Histomonas meleagridis is a facultative anaerobic parasite, which can cause a common poultry disease known as histomoniasis. The species and age of the birds impacts on the susceptibility, with turkey being the most susceptible species. Chickens are less susceptible to H. meleagridis than turkeys and usually serve as reservoir hosts. Here, the diagnosis of an outbreak of histomoniasis in backyard Sanhuang chickens is described. The primary diagnosis was made based on clinical symptoms, general changes at necropsy, histopathology, and the isolation and cultivation of parasites. The pathogen was further confirmed by cloning, PCR identification, and animal inoculation tests. A strain of H. meleagridis, named HM-JSYZ-C, with a higher pathogenicity level in chickens was obtained. The study lays a foundation for further investigations into H. meleagridis and histomoniasis in chickens.
Animals ; Birds ; Chickens ; Clone Cells ; Cloning, Organism ; Diagnosis ; Parasites ; Polymerase Chain Reaction ; Poultry Diseases ; Protozoan Infections ; Turkey ; Turkeys ; Virulence

To expand the epidemiological understanding of Newcastle disease in Jeju Province, Korea, active surveillance was extensively performed through a virological examination for poultry farms and wild birds in Jeju Province during 2007~2008. Samples (swabs or fresh feces) were collected from a total of 6,485 birds including 6,405 domestic birds (chickens, ducks, pheasants, geese, quails, turkeys, and ostriches) and 80 wild birds. A total of 24 hemagglutinating agents were isolated from domestic birds on fourteen farms including five Korean native chicken, one layer chicken, two broiler chicken, four duck and two pheasant farms. The hemagglutinating agents were all identified as lentogenic NDV based on the reverse transcriptase polymerase chain reaction, sequence analysis of amino acids on the F cleavage site and mean death time in chicken embryos. The F gene-based phylogenetic analysis revealed that the NDV isolates were classified into genotypes 1 or 2 of class II. These lentogenic viruses were closely related to NDV vaccine strains used in Jeju Province. Active surveillance conducted for Newcastle disease indicates no scientific evidence of virulent NDV infection in chickens in Jeju Province, Korea since 2005.
Amino Acids ; Animals ; Birds ; Chickens ; Ducks ; Embryonic Structures ; Geese ; Genotype ; Korea ; Newcastle Disease ; Newcastle disease virus ; Poultry ; Quail ; Reverse Transcriptase Polymerase Chain Reaction ; Sequence Analysis ; Turkeys

Avian metapneumovirus (aMPV) causes an acute and highly contagious upper respiratory tract infection in turkeys and chickens. In this study, a competitive ELISA (C-ELISA) was developed for the detection of antibodies to aMPV in chicken sera and/or their egg yolks. This assay is based on the competitive binding of monoclonal antibody with serum antibodies to recombinant aMPV N protein expressed by a recombinant baculovirus. The C-ELISA showed specificity and sensitivity of 100% and 98.0%, respectively, when compared to the virus neutralization test. In specific pathogen-free chickens experimentally infected with aMPV SC1509 strain, the C-ELISA started to detect antibodies to aMPV as early as 5 days post infection from birds infected with aMPV, while a commercial ELISA kit detected first 10 days post infection. The C-ELISA was similar or superior to a commercial ELISA kit when serum and egg yolk samples collected from chickens on six outbreak farms were tested for diagnosis. The C-ELISA developed in the present work provides a short turnaround time and can be a useful diagnostic and screening tool for aMPV infection in the field.
Antibodies ; Baculoviridae ; Binding, Competitive ; Birds ; Chickens ; Egg Yolk ; Enzyme-Linked Immunosorbent Assay ; Mass Screening ; Metapneumovirus ; Neutralization Tests ; Respiratory Tract Infections ; Sensitivity and Specificity ; Sprains and Strains ; Turkeys ; Viruses

Cochlosoma sp. infection was identified in a single case among 60 stunted diarrheic native turkey poults, Meleagris galopavo. A large number of the flagellated parasites was found free or within the intervillous spaces of the jejunum, ileum and cecum. Moderate enteritis was associated with the parasites. In TEM studies of the parasagittal sections of the parasite, a prominent ventral sucker like disc and flagella emerging from an opening on the ventrodorsal surface of the pyriform uninuclear parasite were found. The morphological characteristics of this protozoan match with those described for Cochlosoma anatis. The parasite could be considered as an intestinal pathogenic protozoan causing stunting and diarrhea in turkeys in Iran.
Animals ; Cecum/parasitology/pathology ; Enteritis/diagnosis/parasitology/veterinary ; Ileum/parasitology/pathology ; Iran ; Jejunum/parasitology/pathology ; Organelles/ultrastructure ; Poultry Diseases/*diagnosis/*parasitology ; Protozoan Infections, Animal/*diagnosis/*parasitology ; Trichomonadida/cytology/*isolation & purification ; Turkeys

BACKGROUND: Validation of hemagglutination inhibition (HI) assays is important for evaluating antibody responses to influenza virus, and selection of erythrocytes for use in these assays is important. This study aimed to determine the correlation between receptor binding specificity and effectiveness of the HI assay for detecting antibody response to pandemic influenza H1N1 (pH1N1) virus. METHODS: Hemagglutination (HA) tests were performed using erythrocytes from 6 species. Subsequently, 8 hemagglutinating units of pH1N1 from each species were titrated by real-time reverse transcription-PCR. To investigate the effect of erythrocyte binding preference on HI antibody titers, comparisons of HI with microneutralization (MN) assays were performed. RESULTS: Goose erythrocytes showed most specific binding with pH1N1, while HA titers using human erythrocytes were comparable to those using turkey erythrocytes. The erythrocyte binding efficiency was shown to have an impact on antibody detection. Comparing MN titers, HI titers using turkey erythrocytes yielded the most accurate results, while those using goose erythrocytes produced the highest geometric mean titer. Human blood group O erythrocytes lacking a specific antibody yielded results most comparable to those obtained using turkey erythrocytes. Further, pre-existing antibody to pH1N1 and different erythrocyte species can distort HI assay results. CONCLUSIONS: HI assay, using turkey and human erythrocytes, yielded the most comparable and applicable results for pH1N1 than those by MN assay, and using goose erythrocytes may lead to overestimated titers. Selection of appropriate erythrocyte species for HI assay allows construction of a more reliable database, which is essential for further investigations and control of virus epidemics.
Adult ; Animals ; Antibodies, Neutralizing/immunology ; Antibodies, Viral/*analysis/immunology ; Chickens ; Erythrocytes/*metabolism ; Female ; Geese ; *Hemagglutination Inhibition Tests ; Horses ; Humans ; Influenza A Virus, H1N1 Subtype/genetics/immunology/*metabolism ; Influenza, Human/epidemiology/immunology/virology ; Male ; Middle Aged ; Neutralization Tests ; Pandemics ; Swine ; Turkeys

Avian leukosis virus subgroup J (ALV-J) is an avian retrovirus that can induce myelocytomas. A high-frequency mutation in gene envelope endows ALV-J with the potential for cross-species transmission. We wished to ascertain if the ALV-J can spread across species under selection pressure in susceptible and resistant hosts. First, we inoculated (in turn) two susceptible host birds (specific pathogen-free (SPF) chickens and turkeys). Then, we inoculated three resistant hosts (pheasants, quails and ducks) to detect the viral shedding, pathologic changes, and genetic evolution of different isolates. We found that pheasants and quails were infected under the selective pressure that accumulates stepwise in different hosts, and that ducks were not infected. Infection rates for SPF chickens and turkeys were 100% (16/16), whereas those for pheasants and quails were 37.5% (6/16) and 11.1% (3/27). Infected hosts showed immune tolerance, and inflammation and tissue damage could be seen in the liver, spleen, kidneys and cardiovascular system. Non-synonymous mutation and synonymous ratio (NS/S) analyses revealed the NS/S in hypervariable region (hr) 2 of pheasants and quails was 2.5. That finding suggested that mutation of isolates in pheasants and quails was induced by selective pressure from the resistant host, and that the hr2 region is a critical domain in cross-species transmission of ALV-J. Sequencing showed that ALV-J isolates from turkeys, pheasants and quails had moved away from the original virus, and were closer to the ALV-J prototype strain HPRS-103. However, the HPRS-103 strain cannot infect pheasants and quails, so further studies are needed.
Amino Acid Sequence ; Animals ; Avian Leukosis ; transmission ; virology ; Avian Leukosis Virus ; classification ; genetics ; physiology ; Chickens ; Ducks ; virology ; Galliformes ; virology ; Host Specificity ; Molecular Sequence Data ; Poultry Diseases ; transmission ; virology ; Quail ; virology ; Sequence Alignment ; Turkeys ; virology ; Viral Envelope Proteins ; chemistry ; genetics ; metabolism

Since 2002, H7 subtype avian influenza viruses (AIVs) have caused more than 100 human infection cases in the Netherlands, Italy, Canada, the United States, and the United Kingdom, with clinical illness ranging from conjunctivitis to mild upper respiratory illness to pneumonia. On March 31st, three fatal cases caused by infection of a novel reassortant H7N9 subtype were reported in Shanghai City and Anhui Province in China. With the ability of H7 subtype to cause severe human disease and the increasing isolation of subtype H7 AIVs, we highlighted the need for continuous surveillance in both humans and animals and characterization of these viruses for the development of vaccines and anti-viral drugs.
Animals ; Chickens ; Ducks ; Humans ; Influenza A virus ; genetics ; isolation & purification ; pathogenicity ; physiology ; Influenza Vaccines ; genetics ; immunology ; Influenza in Birds ; immunology ; prevention & control ; virology ; Influenza, Human ; immunology ; prevention & control ; virology ; Poultry Diseases ; immunology ; prevention & control ; virology ; Turkeys

Phylogenetic studies of influenza A viruses have revealed species-specific lineages of viral genes, and that aquatic birds are the source of all influenza viruses in other animal species including humans, pigs, horses, sea mammals and birds. Influenza pandemics, defined as global outbreaks of the disease due to new antigenic subtypes, have exacted a high death toll from human populations. The most devastating pandemic, the so-called Spanish influenza of 1918 to 1919, resulted from an H1N1 virus and caused the deaths of at least 20 million people worldwide. Other much less catastrophic pandemics occurred in 1957 (Asian influenza [H2N2 virus]), 1968 (Hong Kong influenza [H3- N2 virus]), and 1977 (Russian influenza [H1N1 virus]). It is noteworthy that both the Asian and Hong Kong outbreaks were caused by hybrid viruses, or reassortants, that harbored a combination of avian and human viral genes. Avian influenza viruses are therefore key contributors to the emergence of human influenza pandemics. Fowl plague caused by highly pathogenic avian influenza A viruses is a constant threat to the poultry industry, but until the Hong Kong influenza outbreak, there was no zoonotic evidence that avian viruses could be transmitted directly to humans. In May 1997, an H5N1 influenza virus was isolated from a 3-year-old boy in Hong Kong, who died of extensive influenza pneumonia. By the end of 1997, a total of 18 cases of human influenza as an emerging infection had been identified, all caused by the same H5N1 virus. With this outbreak, it became clear that the virulence potential of these viruses extended to humans. The H5N1 isolates were not reassortants like the 1957 and 1968 pandemic strains; instead, all of the viral genes had originated from an avian virus. It will be critical to identify the molecular determinants that allow efficient transmission and replication of avian influenza viruses in humans, so that probable pandemics can be anticipated well before the death toll begins to mount. And health officials should begin to consider the production of emergency vaccines against all 15 existing HA subtypes of influenza virus. Also, given the existence of a vast number of influenza viruses in the aquatic wild-bird reservoir, we must accept the fact that they always pose pandemic threats. Thus, it is recommended that poultry (chickens, turkeys, etc.), domesticated ducks, and pigs be kept in ecologically controlled, secure houses with limited access to wild birds.
Animals ; Asian Continental Ancestry Group ; Birds ; Child, Preschool ; Disease Outbreaks ; Ducks ; Emergencies ; Genes, Viral ; Hong Kong ; Horses ; Humans ; Influenza A virus ; Influenza A Virus, H1N1 Subtype ; Influenza A Virus, H5N1 Subtype ; Influenza in Birds* ; Influenza, Human ; Male ; Mammals ; Orthomyxoviridae ; Pandemics* ; Pneumonia ; Poultry ; Swine ; Turkeys ; Vaccines ; Virulence

Avian metapneumovirus (aMPV) causes upper respiratory tract infections in chickens and turkeys. Although the swollen head syndrome (SHS) associated with aMPV in chickens has been reported in Korea since 1992, this is the study isolating aMPV from chickens in this country. We examined 780 oropharyngeal swab or nasal turbinate samples collected from 130 chicken flocks to investigate the prevalence of aMPV and to isolate aMPV from chickens from 2004-2008. Twelve aMPV subtype A and 13 subtype B strains were detected from clinical samples by the aMPV subtype A and B multiplex real-time reverse transcription polymerase chain reaction (RRT-PCR). Partial sequence analysis of the G glycoprotein gene confirmed that the detected aMPVs belonged to subtypes A and B. Two aMPVs subtype A out of the 25 detected aMPVs were isolated by Vero cell passage. In animal experiments with an aMPV isolate, viral RNA was detected in nasal discharge, although no clinical signs of SHS were observed in chickens. In contrast to chickens, turkeys showed severe nasal discharge and a relatively higher titer of viral excretion than chickens. Here, we reveal the co-circulation of aMPV subtypes A and B, and isolate aMPVs from chicken flocks in Korea.
Animals ; Antibodies, Viral/blood ; Base Sequence ; *Chickens ; Glycoproteins/chemistry/genetics ; Metapneumovirus/immunology/*isolation & purification ; Molecular Sequence Data ; Paramyxoviridae Infections/immunology/*veterinary/virology ; *Phylogeny ; Poultry Diseases/immunology/*virology ; RNA, Viral/chemistry/genetics ; Respiratory Tract Infections/immunology/*veterinary/virology ; Reverse Transcriptase Polymerase Chain Reaction/veterinary ; Sequence Alignment ; Sequence Analysis, DNA ; Serotyping ; Specific Pathogen-Free Organisms ; Turkeys

In order to visually detect H1, N1 and N2 subtype of avian influenza virus (AIV), three reverse transcription loop-mediated isothermal amplification (RT-LAMP) assays were developed. According to the sequences of AIV gene available in GenBank, three degenerate primer sets specific to HA gene of H1 subtype AIV, NA gene of N1 and N2 subtype AIV were designed, and the reaction conditions were optimized. The results showed that all the assays had no cross-reaction with other subtype AIV and other avian respiratory pathogens, and the detection limit was higher than that of conventional RT-PCR. These assays were performed in water bath within 50 minutes. Without opening tube, the amplification result could be directly determined by inspecting the color change of reaction system as long as these assays were fin-ished. Fourteen specimens of H1N1 subtype and eight specimens of H1N2 subtype of AIV were identified from the 120 clinical samples by RT-LAMP assays developed, which was consistent with that of virus isolation. These results suggested that the three newly developed RT-LAMEP assays were simple, specific and sensitive and had potential for visual detection of H1, N1 and N2 subtype of AIV in field.
Animals ; Chickens ; DNA Primers ; genetics ; Ducks ; Influenza A Virus, H1N1 Subtype ; classification ; genetics ; isolation & purification ; Influenza A Virus, H1N2 Subtype ; classification ; genetics ; isolation & purification ; Influenza A virus ; classification ; genetics ; isolation & purification ; Influenza in Birds ; diagnosis ; virology ; Nucleic Acid Amplification Techniques ; methods ; Poultry Diseases ; diagnosis ; virology ; Reverse Transcription ; Turkeys