage against rotaviruses was recorded in children aged <2 years. We initially thought that noroviruses and rotaviruses were more likely to have been the aetiological cause of the disease, but the outbreak was caused by infection with adenovirus 41. These viruses should not be overlooked in the laboratory protocol in the study of acute gastroenteritis outbreaks.