We first report avipoxvirus (APV) infection and an isolate named APV/03/2016 from a red-flanked blue robin (Tarsiger cyanurus) captured at Songhua Lake Scenic Area in Jilin City (Jilin Province, China) on March 24, 2016. The partial sequence of the 4b core protein gene and DNA polymerase gene of APV/03/2016 suggests that the virus belongs to the subclade B1 cluster of clade B (canarypox virus). The BLAST results showed the highest similarity of the two genes with the Pacific shearwater-isolated strain SWPV-2 (KX857215), canarypox virus strain D98-11133 (GQ487567), canarypox virus strain ATCC VR-111 (AY318871), avipoxvirus Mississippi isolate P89 (KC018048), and avipoxvirus Wisconsin isolate P92 (KC018051). The results indicate that APV/03/2016 is a canarypox-like virus. These findings demonstrate the continuous emergence of new APV hosts such as red-flanked blue robins and suggest that monitoring of APV circulation and evolution should be strengthened for T. cyanurus conservation.

Salmonella enterica serovar Enteritidis is the leading cause of salmonellosis in people, and modeling of infections in chickens is used to identify intervention strategies. A review of 80 manuscripts encompassing 119 experiments indicated that the mean dose of infection was 10⁸ CFU per bird. Experiments of less than 10⁶ CFU were primarily conducted in immature birds. To address a lack of information on the impact of low dosages on the hen at lay, two experiments were conducted in triplicate. Experiment A addressed issues associated with vaccination; thus, hens were infected intramuscularly at 10³, 10⁵, and 10⁷ CFU. For Experiment B, which was focused more on colonization and invasion, hens were infected orally with 5 × 10³ CFU with 4 strains from different genomic clades. Samples from liver, spleen, ovarian pedicle, and paired ceca in both experiments were cultured 5, 6, 7, and 8 days postinfection. Eggshell microbiome taxa were assessed in Experiment B. Results indicated that dosages of 10³ CFU in both experiments produced enough positive samples to be used within models. The intramuscular route resulted in approximately twice as many positive samples as the oral route. The kinetics of infection appeared to differ between low and high dosages suggestive of a J-curve response. These results could impact risk assessments if the hen at lay has a nonlinear response to infectious dose.

Hydropericardium syndrome (HPS) is caused by fowl adenovirus serotype 4 (FAdV-4). HPS has caused outbreaks in Chinese populations of broiler chickens since 2015. However, little is known about the molecular mechanisms underlying HPS. In this study, we used transcriptomic analysis to screen differentially expressed genes (DEGs) in the livers of FAdV-4–infected and noninfected chicks. Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis showed that the gene network associated with the arginine metabolism pathway was enriched in livers infected by FAdV-4; 10 genes were downregulated and 8 genes were upregulated in these livers when compared to noninfected livers. The DEGs identified in livers were reanalyzed by real-time fluorescence quantitative PCR (qPCR); results indicated that the mRNA levels of the DEGs concurred with the data derived from KEGG analysis. Next, we used qPCR to detect the DEGs of the arginine metabolism pathway in a hepatocellular carcinoma cell line (LMH) after infection with FAdV-4 for 24 hr; this also indicated that the mRNA levels of the DEGs concurred with that seen in the liver. We also used si-RNA oligonucleotides to knock down the mRNA levels of iNOS in LMH cells infected with FAdV-4 and found that the viral load of FAdV-4 was increased. Further investigation revealed that the addition of 240 µg/ml of arginine into the culture medium of LMH cells infected with FAdV-4 for 24 hr led to a significant increase in the mRNA levels of iNOS but a significant reduction in the viral load of FAdV-4. Therefore, our data indicated that when broiler chickens become infected with FAdV-4, the arginine metabolic pathway in the liver becomes dysfunctional and the iNOS mRNA level decreases. This will add benefit to the replication of FAdV-4 but can be inhibited by the addition of an appropriate amount of arginine.

An infectious bronchitis virus (IBV) with an unusual enteric tropism (CalEnt) was isolated from a California broiler flock exhibiting runting-stunting syndrome. IBV was detected in the small intestine, but not in the respiratory tract or kidney. During virus isolation in embryos, it did not replicate in chorioallantoic membrane (CAM) but could be recovered from intestines. Its S1 protein showed 93% amino acid sequence identity to a California variant isolated in 1999 (Cal99). Intestinal lesions were reproduced following ocular/nasal inoculation of specific-pathogen-free chickens, but respiratory signs and lesions were also present. The virus was detected in both respiratory and intestinal tissues. To determine whether the novel tropism of IBV CalEnt was due to an increased ability of its S1 protein to bind to the intestinal epithelium, we compared the binding of soluble trimeric recombinant S1 proteins derived from CalEnt and Cal99 to chicken tissues. Contrary to expectations, the CalEnt S1 protein did not bind to small intestine and, unlike Cal99 S1, did not bind to the respiratory epithelium or CAM. Using only the CalEnt S1 N-terminal domain or including the S2 ectodomain (lacking membrane and cytoplasmic domains), which have been shown to improve ArkDPI S1 protein binding, did not lead to detectable binding at the standard protein concentration to any tissue tested. Our results indicate no/poor binding of the CalEnt spike protein to both respiratory and intestinal tissues and thus do not support better attachment to intestinal epithelial cells as a reason for CalEnt's extended tropism. These results might reflect shortcomings of the assay, including that it does not detect potential contributions of the S1 C-terminal domain to attachment. We used bioinformatic approaches to explore the possibility that the unique tropism of CalEnt might be a result of functions of the S protein in cell-entry steps subsequent to attachment. These analyses suggest that CalEnt's S2 coding region was acquired through a recombination event and encodes a unique amino acid sequence at the putative recognition site for the protease that activates the S protein for fusion. Thus, S2 activation by tissue-specific proteases might facilitate CalEnt entry into intestinal epithelial cells and compensate for poor binding by its S1 protein.

The chicken major histocompatibility complex (MHC) B locus has been linked to resistance to infectious diseases. We have previously provided evidence that the MHC congenic chicken lines 331/B2 and 335/B19 differ in susceptibility to infectious bronchitis virus (IBV) strains M41 and ArkDPI in in vivo challenge experiments. Innate immune responses can be difficult to measure in vivo because they are nonspecific and can be triggered by environmental factors. In an attempt to address this issue, we used tracheal organ cultures derived from 331/B2 and 335/B19 birds to study local cytokine production after in vitro challenge with IBV M41. Interferon (IFN)-β, interleukin (IL)-1β, IL-6, and IL-10 gene expression and production were assessed. Tracheal organ cultures derived from 335/B19 birds presented an increased inflammatory response compared to 331/B2. However, it was not possible to discriminate between cytokine responses in IBV-infected and phosphate-buffered saline–treated tracheal organ cultures. Because tracheal processing entails physical damage to the trachea, it is possible that the tracheal organ cultures presented high levels of inflammation regardless of the IBV challenge. To demonstrate the effects of IBV on innate immune responses in the MHC congenic chicken lines, we performed an additional in vivo experiment that focused on cytokine gene expression and production in tracheas up to 60 hr after a challenge with IBV M41. Our results corroborate previous in vivo observations that suggest that detrimental local inflammatory responses in 335/B19 birds might be associated with their susceptibility to IBV and that inflammation does not necessarily lead to the assembly of an appropriate adaptive immune response. This work provides further insight into the increased susceptibility of 335/B19 birds to infectious bronchitis.

Rodents serve as amplifiers of Salmonella infections in poultry flocks and can serve as a source of Salmonella contamination in the environment even after thorough cleaning and disinfection. This study aims to determine the dynamics of Salmonella occurrence in rodents and its relation to Salmonella contamination in the layer farm environment, including air dusts and eggs. From 2008 to 2017, roof rats (Rattus rattus), environmental swabs, air dusts, and eggs were collected from an intensive commercial layer farm in East Japan and were tested for Salmonella spp. using standard procedures. In roof rat samples, the Salmonella isolation rate was reached at 10% (95% confidence interval [CI] 8.1–21.9) in which Salmonella Corvallis, Salmonella Infantis, Salmonella Potsdam, and Salmonella Mbandaka were the frequent isolates from the cecal portion of the intestines. On the other hand, the prevalence rate of Salmonella in environmental swabs was at 5.1% (95% CI 2.2–7.4) while air dusts were at 0.9% (95% CI 0.2–1.8). It was observed that the prevalence of predominant Salmonella serotypes shifted over time; in roof rats, it was noted that Salmonella Potsdam gradually replaced Salmonella Infantis. In environmental swabs and eggs, Salmonella Corvallis and Salmonella Potsdam increased significantly while Salmonella Infantis became less frequent. In air dusts, Salmonella Corvallis was observed to decrease and Salmonella Potsdam became more common. Based on our findings, the role of roof rats in the epidemiology of Salmonella in layer farms was expanded from being a reservoir and an amplifier host into a shifting vessel of the most predominant serotypes.

Recombinant Newcastle disease virus (NDV) LaSota (LS) expressing secreted trimeric spike (S)-ectodomain (Se) of infectious bronchitis virus (IBV) (rLS/IBV.Se) was developed and evaluated for protection conferred against IBV challenge. The IBV S-ectodomain protein, which is S excluding the transmembrane anchor and short cytoplasmic domain of S2, expressed from recombinant LS corresponds to an Arkansas (Ark)-type IBV. In a first experiment, chickens were primed at 1 day of age or primed at 1 day of age and boosted at 14 days of age with 10⁴ 50% embryo infectious doses (EID₅₀)/bird of rLS/IBV.Se and challenged with a virulent Ark strain. A single vaccination proved completely ineffective at protecting chickens against challenge, whereas priming and boosting reduced clinical signs and tracheal lesions but did not reduce viral load in lachrymal fluids. In experiment 2, the vaccine dose was increased to 10⁷ EID₅₀/bird and a different virulent Ark strain was used for challenge. In addition, chickens were singly immunized on either day 1 or day 10 after hatch. NDV antibody levels detected in vaccinated chickens were moderate, with hemagglutination inhibition titers varying between 4 and 5 log₂. Slightly higher antibody levels to NDV were observed in chickens vaccinated on day 10 versus day 1 but without the difference achieving statistical significance. In contrast, antibody responses measured using recombinant IBV S1 protein-coated ELISA plates were significantly greater in chickens vaccinated on day 10 than on day 1. The use of a higher rLS/IBV.Se dose substantially enhanced the success of a single vaccination compared to experiment 1. Signs and tracheal lesions were reduced more effectively in chickens vaccinated at day 10 after hatch. However, as in experiment 1, vaccination did not reduce the viral loads in tear fluids of challenged chickens. Similar results, in which no reduction in viral load in the trachea was apparent from rLS/IBV.S vaccination, have been obtained by others. Further work is needed to understand the immune responses induced by this recombinant virus that seems to provide some protection against the disease but does not reduce viral loads in the upper respiratory tract.

A commercial Arkansas (Ark) Delmarva Poultry Industry (DPI)-type vaccine and a more homogeneous population of that vaccine obtained previously through adaptation to chicken embryo kidney (CEK) cells (CEK-ArkDPI) were used as a model to further understand the impact of population genetic structure on generation of immune responses and protection. In a first experiment, vaccinated chickens were challenged with an IBV Ark99-type virulent strain (AL/4614/98). Despite extensive sequence similarity between the vaccines, the more heterogeneous commercial ArkDPI was more efficient at reducing viral loads in challenged chickens, while respiratory signs and tracheal lesions were reduced similarly by either vaccine. A distinct subpopulation of the Ark challenge virus showing asparagine at S1 position 56 was consistently negatively selected by immune pressure originating from vaccination with either vaccine. Antibody levels and antibody avidity to Ark-type S1 protein were greater in CEK-ArkDPI-vaccinated chickens compared to chickens vaccinated with the more diverse commercial ArkDPI vaccine. Synchronous replication of a homogeneous virus population likely elicits clonal expansion and affinity maturation of a greater number of responding B cells compared to a diverse virus population continuously changing its proportion of phenotypes during replication. The results of a second experiment showed that during initial vaccine virus replication (24 and 48 hr postvaccination), the virus population showing increased diversity (commercial ArkDPI) achieved higher concentrations of IBV RNA in the trachea compared to the more homogenous virus. mRNA expression of genes associated with innate immune responses in the trachea 48 hr postvaccination generally showed greater upregulation in chickens vaccinated with the heterogeneous commercial ArkDPI vaccine compared to the CEK-adapted virus. The greater upregulation of these genes is likely associated with higher virus replication achieved by the heterogeneous commercial vaccine. Thus, while the adaptive antibody response was favored by the more homogenous structure of the CEK-ArkDPI vaccine population (higher antibody levels and antibody avidity), the innate immune response was favored by the more diverse viral population of the commercial ArkDPI. We confirmed previous results that distinct subpopulations in wild Ark challenge virus become selected by immune pressure originating from vaccination, and we concluded that the population structure of IBV vaccines impacts innate immune response, antibody avidity, and protection.

The development of immunocompetence in chicks after hatching is not fully understood. However, detailed knowledge of immunocompetence and maturation processes in day-old chicks (DOCs) and juvenile chickens (Gallus gallus domesticus) is necessary to implement enhanced immunization strategies. For viral diseases, this especially includes the development of cellular immunity focusing on T-cell–dependent responses. In the current study, we investigated T-cell subsets in blood and lymphoid tissues of 1-to-21-day-old chickens concerning their cellular composition and localization. We detected an increase of T-cell frequencies in blood and spleen and a shift of the CD8α dimer expression toward a CD8αβ expression on the surface of T cells with increasing age. A relocalization of lymphocytes into antigen presentation structures within the spleen was affirmed. In addition, changes in basal messenger RNA (mRNA) level, with increasing IL2 and IFNγ mRNA levels at different ages were measured. These detected changes suggest an improved T-cell–dependent antiviral response with increasing age in chickens. To confirm this finding on a functional level, we conducted a transfer experiment: adult and, as a negative control, neonatal naïve lymphocytes were transferred into DOCs. Afterward, the protection induced by these transferred cells was verified by a sublethal infection by using a highly pathogenic avian influenza virus with neuraminidase deletion, H5N_del. Previous experiments have shown that adult animals survive infection with this virus strain, while naïve DOCs show severe symptoms or even die. As a result, the transfer of adult, but not neonatal lymphocytes, confers protection to DOCs against the infection, demonstrating functional differences in lymphocytes from chicks of different ages. Collectively, these data reveal the inability of chicks to mount an effective, cellular antiviral response in the first 3 wk of life. Therefore, we propose that the observed maturation of both the innate and the adaptive arms of the immune system early in development is mandatory for controlling influenza infection in chickens, as well as for an effective vaccination with replication-competent viral vaccine strains.

After accumulating data through a nationwide survey, we characterized the recent prevalences and geographic distributions of various genotypes of infectious bronchitis virus (IBV) on layer farms in Japan. Reverse transcription PCR analysis of fecal samples revealed the presence of the IBV nucleoprotein (N) gene on approximately 30% of the farms surveyed. N-gene detection rates were higher in the Chugoku and Kyushu regions than in the remaining surveyed regions. Phylogenetic analysis of S1 gene sequences revealed that JP-I, JP-II, JP-III, and Massachusetts genotypes were particularly prevalent, with JP-I isolated throughout the country. Additionally, JP-II was the genotype detected most frequently in Chugoku, and JP-III was the most frequent in Kyushu. Unlike the previous results obtained in 1998 through 2003, the European-prevalent 4/91 genotype was no longer circulating in Japan. Moreover, the number of prefectures where multiple genotypes were detected simultaneously increased during that time.

Avian influenza A viruses are a major threat to animal and public health. Since 1997, several highly pathogenic H5N1 avian viruses have been directly transmitted from poultry to humans, caused numerous human deaths, and had considerable economic impact on poultry markets. During 2015–2016, a highly pathogenic avian influenza outbreak occurred in southwestern France. Different subtypes circulated, including the A/chicken/France/150169a/2015 H5N1 highly pathogenic virus, which did not possess the full set of genomic determinants known to promote transmission to humans. In order to evaluate the predicted absence of zoonotic potential, a quick method based on in vitro tests was developed to analyze some genetic and phenotypic host restriction determinants. A receptor-binding assay showed that the virus preferentially recognizes avian cell receptors. Temperature sensitivity revealed a cold-sensitive phenotype of the virus at 33 C as virus replication was reduced in contrast with what is expected for human influenza viruses, according to their primary infection sites. Altogether, our quick evaluation method suggests that the A/chicken/France/150169a/2015 H5N1 highly pathogenic virus has an avian phenotype in vitro, in accordance with in silico predictions based on genomic markers.

In recent years, Arkansas Delmarva Poultry Industry (ArkDPI)–derived infectious bronchitis (IB) virus (IBV) vaccines have been used to characterize the immune responses of chickens subsequent to vaccination on day of hatch or beyond. Perhaps because ArkDPI vaccines display increased heterogeneity, the results on cell immune responses have shown ambiguity. In the current study, we investigated the effects of vaccination with a highly stable and homogeneous Massachusetts (Mass)-type vaccine on days 1 or 7 of age on Harderian gland (HG) responses. Confirming previous studies, both IBV serum antibodies and lachrymal IgA levels were greater upon vaccination on day 7 compared with vaccination on day 1 of age. Unlike results with ArkDPI viruses, a clear trend was detected for both B and T cells in the HG after Mass-type vaccination. Consistent with antibody responses, B- and T-helper (CD3⁺CD4⁺) cell frequencies were higher in birds vaccinated on day 7 of age. Cytotoxic T cells (CD3⁺CD8⁺) were also increased compared with chickens vaccinated on day 1 of age. Depending on the most likely age of IB outbreaks to occur in a particular region, postponing the first IBV vaccination may optimize immune responses.

The outbreak of highly pathogenic H5Nx influenza A viruses (IAVs) in the United States during 2014–2015 caused devastating economic losses; therefore, several measures were established to control and eliminate highly pathogenic H5Nx from U.S. poultry flocks. One such measure was a temporary ban on poultry exhibitions during 2015, and this decision dramatically affected youth raising poultry as part of agricultural education programs. During the summer of 2016, surveillance of the environment was conducted at 20 Ohio agricultural fairs to estimate the prevalence of IAV in exhibition poultry to determine the baseline during nonoutbreak exhibition seasons. Of the 400 total samples collected, two were positive by real-time reverse transcription–PCR; however, virus isolation attempts with both embryonating chicken eggs and cell culture were unsuccessful. The detection of nucleic acid highlights the risk exhibition poultry could play in the transmission and spread of IAVs between humans, swine, wild birds, and domestic poultry during low or highly pathogenic IAV outbreaks. Additional surveillance at agricultural fairs and biosecurity education for youth exhibitors in this setting are warranted to reduce risk.