Qiyun Zhu

Genetic and biological characterization of two novel reassortant H5N6 swine influenza viruses in mice and chickens

Novel H5N6 influenza A viruses have infected birds and human beings and caused four human clinical cases in China since 2014. The pig, as a mixing vessel, plays an important role for influenza virus reassortment and transmission. Towards this, routine surveillance for swine influenza in Guangdong province was conducted in 2014. In this study, we reported the biological characterization of two H5N6 influenza viruses isolated from healthy pigs in Guangdong province. Genetic analysis indicates that the two viruses are reassortants of 2.3.4.4 H5N1 and H6N6 avian influenza viruses with a high similarity to duck and human H5N6 influenza viruses isolated from Guangdong province. The data from chicken and mouse experiments show that the viruses are highly pathogenic in chickens and result in a systemic infection, and replicate in the mouse lung accompanying with a clinical inflammatory pathology. The results of the study demonstrate that the two H5N6 influenza viruses isolated from swine are the avian-originated viruses and have not adapted to swine population yet. However, they might keep evolving and pose a potential risk to public health and the continued surveillance of swine influenza should be strengthened.

Co-circulation of H5N6, H3N2, H3N8, and Emergence of Novel Reassortant H3N6 in a Local Community in Hunan Province in China

Multiple infections of avian influenza viruses (AIVs) in poultry or wild birds contribute to the continued evolution of H5 subtype viruses in nature and provide potential recombination of AIVs of different origins. In this study, we carried out surveillance of AIVs in ducks, geese and the environment of a community in Hunan province, China, from 2014–2015. We isolated multiple co-circulated AIVs including H3N2, H3N8, and H5N6, and, most importantly, a novel reassortant: H3N6. Phylogenetic analyses suggest that H3N6 is highly likely derived from H5N6, which has recently been shown to have zoonotic potential with human infections. Studies with mammalian cell lines and a mouse model indicate that four selected AIVs of duck or goose origin can infect MDCK and A549 cells but have low pathogenicity in mice. We propose that a potential co-circulation of multiple subtypes including H5N6 in local area may result in the production of novel subtypes such as H3N6 by gene reassortment.

Two single amino acid substitutions in the intervening region of Newcastle disease virus HN protein attenuate viral replication and pathogenicity

Among the proteins encoded by Newcastle disease virus (NDV), the attachment protein (HN) is an important determinant of virulence and pathogenicity. HN has been molecularly characterized at the protein level; however, the relationship between the molecular character of HN and the animal pathotype it causes has not been well explored. Here, we revisited the intervening region (IR) of the HN stalk and extended the known biological functions of HN. Three distinct substitutions (A89Q, P93A, and L94A) in the IR of genotype VII NDV (G7 strain) HN protein were analyzed. The A89Q and L94A mutations weakened the fusion promotion activity of HN to 44% and 41% of that of wild type, respectively, whereas P93A decreased the neuraminidase activity to 21% of the parental level. At the virus level, P93A and L94A-bearing viruses displayed impaired receptor recognition ability, neuraminidase activity, and fusion-promoting activity, all of which led to virus attenuation. In addition, the L94A-mutated virus showed a dramatic decline in replication and was attenuated in cells and in chickens. Our data demonstrate that the HN biological activities and functions modulated by these specific amino acids in the IR are associated with NDV replication and pathogenicity.

Analysis of the phylogeny of Chinese H9N2 avian influenza viruses and their pathogenicity in mice

We isolated nineteen strains of H9N2 influenza virus from farms across five northern Chinese provinces between 2001 and 2012. Sequence analysis of the genes for the two surface glycoproteins revealed that residue 226 of the hemagglutinin (HA) of eight isolates was a leucine. A T300I mutation in three strains resulted in the loss of a potential glycosylation site. The P315S mutation in seven strains added a potential glycosylation site in HA. The isolates CK/HN/323/08 and CK/HN/321/08 had a full-length neuraminidase (NA) that differed from those seen in other isolates. Phylogenetic and molecular analysis revealed that the nineteen strains shared common ancestry with strains BJ/94 and G1. We examined eight gene sequences in the present study and concluded that the HA and NS genes appeared to be derived directly from BJ/94. The remaining six genes evolved from different reference strains. Specifically, the NA and PA genes of CK/HN/321/08 and CK/HN/323/08 clustered with the G9 and Y439 branch, respectively, and the PB2 genes of CK/SD/513/11 and CK/GS/419/12 were in an unknown lineage. We found evidence that seven new genotypes had undergone intra-subtype reassortment. A mouse infection experiment with six selected isolates showed that five of these isolates were able to replicate in mouse lungs without adaptation. Viral replication in infected mice resulted in minimal weight loss, suggesting that these H9N2 avian influenza viruses had low virulence in mammals. Our findings highlight the genetic and biological diversity of H9N2 avian influenza viruses circulating in China and emphasize the importance in continuing surveillance of these viruses so as to better understand the potential risks they pose to humans.

Development of a solid-phase competition ELISA to detect antibodies against newly emerged Duck Tembusu virus

Duck Tembusu virus (DTMUV) was first isolated in Northern China in 2010, and is an emerging viral pathogen that is now rapidly spreading to most Chinese provinces causing a severe disease and economic losses for the duck breeding industry. The virus can affect ducks, chickens and geese, but currently there are no commercial ELISA methods for detecting antibodies against DTMUV from different species, or for assessing antibody titers in infected birds. In the present study, a solid-phase competition ELISA for this purpose was developed. The sensitivity and specificity of this test were 97.6% and 100%, respectively, when the percent inhibition (PI) was set at 15% using a serum dilution of 1:16. No cross-reaction with the sera against other avian viral pathogens was found in the study and the ELISA results generated for duck and chicken sera from the field were totally consistent with those of the classical virus neutralization assay. Therefore, this solid-phase competition ELISA represents a sensitive, specific and quantitative tool for the serological detection of Tembusu virus in different birds to facilitate the prevention and control of this disease.

Genetic properties and pathogenicity of a novel reassortant H10N5 influenza virus from wild birds

In this study, we analyzed the genome of a H10N5 influenza virus from wild birds. This virus was identified as a novel reassortant virus with internal genes from multiple subtypes and of distinct origins. After sequential passage in mice, mouse-adapted viruses bearing mutations PB2-E627K and HA-G218E were generated. These viruses caused dramatic body weight loss and death, and also replicated in mouse brain, suggesting that the pathogenicity of low pathogenic H10N5 in chickens can be enhanced after passage in mammals. Our data imply that H10N5 viruses might be a potential risk to human health therefore it is important to undertake continued surveillance and biosecurity evaluation of these viruses.

Molecular characterization and expression analysis of the duck viperin gene.

Viperin is well known as one of the interferon-stimulated genes involved in innate immunity. Recent studies showed that this gene is mainly responsible for antiviral response to a large variety of viral infections. In this study, we successfully cloned and characterized the complete coding sequence of duck viperin gene. The duck viperin gene encodes 363 amino acids (aa) and is highly similar to viperins from other species. Moreover, secondary and 3D structures were predicted, and these structures showed two main domains, one signal peptide, and one radical S-adenosyl methionine (SAM) domain. Additionally, the duck viperin expression was analyzed in vitro and in vivo, and analysis results indicated that the duck viperin can be strongly up-regulated by poly(I:C) and Newcastle disease virus in primary duck embryo fibroblast cells. Results also demonstrated that Newcastle disease virus significantly induced duck viperin expression in the spleen, kidneys, liver, brain, and blood. Our findings will contribute to future studies on the detailed functions and potential underlying mechanisms of this novel protein in innate immunity.

Two single mutations in the fusion protein of Newcastle disease virus confer hemagglutinin-neuraminidase independent fusion promotion and attenuate the pathogenicity in chickens

The fusion (F) protein of Newcastle disease virus (NDV) affects viral infection and pathogenicity through mediating membrane fusion. Previously, we found NDV with increased fusogenic activity in which contained T458D or G459D mutation in the F protein. Here, we investigated the effects of these two mutations on viral infection, fusogenicity and pathogenicity. Syncytium formation assays indicated that T458D or G459D increased the F protein cleavage activity and enhanced cell fusion with or without the presence of HN protein. The T458D- or G459D-mutated NDV resulted in a decrease in virus replication or release from cells. The animal study showed that the pathogenicity of the mutated NDVs was attenuated in chickens. These results indicate that these two single mutations in F altered or diminished the requirement of HN for promoting membrane fusion. The increased fusogenic activity may disrupt the cellular machinery and consequently decrease the virus replication and pathogenicity in chickens.

Recombinant Newcastle disease virus expressing African swine fever virus protein 72 is safe and immunogenic in mice

African swine fever (ASF) is a lethal hemorrhagic disease that affects wild and domestic swine. The etiological agent of ASF is African swine fever virus (ASFV). Since the first case was described in Kenya in 1921, the disease has spread to many other countries. No commercial vaccines are available to prevent ASF. In this study, we generated a recombinant Newcastle disease virus (rNDV) expressing ASFV protein 72 (p72) by reverse genetics and evaluated its humoral and cellular immunogenicity in a mouse model. The recombinant virus, rNDV/p72, replicated well in embryonated chicken eggs and was safe to use in chicks and mice. The p72 gene in rNDV/p72 was stably maintained through ten passages. Mice immunized with rNDV/p72 developed high titers of ASFV p72 specific IgG antibody, and had higher levels of IgG1 than IgG2a. Immunization also elicited T-cell proliferation and secretion of IFN-γ and IL-4. Taken together, these results indicate that rNDV expressing ASFV p72 might be a potential vaccine candidate for preventing ASF.

A 113-amino-acid truncation at the NS1 C-terminus is a determinant for viral replication of H5N6 avian influenza virus in vitro and in vivo

Virulence of highly pathogenic avian influenza viruses (AIV) is determined by multiple genes and their encoded proteins. In particular, the nonstructural protein 1 (NS1) of viruses is a multifunctional protein that plays an important role in type I interferon (IFN) antagonism, pathogenicity, and determining viral host range. Naturally-occurring truncation or mutation of NS1 during virus evolution attenuates viral replication and pathogenicity, but the mechanisms underlying this phenomenon remain poorly understood. In the present study, we rescued an H5N6 AIV harboring a 113-amino-acid (aa) truncated NS1 at the C-terminus that had previously naturally occurred in an H3N8 equine influenza virus (designated as rHN109 NS1/112). The replication and pathogenicity of the rescued and parental viruses were then assessed in vitro in cells and in vivo in chickens and mice. Replication of rHN109 NS1/112 virus was significantly attenuated in various cells compared to its parental virus. The attenuation of rHN109 NS1/112 virus was subsequently clarified by investigating the effects on IFN and apoptosis signaling pathways via multiple experiments. The results indicated that the 113-aa truncation of NS1 impairs viral inhibition of IFN production and enhances cellular apoptosis in avian and mammalian cells. Animal studies further indicated that replication of the rHN109 NS1/112 virus is remarkably attenuated in chickens. The results of this study improve our understanding of C-terminal region function for NS1 proteins of influenza viruses.