Embryonated Chicken Eggs Research Articles

Respiratory and hematological physiology of day 15 chicken embryos (Gallus gallus domesticus) during water submergence and air recovery: Implications for bird embryos experiencing nest inundation.

Bird nests of coastal or inland breeding birds can temporarily flood during high tides or storms. However, respiratory physiological disruption of such water submersion and implications for post-submergence survival are poorly understood. We hypothesized that respiratory physiological disturbances caused by submersion would be rapidly corrected following return to normal gas exchange across the eggshell, thus explaining survival of nest inundation in the field. We further hypothesized that the chicken embryo prior to hatching will develop the ability to recover from acid-base disturbance. We exposed day 15 embryonated chicken eggs (a well-studied point 3/4 through development) to half- or full submersion in water (producing moderate and severe hypoxia, respectively) or in mineral oil (anoxia) for periods of 2-24h to create varying degrees of submersion-related respiratory and acid-base disturbances. Egg submergence was followed by up to six hours in air to determine the extent and rate of physiological recovery. Arterialized blood PO2 and [lactate], acid-base and hematology were measured at frequent intervals (5min to 2h depending on tested variable) both during submersion and air recovery. Submersion in mineral oil - eliminating all gas exchange - proved lethal at two hours. Yet, calculated embryonic oxygen stores suggest submerged embryos should be able to maintain pre-submergence oxygen consumption for only ∼15 mins, suggesting a possibly adaptive immediate decline in metabolism upon submergence. Half- or full submergence in water created blood acid-base disturbances within as little as 5min, with partial recovery towards the end of 24h of submergence. Six hours of subsequent air recovery fully restored acid-base homeostasis. Hematological changes that appeared within 5min of submersion - primarily red blood cell swelling - were eliminated within 1h following return to air. Importantly, these data indicate a surprising resilience of the chicken embryo to temporary elimination of normal gas exchange which, if evident in other species, provides underlying mechanisms for surviving nest inundation.

Intranasal influenza-vectored vaccine expressing pneumococcal surface protein A protects against Influenza and Streptococcus pneumoniae infections

Streptococcus pneumoniae and influenza A virus (IAV) are significant agents of pneumonia cases and severe respiratory infections globally. Secondary bacterial infections, particularly by Streptococcus pneumoniae, are common in IAV-infected individuals, leading to critical outcomes. Despite reducing mortality, pneumococcal vaccines have high production costs and are serotype specific. The emergence of new circulating serotypes has led to the search for new prevention strategies that provide a broad spectrum of protection. In this context, vaccination using antigens present in all serotypes, such as Pneumococcal Surface Protein A (PspA), can offer broad coverage regardless of serotype. Employing the reverse genetics technique, our research group developed a recombinant influenza A H1N1 virus that expresses PspA (Flu-PspA), through the replacement of neuraminidase by PspA. This virus was evaluated as a bivalent vaccine against infections caused by influenza A and S. pneumoniae in mice. Initially, we evaluated the Flu-PspA virus’s ability to infect cells and express PspA in vitro, its capacity to multiply in embryonated chicken eggs, and its safety when inoculated in mice. Subsequently, the protective effect against influenza A and Streptococcus pneumoniae lethal challenge infections in mice was assessed using different immunization protocols. Analysis of the production of antibodies against PspA4 protein and influenza, and the binding capacity of anti-PspA4 antibodies/complement deposition to different strains of S. pneumoniae were also evaluated. Our results demonstrate that the Flu-PspA virus vaccine efficiently induces PspA protein expression in vitro, and that it was able to multiply in embryonated chicken eggs even without exogenous neuraminidase. The Flu-PspA-based bivalent vaccine was demonstrated to be safe, stimulated high titers of anti-PspA and anti-influenza antibodies, and protected mice against homosubtypic and heterosubtypic influenza A and S. pneumoniae challenge. Moreover, an efficient binding of antibodies and complement deposition on the surface of pneumococcal strains ascribes the broad-spectrum vaccine response in vivo. In summary, this innovative approach holds promise for developing a dual-protective vaccine against two major respiratory pathogens.

Isolation and Molecular Detection of Fowl Adenovirus Associated with Inclusion Body Hepatitis in Broiler Chickens in Iraq

Inclusion body hepatitis is caused by an infection with fowl adenovirus and is documented all over the globe. The current research aimed to first isolate fowl adenovirus in embryonated chicken eggs by allantoic sac inoculation and then use PCR to identify the virus. Seventy-five samples suspected to be infected with fowl adenovirus were collected from various locations around Iraq, including Diyala, Tikrit, and Karbala. The age of the hens in which infection was detected varied from 25 to 45 days. For two passages, prepared samples (0.1ml) from infected livers were injected into embryonated chicken eggs (nine days old). The pathological alterations were not observable at the time of the first injection; nevertheless, the second passage revealed congestion, subcutaneous tissue haemorrhage, and embryo's death. After collecting the allantoic fluid from the two passages in the biohazard safety equipment, viral nucleic acid (DNA) was isolated. It was followed by viral detection using conventional PCR by amplification of the Loop1 gene, which yielded a positive result for the presence of fowl adenovirus. The results show that chicken embryos are sensitive methods for detecting fowl adenovirus and molecular instruments like PCR offer higher accuracy and sensitivity.

Testing of Retail Cheese, Butter, Ice Cream, and Other Dairy Products for Highly Pathogenic Avian Influenza in the US.

The recent outbreak of highly pathogenic avian influenza (HPAI) in dairy cows has created public health concerns about the potential of consumers being exposed to live virus from commercial dairy products. Previous studies support that pasteurization effectively inactivates avian influenza in milk and an earlier retail milk survey showed viral RNA, but no live virus could be detected in the dairy products tested. Because of the variety of products and processing methods in which milk is used, additional product testing was conducted to determine if HPAI viral RNA could be detected in retail dairy samples, and for positive samples by quantitative real-time RT-PCR (qRT-PCR) further testing for the presence of live virus. Revised protocols were developed to extract RNA from solid dairy products including cheese and butter. The solid dairy product was mechanically liquified with garnet and zirconium beads in a bead beater diluted 1-4 with BHI media. This preprocessing step was suitable in allowing efficient RNA extraction with standard methods. Trial studies were conducted with different cheese types with spiked-in avian influenza virus to show that inoculation of the liquified cheese into embryonating chicken eggs was not toxic to the embryos and allowed virus replication. A total of 167 retail dairy samples, including a variety of cheeses, butter, ice cream, and fluid milk were collected as part of a nationwide survey. A total of 17.4% (29/167) of the samples had detectable viral RNA by qRT-PCR targeting the matrix gene, but all PCR-positive samples were negative for live virus after testing with embryonating egg inoculation. The viral RNA was also evaluated by sequencing part of the hemagglutinin gene using a revised protocol optimized to deal with the fragmented viral RNA. The sequence analysis showed all viral RNA-positive samples were highly similar to previously reported HPAI dairy cow isolates. Using the revised protocols, it was determined that HPAI viral RNA could be detected in a variety of dairy products, but existing pasteurization methods effectively inactivate the virus assuring consumer safety.

Molecular characterization of circulating infectious bursal disease viruses in chickens from different Egyptian governorates during 2023

Infectious bursal disease virus (IBDV) induces severe immunosuppression in chickens, leading to significant economic losses in the global poultry industry. This study investigated 52 chicken flocks, including commercial broilers, layers, and baladi, from various Egyptian governorates in 2023. These flocks exhibited symptoms of depression, along with kidney and bursa lesions, indicative of IBDV infection. Pooled Bursal homogenates were tested using RT-PCR with VP2-specific primers, revealing that 20 flocks tested positive for IBDV. Six representative samples were selected from 20 positive flocks for isolation in embryonated chicken eggs. The embryonic lesions observed included haemorrhage, skull swelling, and liver necrosis with a pale-yellow appearance, in addition to congestion and thickening in the chorioallantoic membrane (CAM). Partial amplification of the VP2 gene from the harvested embryo suspensions of the six IBDV isolates was performed for sequencing. Phylogenetic analysis of the sequences revealed that five IBDV isolates (VV4, VV5, VV6, VV10, and VV16) belonged to the very virulent strain group A3 cluster, whereas one isolate (VV2) clustered with Chinese Variant strains in the A2d group. Sequence analysis of the hypervariable region (HVR) of VP2 compared to that of Egypt-USC-IBD-1-2019 and vvIBDV/Beh21/Egypt/18 highly virulent IBDV strains revealed several amino acid mutations. The VP2 HVR of all isolates maintained the serine-rich heptapeptide sequence SWSASGS, which is adjacent to the major hydrophilic peak B and serves as a virulence marker. Histopathological examination revealed that bursae from chickens infected with vvIBDV exhibited marked interlobular oedema and lymphoid depletion. In contrast, bursae from chickens infected with Variant IBDV showed massive lymphoid depletion, with hyperplasia of the bursal capsule. These findings highlight the circulation of both virulent and Variant IBDV strains in Egyptian chicken flocks, complicating disease control. Consequently, there is a need to update vaccination programs and vaccine strains for IBDV in Egypt.

Validation of a reduction in time for avian influenza virus isolation using specific pathogen-free embryonated chicken eggs.

The international gold standard for avian influenza virus (AIV) diagnosis is virus isolation (VI) in specific pathogen-free embryonated chicken eggs (ECEs). AIV isolation typically involves a 6-day turnaround, during which premises under suspicion for notifiable AIV infection are held under restriction regardless of molecular diagnoses, often with significant welfare implications. A reduction in time for negation by VI was investigated following experimental inoculation of AIV from known-positive original clinical material into ECEs. VI data derived from more than 600 case investigations from epizootics of high-pathogenicity AIV (HPAIV) in Great Britain since 2016 and from low-pathogenicity AIV (LPAIV) cases in Great Britain since 2014 were examined to support a reduction in test timing using alternative regimens. HPAIVs were isolated during the first passage, and for LPAIV VI, the second passage could be reduced to 2 days. Power analysis showed that the benefit of reducing the number of days outweighed the risk of missing a positive isolate. Limited data were available from experimental inoculations. This truncated methodology, which enables an earlier release of restrictions, may substantially ease the economic implications of restriction. It could also reduce bird welfare implications and improve international standards without loss of test performance.

Molecular Detection and Isolation of Chicken Astrovirus from Commercial Chicken Flocks of Kerala, India

Reduced productivity due to enteric infections in chickens is a very common challenge in the poultry industry of India. Various studies associated Chicken astrovirus (CAstV) as a common pathogen in commercial flocks exhibiting poor weight gain, stunted growth and visceral gout. However, no published report documented the detection of the virus from Kerala so far. Hence, this study was done to investigate the presence of CAstV in 50 broiler flocks from different parts of Kerala with clinical signs such as retarded growth, diarrhoea, and a mortality of 5 to 10 %. Out of the 50, five flocks were found positive for the virus by using the Reverse Transcriptase – Polymerase Chain Reaction (RT-PCR) method with the primers targeting the partial ORF1b gene of the viral nucleic acid. The viral presence was confirmed by isolation using embryonated chicken eggs (ECE), which produced notable alteration to the infected embryos. Nucleotide sequencing of the isolates revealed a high identity of up to 100 % with the other CAstV sequences retrieved from the NCBI database. The study confirms the first report of molecular detection and isolation of CAstV from the state of Kerala.

Antibodies to Influenza A Virus in Lesser (Aythya affinis) and Greater Scaup (Aythya marila) in the USA.

Scaup, including both Lesser and Greater (Aythya affinis and Aythya marila, respectively), are a grouping of populous and widespread North American diving ducks. Few influenza type A viruses (IAV) have been reported from these species despite a high prevalence of antibodies to IAV being reported. Existing virologic and serologic data indicate that IAV infection routinely occurs in scaup, yet it is unknown which IAV subtypes are linked to these infections. In this study, we aimed to gain a more complete picture of IAV natural history in Lesser and Greater Scaup from two coastal flyways in North America in 2015-18 (302 samples from California in the Pacific Flyway and 471 samples from Maryland in the Atlantic Flyway). Low prevalence of active IAV infection was detected by real-time reverse-transcription PCR in Lesser Scaup sampled in Maryland and California (2.8% and 8.1%, respectively). A single IAV (H1N1) was isolated in embryonated chicken eggs from a bird sampled in California. Similarly low levels were observed in Greater Scaup in California (3.3%). Antibodies to the nucleoprotein as detected with a commercial blocking ELISA were observed in all species and flyway combinations. Antibody seroprevalence estimates were higher in adult Lesser Scaup than in juveniles at both the ≤0.5 (P<0.001, z=-3.582) and ≤0.7 serum-sample-to-negative-control absorbance thresholds (P=0.003, z=-2.996). Neutralizing antibodies to H1-H12, H14, and H15 were detected using a microtiter virus neutralization assay, with the highest prevalence of antibodies against H1 (38%), H6 (36%), and H11 (35%). The high prevalence of antibodies to IAV and evidence of previous exposure to numerous subtypes are consistent with a high level of population immunity and a low prevalence of infection. These results must be interpreted in the context of season (winter sampling), as results may vary with the annual influx of naïve juvenile birds.

Differential Expression of Mitogen-Activated Protein Kinase Kinase 3 (MAP2K3) and Interleukin12B (IL12B) in the Bursa of Fabricius of chicken infected with Infectious Bursal Disease Virus

Infectious Bursal Disease (IBD) caused by Infectious Bursal Disease virus (IBDV), poses a significant threat to the poultry industry, causing immunosuppression and economic losses since its discovery in 1957. To understand the host response to IBDV infection, this study examined the modulation of MAP2K3 and IL12B in chickens infected with IBDV. A local IBDV isolate propagated in embryonated chicken eggs was inoculated into 18-day-old chicken. The mRNA transcription levels of MAP2K3 and IL12B in bursal tissue were quantified by real-time quantitative polymerase chain reaction on day two post-infection and compared with those of uninfected, age-matched control birds (sham inoculated). The study revealed increased expression of the MAP2K3 and IL12B genes, indicating their role in inflammatory response during IBDV infection. Thus, the present investigation sheds light on the involvement of MAP2K3 and IL12B in the inflammatory response to IBDV infection in chickens. Keywords: Infectious bursal disease virus, immunosuppression, MAP2K3, IL12B, pro-inflammatory cytokine gene expression

Design and biological evaluation of candidate drugs against zoonotic porcine deltacoronavirus (PDCoV)

Porcine deltacoronavirus (PDCoV) is an emerging swine enteric coronavirus with zoonotic potential. PDCoV spillovers were recently detected in Haitian children with acute undifferentiated febrile illness, underscoring the urgent need to develop anti-PDCoV therapeutics. Coronavirus 3C-like protease (CoV 3CLpro) is essential for viral replication, and therefore provides an attractive target for drugs directed against CoV. Here, we initially evaluated the anti-PDCoV effect of Nirmatrelvir (PF-07321332), an FDA-approved anti-SARS-CoV-2 drug targeting viral 3CLpro. Regrettably, a very limited anti-PDCoV effect was achieved. By analyzing the binding modes of Nirmatrelvir with PDCoV 3CLpro and SARS-CoV-2 3CLpro, we demonstrated that the S2 pocket of 3CLpro is the primary factor underlying the differential inhibitory potency of Nirmatrelvir against different CoV 3CLpros. Based on the specific characteristics of the S2 pocket of PDCoV 3CLpro, four derivatives of Nirmatrelvir (compounds T1–T4) with substituted P2 moieties were synthesized. Compound T1, with an isobutyl at the P2 site, displayed improved anti-PDCoV activity invitro (cell infection model) and invivo (embryonated chicken egg infection model), and therefore is a potential candidate drug to combat PDCoV. Together, our results identify the substrate-binding mode and substrate specificity of PDCoV 3CLpro, providing insight into the optimization of Nirmatrelvir as an antiviral therapeutic agent against PDCoV.

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.

Molecular detection of lumpy skin disease virus in naturally infected cattle and buffaloes: unveiling the role of tick vectors in disease spread.

Lumpy skin disease (LSD) is a viral disease that affects cattle and buffaloes in Egypt, causing considerable economic losses in the animal sector. This study aimed to investigate the recent outbreak of LSDV in cattle and buffaloes and evaluate the potential role of the hard tick Rhipicephalus annulatus in their transmission through isolation and molecular characterization by multiplex PCR (mPCR) and real-time quantitative PCR (rt-qPCR) assays. A total of 50 skin biopsies (cattle n = 30, buffaloes n = 20), 110 nasal swabs (cattle n = 76, buffaloes n = 44), and 129 blood samples (cattle n = 84, buffaloes n = 45) were collected. In addition, 145 hard ticks of different stages were collected from cattle and buffaloes of different breeds and ages in different governorates in Egypt from November 2021 to June 2022. Multiplex PCR and real-time quantitative PCR (rt-qPCR) assays based on SYBR Green and targets (P32, VP32, G protein, and viral fusion protein) were used. We identified positive results in 17 out of 30 cattle skin biopsies (56.6%), 1 out of 7 buffalo skin scabs (14.3%), and 5 out of 45 buffalo blood samples (11.11%) using mPCR and RT-qPCR methods. We successfully isolated LSDV from hard ticks and cattle infested with ticks and exhibited characteristic signs of LSD on the chorioallantois membrane (CAM) of specific pathogen-free embryonated chicken eggs (SPF-ECE). The isolates were confirmed by multiplex PCR and RT-qPCR. The cyclic threshold (Ct) with correlation-slandered curve values of rt-qPCR ranging from 10.2 to 36.5 showed the amount of LSDV-DNA in different samples. The study's findings demonstrated the widespread circulation of LSDV in both cattle and buffaloes in Egypt and provided strong evidence that hard ticks R. annulatus play a role in the transmission of LSDV in susceptible animals.

Detection of H1N1 Influenza Virus in the Bile of a Severe Influenza Mouse Model.

Influenza virus infection may lead to fatal complications including multi-organ failure and sepsis. The influenza virus was detected in various extra-pulmonary organs in autopsy studies during the 2009 pandemic. However, limited research has been conducted on the presence of viral particle or viral components in the peripheral blood. We established a mouse model for severe H1N1 influenza. The bile and blood samples were collected over time and inoculated into embryonated chicken eggs. We detected live influenza virus in bile and blood samples in early infection. Immunofluorescence showed influenza viral components in the liver tissue. No live virus was isolated in the bile in mice intragastrically administered with influenza virus, indicating that the virus was spread from the blood stream. Targeted metabolomics analysis of bile acid and liver tissues showed that a secondary bile acid (3-dehydrocholic acid) was decreased after influenza H1N1 infection. Genes related with fatty acid metabolism and bile secretion pathways were down-regulated in liver after influenza virus infection. Our study indicated that influenza virus viremia is present in severe influenza, and that the liver is a target organ for influenza viral sepsis.

Analyzing Molecular Traits of H9N2 Avian Influenza Virus Isolated from a Same Poultry Farm in West Java Province, Indonesia, in 2017 and 2023.

Indonesia is one of the countries that is endemic to avian influenza virus subtype H9N2. This study aims to compare the molecular characteristics of avian influenza virus (AIV) subtype H9N2 from West Java. Specific pathogen-free (SPF) embryonated chicken eggs were used to inoculate samples. RNA extraction and RT-qPCR confirmed the presence of H9 and N2 genes in the samples. RT-PCR was employed to amplify the H9N2-positive sample. Nucleotide sequences were obtained through Sanger sequencing and analyzed using MEGA 7. Homology comparison and phylogenetic tree analysis, utilizing the neighbor-joining tree method, assessed the recent isolate's similarity to reference isolates from GenBank. Molecular docking analysis was performed on the HA1 protein of the recent isolate and the A/Layer/Indonesia/WestJava-04/2017 isolate, comparing their interactions with the sialic acids Neu5Ac2-3Gal and Neu5Ac2-6Gal. RT-qPCR confirmed the isolate samples as AIV subtype H9N2. The recent virus exhibited 11 amino acid residue differences compared to the A/Layer/Indonesia/WestJava-04/2017 isolate. Phylogenetically, the recent virus remains within the h9.4.2.5 subclade. Notably, at antigenic site II, the recent isolate featured an amino acid N at position 183, unlike A/Layer/Indonesia/WestJava-04/2017. Molecular docking analysis revealed a preference of HA1 from the 2017 virus for Neu5Ac2-3Gal, while the 2023 virus displayed a tendency to predominantly bind with Neu5Ac2-6Gal. In summary, the recent isolate displayed multiple mutations and a strong affinity for Neu5Ac2-6Gal, commonly found in mammals.

Propagation of koi herpesvirus using embryonated chicken eggs: a potential substitute method for fish vaccine production?

Koi herpesvirus disease (KHVD) is caused by a large DNA virus that commonly infects carp, Cyprinus carpio (koi and common carp). KHVD has spread rapidly across the globe and caused high mortality in all ages of common carp and koi. Until now, no effective treatment has been applied to prevent KHV infection impacting the mass production of koi and common carp . An environmentally friendly alternative strategy for controlling fish disease is vaccination. One of the challenges facing conventional viral vaccine production is the requirement for koi or common carp cell cultures, which must be frequently maintained with expensive materials required for virus propagation. This study aims to obtain KHV that has been propagated in embryonated chicken eggs (ECE) to formulate an affordable KHV vaccine for the aquaculture industry. This research consisted of three stages; the first stage was virus inoculation into various parts of eggs (allantoic fluid, chorioallantoic membrane, amniotic fluid, and egg yolk). The second stage was observing viral growth and collecting ECE fluid and membranes. The third stage involved quantitatively determining the viral genomic copy numbers using the quantitative Polymerase Chain Reaction (qPCR) assay. KHV propagation in various parts of ECE resulted in varying viral genomic copy numbers with a high DNA copy number reported in allantoic fluid on the third day after inoculation. Further work is required to monitor virus titer in later passages and optimize methodology for using ECE as the potential alternative to cultured cells as the medium for virus propagation. In the future the system could be developed to produce promising vaccine candidates with more affordable vaccine prices for the Indonesian fish farming industry.

In-Ovo Antiviral Activity of Hibiscus sabdariffa against Newcastle Disease Virus

Newcastle disease is a highly contagious viral infection affecting poultry and wild birds. The causative agent is Avian paramyxovirus 1 (APMV-1), causing significant economic losses despite vaccination efforts due to its high mortality rate. Hibiscus sabdariffa was identified at Modibbo Adama University Yola, and laboratory assays were performed at the National Veterinary Research Institute Vom. The study explores the antiviral effects of extracts from H. sabdariffa calyx against a virulent strain of Newcastle Disease Virus (NDV) using embryonated chicken eggs (ECE). Standard methods were employed for cytotoxicity assay, embryo infective dose 50 (EID50) determination, and therapeutic antiviral assays. Methanol was used for extraction and phytochemical analysis, revealing various bioactive compounds like cardiac glycosides, alkaloids, flavonoids, terpenes, and phenols. Toxicity assay showed cytotoxicity at concentrations over 25 mg/ml, but therapeutic antiviral assays demonstrated virus replication inhibition at concentrations as low as 5 mg/ml. These findings suggest the potential of H. sabdariffa calyx extracts as safe and effective treatments for NDV, with promising therapeutic antiviral properties. Further pharmaceutical research is recommended to explore their use in developing novel Newcastle Disease treatments.

In vitro analysis of antiviral immune response against avian influenza virus in chicken tracheal epithelial cells.

Avian influenza virus (AIV) infections first affect the respiratory tract of chickens. The epithelial cells activate the host immune system, which leads to the induction of immune-related genes and the production of antiviral molecules against external environmental pathogens. In this study, we used chicken tracheal epithelial cells (TECs) in vitro model to investigate the immune response of the chicken respiratory tract against avian respiratory virus infections. Eighteen-day-old embryonic chicken eggs were used to culture the primary chicken TECs. Reverse transcription-polymerase chain reaction (RT-PCR) and immunocytochemistry (ICC) analysis of epithelial cell-specific gene makers were performed to confirm the characteristics, morphology, and growth pattern of primary cultured chicken TECs. Moreover, to investigate the cellular immune response to AIV infection or polyinosinic-polycytidylic acid (poly [I:C]) treatment, the TECs were infected with the H5N1 virus or poly (I:C). Then, immune responses were validated by RT-qPCR and western blotting. The TECs exhibited polygonal morphology and formed colony-type cell clusters. The RT-qPCR results showed that H5N1 infection induced a significant expression of antiviral genes in TECs. We found that TECs treated with poly (I:C) and exposed to AIV infection-mediated activation of signaling pathways, leading to the production of antiviral molecules (e.g., pro-inflammatory cytokines and chemokines), were damaged due to the loss of junction proteins. We observed the activation of the nuclear factor kappa B and mitogen-activated protein kinase (MAPK) pathways, which are involved in inflammatory response by modulating the release of pro-inflammatory cytokines and chemokines in TECs treated with poly (I:C) and pathway inhibitors. Furthermore, our findings indicated that poly (I:C) treatment compromises the epithelial cell barrier by affecting junction proteins in the cell membrane. Our study highlights the utility of in vitro TEC models for unraveling the mechanisms of viral infection and understanding host immune responses in the chicken respiratory tract.

Inactivation of Highly Pathogenic Avian Influenza Virus with High-temperature Short Time Continuous Flow Pasteurization and Virus Detection in Bulk Milk Tanks

Infections of dairy cattle with clade 2.3.4.4b H5N1 highly pathogenic avian influenza virus (HPAIV) were reported in March 2024 in the U.S. and viable virus was detected at high levels in raw milk from infected cows. This study aimed to determine the potential quantities of infectious HPAIV in raw milk in affected states where herds were confirmed positive by USDA for HPAIV (and therefore were not representative of the entire population), and to confirm that the commonly used continuous flow pasteurization using the FDA approved 72 °C (161°F) for 15 s conditions for high−temperature short time (HTST) processing, will inactivate the virus. Double-blinded raw milk samples from bulk storage tanks from farms (n = 275) were collected in four affected states. Samples were screened for influenza A using quantitative real-time RT-PCR (qrRT-PCR) of which 158 (57.5%) were positive and were subsequently quantified in embryonating chicken eggs. Thirty-nine qrRT-PCR positive samples (24.8%) were positive for infectious virus with a median titer of 3.5 log10 50% egg infectious doses (EID50) per mL. To closely simulate commercial milk pasteurization processing systems, a pilot-scale continuous flow pasteurizer was used to evaluate HPAIV inactivation in artificially contaminated raw milk using the most common legal conditions in the US: 72 °C (161°F) for 15 s. Among all replicates at two flow rates (n = 5 at 0.5 L/min; n = 4 at 1 L/min), no viable virus was detected. A mean reduction of ≥5.8 ± 0.2 log10 EID50/mL occurred during the heating phase where the milk is brought to 72.5 °C before the holding tube. Estimates from heat-transfer analysis support that standard U.S. continuous flow HTST pasteurization parameters will inactivate >12 log10 EID50/mL of HPAIV, which is ∼9 log10 EID50/mL greater than the median quantity of infectious virus detected in raw milk from bulk storage tank samples. These findings demonstrate that the US milk supply is safe when pasteurized.

Region-selective and site-specific glycation of influenza proteins surrounding the viral envelope membrane

Analysis of protein modifications is critical for quality control of therapeutic biologics. However, the identification and quantification of naturally occurring glycation of membrane proteins by mass spectrometry remain technically challenging. We used highly sensitive LC MS/MS analyses combined with multiple enzyme digestions to determine low abundance early-stage lysine glycation products of influenza vaccines derived from embryonated chicken eggs and cultured cells. Straightforward sequencing was enhanced by MS/MS fragmentation of small peptides. As a result, we determined a widespread distribution of lysine modifications attributed by the region-selectivity and site-specificity of glycation toward influenza matrix 1, hemagglutinin and neuraminidase. Topological analysis provides insights into the site-specific lysine glycation, localizing in the distinct structural regions of proteins surrounding the viral envelope membrane. Our finding highlights the proteome-wide discovery of lysine glycation of influenza membrane proteins and potential effects on the structural assembly, stability, receptor binding and enzyme activity, demonstrating that the impacts of accumulated glycation on the quality of products can be directly monitored by mass spectrometry-based structural proteomics analyses.

RT-PCR based detection and pathotypical characterization of Newcastle disease virus isolated from layer chickens in Mymensingh, Bangladesh

The Newcastle disease virus (NDV) poses a significant threat to commercial chicken operations and is prevalent in Bangladesh. This rapidly spreading viral illness has severe economic implications for the poultry industry globally. In Bangladesh, the velogenic strain of NDV is particularly widespread. This study utilized primers from the Fusion (F) and Matrix (M) genes along with haemagglutination (HA) testing and reverse transcription-polymerase chain reaction (RT-PCR) to isolate and identify NDV. Post-mortem examinations provided 12 samples (from brain, trachea, and proventriculus) taken from four birds suspected of having NDV from Trishal and Mymensingh Sadar. The samples were injected into 10-day-old embryonated chicken eggs using the chorioallantoic membrane technique. Embryos and allantoic fluid (AF) were collected at 48 and 96 hours post-infection. NDV-infected embryos showed edema and hemorrhage. Significant hemagglutination was observed in the allantoic fluid tested with HA. Through the HA test and lesion observation, four NDV isolates were identified. Pathotypic characterization of the field isolates using the Intracerebral Pathogenicity Index (ICPI) and Mean Death Time (MDT) indicated velogenic strains (ICPI: 1.5–2.0, MDT: &lt;60). RT-PCR confirmed the NDV status of all four isolates using primers for partial amplification of the F gene (839 bp) and the common sequence of the ‘F-M’ genes (970 bp). This study demonstrates that RT-PCR is an effective molecular technique for the rapid and confirmatory identification of velogenic NDV strains, particularly prevalent in Mymensingh at the field level.