Cocirculation of Newcastle Disease Virus Genotypes XII and VII Along with Nonvirulent Forms Characterized in Domestic Birds from Peru.

Newcastle disease virus (NDV) is one of the most important pathogens affecting poultry, given its impact on health and production systems worldwide, despite widespread vaccination. Over the past 20 years, NDV has caused severe outbreaks of disease in Peru. These outbreaks primarily affected gamecocks and broiler chickens, with an additional reported case in commercial layers. Therefore, our objective was to identify and characterize the virus responsible for these cases in Peru. We analyzed 14 suspected clinical cases in domestic birds for NDV detection, isolation, and genetic characterization. Among these cases, seven involved gamecocks, with six genotype XII isolates and one genotype VII isolate, representing the first report of NDV genotype VII isolate from fighting roosters in Peru. Additionally, among the six cases in broiler chickens, we detected four genotype XII isolates and three genotype II isolates, including one sample containing both genotypes XII and II. Furthermore, a genotype I viral isolate was identified in a laying hen. Hence, we concluded that two divergent, highly virulent NDV genotypes, genotypes XII and VII, along with avirulent forms such as genotypes I and II are circulating among domestic birds in Peru. Genetic analysis indicates that these viruses are evolving locally within avian species and offers the basis necessary for vaccine adaptation to circulating viruses. Our results highlight the cocirculation of multiple virulent and nonvirulent NDV genotypes in domestic birds in Peru, underscoring the potential role of gamecocks as a viral source of virulent NDV strains in the country and the occurrence of outbreaks in poultry farms.

Cocirculación de los genotipos XII y VII del virus de la enfermedad de Newcastle junto con formas no virulentas caracterizadas en aves domésticas del Perú. El virus de la enfermedad de Newcastle (NDV) es uno de los patógenos más importantes que afectan a la avicultura, dado su impacto en la salud y los sistemas de producción en todo el mundo, a pesar de la vacunación generalizada. Durante los últimos 20 años, el virus de la enfermedad de Newcastle ha causado graves brotes de enfermedades en el Perú. Estos brotes afectaron principalmente a gallos de pelea y pollos de engorde, con un caso adicional reportado en aves de postura comerciales. Por lo tanto, nuestro objetivo fue identificar y caracterizar el virus responsable de estos casos en el Perú. Se analizaron 14 casos cl'inicos sospechosos en aves domésticas para la detección, aislamiento y caracterización genética del virus de Newcastle. Entre estos casos, siete involucraron gallos de pelea, con seis aislamientos del genotipo XII y un aislado del genotipo VII, lo que representa el primer informe de aislamiento del genotipo VII del virus de Newcastle de gallos de pelea en Perú. Además, entre los seis casos en pollos de engorde, se detectaron cuatro aislados del genotipo XII y tres aislados del genotipo II, incluida una muestra que con-ten'ia ambos genotipos XII y II. Además, se identificó un aislado viral de genotipo I en una gallina de postura. Por lo tanto, se concluye que dos genotipos divergentes y altamente virulentos del virus de Newcastle, los genotipos XII y VII, junto con formas avirulentas como los genotipos I y II, están circulando entre las aves domésticas en el Perú. El análisis genético indica que estos virus están evolucionando localmente dentro de las especies aviares y ofrece las bases necesarias para realizar adaptaciones de las vacunas contra los virus circulantes. Nuestros resultados resaltan la cocirculación de múltiples genotipos del virus de Newcastle virulentos y no virulentos en aves domésticas en Perú, subrayando el papel potencial de los gallos de pelea como fuente viral de cepas virulentas del virus de Newcastle en el pa'is y la aparición de brotes en granjas av'icolas.

Entry of Newcastle disease virus into host cells: an interplay among viral and host factors.

Newcastle disease (ND) is a major burden for the poultry industry worldwide, especially in developing countries. The virus that causes this disease, Newcastle disease virus (NDV), is also an effective vector for the development of novel human and animal vaccines and a promising oncolytic virus for cancer therapy. The mechanism of entry of NDV into host cells is of particular interest because it has a significant impact on the infectivity, host range, and pathogenicity of the virus. Here, we present an overview of the entry of NDV into cells, focusing on the interplay among viral and host factors involved in this process. In particular, recent research revealing novel features of NDV attachment to cells, the identification of viral and cellular components that regulate binding of the virus to cells, and the emerging role of novel cellular routes of NDV entry are discussed. More importantly, some of the remaining gaps in our understanding of NDV entry and some fundamental questions for research efforts in the future are also highlighted.

Phylogenetic analysis, genetic diversity, and epidemiology of pigeon paramyxovirus type 1 in China.

Pigeon paramyxovirus type 1 (PPMV-1) poses significant economic challenges to the pigeon industry in China. However, information about the prevalence, genetic diversity, and epidemiology of PPMV-1 in China is still lacking. In this study, we isolated six strains of PPMV-1 from Hubei and Zhejiang provinces in 2022. All six isolates were found to belong to subgenotype VI.2.1.1.2.2. Five of them were identified as mesogenic and one as lentogenic. Multiple mutations were observed in the F and HN proteins of these isolates. Comprehensive analysis of global PPMV-1 strains highlighted the dominance of genotype VI, showing that VI.2.1.1.2.2 has been the dominant subgenotype since 2011. We also identified 36 host-specific amino acid substitutions that are unique to PPMV-1 in comparison to chicken-origin NDVs. The data reported here contribute to our understanding of the epidemiology, genetic diversity, and prevalence of PPMV-1 and serve as a valuable reference for the prevention and control of PPMV-1.

Assessment of PPMV-1 Genotype VI Virulence in Pigeons and Chickens and Protective Effectiveness of Paramyxovirus Vaccines in Pigeons.

Pigeon paramyxovirus serotype 1 (PPMV-1), an antigenic and host variant of avian paramyxovirus Newcastle disease virus (NDV), primarily originating from racing pigeons, has become a global panzootic. Egypt uses both inactivated PPMV-1 and conventional NDV vaccines to protect pigeons from disease and mortality. However, the impact of prevalent strains and the effectiveness of available vaccines in pigeons in Egypt are unclear. This study investigates the virulence of PPMV-1 (Pigeon/Egypt/Sharkia-19/2015/KX580988) and evaluates available paramyxovirus vaccines in protecting pigeons against a PPMV-1 challenge. Ten-day-old specific-pathogen-free (SPF) embryonated chicken eggs infected with this strain exhibited a mean death time (MDT) of 86.4 ± 5.88 h. The intracerebral pathogenicity index (ICPI) in day-old chickens was 0.8, while pigeons experienced an ICPI of 0.96 and an intravenous pathogenicity index (IVPI) of 2.11. These findings classify the strain as virulent and velogenic. Experimental infection of pigeons with this PPMV-1 strain at 106 EID50/0.1 mL resulted in a 62.5% mortality rate, displaying nervous and enteric distress. The virus caused extensive lesions in visceral organs, with strong immunohistochemistry signals in all examined organs, indicating the systemic spread of the virus concurrent to its neurotropic and viscerotropic tropism. Furthermore, vaccination using an inactivated PPMV-1 and live NDV LaSota vaccine regimen protected 100% of pigeons against mortality, while with a single NDV LaSota vaccine, it was 62.5%. The PPMV alone or combined with NDV LaSota induced protective levels of haemagglutination inhibition (HI) antibody titres and reduced virus shedding from buccal and cloacal cavities. Based on generalised linear gamma model analysis, both PPMV-1 and NDV LaSota are antigenically comparable by HI. These findings suggest that using both inactivated PPMV-1 (G-VI) and live attenuated NDV (LaSota) vaccines is an effective prophylactic regimen for preventing and controlling PPMV-1 and NDV in pigeons, thereby reducing the risk of interspecies transmission.

Genomic Diversity and Evolutionary Insights of Avian Paramyxovirus-1 in Avian Populations in Pakistan.

The virulent form of Avian paramyxovirus-1 (APMV-1), commonly known as Newcastle Disease Virus (NDV), is a pathogen with global implications for avian health, affecting both wild and domestic bird populations. In Pakistan, recurrent Newcastle Disease (caused by NDV) outbreaks have posed significant challenges to the poultry industry. Extensive surveillance in Pakistan over 20 years has demonstrated a dynamic genetic diversity among circulating APMV-1 strains, emphasizing the potential necessity for customized vaccination strategies and continuous surveillance. In this study, 13 APMV-1-positive isolates harboring four different APMV-1 genotypes circulating throughout Pakistan were identified. These included the highly virulent genotypes VII and XIII, genotype XXI, commonly associated with Columbiformes, and genotype II, hypothesized to have been detected following vaccination. These findings underscore the intricate interplay of mutational events and host-immune interactions shaping the evolving NDV landscape. This study advances our understanding of the evolutionary dynamics of APMV-1 in Pakistan, highlighting the need for tailored vaccination strategies and continuous surveillance to enable effective APMV-1 management in avian populations, further emphasizing the importance of globally coordinated strategies to tackle APMV-1, given its profound impact on wild and domestic birds.

Integrative study of chicken lung transcriptome to understand the host immune response during Newcastle disease virus challenge.

Introduction: Newcastle disease is one of the significant issues in the poultry industry, having catastrophic effects worldwide. The lung is one of the essential organs which harbours Bronchus-associated lymphoid tissue and plays a vital role in the immune response. Leghorn and Fayoumi breeds are known to have differences in resistance to Newcastle disease. Along with genes and long non-coding RNAs (lncRNAs) are also known to regulate various biological pathways through gene regulation. Methods: This study analysed the lung transcriptome data and identified the role of genes and long non-coding RNAs in differential immune resistance. The computational pipeline, FHSpipe, as used in our previous studies on analysis of harderian gland and trachea transcriptome was used to identify genes and lncRNAs. This was followed by differential expression analysis, functional annotation of genes and lncRNAs, identification of transcription factors, microRNAs and finally validation using qRT-PCR. Results and discussion: A total of 8219 novel lncRNAs were identified. Of them, 1263 lncRNAs and 281 genes were differentially expressed. About 66 genes were annotated with either an immune-related GO term or pathway, and 12 were annotated with both. In challenge and breed-based analysis, most of these genes were upregulated in Fayoumi compared to Leghorn, and in timepoint-based analysis, Leghorn challenge chicken showed downregulation between time points. A similar trend was observed in the expression of lncRNAs. Co-expression analysis has revealed several lncRNAs co-expressing with immune genes with a positive correlation. Several genes annotated with non-immune pathways, including metabolism, signal transduction, transport of small molecules, extracellular matrix organization, developmental biology and cellular processes, were also impacted. With this, we can understand that Fayoumi chicken showed upregulated immune genes and positive cis-lncRNAs during both the non-challenged and NDV-challenge conditions, even without viral transcripts in the tissue. This finding shows that these immune-annotated genes and coexpressing cis-lncRNAs play a significant role in Fayoumi being comparatively resistant to NDV compared to Leghorn. Our study affirms and expands upon the outcomes of previous studies and highlights the crucial role of lncRNAs during the immune response to NDV. Conclusion: This analysis clearly shows the differences in the gene expression patterns and lncRNA co-expression with the genes between Leghorn and Fayoumi, indicating that the lncRNAs and co-expressing genes might potentially have a role in differentiating these breeds. We hypothesise that these genes and lncRNAs play a vital role in the higher resistance of Fayoumi to NDV than Leghorn. This study can pave the way for future studies to unravel the biological mechanism behind the regulation of immune-related genes.

Co-production of hemagglutinin H9N2 influenza virus and fusion protein Newcastle virus in insect cell using baculovirus expression system.

Influenza and Newcastle disease are the most important poultry diseases that cause high annual damage to poultry farms worldwide. Newcastle virus fusion (F) gene and Influenza Virus Hemagglutinin (HA) gene are capable of encoding F and HA proteins that are the main factors in creating immunity, so this study aimed to clone and express these genes in Spodoptera frugiperda (Sf9) cells using baculovirus expression system. After isolating the Newcastle and Influenza virus genome, the HA gene of influenza virus and the F gene of Newcastle virus were amplified by reverse transcriptase PCR and specific primers and then cloned into pFastBacTM Dual plasmid. A recombinant sucker with these genes was produced in the DH10Bac host cell. By transfecting Sf9 cells with recombinant bacmid, expression was assessed by SDS-PAGE, western blotting, and Bradford methods. Cloning of genes into the bacmid was successful. By transfecting the recombinant bacmid into Spodoptera frugiperda cells, 218 µg/ml of the recombinant protein was obtained in the supernatant. In addition, the presence of protein was confirmed by western blotting. The PCR products of HA and F genes showed one band of 1.7 kb size using specific primers. The pFastHA1 vector was about 7 kb in size. Two bands of about 7 kb and 1.7 kb were created by ligation of the F gene and pFastHA1 vector based on enzymatic digestion, indicating the correct ligation of F gene under the P10 promoter. This is the first report on the cloning and Co-expression of two HA and F genes using baculovirus expression system and can be a candidate for dual influenza and Newcastle vaccine. Mixtures of these recombinant proteins can be used as vaccine candidates against both avian influenza and Newcastle disease.

HRS Facilitates Newcastle Disease Virus Replication in Tumor Cells by Promoting Viral Budding.

Newcastle disease virus (NDV) is a highly pathogenic avian infectious disease agent and also a promising oncolytic virus with broad application prospects. The Endosomal Sorting Complex Required for Transport (ESCRT) machinery has been increasingly recognized for its crucial role in the life cycles of enveloped viruses, influencing processes such as viral entry, replication, and budding. In this study, we employed an RNA interference screening approach to identify key ESCRT components that regulate NDV replication in tumor cells. qPCR, immunofluorescence, and Western blot assays demonstrated that knockdown of HRS, CHMP4A, CHMP4B, and CHMP4C significantly impaired NDV replication in HeLa cells, with HRS exhibiting the most pronounced inhibitory effect. Additionally, HRS knockout significantly inhibited viral budding and suppressed NDV-induced cell death in HeLa cells. Notably, NDV infection was shown to significantly upregulate HRS gene and protein expression in a time-dependent manner. In conclusion, this study systematically identifies critical ESCRT components involved in NDV replication within tumor cells, with a particular focus on the role of HRS in promoting NDV's replication by promoting viral budding, offering new insights for the development of NDV-based oncolytic therapies.

Molecular Cloning, Tissue Distribution and Antiviral Immune Response of Duck Src.

As a founding member of the Src family of kinases, Src has been confirmed to participate in the regulation of immune responses, integrin signaling, and motility. Ducks are usually asymptomatic carriers of RNA viruses such as Newcastle disease virus and avian influenza virus, which can be deadly to chickens. The beneficial role of Src in modulating the immune response remains largely unknown in ducks. Here, we characterized the duck Src and found that it contains a 192-base-pair 5' untranslated region, a 1602-base-pair coding region, and a 2541-base-pair 3' untranslated region, encoding 533 amino acid residues. Additionally, duSrc transcripts were significantly activated in duck tissues infected by Newcastle disease virus compared to controls. The duSrc transcripts were notably widespread in all tissues examined, and the expression level was higher in liver, blood, lung, pancreas, and thymus. Moreover, we found the expression levels of IFN-ß, NF-κB, IRF3, and Src were significantly increased in DEFs after infection with 5'ppp dsRNA, but there was no significant difference before and after treatment in DF1 cells. Furthermore, overexpression of duSrc followed by stimulation with 5'ppp dsRNA led to an elevation of IFN-ß levels. The SH3 and PTKc domains of duSrc contributed to promoting the activity of IFN-ß and NF-κB in DEFs stimulated by 5'ppp dsRNA.

Isolation and Genetic Characterization of Genotype VII Velogenic Pathotype Newcastle Disease Virus from Commercial Chicken Farms in Central Ethiopia, Distinct from the Local Vaccine Strains.

Newcastle disease (ND) is caused by virulent strains of avian paramyxovirus type 1, also known as Newcastle disease virus (NDV). Despite vaccination, the frequency of reported outbreaks in Ethiopia has increased. From January to June 2022, an active outbreak investigation was conducted in six commercial chicken farms across areas of central Ethiopia to identify the circulating NDV strains. Thirty pooled tissue specimens were collected from chickens suspected of being infected with NDV. A questionnaire survey of farm owners and veterinarians was also carried out to collect information on the farms and the outbreak status. NDV was isolated using specific-pathogen-free (SPF)-embryonated chicken eggs and detected using haemagglutination and the reverse transcriptase-polymerase chain reaction (RT-PCR). The genotype and virulence of field NDV isolates were determined using phylogenetic analysis of fusion (F) protein gene sequences and the mean death time (MDT) test in SPF-embryonated chicken eggs. The questionnaire results revealed that ND caused morbidity (23.1%), mortality (16.3%), case fatality (70.8%), and significant economic losses. Eleven of thirty tissue specimens tested positive for NDV using haemagglutination and RT-PCR. The MDT testing and sequence analysis revealed the presence of virulent NDV classified as genotype VII of class II velogenic pathotype and distinct from locally used vaccine strains (genotype II). The amino acid sequences of the current virulent NDV fusion protein cleavage site motif revealed 112RRQKR↓F117, unlike the locally used avirulent vaccine strains (112GRQGR↓L117). The epidemiological data, MDT results, cleavage site sequence, and phylogenetic analysis all indicated that the present NDV isolates were virulent. The four NDV sequences were deposited in GenBank with accession numbers F gene (PP726912-15) and M gene (PP726916-19). The genetic difference between avirulent vaccine strains and circulating virulent NDV could explain the low level of protection provided by locally used vaccines. Further studies are needed to better understand the circulating NDV genotypes in different production systems.

Arginyltransferase 1 (ATE1)-mediated proteasomal degradation of viral haemagglutinin protein: a unique host defence mechanism.

The extensive protein production in virus-infected cells can disrupt protein homeostasis and activate various proteolytic pathways. These pathways utilize post-translational modifications (PTMs) to drive the ubiquitin-mediated proteasomal degradation of surplus proteins. Protein arginylation is the least explored PTM facilitated by arginyltransferase 1 (ATE1) enzyme. Several studies have provided evidence supporting its importance in multiple physiological processes, including ageing, stress, nerve regeneration, actin formation and embryo development. However, its function in viral pathogenesis is still unexplored. The present work utilizes Newcastle disease virus (NDV) as a model to establish the role of the ATE1 enzyme and its activity in pathogenesis. Our data indicate a rise in levels of N-arginylated cellular proteins in the infected cells. Here, we also explore the haemagglutinin-neuraminidase (HN) protein of NDV as a presumable target for arginylation. The data indicate that the administration of Arg amplifies the arginylation process, resulting in reduced stability of the HN protein. ATE1 enzyme activity inhibition and gene expression knockdown studies were also conducted to analyse modulation in HN protein levels, which further substantiated the findings. Moreover, we also observed Arg addition and probable ubiquitin modification to the HN protein, indicating engagement of the proteasomal degradation machinery. Lastly, we concluded that the enhanced levels of the ATE1 enzyme could transfer the Arg residue to the N-terminus of the HN protein, ultimately driving its proteasomal degradation.

Genetic evolution of Newcastle Disease Virus sub-genotype VII.2 isolates, diagnosed from vaccinated poultry farms of Gujarat, India.

Newcastle disease was suspected in 37 commercial poultry farms, including 12 layer and 25 broiler farms in four districts of Gujarat, India. Vaccination had been done in 32 (20 broilers and 12 layers) farms. Tissue samples from each farm were pooled as one sample. In egg embryo inoculation, HA-HI and PCR, respectively, 32/37, 29/37, and 24/37 samples were found positive. Pathotyping by mean death time calculation and primer combination PCR revealed velogenic NDV, which was later confirmed with the presence of the 112-RRQKR*F-117 sequence at the F protein cleavage site. Phylogenetic analysis of full F gene sequences (N=10) confirmed the presence of sub-genotype VII.2 in 9/10 sequences, and genotype II in one sample. These 9 sequences were only 0.7 to 2.6 % divergent with two VII.2 (=VIIi) sequences (HQ697254.1 chicken/Banjarmas/Indonesia and KU862293.1 Parakeet/Karachi/Pakistan) but had 2.2 to 3.6 % diversion from two VII.2 sequences (OR185447 and MZ546197) from India. Then branching was found from sequences of VIIh, VIIk (VII.2), and VIIa (VII.1.2), and then from sub-genotypes VII.1.1 and VII.1.2. Due to less than 5 % diversion, these sequences could not be qualified as new sub-genotype in evolutionary distance analysis. At the amino acid level, our sequences had aa N-T-I-A-L-T at 24-79-125-385-445-482. Whereas at the same positions, in most of the retrieved VII.2 sequences and vaccines, the sequence was S-A-V-T-Q/I- E/A. Two sequences revealed additional six and four amino acid differences,respectively.This indicates rapid continuous genetic evolution of sub-genotype VII.2 and partially explains vaccinal immunity escape.

A time series transcriptome profiling of host cell responses to Newcastle disease virus infection.

Newcastle disease virus (NDV), an avian paramyxovirus, causes major economic losses in the poultry industry worldwide. NDV strains are classified as avirulent, moderately virulent, or virulent according to the severity of the disease they cause. In order to gain a deeper understanding of the molecular mechanisms of virus-host interactions, we conducted Illumina HiSeq-based RNA-Seq analysis on chicken embryo fibroblast (DF1) cells during the first 24 hours of infection with NDV strain Komarov. Comparative analysis of uninfected DF1 cells versus NDV-infected DF1 cells at 6, 12, and 24 h postinfection identified 462, 459, and 410 differentially expressed genes, respectively. The findings revealed an increase in the expression of genes linked to the MAPK signalling pathway in the initial stages of NDV infection. This overexpression potentially aids viral multiplication while hindering pathogen detection and subsequent immune responses from the host. Our findings provide initial insights into the early responses of DF1 cells to NDV infection.

Evaluation of the immune responses of biological adjuvant bivalent vaccine with three different insertion modes for ND and IBD.

Infectious bursal disease (IBD) is a widespread problem in the poultry industry, and vaccination is the primary preventive method. However, moderately virulent vaccines may damage the bursa, necessitating the development of a safe and effective vaccine. The Newcastle disease virus (NDV) has been explored as a vector for vaccine development. In this study, reverse genetic technology was used to obtain three recombinant viruses, namely, rClone30-VP2L (P/M)-chGM-CSF (NP), rClone30-chGM-CSF (P/M)-VP2L (NP), and rClone30-VP2L-chGM-CSF (P/M). Animal experiments showed that the three biological adjuvant bivalent vaccines effectively increased anti-NDV and anti-infectious bursal disease virus (IBDV) titres, enhancing both humoral and cellular immune responses in chickens without leading to any harm. Amongst the three biological adjuvant bivalent vaccines, the rClone30-chGM-CSF (P/M)-VP2L (NP) group had higher levels of anti-NDV antibodies at 14 days after the first immunization and stimulated a greater humoral immune response in 7-10 days. While, the rClone30-VP2L (P/M)-chGM-CSF (NP) group was the most effective in producing a higher level of IBDV antibody response. In conclusion, these three vaccines can induce immune responses more rapidly and effectively, streamline production processes, be cost-effective, and provide a new avenue for the development of Newcastle disease (ND) and IBD bivalent vaccines.

Computational exploration and molecular dynamic simulation for the discovery of antiviral agents targeting Newcastle disease virus.

Newcastle disease virus (NDV) is a highly infectious viral disease that impacts birds globally, especially domestic poultry. NDV is a type of avian paramyxovirus which poses a major threat to the poultry industry due to its ability to inflict significant economic damage. The membrane protein, Hemagglutinin-Neuraminidase (HN) of NDV is an attractive therapeutic candidate. It contributes to pathogenicity through various functions, such as promoting fusion and preventing viral self-agglutination, which allows for viral spread. In this study, we used pharmacophore modeling to identify natural molecules that can inhibit the HN protein of NDV. Physicochemical characteristics and phylogenetic analysis were determined to elucidate structural information and phylogeny of target protein across different species as well as members of the virus family. For structural analysis, the missing residues of HN target protein were filled and the structure was evaluated by PROCHECK and VERIFY 3D. Moreover, shape and feature-based pharmacophore model was employed to screen natural compounds' library through numerous scoring schemes. Top 48 hits with 0.8860 pharmacophore fit score were subjected towards structure-based molecular docking. Top 9 compounds were observed witihin the range of -8.9 to -7.5 kcal/mol binding score. Five best-fitting compounds in complex with HN receptor were subjected to predict biological activity and further analysis. Top two hits were selected for MD simulations to validate binding modes and structural stability. Finally, upon scrutinization, A1 (ZINC05223166) emerges as potential HN inhibitor to treat NDV, necessitating further validation via clinical trials.

Unraveling dynamics of paramyxovirus-receptor interactions using nanoparticles displaying hemagglutinin-neuraminidase.

Sialoglycan-binding enveloped viruses often possess receptor-destroying activity to avoid being immobilized by non-functional decoy receptors. Sialic acid (Sia)-binding paramyxoviruses contain a hemagglutinin-neuraminidase (HN) protein that possesses both Sia-binding and -cleavage activities. The multivalent, dynamic receptor interactions of paramyxovirus particles provide virion motility and are a key determinant of host tropism. However, such multivalent interactions have not been exhaustively analyzed, because such studies are complicated by the low affinity of the individual interactions and the requirement of high titer virus stocks. Moreover, the dynamics of multivalent particle-receptor interactions are difficult to predict from Michaelis-Menten enzyme kinetics. Therefore, we here developed Ni-NTA nanoparticles that multivalently display recombinant soluble HN tetramers via their His tags (HN-NPs). Applying this HN-NP platform to Newcastle disease virus (NDV), we investigated using biolayer interferometry (BLI) the role of important HN residues in receptor-interactions and analyzed long-range effects between the catalytic site and the second Sia binding site (2SBS). The HN-NP system was also applicable to other paramyxoviruses. Comparative analysis of HN-NPs revealed and confirmed differences in dynamic receptor-interactions between type 1 human and murine parainfluenza viruses as well as of lab-adapted and clinical isolates of human parainfluenza virus type 3, which are likely to contribute to differences in tropism of these viruses. We propose this novel platform to be applicable to elucidate the dynamics of multivalent-receptor interactions important for host tropism and pathogenesis, particularly for difficult to grow sialoglycan-binding (paramyxo)viruses.

Nucleotide sequence characterization, amino acid variations and 3D structural analysis of HN protein of the NDV VIId genotype.

BACKGROUND: Haemagglutinin-neuraminidase (HN) is one of the membrane proteins of Newcastle disease virus (NDV) that plays a significant role during host viral infection. Therefore, antibodies against HN are vital for the host's ability to protect itself against NDV infection due to their critical functions in viral infection. As a result, HN has been a candidate protein in vaccine development against the Newcastle disease virus. METHODS: This report used the full-length sequence of the HN protein of NDV isolated in Iran (VIId subgenotype). We characterize and identify amino acid substitutions in comparison to other more prevalent NDV genotypes, VII subgenotypes and vaccine strains. Furthermore, bioinformatics tools were applied to determine the three-dimensional structure, molecular dynamics simulation and prediction of B-cell antigenic epitopes. RESULTS: The results showed that the antigenic regions of our isolate are quite comparable to the other VII subgenotypes of NDV isolated from different geographical places. Moreover, by employing the final 3D structure of our HN protein, the amino acid residues are proposed as a B-cell epitope by epitope prediction servers, which leads to the introduction of linear and conformational antigenic sites. CONCLUSIONS: Immunoinformatic vaccine design principles currently exhibit tremendous potential for developing a new generation of candidate vaccines quickly and economically to eradicate infectious viruses, including the NDV. In order to accomplish this, focus is directed on residues that might be considered antigenic.

Intranasal SARS-CoV-2 Omicron variant vaccines elicit humoral and cellular mucosal immunity in female mice.

BACKGROUND: In order to prevent the emergence and spread of future variants of concern of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), developing vaccines capable of stopping transmission is crucial. The SARS-CoV-2 vaccine NDV-HXP-S can be administered live intranasally (IN) and thus induce protective immunity in the upper respiratory tract. The vaccine is based on Newcastle disease virus (NDV) expressing a stabilised SARS-CoV-2 spike protein. NDV-HXP-S can be produced as influenza virus vaccine at low cost in embryonated chicken eggs. METHODS: The NDV-HXP-S vaccine was genetically engineered to match the Omicron variants of concern (VOC) BA.1 and BA.5 and tested as an IN two or three dose vaccination regimen in female mice. Furthermore, female mice intramuscularly (IM) vaccinated with mRNA-lipid nanoparticles (LNPs) were IN boosted with NDV-HXP-S. Systemic humoral immunity, memory T cell responses in the lungs and spleens as well as immunoglobulin A (IgA) responses in distinct mucosal tissues were characterised. FINDINGS: NDV-HXP-S Omicron variant vaccines elicited high mucosal IgA and serum IgG titers against respective SARS-CoV-2 VOC in female mice following IN administration and protected against challenge from matched variants. Additionally, antigen-specific memory B cells and local T cell responses in the lungs were induced. Host immunity against the NDV vector did not interfere with boosting. Intramuscular vaccination with mRNA-LNPs was enhanced by IN NDV-HXP-S boosting resulting in improvement of serum neutralization titers and induction of mucosal immunity. INTERPRETATION: We demonstrate that NDV-HXP-S Omicron variant vaccines utilised for primary immunizations or boosting efficiently elicit humoral and cellular immunity. The described induction of systemic and mucosal immunity has the potential to reduce infection and transmission. FUNDING: This work was partially funded by the NIAIDCenters of Excellence for Influenza Research and Response (CEIRR) and by the NIAID Collaborative Vaccine Innovation Centers and by institutional funding from the Icahn School of Medicine at Mount Sinai. See under Acknowledgements for details.

The Application of Newcastle Disease Virus (NDV): Vaccine Vectors and Tumor Therapy.

Newcastle disease virus (NDV) is an avian pathogen with an unsegmented negative-strand RNA genome that belongs to the Paramyxoviridae family. While primarily pathogenic in birds, NDV presents no threat to human health, rendering it a safe candidate for various biomedical applications. Extensive research has highlighted the potential of NDV as a vector for vaccine development and gene therapy, owing to its transcriptional modularity, low recombination rate, and lack of a DNA phase during replication. Furthermore, NDV exhibits oncolytic capabilities, efficiently eliciting antitumor immune responses, thereby positioning it as a promising therapeutic agent for cancer treatment. This article comprehensively reviews the biological characteristics of NDV, elucidates the molecular mechanisms underlying its oncolytic properties, and discusses its applications in the fields of vaccine vector development and tumor therapy.

Oncolytic Newcastle disease virus carrying the IL24 gene exerts antitumor effects by inhibiting tumor growth and vascular sprouting.

The second-leading cause of death, cancer, poses a significant threat to human life. Innovations in cancer therapies are crucial due to limitations in traditional approaches. Newcastle disease virus (NDV), a nonpathogenic oncolytic virus, exhibits multifunctional anticancer properties by selectively infecting, replicating, and eliminating tumor cells. To enhance NDV's antitumor activity, four oncolytic NDV viruses were developed, incorporating IL24 and/or GM-CSF genes at different gene loci using reverse genetics. In vitro experiments revealed that oncolytic NDV virus augmented the antitumor efficacy of the parental virus rClone30, inhibiting tumor cell proliferation, inducing tumor cell fusion, and promoting apoptosis. Moreover, NDV carrying the IL24 gene inhibited microvessel formation in CAM experiments. Evaluation in a mouse model of liver cancer confirmed the therapeutic efficacy of oncolytic NDV viral therapy. Tumors in mice treated with oncolytic NDV virus significantly decreased in size, accompanied by tumor cell detachment and apoptosis evident in pathological sections. Furthermore, oncolytic NDV virus enhanced T cell and dendritic cell production and substantially improved the survival rate of mice with hepatocellular carcinoma, with rClone30-IL24(P/M) demonstrating significant therapeutic effects. This study establishes a basis for utilizing oncolytic NDV virus as an antitumor agent in clinical practice.