Enhanced Protection by Recombinant Newcastle Disease Virus Expressing Infectious Bronchitis Virus Spike Ectodomain and Chicken Granulocyte-Macrophage Colony-Stimulating Factor.

We previously reported that recombinant Newcastle disease virus LaSota (rLS) expressing infectious bronchitis virus (IBV) Arkansas (Ark)-type trimeric spike (S) ectodomain (Se; rLS/ArkSe) provides suboptimal protection against IBV challenge. We have now developed rLS expressing chicken granulocyte-macrophage colony-stimulating factor (GMCSF) and IBV Ark Se in an attempt to enhance vaccine effectiveness. In the current study, we first compared protection conferred by vaccination with rLS/ArkSe and rLS/ArkSe.GMCSF. Vaccinated chickens were challenged with virulent Ark, and protection was determined by clinical signs, viral load, and tracheal histomorphometry. Results showed that coexpression of GMCSF and the Se from rLS significantly reduced tracheal viral load and tracheal lesions compared with chickens vaccinated with rLS/ArkSe. In a second experiment, we evaluated enhancement of cross-protection of a Massachusetts (Mass) attenuated vaccine by priming or boosting with rLS/ArkSe.GMCSF. Vaccinated chickens were challenged with Ark, and protection was evaluated. Results show that priming or boosting with the recombinant virus significantly increased cross-protection conferred by Mass against Ark virulent challenge. Greater reductions of viral loads in both trachea and lachrymal fluids were observed in chickens primed with rLS/ArkSe.GMCSF and boosted with Mass. Consistently, Ark Se antibody levels measured with recombinant Ark Se protein-coated ELISA plates 14 days after boost were significantly higher in these chickens. Unexpectedly, the inverse vaccination scheme, that is, priming with Mass and boosting with the recombinant vaccine, proved somewhat less effective. We concluded that a prime and boost strategy by using rLS/ArkSe.GMCSF and the worldwide ubiquitous Mass attenuated vaccine provides enhanced cross-protection. Thus, rLS/GMCSF coexpressing the Se of regionally relevant IBV serotypes could be used in combination with live Mass to protect against regionally circulating IBV variant strains.

Protección incrementada por el virus recombinante de la enfermedad de Newcastle que expresa el ectodominio de la espícula del virus de la bronquitis infecciosa y el factor estimulante de colonias de granulocitos y macrófagos del pollo. Anteriormente se reportó que la cepa LaSota recombinante del virus de la enfermedad de Newcastle (rLS) que expresa el ectodominio de la espícula trimérica (S) de tipo Arkansas (Ark) del virus de la bronquitis infecciosa (IBV) (Se; rLS/ArkSe) proporciona una protección subóptima contra la exposición al virus de la bronquitis infecciosa. Ahora se ha desarrollado hemos desarrollado una cepa LaSota recombinante (rLS) que expresa el factor estimulante de colonias de granulocitos y macrófagos de pollo (GMCSF) y la espícula del virus de bronquitis Arkansas en un intento para mejorar la efectividad de la vacuna. En el estudio actual, primero se comparó la protección conferida por la vacunación con los virus rLS/ArkSe y rLS/ArkSe.GMCSF. Los pollos vacunados se desafiaron con un virus Arkansas virulento y la protección se determinó mediante los signos clínicos, la carga viral y la histomorfometría de la tráquea. Los resultados mostraron que la coexpresión del factor estimulante de colonias de granulocitos y macrófagos de pollo y la espícula de la cepa recombinante LaSota redujo significativamente la carga viral traqueal y las lesiones traqueales en comparación con los pollos vacunados con el virus rLS/ArkSe. En un segundo experimento, se evaluó el incremento en la protección cruzada por una vacuna atenuada de Massachusetts (Mass) mediante la primovacunación o la vacunación de refuerzo con rLS/ArkSe.GMCSF. Los pollos vacunados fueron desafiados con el virus Arkansas y se evaluó la protección. Los resultados mostraron que la primovacunación o la vacunación de refuerzo con el virus recombinante aumentó significativamente la protección cruzada conferida por el virus Massachusetts contra el desafío virulento con el virus Arkansas. Se observaron mayores reducciones de las cargas virales en los fluidos traqueales y lagrimales en pollos primovacunadoss con rLS/ArkSe.GMCSF y con vacunación de refuerzo con Massachusetts. De manera consistente, los niveles de anticuerpos Ark Se medidos con placas de ELISA recubiertas con proteína Ark Se recombinante a los 14 días después del refuerzo fueron significativamente más altos en estos pollos. De manera inesperada, el esquema de vacunación inverso, es decir, la primovacunación con Massachusetts y el refuerzo con la vacuna recombinante, resultó menos efectivo. Se concluye que una estrategia de primovacunación y refuerzo mediante el uso de rLS/ArkSe.GMCSF y la vacuna atenuada con Massachusetts usada en todo el mundo proporciona una protección cruzada aumentada. Por tanto, el virus rLS/GMCSF que coexpresa la proteína de la espícula de los serotipos regionales relevantes de bronquitis infecciosa podría usarse en combinación con una vacuna viva Massachusetts para proteger contra cepas variantes del virus de la bronquitis infecciosa que circulan regionalmente.

N-glycosylation of infectious bronchitis virus M41 spike determines receptor specificity.

Infection of chicken coronavirus infectious bronchitis virus (IBV) is initiated by binding of the viral heavily N-glycosylated attachment protein spike to the alpha-2,3-linked sialic acid receptor Neu5Ac. Previously, we have shown that N-glycosylation of recombinantly expressed receptor binding domain (RBD) of the spike of IBV-M41 is of critical importance for binding to chicken trachea tissue. Here we investigated the role of N-glycosylation of the RBD on receptor specificity and virus replication in the context of the virus particle. Using our reverse genetics system we were able to generate recombinant IBVs for nine-out-of-ten individual N-glycosylation mutants. In vitro growth kinetics of these viruses were comparable to the virus containing the wild-type M41-S1. Furthermore, Neu5Ac binding by the recombinant viruses containing single N-glycosylation site knock-out mutations matched the Neu5Ac binding observed with the recombinant RBDs. Five N-glycosylation mutants lost the ability to bind Neu5Ac and gained binding to a different, yet unknown, sialylated glycan receptor on host cells. These results demonstrate that N-glycosylation of IBV is a determinant for receptor specificity.

The S2 Subunit of QX-type Infectious Bronchitis Coronavirus Spike Protein Is an Essential Determinant of Neurotropism.

Some coronaviruses (CoVs) have an extra furin cleavage site (RRKR/S, furin-S2' site) upstream of the fusion peptide in the spike protein, which plays roles in virion adsorption and fusion. Mutation of the S2' site of QX genotype (QX-type) infectious bronchitis virus (IBV) spike protein (S) in a recombinant virus background results in higher pathogenicity, pronounced neural symptoms and neurotropism when compared with conditions in wild-type IBV (WT-IBV) infected chickens. In this study, we present evidence suggesting that recombinant IBV with a mutant S2' site (furin-S2' site) leads to higher mortality. Infection with mutant IBV induces severe encephalitis and breaks the blood-brain barrier. The results of a neutralization test and immunoprotection experiment show that an original serum and vaccine can still provide effective protection in vivo and in vitro. This is the first demonstration of IBV-induced neural symptoms in chickens with encephalitis and the furin-S2' site as a determinant of neurotropism.

N-Linked glycosylation of the membrane protein ectodomain regulates infectious bronchitis virus-induced ER stress response, apoptosis and pathogenesis.

Coronavirus membrane (M) protein is the most abundant structural protein playing a critical role in virion assembly. Previous studies show that the N-terminal ectodomain of M protein is modified by glycosylation, but its precise functions are yet to be thoroughly investigated. In this study, we confirm that N-linked glycosylation occurs at two predicted sites in the M protein ectodomain of infectious bronchitis coronavirus (IBV). Dual mutations at the two sites (N3D/N6D) did not affect particle assembly, virus-like particle formation and viral replication in culture cells. However, activation of the ER stress response was significantly reduced in cells infected with rN3D/N6D, correlated with a lower level of apoptosis and reduced production of pro-inflammatory cytokines. Taken together, this study demonstrates that although not essential for replication, glycosylation in the IBV M protein ectodomain plays important roles in activating ER stress, apoptosis and proinflammatory response, and may contribute to the pathogenesis of IBV.

Glycosylation of the viral attachment protein of avian coronavirus is essential for host cell and receptor binding.

Avian coronaviruses, including infectious bronchitis virus (IBV), are important respiratory pathogens of poultry. The heavily glycosylated IBV spike protein is responsible for binding to host tissues. Glycosylation sites in the spike protein are highly conserved across viral genotypes, suggesting an important role for this modification in the virus life cycle. Here, we analyzed the N-glycosylation of the receptor-binding domain (RBD) of IBV strain M41 spike protein and assessed the role of this modification in host receptor binding. Ten single Asn-to-Ala substitutions at the predicted N-glycosylation sites of the M41-RBD were evaluated along with two control Val-to-Ala substitutions. CD analysis revealed that the secondary structure of all variants was retained compared with the unmodified M41-RBD construct. Six of the 10 glycosylation variants lost binding to chicken trachea tissue and an ELISA-presented α2,3-linked sialic acid oligosaccharide ligand. LC/MSE glycomics analysis revealed that glycosylation sites have specific proportions of N-glycan subtypes. Overall, the glycosylation patterns of most variant RBDs were highly similar to those of the unmodified M41-RBD construct. In silico docking experiments with the recently published cryo-EM structure of the M41 IBV spike protein and our glycosylation results revealed a potential ligand receptor site that is ringed by four glycosylation sites that dramatically impact ligand binding. Combined with the results of previous array studies, the glycosylation and mutational analyses presented here suggest a unique glycosylation-dependent binding modality for the M41 spike protein.

Identification of Novel Linear Epitopes Located in the Infectious Bronchitis Virus Spike S2 Region.

We identified novel linear epitopes on the infectious bronchitis virus (IBV) spike S2 region. The conformational structure of the IBV spike protein was predicted from a homologous protein, human coronavirus NL63 spike. Although the obtained structure was incomplete, most of the IBV spike protein structure was predicted; the N-terminus of the S1 region could not be predicted due to its variability. In the model, the region located in the proximity of the fusion peptide appeared to be well conserved, and we evaluated the antigenicity of these domains, which are involved in the membrane fusion machinery. Western blotting revealed that IBV TM86 spike residues 686-723 were antigenic. Epitope mapping analysis using synthesized peptides revealed that IBV TM86 spike 669-685 (SNFSTGAFNISLLLTPP), 686-697 (SNPRGRSFIEDL), and 692-703 (SFIEDLLFTSVE) residues were major linear epitopes; two identified epitopes (686-697 and 692-703) were covered by the fusion peptide, and the other epitope (669-685) was adjacent to the fusion peptide. Although the identified epitopes are identically located as the neutralizing epitope in severe acute respiratory syndrome coronavirus, the recombinant protein that includes those epitopes could not elicit neutralizing antibodies against IBV. This is the first report describing IBV spike S2 epitopes located in the proximity of the fusion peptide, and it is suggested that the spike fusion machinery of IBV may differ from that of severe acute respiratory syndrome coronavirus, or, alternatively, IBV may have another mechanism to penetrate the cell membrane.

Structural basis for dimerization and RNA binding of avian infectious bronchitis virus nsp9.

The potential for infection by coronaviruses (CoVs) has become a serious concern with the recent emergence of Middle East respiratory syndrome and severe acute respiratory syndrome (SARS) in the human population. CoVs encode two large polyproteins, which are then processed into 15-16 nonstructural proteins (nsps) that make significant contributions to viral replication and transcription by assembling the RNA replicase complex. Among them, nsp9 plays an essential role in viral replication by forming a homodimer that binds single-stranded RNA. Thus, disrupting nsp9 dimerization is a potential anti-CoV therapy. However, different nsp9 dimer forms have been reported for alpha- and beta-CoVs, and no structural information is available for gamma-CoVs. Here we determined the crystal structure of nsp9 from the avian infectious bronchitis virus (IBV), a representative gamma-CoV that affects the economy of the poultry industry because it can infect domestic fowl. IBV nsp9 forms a homodimer via interactions across a hydrophobic interface, which consists of two parallel alpha helices near the carboxy terminus of the protein. The IBV nsp9 dimer resembles that of SARS-CoV nsp9, indicating that this type of dimerization is conserved among all CoVs. This makes disruption of the dimeric interface an excellent strategy for developing anti-CoV therapies. To facilitate this effort, we characterized the roles of six conserved residues on this interface using site-directed mutagenesis and a multitude of biochemical and biophysical methods. We found that three residues are critical for nsp9 dimerization and its abitlity to bind RNA.

Insights from molecular structure predictions of the infectious bronchitis virus S1 spike glycoprotein.

Infectious bronchitis virus is an important respiratory pathogen in chickens. The IBV S1 spike is a viral structural protein that is responsible for attachment to host receptors and is a major target for neutralizing antibodies. To date, there is no experimentally determined structure for the IBV S1 spike. In this study, we sought to find a predicted tertiary structure for IBV S1 using I-TASSER, which is an automated homology modeling platform. We found that the predicted structures obtained were robust and consistent with experimental data. For instance, we observed that all four residues (38, 43, 63, and 68) that have been shown to be critical for binding to host tissues, were found at the surface of the predicted structure of Massachusetts (Mass) S1 spike. Together with antigenicity index analysis, we were also able to show that Ma5 vaccine has higher antigenicity indices at residues close to the receptor-binding region than M41 vaccine, thereby providing a possible mechanism on how Ma5 achieves better protection against challenge. Examination of the predicted structure of the Arkansas IBV S1 spike also gave insights on the effect of polymorphisms at position 43 on the surface availability of receptor binding residues. This study showcases advancements in protein structure prediction and contributes useful, inexpensive tools to provide insights into the biology of IBV.

Infectious bronchitis virus poly-epitope-based vaccine protects chickens from acute infection.

Infectious bronchitis virus (IBV) causes major losses in the poultry industry. The safe and effective vaccine to control IBV spread is imperative. In the present study, we developed IBV S1 glycoprotein poly-epitope-based DNA vaccine pV-S1B+S1T consisting of SH1208 and Holte strain BF2-restricted T cell epitopes and Australian T strain dominant B cell neutralization epitopes. Specific pathogen-free chickens were vaccinated with pV-S1B+S1T and control plasmids twice to elicit strong humoral and cellular immune response, as indicated by viral neutralization titers and results of CD8+ T cell proliferation assays. A lethal dose of IBV SH1208 strain used for protection and challenge experiments at two weeks post-booster immunization following challenge protection and virus shedding reverse transcription quantitative PCR assay, indicated that pV-S1B+S1T protected against IBV and significantly reduced viral excretion. These results demonstrated that the IBV poly-epitope-based vaccine effectively prevents infection and represents a potential IBV vaccine.

Evolutionary and bioinformatic analysis of the spike glycoprotein gene of H120 vaccine strain protectotype of infectious bronchitis virus from India.

The infectious bronchitis virus is a causative agent of avian infectious bronchitis (AIB), and is is an important disease that produces severe economic losses to the poultry industry worldwide. Recent AIB outbreaks in India have been associated with poor growth in broilers, drop in egg production, and thin egg shells in layers. The complete spike gene of Indian AIB vaccine strain was amplified and sequenced using a conventional reverse transcription polymerase chain reaction and is submitted to the GenBank (accession no KF188436). Phylogenetic analysis revealed that the vaccine strain currently used belongs to H120 genotype, an attenuated strain of Massachusetts (Mass) serotype. Nucleotide and amino acid sequence comparisons have shown that the reported spike gene from Indian isolates have 71.8%-99% and 71.4%-96.9% genetic similarity with the sequenced H120 strain. The study identifies live attenuated IBV vaccine strain, which is routinely used for vaccination, for the first time. Based on nucleotide and amino acid relatedness studies of the vaccine strain with reported IBV sequences from India, it is shown that the current vaccine strain is efficient in controlling the IBV infection. Continuous monitoring of IBV outbreaks by sequencing for genotyping and in vivo cross protection studies for serotyping is not only important for epidemiological investigation but also for evaluation of efficacy of the current vaccine.

Molecular detection and Smoothing spline clustering of the IBV strains detected in China during 2011-2012.

Infectious bronchitis virus (IBV) is a highly variable virus with a large number of genotypes. During 2011-2012, nineteen wild IBV strains were isolated in China. Sequence analysis showed that these isolates were divided into five sub-clusters: A2-like, CKCHLDL08I-like, SAIBK-like, KM91-like and TW97/4-like. Phylogenetic analysis based on the 1118 sequences available on line suggested that all IBVs were classified into six clusters. The prevalent strains including all the isolates were in cluster VI with a 0.194-0.259 genetic distance to Mass type vaccines. In addition, we introduced the smoothing spline clustering (SSC) method to estimate the highly variable sites for some sub-clusters. The results showed that highly variable sites range from sub-clusters, the N-terminal sequences of 4/91-like, TW97/4-like and Arkansas-like are more variable than other sub-clusters. This is the first time that the SSC method has been used for the evolution study of IBV.

Analysis of synonymous codon usage in spike protein gene of infectious bronchitis virus.

Infectious bronchitis virus (IBV) is responsible for causing respiratory, renal, and urogenital diseases in poultry. IBV infection in poultry leads to high mortality rates in affected flocks and to severe economic losses due to a drop in egg production and a reduced gain in live weight of the broiler birds. IBV-encoded spike protein (S) is the major protective immunogen for the host. Although the functions of the S protein have been well studied, the factors shaping synonymous codon usage bias and nucleotide composition in the S gene have not been reported yet. In the present study, we analyzed the relative synonymous codon usage and effective number of codons (Nc) using the 53 IBV S genes. The major trend in codon usage variation was studied using correspondence analysis. The plot of Nc values against GC3 as well as the correlation between base composition and codon usage bias suggest that mutational pressure rather than natural selection is the main factor that determines the codon usage bias in the S gene. Interestingly, no association of aromaticity, degree of hydrophobicity, and aliphatic index was observed with the codon usage variation in IBV S genes. The study represents a comprehensive analysis of IBV S gene codon usage patterns and provides a basic understanding of the codon usage bias.

Structural view and substrate specificity of papain-like protease from avian infectious bronchitis virus.

Papain-like protease (PLpro) of coronaviruses (CoVs) carries out proteolytic maturation of non-structural proteins that play a role in replication of the virus and performs deubiquitination of host cell factors to scuttle antiviral responses. Avian infectious bronchitis virus (IBV), the causative agent of bronchitis in chicken that results in huge economic losses every year in the poultry industry globally, encodes a PLpro. The substrate specificities of this PLpro are not clearly understood. Here, we show that IBV PLpro can degrade Lys(48)- and Lys(63)-linked polyubiquitin chains to monoubiquitin but not linear polyubiquitin. To explain the substrate specificities, we have solved the crystal structure of PLpro from IBV at 2.15-Å resolution. The overall structure is reminiscent of the structure of severe acute respiratory syndrome CoV PLpro. However, unlike the severe acute respiratory syndrome CoV PLpro that lacks blocking loop (BL) 1 of deubiquitinating enzymes, the IBV PLpro has a short BL1-like loop. Access to a conserved catalytic triad consisting of Cys(101), His(264), and Asp(275) is regulated by the flexible BL2. A model of ubiquitin-bound IBV CoV PLpro brings out key differences in substrate binding sites of PLpros. In particular, P3 and P4 subsites as well as residues interacting with the ß-barrel of ubiquitin are different, suggesting different catalytic efficiencies and substrate specificities. We show that IBV PLpro cleaves peptide substrates KKAG-7-amino-4-methylcoumarin and LRGG-7-amino-4-methylcoumarin with different catalytic efficiencies. These results demonstrate that substrate specificities of IBV PLpro are different from other PLpros and that IBV PLpro might target different ubiquitinated host factors to aid the propagation of the virus.

Mapping of the receptor-binding domain and amino acids critical for attachment in the spike protein of avian coronavirus infectious bronchitis virus.

The infection of the avian coronavirus infectious bronchitis virus (IBV) is initiated by the binding of the spike glycoprotein S to sialic acids on the chicken host cell. In this study we identified the receptor-binding domain (RBD) of the spike of the prototype IBV strain M41. By analyzing the ability of recombinantly expressed chimeric and truncated spike proteins to bind to chicken tissues, we demonstrate that the N-terminal 253 amino acids of the spike are both required and sufficient for binding to chicken respiratory tract in an α-2,3-sialic acid-dependent manner. Critical amino acids for attachment of M41 spike are present within the N-terminal residues 19-69, which overlap with a hypervariable region in the S1 gene. Our results may help to understand the differences between IBV S1 genotypes and the ultimate pathogenesis of IBV in chickens.

[Rescue of the recombinant infectious bronchitis virus with the ectodomain region of H120 spike glycoprotein].

To explore the expression potential of heterogeneous genes using the backbone of infectious bronchitis virus (IBV) Beaudette strain, the ectodomain region of the Spike gene (1,302 bp) of IBV H120 strain was amplified by RT-PCR and replaced into the corresponding location of the IBV Beaudette strain full-length cDNA. This recombinant was designated as BeauR-H120(S1). BeauR-H120(S1) was directly used as the DNA template for the transcription of viral genomic RNA in vitro. Then, the transcription product was transfected into Vero cells by electroporation. At 48 h post-transfection, the transfected Vero cells were harvested, and passaging continued. A syncytium was not observed until the recombinant virus had passed through four passages. The presence of rBeau-H120(S1) was verified by the detection of the replaced ectodomain region of the H120 Spike gene using RT-PCR. Western blot analysis of rBeau-H120 (S1)-infected Vero cell lysates demonstrated that the nucleocapsid (N) protein was expressed, which implied that rBeau-H120(S1) could propagate in Vero cells. The TCIDs0 and EIDs0 data demonstrated that the titer levels of rBeau-H120(S1) reached 10(590+/-0.22)TCID50/mL and 10(6.13+/-0.23)EID50/mL in Vero cells and 9-day-old SPF chicken embryos, respectively. Protection studies showed that the percentage of antibody-positive chickens, which were vaccinated with rBeau-H120(S1) at 7 days after hatching, rose to 90% at 21 days post-inoculation. Inoculation provided an 85% rate of immune protection against a challenge of the virulent IBV M41 strain (103EID50/chicken). This recombinant virus constructed using reverse genetic techniques could be further developed as a novel genetic engineering vaccine against infectious bronchitis.

Contributions of the S2 spike ectodomain to attachment and host range of infectious bronchitis virus.

The spike protein is the major viral attachment protein of the avian coronavirus infectious bronchitis virus (IBV) and ultimately determines viral tropism. The S1 subunit of the spike is assumed to be required for virus attachment. However, we have previously shown that this domain of the embryo- and cell culture adapted Beaudette strain, in contrast to that of the virulent M41 strain, is not sufficient for binding to chicken trachea (Wickramasinghe et al., 2011). In the present study, we demonstrated that the lack of binding of Beaudette S1 was not due to absence of virus receptors on this tissue nor due to the production of S1 from mammalian cells, as S1 proteins expressed from chicken cells also lacked the ability to bind IBV-susceptible embryonic tissue. Subsequently, we addressed the contribution of the S2 subunit of the spike in IBV attachment. Recombinant IBV Beaudette spike ectodomains, comprising the entire S1 domain and the S2 ectodomain, were expressed and analyzed for binding to susceptible embryonic chorio-allantoic membrane (CAM) in our previously developed spike histochemistry assay. We observed that extension of the S1 domain with the S2 subunit of the Beaudette spike was sufficient to gain binding to CAM. A previously suggested heparin sulfate binding site in Beaudette S2 was not required for the observed binding to CAM, while sialic acids on the host tissues were essential for the attachment. To further elucidate the role of S2 the spike ectodomains of virulent IBV M41 and chimeras of M41 and Beaudette were analyzed for their binding to CAM, chicken trachea and mammalian cell lines. While the M41 spike ectodomain showed increased attachment to both CAM and chicken trachea, no binding to mammalian cells was observed. In contrast, Beaudette spike ectodomain had relatively weak ability to bind to chicken trachea, but displayed marked extended host range to mammalian cells. Binding patterns of chimeric spike ectodomains to these tissues and cells indicate that S2 subunits most likely do not contain an additional independent receptor-binding site. Rather, the interplay between S1 and S2 subunits of spikes from the same viral origin might finally determine the avidity and specificity of virus attachment and thus viral host range.

Purification, crystallization and preliminary X-ray analysis of nonstructural protein 2 (nsp2) from avian infectious bronchitis virus.

Avian infectious bronchitis virus (IBV) is a member of the group III coronaviruses, which differ from the other groups of coronaviruses in that they do not encode the essential pathogenic factor nonstructural protein 1 (nsp1) and instead start with nsp2. IBV nsp2 is one of the first replicase proteins to be translated and processed in the viral life cycle; however, it has an entirely unknown function. In order to better understand the structural details and functional mechanism of IBV nsp2, the recombinant protein was cloned, overexpressed in Escherichia coli, purified and crystallized. The crystals diffracted to 2.8 Å resolution and belonged to space group P2(1), with unit-cell parameters a = 57.0, b = 192.3, c = 105.7 Å, ß = 90.8°. Two molecules were found in the asymmetric unit; the Matthews coefficient was 3.9 Å(3) Da(-1), corresponding to a solvent content of 68.2%.

A single polar residue and distinct membrane topologies impact the function of the infectious bronchitis coronavirus E protein.

The coronavirus E protein is a small membrane protein with a single predicted hydrophobic domain (HD), and has a poorly defined role in infection. The E protein is thought to promote virion assembly, which occurs in the Golgi region of infected cells. It has also been implicated in the release of infectious particles after budding. The E protein has ion channel activity in vitro, although a role for channel activity in infection has not been established. Furthermore, the membrane topology of the E protein is of considerable debate, and the protein may adopt more than one topology during infection. We previously showed that the HD of the infectious bronchitis virus (IBV) E protein is required for the efficient release of infectious virus, an activity that correlated with disruption of the secretory pathway. Here we report that a single residue within the hydrophobic domain, Thr16, is required for secretory pathway disruption. Substitutions of other residues for Thr16 were not tolerated. Mutations of Thr16 did not impact virus assembly as judged by virus-like particle production, suggesting that alteration of secretory pathway and assembly are independent activities. We also examined how the membrane topology of IBV E affected its function by generating mutant versions that adopted either a transmembrane or membrane hairpin topology. We found that a transmembrane topology was required for disrupting the secretory pathway, but was less efficient for virus-like particle production. The hairpin version of E was unable to disrupt the secretory pathway or produce particles. The findings reported here identify properties of the E protein that are important for its function, and provide insight into how the E protein may perform multiple roles during infection.

Isolation and molecular characterization of infectious bronchitis virus from recent outbreaks in broiler flocks reveals emergence of novel strain in India.

In this study, two isolates of infectious bronchitis virus (IBV) from field outbreaks in 2008 (India/LKW/56/IVRI/08) and 2010 (India/NMK/72/IVRI/10) from broiler chickens in India were isolated and characterized. Reverse transcription polymerase chain reaction-restriction fragment length polymorphism of the entire S1 gene revealed that these isolates belong to two different genotypes, India/LKW/56/IVRI/08 as Mass strain whereas India/NMK/72/IVRI/10 as of different genotype. Nucleotide sequencing analysis showed that India/LKW/56/IVRI/08 shared 99 % homology with THA280252 (Thailand) and India/NMK/72/IVRI/10 shared greater than 99 % homology with 4/91 pathogenic strain (UK), JP/Wakayama/2/2004 (Japan) and TA03 (China), while the two Indian IBV isolates shared 73 % identity between them. Phylogenetic data allowed classification of two Indian isolates, India/LKW/56/IVRI/08 as having unique lineage within Mass genotype and India/NMK/72/IVRI/10 as of 4/91 genotype. Our study confirmed the presence of 4/91 (793/B) IBV nephropathogenic strain for the first time in India by virus isolation and sequencing.

Genetic diversity of avian infectious bronchitis coronavirus in recent years in China.

Fifty-six isolates of avian infectious bronchitis virus (IBV) were obtained from different field outbreaks in China in 2010, and they were genotyped by comparison with 19 reference strains in the present study. The results showed that LX4-type isolates are still the predominant IBVs circulating in chicken flocks in China, and these isolates could be grouped further into two clusters. Viruses in each cluster had favored amino acid residues at different positions in the S1 subunit of the spike protein. In addition, a recombination event was observed to have occurred between LX4- and tl/CH/LDT3/03I-type strains, which contributed to the emergence of a new strain. The most important finding of the study is the isolation and identification of Taiwan II-type (TW II-type) strains of IBV in mainland China in recent years. The genome of TW II-type IBV strains isolated in mainland China has experienced mutations and deletions, as demonstrated by comparison of the entire genome sequence with those of IBV strains isolated in Taiwan. Pathogenicity testing and sequence analysis of the 3' terminal untranslated region revealed that TW II-type IBV strains isolated in mainland China have a close relationship with the embryo-passaged, attenuated TW2296/95.