Single-cell genomics-based analysis of virus–host interactions in marine surface bacterioplankton

Viral infections dynamically alter the composition and metabolic potential of marine microbial communities and the evolutionary trajectories of host populations with resulting feedback on biogeochemical cycles. It is quite possible that all microbial populations in the ocean are impacted by viral infections. Our knowledge of virus–host relationships, however, has been limited to a minute fraction of cultivated host groups. Here, we utilized single-cell sequencing to obtain genomic blueprints of viruses inside or attached to individual bacterial and archaeal cells captured in their native environment, circumventing the need for host and virus cultivation. A combination of comparative genomics, metagenomic fragment recruitment, sequence anomalies and irregularities in sequence coverage depth and genome recovery were utilized to detect viruses and to decipher modes of virus–host interactions. Members of all three tailed phage families were identified in 20 out of 58 phylogenetically and geographically diverse single amplified genomes (SAGs) of marine bacteria and archaea. At least four phage–host interactions had the characteristics of late lytic infections, all of which were found in metabolically active cells. One virus had genetic potential for lysogeny. Our findings include first known viruses of Thaumarchaeota, Marinimicrobia, Verrucomicrobia and Gammaproteobacteria clusters SAR86 and SAR92. Viruses were also found in SAGs of Alphaproteobacteria and Bacteroidetes. A high fragment recruitment of viral metagenomic reads confirmed that most of the SAG-associated viruses are abundant in the ocean. Our study demonstrates that single-cell genomics, in conjunction with sequence-based computational tools, enable in situ, cultivation-independent insights into host–virus interactions in complex microbial communities.     

High-Level Diversity of Tailed Phages,Eukaryote-Associated Viruses,and Virophage-Like Elements in the Metaviromes of Antarctic Soils

The metaviromes of two distinct Antarctic hyperarid desert soil communities have been characterized. Hypolithic communities, cyanobacterium-dominated assemblages situated on the ventral surfaces of quartz pebbles embedded in the desert pavement, showed higher virus diversity than surface soils, which correlated with previous bacterial community studies. Prokaryotic viruses (i.e., phages) represented the largest viral component (particularly Mycobacterium phages) in both habitats, with an identical hierarchical sequence abundance of families of tailed phages (Siphoviridae > Myoviridae > Podoviridae). No archaeal viruses were found. Unexpectedly, cyanophages were poorly represented in both metaviromes and were phylogenetically distant from currently characterized cyanophages. Putative phage genomes were assembled and showed a high level of unaffiliated genes, mostly from hypolithic viruses. Moreover, unusual gene arrangements in which eukaryotic and prokaryotic virus-derived genes were found within identical genome segments were observed. Phycodnaviridae and Mimiviridae viruses were the second-most-abundant taxa and more numerous within open soil. Novel virophage-like sequences (within the Sputnik clade) were identified. These findings highlight high-level virus diversity and novel species discovery potential within Antarctic hyperarid soils and may serve as a starting point for future studies targeting specific viral groups.     

Metagenomic sequencing reveals viral abundance and diversity in mosquitoes from the Shaanxi-Gansu-Ningxia region,China

BackgroundMosquitoes host and transmit numerous arthropod-borne viruses (arboviruses) that cause disease in both humans and animals. Effective surveillance of virome profiles in mosquitoes is vital to the prevention and control of mosquito-borne diseases in northwestern China, where epidemics occur frequently.MethodsMosquitoes were collected in the Shaanxi-Gansu-Ningxia region (Shaanxi Province, Gansu Province, and Ningxia Hui Autonomous Region) of China from June to August 2019. Morphological methods were used for taxonomic identification of mosquito species. High-throughput sequencing and metagenomic analysis were used to characterize mosquito viromes.ResultsA total of 22,959 mosquitoes were collected, including Culex pipiens (45.7%), Culex tritaeniorhynchus (40.6%), Anopheles sinensis (8.4%), Aedes (5.2%), and Armigeres subalbatus (0.1%). In total, 3,014,183 (0.95% of clean reads) viral sequences were identified and assigned to 116 viral species (including pathogens such as Japanese encephalitis virus and Getah virus) in 31 viral families, including Flaviviridae, Togaviridae, Phasmaviridae, Phenuiviridae, and some unclassified viruses. Mosquitoes collected in July (86 species in 26 families) showed greater viral diversity than those from June and August. Culex pipiens (69 species in 25 families) and Culex tritaeniorhynchus (73 species in 24 families) carried more viral species than Anopheles sinensis (50 species in 19 families) or Aedes (38 species in 20 families) mosquitoes.ConclusionViral diversity and abundance were affected by mosquito species and collection time. The present study elucidates the virome compositions of various mosquito species in northwestern China, improving the understanding of virus transmission dynamics for comparison with those of disease outbreaks.     

Within you, without you: HIV-1 Rev and RNA export

There are hundreds of viruses that infect different human organs and cause diseases. Some fatal emerging viral infections have become serious public health issues worldwide. Early diagnosis and subsequent treatment are therefore essential for fighting viral infections. Current diagnostic techniques frequently employ polymerase chain reaction (PCR)-based methods to quickly detect the pathogenic viruses and establish the etiology of the disease or illness. However, the fast PCR method suffers from many drawbacks such as a high false-positive rate and the ability to detect only one or a few gene targets at a time. Microarray technology solves the problems of the PCR limitations and can be effectively applied to all fields of molecular medicine. Recently, a report in Retrovirology described a multi-virus DNA array that contains more than 250 open reading frames from eight human viruses including human immunodeficiency virus type 1. This array can be used to detect multiple viral co-infections in cells and in vivo. Another benefit of this kind of multi-virus array is in studying promoter activity and viral gene expression and correlating such readouts with the progression of disease and reactivation of latent infections. Thus, the virus DNA-chip development reported in Retrovirology is an important advance in diagnostic application which could be a potent clinical tool for characterizing viral co-infections in AIDS as well as other patients.     

Examining Landscape Factors Influencing Relative Distribution of Mosquito Genera and Frequency of Virus Infection

Mosquito-borne infections cause some of the most debilitating human diseases, including yellow fever and malaria, yet we lack an understanding of how disease risk scales with human-driven habitat changes. We present an approach to study variation in mosquito distribution and concomitant viral infections on the landscape level. In a pilot study we analyzed mosquito distribution along a 10-km transect of a West African rainforest area, which included primary forest, secondary forest, plantations, and human settlements. Variation was observed in the abundance of Anopheles, Aedes, Culex, and Uranotaenia mosquitoes between the different habitat types. Screening of trapped mosquitoes from the different habitats led to the isolation of five uncharacterized viruses of the families Bunyaviridae, Coronaviridae, Flaviviridae, and Rhabdoviridae, as well as an unclassified virus. Polymerase chain reaction screening for these five viruses in individual mosquitoes indicated a trend toward infection with specific viruses in specific mosquito genera that differed by habitat. Based on these initial analyses, we believe that further work is indicated to investigate the impact of anthropogenic landscape changes on mosquito distribution and accompanying arbovirus infection.     

Cricket Paralysis Virus, a Potential Control Agent for the Olive Fruit Fly, Dacus oleae Gmel

Representatives of several families of insect viruses were tested for growth and pathogenicity in the olive fruit fly, Dacus oleae Gmel. The viruses included nuclear polyhedrosis viruses, an iridovirus, two picornaviruses, and Trichoplusia ni small RNA virus (a member of the Nudaurelia β family), in addition to two naturally occurring viruses of the olive fruit fly. Two viruses, one of the two picornaviruses (cricket paralysis virus [CrPV] and the iridovirus (type 21 from Heliothis armigera), were found to replicate in adult flies. Flies which were fed on a solution containing CrPV for 1 day demonstrated a high mortality with 50% dying within 5 days and nearly 80% dying within 12 days of being fed. The virus was transmissible from infected to noninfected flies by fecal contamination. The CrPV which replicated in the infected flies was demonstrated to be the same as input virus by infection of Drosophila melanogaster cells and examination of the expressed viral proteins, immunoprecipitation of the virus purified from flies, and electrophoretic analysis of the structural proteins.     

The Discovery,Distribution, and Evolution of Viruses Associated with Drosophila melanogaster

Drosophila melanogaster is a valuable invertebrate model for viral infection and antiviral immunity, and is a focus for studies of insect-virus coevolution. Here we use a metagenomic approach to identify more than 20 previously undetected RNA viruses and a DNA virus associated with wild D. melanogaster. These viruses not only include distant relatives of known insect pathogens but also novel groups of insect-infecting viruses. By sequencing virus-derived small RNAs, we show that the viruses represent active infections of Drosophila. We find that the RNA viruses differ in the number and properties of their small RNAs, and we detect both siRNAs and a novel miRNA from the DNA virus. Analysis of small RNAs also allows us to identify putative viral sequences that lack detectable sequence similarity to known viruses. By surveying >2,000 individually collected wild adult Drosophila we show that more than 30% of D. melanogaster carry a detectable virus, and more than 6% carry multiple viruses. However, despite a high prevalence of the Wolbachia endosymbiont—which is known to be protective against virus infections in Drosophila—we were unable to detect any relationship between the presence of Wolbachia and the presence of any virus. Using publicly available RNA-seq datasets, we show that the community of viruses in Drosophila laboratories is very different from that seen in the wild, but that some of the newly discovered viruses are nevertheless widespread in laboratory lines and are ubiquitous in cell culture. By sequencing viruses from individual wild-collected flies we show that some viruses are shared between D. melanogaster and D. simulans. Our results provide an essential evolutionary and ecological context for host–virus interaction in Drosophila, and the newly reported viral sequences will help develop D. melanogaster further as a model for molecular and evolutionary virus research.     

Replication and transmission of H9N2 influenza viruses in ferrets: evaluation of pandemic potential

H9N2 avian influenza A viruses are endemic in poultry of many Eurasian countries and have caused repeated human infections in Asia since 1998. To evaluate the potential threat of H9N2 viruses to humans, we investigated the replication and transmission efficiency of H9N2 viruses in the ferret model. Five wild-type (WT) H9N2 viruses, isolated from different avian species from 1988 through 2003, were tested in vivo and found to replicate in ferrets. However these viruses achieved mild peak viral titers in nasal washes when compared to those observed with a human H3N2 virus. Two of these H9N2 viruses transmitted to direct contact ferrets, however no aerosol transmission was detected in the virus displaying the most efficient direct contact transmission. A leucine (Leu) residue at amino acid position 226 in the hemagglutinin (HA) receptor-binding site (RBS), responsible for human virus-like receptor specificity, was found to be important for the transmission of the H9N2 viruses in ferrets. In addition, an H9N2 avian-human reassortant virus, which contains the surface glycoprotein genes from an H9N2 virus and the six internal genes of a human H3N2 virus, showed enhanced replication and efficient transmission to direct contacts. Although no aerosol transmission was observed, the virus replicated in multiple respiratory tissues and induced clinical signs similar to those observed with the parental human H3N2 virus. Our results suggest that the establishment and prevalence of H9N2 viruses in poultry pose a significant threat for humans.     

Small RNA Profiling in Dengue Virus 2-Infected Aedes Mosquito Cells Reveals Viral piRNAs and Novel Host miRNAs

In Aedes mosquitoes, infections with arthropod-borne viruses (arboviruses) trigger or modulate the expression of various classes of viral and host-derived small RNAs, including small interfering RNAs (siRNAs), PIWI interacting RNAs (piRNAs), and microRNAs (miRNAs). Viral siRNAs are at the core of the antiviral RNA interference machinery, one of the key pathways that limit virus replication in invertebrates. Besides siRNAs, Aedes mosquitoes and cells derived from these insects produce arbovirus-derived piRNAs, the best studied examples being viruses from the Togaviridae or Bunyaviridae families. Host miRNAs modulate the expression of a large number of genes and their levels may change in response to viral infections. In addition, some viruses, mostly with a DNA genome, express their own miRNAs to regulate host and viral gene expression. Here, we perform a comprehensive analysis of both viral and host-derived small RNAs in Aedes aegypti Aag2 cells infected with dengue virus 2 (DENV), a member of the Flaviviridae family. Aag2 cells are competent in producing all three types of small RNAs and provide a powerful tool to explore the crosstalk between arboviral infection and the distinct RNA silencing pathways. Interestingly, besides the well-characterized DENV-derived siRNAs, a specific population of viral piRNAs was identified in infected Aag2 cells. Knockdown of Piwi5, Ago3 and, to a lesser extent, Piwi6 results in reduction of vpiRNA levels, providing the first genetic evidence that Aedes PIWI proteins produce DENV-derived small RNAs. In contrast, we do not find convincing evidence for the production of virus-derived miRNAs. Neither do we find that host miRNA expression is strongly changed upon DENV2 infection. Finally, our deep-sequencing analyses detect 30 novel Aedes miRNAs, complementing the repertoire of regulatory small RNAs in this important vector species.     

A Preliminary Study of Viral Metagenomics of French Bat Species in Contact with Humans: Identification of New Mammalian Viruses

The prediction of viral zoonosis epidemics has become a major public health issue. A profound understanding of the viral population in key animal species acting as reservoirs represents an important step towards this goal. Bats harbor diverse viruses, some of which are of particular interest because they cause severe human diseases. However, little is known about the diversity of the global population of viruses found in bats (virome). We determined the viral diversity of five different French insectivorous bat species (nine specimens in total) in close contact with humans. Sequence-independent amplification, high-throughput sequencing with Illumina technology and a dedicated bioinformatics analysis pipeline were used on pooled tissues (brain, liver and lungs). Comparisons of the sequences of contigs and unassembled reads provided a global taxonomic distribution of virus-related sequences for each sample, highlighting differences both within and between bat species. Many viral families were present in these viromes, including viruses known to infect bacteria, plants/fungi, insects or vertebrates, the most relevant being those infecting mammals (Retroviridae, Herpesviridae, Bunyaviridae, Poxviridae, Flaviviridae, Reoviridae, Bornaviridae, Picobirnaviridae). In particular, we detected several new mammalian viruses, including rotaviruses, gammaretroviruses, bornaviruses and bunyaviruses with the identification of the first bat nairovirus. These observations demonstrate that bats naturally harbor viruses from many different families, most of which infect mammals. They may therefore constitute a major reservoir of viral diversity that should be analyzed carefully, to determine the role played by bats in the spread of zoonotic viral infections.     

Oseltamivir-Resistant Variants of the 2009 Pandemic H1N1 Influenza A Virus Are Not Attenuated in the Guinea Pig and Ferret Transmission Models

Oseltamivir is routinely used worldwide for the treatment of severe influenza A virus infection, and should drug-resistant pandemic 2009 H1N1 viruses become widespread, this potent defense strategy might fail. Oseltamivir-resistant variants of the pandemic 2009 H1N1 influenza A virus have been detected in a substantial number of patients, but to date, the mutant viruses have not moved into circulation in the general population. It is not known whether the resistance mutations in viral neuraminidase (NA) reduce viral fitness. We addressed this question by studying transmission of oseltamivir-resistant mutants derived from two different isolates of the pandemic H1N1 virus in both the guinea pig and ferret transmission models. In vitro, the virus readily acquired a single histidine-to-tyrosine mutation at position 275 (H275Y) in viral neuraminidase when serially passaged in cell culture with increasing concentrations of oseltamivir. This mutation conferred a high degree of resistance to oseltamivir but not zanamivir. Unexpectedly, in guinea pigs and ferrets, the fitness of viruses with the H275Y point mutation was not detectably impaired, and both wild-type and mutant viruses were transmitted equally well from animals that were initially inoculated with 1:1 virus mixtures to naïve contacts. In contrast, a reassortant virus containing an oseltamivir-resistant seasonal NA in the pandemic H1N1 background showed decreased transmission efficiency and fitness in the guinea pig model. Our data suggest that the currently circulating pandemic 2009 H1N1 virus has a high potential to acquire drug resistance without losing fitness.Oseltamivir resistance was rare until 2008, when resistant seasonal H1N1 viruses were found circulating in the general Scandinavian population (15). Soon after, studies from other countries in Europe also reported the isolation of oseltamivir-resistant viruses, and eventually, oseltamivir resistance was recognized as a global phenomenon (9, 27). Prior to 2008, resistant viruses were primarily isolated from patients with nonresponsive influenza virus infections or from infected patients who received a low-dose prophylaxis regiment prior to symptom onset. At the time, these resistant isolates accounted for 1% of the circulating H1N1 virus. Drug resistance mutations were identified during oseltamivir development, including a histidine-to-tyrosine mutation at position 275 (H275Y) in N1 neuraminidase (NA). This mutation in particular was shown to attenuate virus growth and pathology in ferrets (17). Additionally, oseltamivir-resistant viruses with a nearby mutation in N2 neuraminidase transmitted less efficiently than oseltamivir-sensitive viruses in the guinea pig transmission model (4). Surprisingly, the seasonal 2008 H1N1 viral isolates that spread around the world had the same tyrosine mutation, which was previously associated with iatrogenic infections and attenuation. Furthermore, epidemiological studies concluded that this resistant virus developed independently of drug selection, suggesting that compensatory adaptations allowed an attenuating mutation to become permissible (3, 18). The ability of resistant 2008 isolates to perform on par with nonresistant 2008 isolates in growth curves, in mean plaque size, and in a transmission model was recently confirmed (2). Currently, 99% of seasonal H1N1 viruses are oseltamivir resistant; however, the prevalence of these viruses is very low due to replacement by a novel reassortant H1N1 virus (6, 8). This novel reassortant was originally identified in Mexico by doctors concerned about a jump in the number of influenza cases during the month of March in 2009 (7). Later referred to as swine-origin influenza virus, novel H1N1 virus, or 2009 pandemic H1N1 virus, this virus would continue to efficiently transmit around the world, even during the summer months of the northern hemisphere. Its robust transmission was later confirmed in aerosol transmission models, in which 86% of ferrets and 100% of guinea pigs exposed to infected animals contracted pandemic influenza (22, 28, 31). Oseltamivir was used broadly during the outbreak, treating those with complications and prophylactically treating close contacts of confirmed cases. The use of oseltamivir in this manner provided ample opportunity for oseltamivir-resistant viruses to develop. More than 225 cases of oseltamivir-resistant infections have been confirmed from the beginning of the pandemic, including four incidents of suspected aerosol transmission (21, 32, 33). Fortunately, these clinical isolates never progressed into stable transmission in the general public. This study seeks to evaluate if introducing the H275Y mutation into the pandemic 2009 H1N1 virus attenuates virus replication in vitro or in vivo using the guinea pig model and the ferret model to test aerosol transmission efficiency. Furthermore, this study evaluates if a reassortant between the circulating novel H1N1 virus and seasonal neuraminidase (NA) forms a well-adapted, resistant virus capable of efficient transmission.Currently, oseltamivir is the drug of choice for treating novel H1N1 complications and outpatient prophylaxis. Therefore, it is of great importance to study the in vitro replication and transmission phenotypes of oseltamivir-resistant novel H1N1 viruses to understand why broad oseltamivir resistance has not occurred or whether we should expect it to occur in the future.     

Assessing the Viral Fitness of Oseltamivir-Resistant Influenza Viruses in Ferrets,Using a Competitive-Mixtures Model

To determine the relative fitness of oseltamivir-resistant strains compared to susceptible wild-type viruses, we combined mathematical modeling and statistical techniques with a novel in vivo “competitive-mixtures” experimental model. Ferrets were coinfected with either pure populations (100% susceptible wild-type or 100% oseltamivir-resistant mutant virus) or mixed populations of wild-type and oseltamivir-resistant influenza viruses (80%:20%, 50%:50%, and 20%:80%) at equivalent infectivity titers, and the changes in the relative proportions of those two viruses were monitored over the course of the infection during within-host and over host-to-host transmission events in a ferret contact model. Coinfection of ferrets with mixtures of an oseltamivir-resistant R292K mutant A(H3N2) virus and a R292 oseltamivir-susceptible wild-type virus demonstrated that the R292K mutant virus was rapidly outgrown by the R292 wild-type virus in artificially infected donor ferrets and did not transmit to any of the recipient ferrets. The competitive-mixtures model was also used to investigate the fitness of the seasonal A(H1N1) oseltamivir-resistant H274Y mutant and showed that within infected ferrets the H274Y mutant virus was marginally outgrown by the wild-type strain but demonstrated equivalent transmissibility between ferrets. This novel in vivo experimental method and accompanying mathematical analysis provide greater insight into the relative fitness, both within the host and between hosts, of two different influenza virus strains compared to more traditional methods that infect ferrets with only pure populations of viruses. Our statistical inferences are essential for the development of the next generation of mathematical models of the emergence and spread of oseltamivir-resistant influenza in human populations.The neuraminidase (NA) inhibitors are a class of influenza antiviral drugs that are specifically designed to inhibit the enzymatic function of the NA, thereby preventing normal viral replication. Since 1999, two NA inhibitors (NAIs), oseltamivir (Tamiflu) and zanamivir (Relenza), have been shown to be effective for the treatment and prophylaxis of patients infected with not only seasonal influenza, but also highly pathogenic A(H5N1) and the newly emerged A(H1N1) pandemic virus. Prior to 2007, resistance to this class of drugs was considered relatively uncommon, particularly in comparison with the other class of influenza antivirals, the adamantanes, which readily select for viral resistance in treated patients. During early clinical trials, oseltamivir resistance was detected in only 1 to 2% of adults (14) and 5 to 6% of children (33) under treatment, although later studies detected resistance in up to 18% of oseltamivir-treated children (16). In contrast, resistance following zanamivir treatment is rare, with only one reported case observed in an immunocompromised patient (6). Influenza viruses that develop resistance to these drugs typically contain mutations in the NA which, either directly or indirectly, alter the shape of the NA enzymatic site, thereby reducing the ability of the drugs to bind to this specific pocket. One of the most commonly observed mutations in oseltamivir-resistant A(H3N2) viruses is an arginine-to-lysine mutation at residue 292 (R292K) of the NA, while the predominant NA mutation in oseltamivir-resistant A(H1N1) viruses is a histidine-to-tyrosine mutation at residue 274 (H274Y) (N2 NA amino acid numbering, equivalent to residue 275 based on N1 numbering). Both of these mutations have an indirect impact on drug binding, as they affect the ability of the glutamic acid residue at position 276 to reorientate, as required for slow binding by oseltamivir (3). Many mutations that cause NAI resistance also cause reduced NA enzyme activity and, consequently, can compromise viral fitness.Previous studies have demonstrated that viruses with an R292K NA mutation demonstrated compromised growth in vitro (36) and in ferrets were significantly less infectious and did not transmit (9). The replication and transmission fitness of the H274Y mutation has also been studied previously. An H274Y mutant A(H1N1) strain isolated from a patient under oseltamivir treatment demonstrated compromised growth in cell culture compared to a wild-type (WT) virus (13), although a strain carrying the same mutation selected in vitro was found to replicate as well as the wild type (32). The infectivity and transmissibility of an H274Y mutant were found to be restricted in ferrets (13), although a second study demonstrated that transmission of the mutant virus between ferrets was possible, but required a greater viral dose of the mutant compared to the wild type (10). These results suggest that resistant virus variants with the same NA mutation may differ in replication or transmission fitness depending on other viral components. Nevertheless, based on these data and the viral fitness of other resistant mutants, it was believed that NAI-resistant viruses were unlikely to spread throughout the community due to their compromised viral fitness in the absence of drug selective pressure. This was proven incorrect during the Northern Hemisphere 2007-2008 influenza season, when large numbers of oseltamivir-resistant seasonal A(H1N1) viruses with an H274Y mutation were detected in patients who had not been treated with oseltamivir (4, 24). The mutant strain continued to spread to the Southern Hemisphere, such that by late 2008 virtually all circulating seasonal A(H1N1) viruses were oseltamivir resistant (11). The rapid global spread of this strain clearly suggested that the oseltamivir-resistant seasonal A(H1N1) virus had fitness equivalent to or greater than that of the previous oseltamivir-sensitive A(H1N1) strain. The reasons for enhanced viral fitness in this strain, when previous studies demonstrated that the acquisition of an H274Y mutation led to reduced viral fitness, remain unclear but probably involve compensatory mutations or reassortment events which may have improved the hemagglutinin (HA)/NA balance, allowing efficient transmission (5, 26).Experimental methods have been developed to assess the relative fitness of NAI-resistant strains compared with respective wild-type viruses, both in vitro and in vivo. Ferrets have been considered the most appropriate model animal for influenza research, and fitness studies have assessed variables such as minimum dose required to achieve infection, duration of viral shedding, and levels of viral load to allow comparisons between viruses. The guinea pig model has also been previously used to assess the viral fitness of influenza viruses, particularly in comparing the transmissibility of strains via either the contact or aerosol route (2). As an alternative to these traditional approaches, we have investigated a methodology that involves coinfection of ferrets with a mixture of two influenza viruses. Daily monitoring of changes in the relative proportion of those viruses over the course of the infection allows determination of the relative replication fitness of the viruses. Monitoring of recipient ferrets exposed to the infected ferrets enables the relative transmissibility of the viruses (henceforth, the relative transmission fitness) to be determined. In this study, the “competitive-mixtures” methodology was used to assess the relative replication and transmission fitness of an oseltamivir-resistant R292K mutant A(H3N2) virus compared with an oseltamivir-sensitive A(H3N2) wild-type strain and also to asses the relative replication and transmission fitness of an oseltamivir-resistant H274Y seasonal A(H1N1) mutant compared with an oseltamivir-sensitive A(H1N1) wild-type strain. Quantitative estimates for the replication fitness of mutant viruses were determined using a simple mathematical model of within-host viral replication and mixed-effects statistical tests. Transmission fitness was evaluated by application of a graphical technique that demonstrated the relationship between the proportion of mutant virus in the infectee ferrets as a function of the proportion of mutant virus in the infector ferrets.Inferences drawn from the statistical analyses presented here are essential for the refinement of existing mathematical models that simulate the spread of influenza in the human population and model the deployment of antiviral agents. These models are designed to assess the likely impact of different antiviral agent deployment strategies to control pandemic influenza (18, 21, 35). At present, data on the probability of emergence of NAI-resistant strains, the relative transmission fitness of these strains, and the probability of an individual''s infection reverting to an NAI-sensitive strain in the absence of ongoing selective pressure are severely limited. In consequence, human population-level models of influenza spread must make gross assumptions on the likely characteristics of NAI-resistant strains. Data such as those presented here will be used to inform new models of drug deployment and result in improved pandemic policy advice (20, 23).     

Melanoma Differentiation-Associated Gene 5 (MDA5) Is Involved in the Innate Immune Response to Paramyxoviridae Infection In Vivo

The early host response to pathogens is mediated by several distinct pattern recognition receptors. Cytoplasmic RNA helicases including RIG-I and MDA5 have been shown to respond to viral RNA by inducing interferon (IFN) production. Previous in vitro studies have demonstrated a direct role for MDA5 in the response to members of the Picornaviridae, Flaviviridae and Caliciviridae virus families ((+) ssRNA viruses) but not to Paramyxoviridae or Orthomyxoviridae ((−) ssRNA viruses). Contrary to these findings, we now show that MDA5 responds critically to infections caused by Paramyxoviridae in vivo. Using an established model of natural Sendai virus (SeV) infection, we demonstrate that MDA5^−/− mice exhibit increased morbidity and mortality as well as severe histopathological changes in the lower airways in response to SeV. Moreover, analysis of viral propagation in the lungs of MDA5^−/− mice reveals enhanced replication and a distinct distribution involving the interstitium. Though the levels of antiviral cytokines were comparable early during SeV infection, type I, II, and III IFN mRNA expression profiles were significantly decreased in MDA5^−/− mice by day 5 post infection. Taken together, these findings indicate that MDA5 is indispensable for sustained expression of IFN in response to paramyxovirus infection and provide the first evidence of MDA5-dependent containment of in vivo infections caused by (−) sense RNA viruses.     

Metagenomic analysis of viral community in the Yangtze River expands known eukaryotic and prokaryotic virus diversity in freshwater

Viruses in aquatic ecosystems are characterized by extraordinary abundance and diversity. Thus far, there have been limited studies focused on viral communities in river water systems. Here, we investigated the virome of the Yangtze River Delta using viral metagenomic analysis. The compositions of viral communities from six sampling sites were analyzed and compared. By using library construction and next generation sequencing, contigs and singlet reads similar to viral sequences were classified into 17 viral families, including nine dsDNA viral families, four ssDNA viral families and four RNA viral families. Statistical analysis using Friedman test suggested that there was no significant difference among the six sampling sites (P > 0.05). The viromes in this study were all dominated by the order Caudovirales, and a group of Freshwater phage uvFW species were particularly prevalent among all the samples. The virome from Nanjing presented a unique pattern of viral community composition with a relatively high abundance of family Parvoviridae. Phylogenetic analyses based on virus hallmark genes showed that the Caudovirales order and CRESS-DNA viruses presented high genetic diversity, while viruses in the Microviridae and Parvoviridae families and the Riboviria realm were relatively conservative. Our study provides the first insight into viral community composition in large river ecosystem, revealing the diversity and stability of river water virome, contributing to the proper utilization of freshwater resource.     

New archaeal viruses discovered by metagenomic analysis of viral communities in enrichment cultures

Viruses infecting hyperthermophilic archaea of the phylum Crenarchaeota display enormous morphological and genetic diversity, and are classified into 12 families. Eight of these families include only one or two species, indicating sparse sampling of the crenarchaeal virus diversity. In an attempt to expand the crenarchaeal virome, we explored virus diversity in the acidic, hot spring Umi Jigoku in Beppu, Japan. Environmental samples were used to establish enrichment cultures under conditions favouring virus replication. The host diversity in the enrichment cultures was restricted to members of the order Sulfolobales. Metagenomic sequencing of the viral communities yielded seven complete or near-complete double-stranded DNA virus genomes. Six of these genomes could be attributed to polyhedral and filamentous viruses that were observed by electron microscopy in the enrichment cultures. Two icosahedral viruses represented species in the family Portogloboviridae. Among the filamentous viruses, two were identified as new species in the families Rudiviridae and Lipothrixviridae, whereas two other formed a group seemingly distinct from the known virus genera. No particle morphotype could be unequivocally assigned to the seventh viral genome, which apparently represents a new virus type. Our results suggest that filamentous viruses are globally distributed and are prevalent virus types in extreme geothermal environments.     

The Fecal Virome of Children with Hand,Foot, and Mouth Disease that Tested PCR Negative for Pathogenic Enteroviruses

Hand, foot, and mouth disease (HFMD) affects infant and young children. A viral metagenomic approach was used to identify the eukaryotic viruses in fecal samples from 29 Thai children with clinical diagnosis of HFMD collected during the 2012 outbreak. These children had previously tested negative by PCR for enterovirus 71 and coxsackievirus A16 and A6. Deep sequencing revealed nine virus families: Picornaviridae, Astroviridae, Parvoviridae, Caliciviridae, Paramyxoviridae, Adenoviridae, Reoviridae, Picobirnaviridae, and Polyomaviridae. The highest number of viral sequences belonged to human rhinovirus C, astrovirus-MLB2, and coxsackievirus A21. Our study provides an overview of virus community and highlights a broad diversity of viruses found in feces from children with HFMD.     

Inactivation of plant and animal viruses by proanthocyanidins from Alpinia zerumbet extract

Alpinia zerumbet (Pers.) B.L. Burtt and R.M. Smith belongs to the Alpinia genus in the Zingiberaceae family. In East Asia, Alpinia zerumbet has been widely used as food and traditional medicine. Previously, we identified proanthocyanidins (PACs), an anti-plant-virus molecule in A. zerumbet, using Nicotiana benthamiana and tomato mosaic virus (ToMV). Here, we found that PACs from A. zerumbet, apple, and green tea effectively inhibited ToMV infection. Additionally, the PACs from A. zerumbet exhibited greater antiviral activity than those from apple and green tea. The PACs from A. zerumbet also effectively inactivated influenza A virus and porcine epidemic diarrhea virus (PEDV), which acts as a surrogate for human coronaviruses, in a dose-dependent manner. The results from the cytopathic effect assays indicated that 0.1 mg/ml PACs from A. zerumbet decreased the titer of influenza A virus and PEDV by >3 log. These findings suggested that the direct treatment of viruses with PACs from A. zerumbet before inoculation reduced viral activity; thus, PACs might inhibit infections by an influenza virus, coronaviruses, and plant viruses.     

The HA and NS Genes of Human H5N1 Influenza A Virus Contribute to High Virulence in Ferrets

Highly pathogenic H5N1 influenza A viruses have spread across Asia, Europe, and Africa. More than 500 cases of H5N1 virus infection in humans, with a high lethality rate, have been reported. To understand the molecular basis for the high virulence of H5N1 viruses in mammals, we tested the virulence in ferrets of several H5N1 viruses isolated from humans and found A/Vietnam/UT3062/04 (UT3062) to be the most virulent and A/Vietnam/UT3028/03 (UT3028) to be avirulent in this animal model. We then generated a series of reassortant viruses between the two viruses and assessed their virulence in ferrets. All of the viruses that possessed both the UT3062 hemagglutinin (HA) and nonstructural protein (NS) genes were highly virulent. By contrast, all those possessing the UT3028 HA or NS genes were attenuated in ferrets. These results demonstrate that the HA and NS genes are responsible for the difference in virulence in ferrets between the two viruses. Amino acid differences were identified at position 134 of HA, at positions 200 and 205 of NS1, and at positions 47 and 51 of NS2. We found that the residue at position 134 of HA alters the receptor-binding property of the virus, as measured by viral elution from erythrocytes. Further, both of the residues at positions 200 and 205 of NS1 contributed to enhanced type I interferon (IFN) antagonistic activity. These findings further our understanding of the determinants of pathogenicity of H5N1 viruses in mammals.