An Outbreak of Japanese Encephalitis Virus in Australia; What Is the Risk to Blood Safety?

Cellular NONO protein binds to the flavivirus replication complex and promotes positive-strand RNA synthesis

A cellular protein, non-POU-domain-containing octamer binding protein (NONO), bound to the replication complex of Japanese encephalitis virus (JEV) by directly interacting with the viral 3' UTR RNA and NS3 protein. These interactions were also identified in West Nile virus (WNV) and Zika virus (ZIKV). The infection of JEV or the expression of JEV NS3 protein in cells could induce relocation of NONO protein from the nucleus to the cytoplasm. In JEV-infected cells, the NS3, NS5, and viral RNA could be concurrently detected in the immunoprecipitation by the NONO-specific antibody, suggesting that NONO could integrate into the replication complex of JEV. Further results of co-immunoprecipitation assays showed that NONO protein interacted with NS3 helicase domains 1 and 2 by its two RNA recognize motifs (RRMs). The knockdown and knockout of NONO in cells could significantly reduce the replication of JEV and ZIKV but had no effect on the replication of vesicular stomatitis virus (VSV). The effect of NONO protein on JEV proliferation occurred during the replication stage, rather than the attachment and entry stages. The level of viral positive-strand RNA in NONO knockout cells was significantly reduced than that in wild-type cells at 12-48 h post-JEV infection. However, the level of negative-strand virus RNA had no difference between NONO knockout and wild-type cells at 12-24 h post-infection. In summary, our study identified a cellular protein that bound to the replication complex of flavivirus and facilitated the synthesis of positive-strand RNA.IMPORTANCEOver half of the world's population is at risk of flaviviruses infection, posing a serious global health concern. To date, there are no antiviral drugs or treatments for the severe symptoms caused by the infection of flaviviruses. Some cellular proteins could participate in the replication of virus, and these cellular proteins were also ideal targets in antiviral strategy. Here, we identified cellular NONO protein was recruited by flavivirus NS3 protein to the cytoplasm, serving as a "scaffold" for viral replication complex. Our findings also revealed that NONO protein was critical for flavivirus positive-strand RNA synthesis. Specific areas where NONO interacted with flavivirus NS3 proteins and viral UTRs have also been identified. These results propose a new mechanism for cellular protein to participate in flavivirus replication and also raise a new potential anti-flavivirus strategy.

Arbovirus Transmission in Australia from 2002 to 2017

Arboviruses pose a significant global public health threat, with Ross River virus (RRV), Barmah Forest virus (BFV), and dengue virus (DENV) being among the most common and clinically significant in Australia. Some arboviruses, including those prevalent in Australia, have been reported to cause transfusion-transmitted infections. This study examined the spatiotemporal variation of these arboviruses and their potential impact on blood donation numbers across Australia. Using data from the Australian Department of Health on eight arboviruses from 2002 to 2017, we retrospectively assessed the distribution and clustering of incidence rates in space and time using Geographic Information System mapping and space-time scan statistics. Regression models were used to investigate how weather variables, their lag months, space, and time affect case and blood donation counts. The predictors' importance varied with the spatial scale of analysis. Key predictors were average rainfall, minimum temperature, daily temperature variation, and relative humidity. Blood donation number was significantly associated with the incidence rate of all viruses and its interaction with local transmission of DENV, overall. This study, the first to cover eight clinically relevant arboviruses at a fine geographical level in Australia, identifies regions at risk for transmission and provides valuable insights for public health intervention.

Orthoflavivirus Lammi in Russia: Possible Transovarial Transmission and Trans-Stadial Survival in Aedes cinereus (Diptera, Culicidae)

In the last few years, there has been a dramatic increase in the number of discovered viruses that are transmitted by arthropods. Some of them are pathogenic for humans and mammals, and the pathogenic potential of others is unknown. The genus Orthoflavivirus belongs to the family Flaviviridae and includes arboviruses that cause severe human diseases with damage to the central nervous system and hemorrhagic fevers, as well as viruses with unknown vectors and viruses specific only to insects. The latter group includes Lammi virus, first isolated from a mosquito pool in Finland. It is known that Lammi virus successfully replicates in mosquito cell lines but not in mammalian cell cultures or mice. Lammi virus reduces the reproduction of West Nile virus during superinfection and thus has the potential to reduce the spread of West Nile virus in areas where Lammi virus is already circulating. In this work, we isolated Lammi virus from a pool of adult Aedes cinereus mosquitoes that hatched from larvae/pupae collected in Saint Petersburg, Russia. This fact may indicate transovarial transmission and trans-stadial survival of the virus.

Structural and energetic analysis of NS5 protein inhibition by small molecules in Japanese encephalitis virus using machine learning and steered molecular dynamics approach

One of the viral diseases that affect millions of people around the world, particularly in developing countries, is Japanese encephalitis (JE). In this study, the conserved protein of this virus, that is, non-structural protein 5 (NS5), was used as a target protein for this study, and a compound library of 749 antiviral molecules was screened against NS5. The current study employed machine learning-based virtual screening combined with molecular docking. Here, three hits (24360, 123519051 and 213039) had lower binding energies (< -8 kcal/mol) than the control, S-Adenosyl-L-homocysteine (SAH). All the compounds showed significant H-bond interactions with functional residues, which were also observed by the control. Molecular dynamics simulation, MM/GBSA for binding free energy analysis, principal component analysis and free energy landscape were also performed to study the stability of the complex formation. All three compounds had similar root mean square deviation trends, which were comparable to the control, SAH. Post-MD, the 123519051-receptor complex had the highest number of H-bonds (4 to 5) after the control, out of which three exhibited the highest percentage occupancy (50%, 24% and 79%). Both docking and MD, 123519051 showed an H-bond with the residue Gly111, which was also found for the control-protein complex. 123519051 showed the lowest binding free energy with ΔGbind of -89 kJ/mol. Steered molecular dynamics depicted that 123519051 had the maximum magnitude of dissociation (1436.43 kJ/mol/nm), which was more than the control, validating its stable complex formation. This study concluded that 123519051 is a binder and could inhibit the protein NS5 of JE.

Viruses Special Issue "Transfusion-Transmitted Viral Infections"

Blood transfusion is a life-saving treatment that requires patients to have access to safe and adequate blood products that are available in a timely manner [...].