This study provides a detailed description of the major morphoanatomic and ultrastructural features of the nasal gland in turkeys. In this avian species, nasal or salt glands are bilateral, pale pink, elongated to spindle-shaped, serous, tubuloalveolar structures, with a mean length ranging from 0.64 ± 0.15 cm in poults of 4 days of age to 2.15 ± 0.17 cm at 22 weeks. Instead of having a supraorbital location as commonly seen in waterfowl and other avian species, these glands run underneath the lacrimal, frontal, and nasal bones in turkeys. The reference point for sample collection for histologic examination is just before the rostral edge of the eyelid. Each gland adheres to the surrounding bone through a thick capsule of dense connective tissue merging with the skull periosteum. Histologically, the salt gland consists of secretory tubuloalveolar structures, lined by cuboidal epithelial cells with a central canaliculus and ducts. There are small and large ducts lined by a bilayered epithelium consisting of large apical columnar secretory cells occasionally admixed with rare cuboidal cells. These cells are periodic acid Schiff negative and slightly Alcian blue positive. Both alveolar and secretory ductal cells contain slightly electrondense granular vesicles, highly folded lateral surfaces, and large numbers of mitochondria, characteristic of ion-transporting epithelia. This study provides valuable information for the accurate identification and localization of the nasal gland during necropsy, as well as its correct histologic interpretation, ultimately improving our understanding of the role of this gland in the pathophysiology of specific diseases in turkeys.

Intestinal inflammation may provide a growth advantage for Salmonella and enhance its systemic spread in chickens. Salmonella triggers intestinal inflammation in the host by using type III secretion systems (T3SS) and produces the inflammatory end product tetrathionate. In mice, tetrathionate respiration confers a growth advantage for Salmonella Typhimurium over the competitive microbiome in the inflamed intestine. Coccidia also promote intestinal inflammation and enhance Salmonella intestinal growth and systemic spread in chickens. The objective of this study was to evaluate the contribution of inflammation, induced by Eimeria spp. or Salmonella Typhimurium, to Salmonella colonization and dissemination in chickens. In addition, the fitness costs associated with defects in tetrathionate reductase and T3SS associated with Salmonella Pathogenicity Island 1 or 2 (SPI-1 or SPI-2) were evaluated in in vivo competition experiments with wild-type Salmonella strain, with or without Eimeria coinfection. One-day-old specific-pathogen-free chickens were orally inoculated with a sham inoculum or with 4 × 10²Eimeria oocysts cocktail of Eimeria tenella, Eimeria acervulina, Eimeria maxima, and Eimeria mitis. At 6 days of age, birds were orally administered a 1:1 ratio of Salmonella Typhimurium wild-type and mutant deficient in tetrathionate reductase, SPI-1, or SPI-2 (10⁸ colony forming units/bird). Ceca, livers, and drumsticks were collected at 3, 7, 14, and 42 days after Salmonella infection, for bacteriology. Intestinal inflammation was scored by histology. Significantly higher intestinal inflammation was observed in challenge groups compared with the control. However, there were no significant differences in intestinal inflammation scores between groups coinfected with both Eimeria spp. and Salmonella Typhimurium and birds infected with Salmonella alone, and Eimeria coinfection did not increase Salmonella prevalence or abundance. Contrary to mouse studies, tetrathionate reductase did not enhance Salmonella Typhimurium cecal colonization or systemic spread in chickens. SPI-1 and SPI-2 played a significant role in Salmonella dissemination and cecal colonization in chickens, respectively.

Gizzard erosions have been noticed in slaughtered broiler chickens during inspection at a processing plant in Iran. The condition was detected in piled gizzards derived from seven commercial broiler farms brought to slaughter on the same day. In total, 48 gizzards with lesions underwent thorough pathologic and virologic investigation. Perforation, roughening, and discoloration of the koilin layer as well as inflammation of the mucosa were observed macroscopically. Histologic examination showed dissociation of and cellular debris in the koilin layer accompanied by a loss and degeneration of glandular epithelium with mild to marked infiltration of inflammatory cells in the mucosa, submucosa, and muscular layer. Fowl adenovirus serotypes 1 (FAdV-1), 11 (FAdV-11), and 8a (FAdV-8a) were found in 13, 12, and 1 gizzard(s), respectively. Therein included were two gizzards that showed mixed infections with FAdV-1 and FAdV-11. Detailed analysis of the hexon gene revealed that the Iranian FAdV-1 isolates could be divided into two subclusters, more closely related to either the European (CELO) or the Asian (Ote) FAdV-1 reference strains. The present study, for the first time, describes not only the appearance of gizzard erosion but also the isolation of FAdV-1 and FAdV-8a from broilers in Iran and offers insights on the epidemiology of FAdV infection in Iranian flocks.

Identifying Eimeria spp. circulating in a poultry flock assists in designing vaccine preventive programs, as different species do not cross-protect. Because species differ in anticoccidial drug susceptibility, species identification can also be used to optimize anticoccidial medication. In the present study, we designed pan-Eimeria–specific primers for the 18S rDNA and the cytochrome oxidase I (COI) genes, and tested whether next-generation sequencing of their amplicons allowed reliable identification of Eimeria spp. in samples of isolated oocysts. For each gene, two sets of primers to be used in a nested PCR (nPCR) system were designed. In silico evaluation of the primers using published sequences showed that nucleotide sequence identities of the nested amplicons were less than 97% between most species, while only identities of 18S rDNA genes of Eimeria necatrix and Eimeria tenella and between the COI genes of Eimeria mitis and Eimeria mivati were higher than 97%. Three vaccines and five Eimeria samples from chickens in backyard flocks were investigated by nPCRs and by direct PCRs (dPCR) using the nested (inner) primers with genomic DNA as the template. Seventeen further Eimeria samples from chickens in backyard flocks and three Eimeria samples from commercial broiler flocks were investigated only by nPCR. Sequencing nPCR products tended to detect more species than sequencing dPCR products and sequencing 18S rDNA products tended to detect more species than sequencing COI products. Regarding the detected species, there was a clear difference between the commercial broiler flocks and the backyard flocks. Eimeria acervulina, Eimeria maxima, and E. tenella/E. necatrix were the only species detected in broiler flocks, while the population in the backyard flocks was more varied, with Eimeria brunetti and E. mitis/E. mivati and the previously described operational taxonomic unit Y being more prevalent. Several sequences having less than 97% identity with one of the sequences used for clustering were detected in samples from backyard flocks. In conclusion, next-generation amplicon sequencing can be a useful tool to determine which Eimeria spp. are circulating in chicken flocks.

Salmonella enterica serovar Gallinarum is a nonmotile host-adapted Salmonella that causes fowl typhoid (FT), and an outbreak of FT is characterized by anorexia, greenish-yellow diarrhea, paleness, and sudden death with high mortality in poultry. To control and treat FT in commercial chickens, fluoroquinolones are widely used in Korea. This study aimed to investigate the genetic characteristics of fluoroquinolone-resistant Salmonella Gallinarum isolates from 2014–18 from chicken in Korea. A total of 35 ciprofloxacin (CIP)-resistant Salmonella Gallinarum was tested, and 22 (62.9%) isolates were observed to have multidrug resistance. All isolates had a mutation at the Ser83 or Asp87 codon in the gyrA gene, whereas three isolates had only double mutations at Ser83 → Phe and Asp87 → Asn or Ser83 → Phe and Asp87 → Gly. Minimum inhibitory concentrations of isolates with double mutations were relatively higher (≥8 mg/L for CIP and ≥16 mg/L for enrofloxacin) than those of other isolates with a single mutation in gyrA. Among 35 CIP-resistant Salmonella Gallinarum, plasmid-mediated quinolone resistance genes were detected in six (17.1%) isolates, and qnrB and qnrS were detected in four and two isolates, respectively. In the distribution of antimicrobial resistance genes in 35 CIP-resistant Salmonella Gallinarum, ant(2″)-I (54.3%) was the most prevalent gene, followed by TEM-1 (14.3%), sul1 (11.4%), and cmlA (5.7%). Fifteen (42.9%) of the 35 CIP-resistant Salmonella Gallinarum also carried class 1 integrons, which showed five types of resistance gene cassettes: aadA2 (7 isolates), aadA2 + dfrA12 (5 isolates), and aadA1 + aad A2 (3 isolates). Among plasmid replicons, 23 isolates (65.7%) carried five different plasmid replicons: Frep (9 isolates), FIB (7 isolates), FIIA (6 isolates), B/O (4 isolates), and I1 (3 isolates). These results suggest that continued monitoring of fluoroquinolone resistance is necessary to preserve the effectiveness of fluoroquinolones in poultry and to surveil the transmission to humans through the food chain.

Marek's disease (MD) vaccines are cell-associated and require special handling and care during administration. Vaccine dose is evaluated by plaque assay and is indicated as the number of plaque-forming units (PFUs) per dose. The objectives of this study were to evaluate the dose variability within each vial of MD vaccines and to assess those factors (from both manufacturing and handling and administration of the vaccine) that could affect vaccine dose variability. Three experiments were conducted. Experiment 1 was to evaluate dose variability in 36 MD vaccine vials and the effect of manufacturing factors on dose variability. Vaccines were titrated 10 times. Dose variability was measured as the coefficient of variability (CV) calculated as standard deviation divided by average PFU and multiplied by 100. Our results showed that all evaluated vaccines had levels of CV ranging from 10% to 34%. Variability existed regardless of manufacturer, vaccine serotype, and batch. Experiment 2 was conducted to evaluate the effect of infectivity rate (IR) on CV. IR was artificially reduced by adding noninfected chicken embryo fibroblast to the reconstituted vaccine before titration. Our results showed that decreased IR results in higher CV. Experiment 3 was to evaluate the handling and administration factors (time and mixing during administration) on CV. Our results showed that CV tends to increase with time and that this effect is more remarkable if vaccines were not mixed. Our study emphasizes the relevance of proper handling of MD vaccines and shows that dose variability can jeopardize the uniformity of vaccination in a flock and therefore the success of vaccination.

Virulent strains of avian orthoavulavirus 1, historically known as Newcastle disease virus (NDV), are widespread and cause high levels of mortality in poultry worldwide. Wild birds may play an important role in the maintenance of Avian orthoavulavirus 1 in nature. Prior to 2014, most of the lentogenic NDV strains isolated from Central Asia were obtained from the avian order Anseriformes (ducks and geese). Wild birds were monitored from 2014–2016 to detect the circulation of NDV. A total of 1522 samples belonging to 73 avian species were examined, and 26 positive samples were identified. The isolates of Avian orthoavulavirus 1 belonged to three genotypes: viruses from doves (Columbiformes) and cormorants (Suliformes) were attributed to the velogenic genotypes VI and XIII, respectively, while the isolate from poultry belonged to lentogenic genotype I. The isolation of Avian orthoavulavirus 1 from doves may confirm their role as a reservoir of pigeon paramyxoviruses (antigenic variant of the genotype VI NDV) in nature and indicates the potential threat of introduction of velogenic strains into the poultry population. Our study describes an epizootic scenario in Kazakhstan among cormorants with mortality among juveniles of up to 3 wk of age and isolation of the NDV from apparently healthy birds. These observations may support the idea that cormorants are one of the potential reservoirs and victims of velogenic Avian orthoavulavirus 1 in Central Asia. The seasonal migrations of cormorants may partially contribute to viral dissemination throughout the continent; however, this hypothesis needs more evidence.

Infectious bursal disease (IBD) virus (IBDV) is the causative agent of a highly contagious and immunosuppressive disease of chickens with huge economic losses to the poultry industry despite extensive vaccination. Analysis of isolated IBDV field strains from vaccinated birds would greatly improve the current immunization regimens and support the development of vaccines that offer better immunity. The study investigated the genetic characteristics and pathologic features of IBDVs in commercial broiler chicken farms, as well as the effect of IBDV infection on the efficacy of vaccination against avian influenza virus (AIV) and Newcastle disease virus (NDV) under field conditions. A preliminary diagnosis of IBD was made on the basis of the flock history and the characteristic gross pathologic findings. Microscopically, lymphoid depletion in bursal follicles with infiltration of lymphomononuclear cells along with cystic cavitations reflected the IBDV infection. The molecular analysis confirmed the IBDV infection in (57.1%) of tested flocks. Upon phylogenetic analysis of the VP2 hypervariable region of 14 Egyptian IBDVs, most viruses (n = 12) were clustered within the genogroup 3, while two viruses were closely related to attenuated vaccine isolates in genogroup 1. The analysis of the amino acid (aa) sequences revealed that most of the strains possessed five consistent aas at the VP2 protein (222A, 242I, 256I, 294I, and 299S), which are characteristic for the very virulent IBDV (vvIBDV). Serology indicated the immunosuppressive effect of IBDV, which is represented by a decrease (1.6–2.6 and 1.4–2.6 mean log ₂) in the hemagglutination inhibition titer of the low pathogenic AIV subtype H9N2 and NDV, respectively. The examined IBDVs showed a high mutation rate within the hypervariable domain of the VP2 peptide. The results highlighted the need for carrying out an inclusive surveillance of IBDV infections in chicken flocks in Egypt.

Fowl adenovirus (FAdV) infection is an emerging problem in the world poultry industry, especially in broilers, as the causal agent of inclusion body hepatitis or hepatitis-hydropericardium syndrome. From December 2017 to January 2019, we recorded 116 cases of suspected hepatitis-hydropericardium syndrome in chicken farms throughout Indonesia. Necropsy was done on each farm site with three to five freshly dead birds per farm. Tissue samples were collected in virus transport medium and frozen at –20 C. The virus was cultivated in 9-day-old fertilized specific-pathogenic-free chicken eggs. FAdV was detected using polymerase chain reaction with a published primer set. The polymerase chain reaction products were sequenced and subjected to a BLAST search. The phylogeny was inferred using the neighbor-joining method and tested using the bootstrap test. FadV-D and -E are present in Indonesia and confirmed in 40 of 116 suspected cases. The affected chicken ages were 27.27 ± 8.94 days. Most affected farms were raising broiler chickens. The only typical clinical sign was unusual daily mortality of >1%, while the three most frequent pathologic lesions were swelling and hemorrhage of kidney and liver, as well as hydropericardium. To reduce economic loss, a vaccine should be developed immediately.

A bioinformatics approach using single-nucleotide polymorphism (SNP) analysis was performed to improve the current real-time reverse transcription–PCR (RRT-PCR) tests for the rapid detection of Newcastle disease virus (NDV). In total, 422 NDV complete genomes were analyzed using the Virus Pathogen Resource to compare the conservation of the primer and probe sequences and to select regions to develop new RRT-PCR tests. The sensitivity and specificity of the three new RRT-PCR tests targeting the nucleoprotein (NP) and polymerase (L) genes were optimized and were compared with established tests for NDV detection. The SNP analysis was also used to identify the number of mismatches between selected primers/probes and the NDV complete genome sequences. The SNP analysis, averaged over the entire primer or probe, showed the primer/probe sequences of three new tests were more conserved than the primer/probe sequences of the commonly used test targeting the matrix (M) gene. The M RRT-PCR test was compared with the new tests on a panel of 46 viruses, comprising 31 NDV isolates. Limit of detection (LOD) varied from 1.3 to 3.7 log 50% egg-infective doses using five isolates from different genotypes by all tests. The two RRT-PCR tests targeting the L and M genes detected three out of five isolates with the lowest LOD. The NP and M RRT-PCR tests had the lowest and highest rates of genetic variants, respectively, among all probes. Because currently used tests are likely to miss some isolates, the availability of validated alternative tests provides alternatives for detection of viral variants that can be rapidly deployed to diagnostic laboratories.

Chickens in live bird markets (LBMs) from six different regions of Tanzania were surveyed for Newcastle disease (ND) virus (NDV) and avian influenza virus in 2012. ELISA-based serology, virus isolation, and characterization, including pathotyping was conducted. Virulent NDV was isolated from almost 10% of the tested samples, with two distinct genotypes being detected. One genotype was similar to recent viruses circulating in Kenya and Uganda, which share a northern border with Tanzania. Several viruses of this genotype were also isolated from Tanzania in 1995, the last time surveillance for NDV was conducted in the country. The second genotype of virus from Tanzania was closely related to viruses from Mozambique, a southern neighbor, and more distantly to viruses from South Africa, Botswana, and several European countries. Partial fusion gene sequence from the isolated viruses showed identical fusion cleavage sites that were compatible with virulent viruses. Selected viruses were tested by the intracerebral pathogenicity index, and all viruses tested had scores of >1.78, indicating highly virulent viruses. Serology showed only a third of the chickens had detectable antibody to NDV, suggesting that vaccination is not being commonly used in the country, despite the availability of vaccines in agricultural-related markets. All samples were taken from clinically healthy birds, and it is believed that the birds were sold or slaughtered before showing ND clinical signs. LBMs remain a biosecurity risk for farmers through the return of live infected birds to the farm or village or the movement of virus on fomites, such as uncleaned wooden cages.

The aim of the present investigation is to report the prevalence of spontaneous fractures associated with leg skeletal pathology and compromised welfare in commercial broiler chickens. Our studies focused on fractures of different leg segments (femur, tibiotarsus, tarsometatarsus) detected as incidental findings during pathoanatomic examinations in cases of rickets, tibial dyschondroplasia (TD), and femoral head necrosis (FHN). The morphogenetic and etiopathogenetic aspects of the findings were further investigated through histopathologic, bacteriologic, and bone mineral analyses. The gross anatomy study showed that in about 10% of bones affected by rickets-specific lesions, fractures of the proximal tibiotarsus were present. A relatively low percentage (6.5%) of fractures of the same anatomic location could be attributed to TD lesions. The highest prevalence of fractures (68.5%), mainly of the proximal femur, was associated with FHN and osteomyelites. The results from the large-scale field surveys allowed us to confirm that the prevalence of spontaneous bone fractures of the legs in broiler chickens was largely associated with FHN, rickets, and TD. The poor vascularization of the grown prehypertrophic cartilage in cases of rickets and TD, as well as the osteolytic lesions in FHN, resulted in degenerative, necrobiotic processes which may entail bone fractures.

Retrospective analysis of pigeon necropsy submissions to the California Animal Health and Food Safety Laboratory System from 2000 to 2018 revealed 14 submissions diagnosed with rotavirus A hepatic necrosis or “reoviruslike” viral hepatitis. Nine of the 14 submissions (64%) occurred in 2018. Submissions were racing pigeons and squab breeders from flocks with increased mortality. Juvenile and adult pigeons were submitted with a history of depression, diarrhea, regurgitation, labored breathing, and weakness. Flock morbidity peaked at 80% and mortality at 28%. The most consistent findings on postmortem examination were variably congested, mottled, and enlarged livers and spleens. Microscopically, mild to severe hepatic necrosis was observed with variable bile duct hyperplasia, sinusoidal congestion, hemosiderosis, and portal lymphoplasmacytic inflammation. Rotavirus A was detected in hepatocytes and inflammatory cells by immunohistochemistry. Negative-stain electron microscopy identified viral particles consistent with a member of Reoviridae in all negatively stained liver homogenates. Eleven cases were analyzed by reverse transcriptase-PCR targeting rotavirus A viral protein (VP) 6 and VP7 genes. Subsequent phylogenetic analysis of the VP6 and VP7 sequences compared to published Chinese, Nigerian, and German rotavirus A VP6 and VP7 sequences demonstrated the formation of two and three distinct clades, respectively. To the authors’ knowledge, rotavirus A hepatic necrosis in pigeons has not been previously reported in the United States and represents a significant emerging disease for the pigeon industry due to the potential for high flock mortality and lost production.

The aim of the present study was to evaluate the effect of a commercial Bacillus direct-fed microbial (DFM) on aflatoxin B1 toxic effects, performance, and biochemical and immunologic parameters in broiler chickens. Ninety 1-day-old Cobb 500 male broiler chicks were raised in floor pens for a period of 21 days. Chicks were neck-tagged, individually weighed, and randomly allocated to one of three groups: Negative control (basal feed), aflatoxin B1 (basal feed + 2 ppm AFB1), and DFM (basal feed + 2 ppm AFB1 + Bacillus direct-fed microbial). Each group had three replicates of 10 chickens (n = 30/group). Body weight and body weight gain were calculated weekly, while feed intake and feed conversion ratio were determined when broilers were 21 days old. On day 21, all chickens were bled, gastrointestinal samples were collected, and spleen and bursa of Fabricius were weighed. This study confirmed that 2 ppm of AFB1 causes severe detrimental effects on performance, biochemical parameters, and immunologic parameters, generating hepatic lesions in broiler chickens (P < 0.05). However, it was also observed that DFM supplementation provided beneficial effects that might help to improve gut barrier function, anti-inflammatory and antioxidant activities, as well as humoral and cellular immunomodulation. The results of the present study suggest that this Bacillus-DFM added at a concentration of 10⁶ spores/gram of feed can be used to counteract the negative effects that occur when birds consume diets contaminated with AFB1, showing beneficial effects on performance parameters, relative organ weights, hepatic lesions, immune response, and serum biochemical variables. The addition of this Bacillus-DFM might mitigate and decrease aflatoxicosis problems in the poultry industry, improving food security, alleviating public health problems, and providing economic benefits. Future studies are needed to fully elucidate the specific mechanisms by which this Bacillus-DFM counteracts the toxic effects of aflatoxin B1.

Marek's disease (MD) is a complex pathology of chickens caused by MD virus (MDV) 1 and is observed as paralysis, immune suppression, neurologic signs, and the rapid formation of T-cell lymphomas. The incidence of MD in commercial broilers is largely controlled via vaccination, either in ovo or at hatch with live attenuated vaccines, i.e., turkey herpesvirus (HVT) or a bivalent combination of HVT with the MDV 2 strain (SB1). To further extend the protection conferred by bivalent HVT/SB-1, recombinant HVTs encoding transgenes of other avian viruses have similarly been used for in ovo administration. Despite decades of use, the specific mechanisms associated with vaccine-induced protection remain obscure. Additionally, the mechanistic basis for vaccine synergism conferred by bivalent HVT/SB-1, compared with HVT or SB-1 administered alone, is largely unknown. In the present study, we report on temporal changes in innate and acquired immune-patterning gene expression by using ex vivo splenocyte infection and in ovo vaccination models. We report that in the ex vivo splenocyte infection model, by 72 hr postinfection, vaccines induced IFN and IFN-stimulated gene expression, with lesser proinflammatory cytokine induction. For several genes (TLR3, IFN-γ, OASL, Mx1, NOS2A, and IL-1β), the effects on gene expression were additive for HVT, SB1, and HVT/SB1 infection. We observed similar patterns of induction in in ovo–vaccinated commercial broiler embryos and chicks with HVT/SB-1 or recombinant HVT–based bivalent combination (HVT-LT/SB-1). Furthermore, HVT/SB-1 or HVT-LT/SB-1 in ovo vaccination appeared to hasten immune maturation, with expression patterns suggesting accelerated migration of T and natural killer cells into the spleen. Finally, HVT/SB-1 vaccination resulted in a coordinated induction of IL-12p40 and downregulation of suppressors of cytokine signaling 1 and 3, indicative of classical macrophage 1 and T-helper 1 patterning.

Turkey arthritis reovirus (TARV) causes tenosynovitis in turkeys, resulting in decreased profits for producers due to the increase in morbidity, mortality, and feed conversion ratio. There is limited information on TARV epidemiology, including the dynamics of diagnostic submissions to veterinary diagnostic laboratories. In this study, we retrospectively analyzed 719 cases of lameness in turkeys submitted to the Minnesota Veterinary Diagnostic Laboratory from March 2010 to May 2018. Almost all submissions were tendon pools, which were tested by virus isolation and/or real-time reverse transcription–polymerase chain reaction. Most of the submissions were from Minnesota. We found 52% of the submitted cases to be positive for TARV. The TARV-positive submissions increased considerably in the last few years. There was no statistical evidence that TARV diagnostic submissions were seasonal, although positive submissions were higher in January, April, July, and December. TARV-positive submissions also increased as flocks aged. In summary, we found that TARV submissions have increased in the last few years, have varied over time, and are correlated with age of the bird. This information is important guidance for conducting more studies to understand TARV infection dynamics.

The effect of aspirin on intestinal lesions was evaluated in birds undergoing an experimental challenge with Clostridium perfringens as part of a model for inducing subclinical necrotic enteritis (SNE). Broilers were raised on clean wood shavings and randomly assigned to three treatments: Uninfected (U), Infected (I), and Infected + Aspirin (I+A; 0.025% acetylsalicylic acid in drinking water during days 21–25). Birds in the I and I+A groups were gavaged with Eimeria maxima on day 18 and their feed was inoculated with C. perfringens (1 × 10⁹ CFU/bird) during days 23–25. On day 26, birds were euthanatized, intestinal lesions were evaluated, and intestinal tissue was collected for qPCR assessment of genes thought to be involved in the immune response to SNE: IL-1β, IL-10, MMP-2, and MMP-7. Birds in the I+A group had more-severe and numerous lesions compared to the I group. For all genes except MMP-2, expression was upregulated in the I group compared to the U group, but did not differ between the I and I+A groups. These results indicate that aspirin exacerbated the intestinal lesions associated with this disease. Aspirin could play a role in the development of a reliable and consistent model for the induction of necrotic enteritis under experimental settings.

Mycoplasma gallisepticum (MG) is the most pathogenic avian mycoplasma species. It affects commercial and noncommercial poultry and wild birds. Current MG sequence typing methods rely on the partial sequence of one or more surface antigen genes. Multilocus sequence typing (MLST), a widely used typing method for many human and animal pathogens, relies on conserved housekeeping genes. Recently, MLST assays have been developed for Mycoplasma synoviae (MS) and Mycoplasma iowae. Additionally, a whole genome–based core genome MLST (cgMLST) assay has been developed for MG and MS. However, cgMLST can be implemented only on pure isolates and cannot be applied to clinical samples. Here, we have developed a seven-locus–based MLST scheme for MG that can be applied directly on clinical samples without the need for isolation. The seven loci were selected from 425 genes recently used for the cgMLST assay. A total of 101 diverse MG samples, including isolates and clinical samples, were typed with the newly developed seven-locus MLST. The phylogeny and discriminatory power of the seven-locus MLST were evaluated and compared with the cgMLST and gene-targeted sequencing methods currently used for MG sequence typing. The seven-locus MLST provided optimum discriminatory power and congruent phylogeny to cgMLST. Additionally, a database for MG MLST was created and is currently available for public use online. This assay will increase accessibility to MG sequence typing and provide a stable and expandable nomenclature compatible with cgMLST. The seven-locus MLST assay represents an important tool for epidemiologic investigation of MG that can contribute to better control and eradication efforts.

Surveys of mycotoxins worldwide have shown that deoxynivalenol (DON), fumonisins (FB), and zearalenone (ZON) are the most abundant Fusarium mycotoxins (FUS) in European poultry feed, in both the level and the frequency of contamination. Previous studies reported that a combination of FUS at concentrations that individually are not toxic may negatively affect animals. However, although toxic thresholds and regulatory guidelines exist for FUS, none account for the risk of multiple contamination, which is the most frequent. The aim of this study was to compare DON, FB, and ZON toxicity, alone and in combination, in male turkey poults. Ground cultured toxigenic Fusarium strains were incorporated in corn–soybean-based feed in five experimental diets: control diet, containing no mycotoxins, DON diet (5 mg DON/kg), FB diet (20 mg FB1 + FB2/ kg), ZON diet (0.5 mg ZON/kg), and DONFBZON diet (5, 20, and 0.5 mg/kg of DON, FB1 + FB2, and ZON, respectively). Seventy male Grade Maker turkeys were reared in individual cages on mycotoxin-free diets from 0 to 55 days of age. On the 55th day, the turkeys were weighed and divided into five groups each comprising 14 birds. Each group was fed one of the five experimental diets for a period of 14 days. On the 70th day of age, feed was withheld for 8 hr, at which time a blood sample was collected, and then all the turkeys were killed, autopsied, and different tissues sampled. The weight of the different organs, analyses of performance, biochemistry, histopathology, oxidative damage, and testis toxicity revealed no significant effects attributable to FUS. Measurement of sphingolipids in the liver revealed an increase in the sphinganine to sphingosine ratio in turkeys fed diets containing FB, but had no apparent consequences in terms of toxicity. Finally, only slight differences were found in some variables and the results of this study showed no interactions between DON, FB, and ZON. Taken together, results thus suggest that the maximum tolerated levels established for individual contamination by DON, FB, and ZON can also be considered safe in turkeys fed with combinations of these FUS for a period of 14 days.

Infectious bursal disease (IBD) is an economically important disease of young chickens caused by an Avibirnavirus, the infectious bursal disease virus (IBDV). The causative virus is highly resilient in poultry environments and vaccination is the most effective measure for IBDV control. However, both the suspected neutralization of highly attenuated strains by maternal antibodies and the assumed virulence of partly attenuated strains have limited the implementation of conventional live IBDV vaccine strains in pre- and posthatch chicks. Nevertheless, preliminary data have raised questions about the validity of this prevailing dogma. To investigate the possible application of a live IBDV intermediate plus vaccine strain, the IBDV MB-1, to maternally immunized chicken embryos and day-of-hatch chicks, four large-scale field trials have been conducted in distinct global locations. The four trials have measured the relative safety, IBDV immunization parameters, and production performances of MB-1 vs. the established live and immune complex IBDV vaccines in a variety of commercial broiler systems. The overall health and production performances in all four trials have been similar or better in the MB-1 groups. The results challenge the prevailing notion that live IBDV strains may be neutralized or break through maternal immunity and induce permanent damage to the young broiler chick's immune response. A delayed replication phenomenon following parenteral administration of the live IBDV vaccine strain has been observed, while the delayed replication mechanism remains to be elucidated. This study's findings warrant further investigation of conventional live IBDV vaccine strains as an alternative for pre- and posthatch broilers active immunization.

Avian influenza (AI) virus (AIV) subtype H9N2 continues to cause significant outbreaks among commercial and backyard poultry in Pakistan. Despite this, the characterization of H9N2 viruses in avian hosts other than chickens in Pakistan has not been thoroughly investigated. In this study, 12 low pathogenicity avian influenza viruses subtype H9N2 were isolated from peacocks (n = 4), ducks (n = 4), pheasants (n = 2), geese (n = 1), and black swans (n = 1) in Pakistan during 2016 and were characterized on the basis of the hemagglutinin (HA) and neuraminidase genes. All of the viruses possessed an amino acid substitution Q226L in the receptor-binding site of the HA protein, which is known to contribute to increased viral replication and virulence in mammals. In addition, phylogenetic studies showed that these H9N2 AIVs belonged to the Middle East B genetic group of sublineage G1 and were very similar to viruses isolated from an outbreak in chickens in Pakistan in 2017. This demonstrates an epidemiologic link between poultry and other avian species, which is a fact to consider in future H9N2 disease management programs.

Gallibacterium is a genus of the family of Pasteurellaceae. It is well known as a commensal inhabitant of the respiratory and reproductive tract of healthy chickens. But in the last years, Gallibacterium anatis is increasingly reported in field cases with a decrease in laying performance due to infections of the reproductive tract. The aim of the present study was to investigate the implication of G. anatis infection in layer flocks facing a decrease in laying performance in Morocco. Birds were received from five different laying hen farms in two regions in Morocco showing a drop of egg production. Necropsy revealed 46.1 % (24/52) of sampled birds showed variable lesions in ovaries, salpinx, and trachea. In fact, 24 birds were affected by salpingitis, 18 by oophoritis, and 11 birds by atrophy of ovaries. Furthermore, tracheitis was observed in 24 birds. Bacteriological investigation was done from different organs, and G. anatis was found in ovaries (n = 20), trachea (n = 17), and cloaca (n = 3). Identification was based on growth morphology, Gram staining, and biochemical properties. Additionally, polymerase chain reaction test using specific primers for the genus identification was carried out. All isolates showed bands of 925 bp specific for G. anatis expressing the virulent toxin GtxA. Antibiotic resistance testing was performed and revealed that isolates were sensitive to enrofloxacin, florfenicol, and gentamycin but resistant to ampicillin, erythromycin, oxytetracycline, and sulfamethoxazole-trimethoprim. The present study is the first report of G. anatis in Morocco, demonstrating the need for further epidemiologic investigations as well as in regard to antibiotic resistance development.

Goose astrovirus is a novel and distinct astrovirus that causes fatal visceral gout in 4- to 21-day-old goslings. Goose parvovirus is the etiologic agent of Derzsy disease, an acute, contagious, and fatal disease that affects mainly young goslings. This paper describes the clinical signs and gross and histopathologic features of co-infection with astrovirus and goose parvovirus. Clinical signs and history included increased mortality, depression, anorexia, enteritis, joint swelling, and paralysis. Postmortem examination showed a considerable amount of urate covering the internal organs, especially the heart, liver, and kidney. Some goslings had swollen duodenum and ileum. Histologic lesions in the kidney, liver, spleen, lung, proventriculus, and brain included hemorrhage, congestion, edema, cell necrosis, inflammatory cell infiltration, and an eosinophilic protein-like substance in renal tubules. The extensive infiltration of heterophil myelocytes into the kidney, spleen, liver, lung, bursa of Fabricius, and pancreas is a new finding.