A turkey rhinotracheitis outbreak caused by the environmental spread of a vaccine-derived avian metapneumovirus

Avian metapneumovirus (aMPV) subtype A was isolated from 7-week-old turkeys showing respiratory disease typical of turkey rhinotracheitis. Comparison of the virus sequence with previously determined vaccine marker sequences showed that the virulent virus had originated from a licensed live subtype A aMPV vaccine. The vaccine had neither been in use on the farm within a period of at least 6 months nor had it been used on farms within a distance of approximately 5 km. Isolation of the virus and exposure to naive turkeys caused disease typical of a virulent aMPV field strain. The study shows that disease was caused by exposure to aMPV vaccine-derived virus that was present in the environment, and indicates that such virus is able to circulate for longer than was previously envisaged.     

Subtype B avian metapneumovirus resembles subtype A more closely than subtype C or human metapneumovirus with respect to the phosphoprotein,and second matrix and small hydrophobic proteins

Avian metapneumovirus (aMPV) subtype B (aMPV/B) nucleotide sequences were obtained for the phosphoprotein (P), second matrix protein (M2), and small hydrophobic protein (SH) genes. By comparison with sequences from other metapneumoviruses, aMPV/B was most similar to subtype A aMPV (aMPV/A) relative to the US subtype C isolates (aMPV/C) and human metapneumovirus (hMPV). Strictly conserved residues common to all members of the Pneumovirinae were identified in the predicted amino acid sequences of the P and M2 protein-predicted amino acid sequences. The Cys(3)-His(1) motif, thought to be important for binding zinc, was also present in the aMPV M2 predicted protein sequences. For both the P and M2-1 protein-predicted amino acid sequences, aMPV/B was most similar to aMPV/A (72 and 89% identity, respectively), having only approximately 52 and 70% identity, respectively, relative to aMPV/C and hMPV. Differences were more marked in the M2-2 proteins, subtype B having 64% identity with subtype A but < or = 25% identity with subtype C and hMPV. The A and B subtypes of aMPV had predicted amino acid sequence identities for the SH protein of 47%, and less than 20% with that of hMPV. An SH gene was not detected in the aMPV/C. Phylogenetically, aMPV/B clustered with aMPV/A, while aMPV/C grouped with hMPV.     

Reproducibility of swollen sinuses in broilers by experimental infection with avian metapneumovirus subtypes A and B of turkey origin and their comparative pathogenesis.

Swollen head syndrome (SHS) associated with avian metapneumovirus (aMPV) subtype A or subtype B in broilers and broiler breeders has been reported worldwide. Data about pathogenesis of aMPV subtypes A and B in broilers are scarce. It has been difficult to reproduce swollen sinuses in chickens with aMPV under experimental conditions. In the field, SHS in broilers is suspected to be induced by combined infections with different respiratory pathogens. The objectives of the present study were to compare the pathogenesis of subtypes A and B aMPV in commercial broilers and to investigate the reproducibility of clinical disease. In two repeat experiments, commercial broilers free of aMPV maternal antibodies were inoculated with aMPV subtypes A and B of turkey origin. The clinical signs such as depression, coughing, nasal exudates, and frothy eyes appeared at 4 days post inoculation, followed by swelling of periorbital sinuses at 5 days post inoculation. Higher numbers of broilers showed clinical signs in subtype-B-inoculated compared with subtype-A-inoculated groups. Seroconversion to aMPV was detectable from 10 to 11 days post inoculation. The appearance of serum aMPV enzyme-linked immunosorbent assay antibodies and the clearance of the aMPV genome coincided. Subtype B aMPV showed a broader tissue distribution and longer persistence than subtype A. Histopathological changes were observed in the respiratory tract tissues of aMPV-inoculated broilers, and also in paraocular glands, such as the Harderian and lachrymal glands. Overall, our study shows that representative strains of both aMPV turkey isolates induced lesions in the respiratory tract, accompanied by swelling of infraorbital sinuses, indicating the role of aMPV as a primary pathogen for broilers.     

Evidence of avian metapneumovirus subtype C infection of wild birds in Georgia,South Carolina,Arkansas and Ohio,USA

Metapneumoviruses (MPVs) were first reported in avian species (aMPVs) in the late 1970s and in humans in 2001. Although aMPVs have been reported in Europe and Asia for over 20 years, the virus first appeared in the United States in 1996, leaving many to question the origin of the virus and why it proved to be a different subtype from those found elsewhere. To examine the potential role of migratory waterfowl and other wild birds in aMPV spread, our study focused on determining whether populations of wild birds have evidence of aMPV infection. Serum samples from multiple species were initially screened using a blocking enzyme-linked immunosorbent assay. Antibodies to aMPVs were identified in five of the 15 species tested: American coots, American crows, Canada geese, cattle egrets, and rock pigeons. The presence of aMPV-specific antibodies was confirmed with virus neutralization and western blot assays. Oral swabs were collected from wild bird species with the highest percentage of aMPV-seropositive serum samples: the American coots and Canada geese. From these swabs, 17 aMPV-positive samples were identified, 11 from coots and six from geese. Sequence analysis of the matrix, attachment gene and short hydrophobic genes revealed that these viruses belong to subtype C aMPV. The detection of aMPV antibodies and the presence of virus in wild birds in Georgia, South Carolina, Arkansas and Ohio demonstrates that wild birds can serve as a reservoir of subtype C aMPV, and may provide a potential mechanism to spread aMPVs to poultry in other regions of the United States and possibly to other countries in Central and South America.     

Changes in the bovine herpesvirus 1 genome during acute infection,after reactivation from latency,and after superinfection in the host animal

Summary Three subtypes, as defined byHindIII restriction endonuclease (RE) analysis patterns [17], of bovine herpesvirus 1 (BHV 1) were used to inoculate seronegative, BHV 1-free cattle. These included: infectious bovine rhinotracheitis virus (IBRV), subtype 1.1; infectious pustular vulvovaginitis virus (IPPV) isolate K22, subtype 1.2b; and IPVV isolate FI, subtype 1.2a. Nasal, vaginal, and buffy coat samples were taken for virus isolation from each animal. RE analysis was done on virus isolates collected during acute infection, after reactivation from latency, and after reactivation followed by superinfection with a subtype of BHV 1 that differed from the primary inoculation virus. Changes occurred in the BHV1 genome after only 1 passage in the host animal, and varied from tissue to tissue within the same animal. Viruses reactivated from latency also displayed genome variability. Only animals that received IPVV as the primary inoculation virus were successfully superinfected. After superinfection, cattle shed both superinfecting and reactivated viruses, and genome variability was observed. These data suggest that the application of RE analysis in diagnostic and epidemiologic studies of BHV 1 is limited to analysis between types and subtypes, and is not applicable for the examination of isolates from within a BHV 1 subtype.     

Distribution of HIV-1 subtypes among HIV-seropositive patients in the interior of Côte d'Ivoire

Limited data exist on the distribution of HIV-1 subtypes in C?te d'Ivoire. The aim of this study is to describe the distribution of genetic subtypes of HIV-1 strains in six regions of C?te d'Ivoire. In 1997, we consecutively collected blood from 172 HIV-1-infected patients from six regional tuberculosis treatment centers. Peripheral blood mononuclear cells (PBMCs) from these people were analyzed by a restriction fragment-length polymorphism (RFLP) assay that involves a sequential endonuclease digestion of a 297-base pair polymerase chain reaction (PCR) fragment; plasma samples were tested by a V3-loop peptide enzyme immunoassay (PEIA). DNA sequencing of the protease or env genes was performed on all samples discordant in the two assays as well as a random sample of the concordant subtyped samples. Of 172 specimens, 3 were PCR-negative, and 169 were putatively classified as subtype A by RFLP. The 3 PCR-negative samples were unequivocally subtyped A by PEIA. Of the 169 RFLP subtype A samples, 159 (94%) were subtyped A by PEIA. Of the 10 discordant samples, PEIA testing classified 3 as subtype C, 2 as D, and 5 as F. Sequencing of the env gene classified these samples as 1 subtype A, 4 Ds, and 5 Gs. Thus, 163 (95%) of the specimens were subtype A, 3 subtype D, 4 subtype G, 1 A/D, and 1 A/G (IbNG) circulating recombinant forms (CRF). In conclusion, most HIV-1-infected tuberculosis patients throughout the interior of C?te d'Ivoire are infected with HIV-1 subtype A, which are very likely the A/G (IbNG) CRF. The uniform distribution of this subtype makes C?te d'Ivoire a potential site for vaccine trials.     

Compromised T-cell immunity in turkeys may lead to an unpredictable avian metapneumovirus vaccine response and variable protection against challenge

Avian metapneumovirus (aMPV) is an important respiratory pathogen of turkeys with considerable economic impact on poultry production. Although vaccination is widely used for the control of the disease, questions regarding vaccine safety and efficacy remain to be elucidated. This report describes the problems associated with reproducibility of the aMPV-vaccine response, comparing T-lymphocyte-compromised and T-cell-intact turkeys. In three consecutive experiments, turkeys partially depleted of T-lymphocytes by treatment with cyclosporin A as well as untreated turkeys were vaccinated with a commercial live aMPV subtype A (aMPV-A) vaccine at 2 weeks of age. Two weeks later they were challenged with a virulent aMPV-A strain. Despite similar genetic background of the turkeys, comparable housing conditions under isolation and the application of the same aMPV-A vaccine, considerable variation was observed among the experiments regarding replication of the vaccine virus, vaccine-induced clinical signs and protection against challenge infection. The results indicate that differences in the outcome of aMPV-A vaccination may be associated with T-lymphocyte suppression and additionally with an interfering aMPV-B vaccine exposure at the hatchery in two of the experiments. Our study provides possible explanations for the variable protection provided by aMPV vaccines under field conditions.     

DNA cloned from the ayw subtype of hepatitis B virus

DNA from the ayw subtype of hepatitis B virus (HBV) was ligated into the EcorI site of DNA from plasmid pBR322 and propagated in E coli chi 776. A plasmid with a 3200 base pair insert (pHBV-1) was isolated and the cloned HBV DNA was mapped with restriction endonucleases. Differences were found in restriction endonuclease cleavage sites for DNAs from HBV of subtype ayw and adr.     

Genotyping of varicella zoster virus strains isolated in Mongolia

This study analyzed 50 varicella zoster virus (VZV) samples collected during 2004 to 2007 from patients with VZV infection, who were treated at the National Center of Communicable Diseases, Ulan-Bator, Mongolia. The method based on amplification of specific DNA fragments of the ORF21, ORF22, and ORF50 genes was used, followed by the sequencing and detection of the status of characteristic point mutations in these fragments. The results indicated that the collected samples belonged to genotypes J (62%), M1 (18%), E1 (12%), E2 (4%), and M2 (4%). Moreover, restriction endonuclease polymorphism in ORF 62 for the cleavage site Smal and Mspl, in ORF 38 and ORF 54 for the cleavage site Pstl and Bgll were analyzed. All the samples were Sma- Msp-. All samples with genotype E were Pst+ Bgl-; all samples with genotype M1 and M2 were Pst+ Bgl+. Out of 31 samples with genotype J, 29 and 2 were Pst+ Bgl+ and Pst+ Bgl+, respectively. The study could identify the genotypes of VZV circulating in Mongolia and confirmed the absence of mutations characteristic for the vaccine strain.     

Comparison of the full-length genome sequence of avian metapneumovirus subtype C with other paramyxoviruses

We determined the nucleotide (nt) sequence of the small hydrophobic (SH), attachment glycoprotein (G), and RNA polymerase (L) genes, plus the leader and trailer regions of the Colorado strain of Avian metapneumovirus subtype C (aMPV/C) in order to complete the genome sequencing. The complete genome comprised of 13,134 nucleotides, with a 40 nt leader at its 3' end and a 45 nt trailer at its 5' end. The aMPV/C L gene was the largest with 6173 nt and consisting of a single open reading frame encoding a 2005 amino acids (aa) protein. Comparison of the aMPV/C SH, G, and L nt and predicted aa sequences with those of Human metapneumoviruses (hMPV) revealed higher nt and aa sequence identities than the sequence identities between the aMPV subtypes A, B, C, and D, supporting earlier finding that aMPV/C was closer evolutionary to hMPV than the other aMPV subtypes.     

Avian metapneumovirus infection of chicken and turkey tracheal organ cultures: comparison of virus–host interactions

Avian metapneumovirus (aMPV) is a pathogen with worldwide distribution, which can cause high economic losses in infected poultry. aMPV mainly causes infection of the upper respiratory tract in both chickens and turkeys, although turkeys seem to be more susceptible. Little is known about virus–host interactions at epithelial surfaces after aMPV infection. Tracheal organ cultures (TOC) are a suitable model to investigate virus–host interaction in the respiratory epithelium. Therefore, we investigated virus replication rates and lesion development in chicken and turkey TOC after infection with a virulent aMPV subtype A strain. Aspects of the innate immune response, such as interferon-α and inducible nitric oxide synthase mRNA expression, as well as virus-induced apoptosis were determined. The aMPV-replication rate was higher in turkey (TTOC) compared to chicken TOC (CTOC) (P?<?0.05), providing circumstantial evidence that indeed turkeys may be more susceptible. The interferon-α response was down-regulated from 2 to 144 hours post infection in both species compared to virus-free controls (P?<?0.05); this was more significant for CTOC than TTOC. Inducible nitric oxide synthase expression was significantly up-regulated in aMPV-A-infected TTOC and CTOC compared to virus-free controls (P?<?0.05). However, the results suggest that NO may play a different role in aMPV pathogenesis between turkeys and chickens as indicated by differences in apoptosis rate and lesion development between species. Overall, our study reveals differences in innate immune response regulation and therefore may explain differences in aMPV – A replication rates between infected TTOC and CTOC, which subsequently lead to more severe clinical signs and a higher rate of secondary infections in turkeys.     

Nucleotide and predicted amino acid sequence-based analysis of the avian metapneumovirus type C cell attachment glycoprotein gene: phylogenetic analysis and molecular epidemiology of U.S. pneumoviruses

A serologically distinct avian metapneumovirus (aMPV) was isolated in the United States after an outbreak of turkey rhinotracheitis (TRT) in February 1997. The newly recognized U.S. virus was subsequently demonstrated to be genetically distinct from European subtypes and was designated aMPV serotype C (aMPV/C). We have determined the nucleotide sequence of the gene encoding the cell attachment glycoprotein (G) of aMPV/C (Colorado strain and three Minnesota isolates) and predicted amino acid sequence by sequencing cloned cDNAs synthesized from intracellular RNA of aMPV/C-infected cells. The nucleotide sequence comprised 1,321 nucleotides with only one predicted open reading frame encoding a protein of 435 amino acids, with a predicted M(r) of 48,840. The structural characteristics of the predicted G protein of aMPV/C were similar to those of the human respiratory syncytial virus (hRSV) attachment G protein, including two mucin-like regions (heparin-binding domains) flanking both sides of a CX3C chemokine motif present in a conserved hydrophobic pocket. Comparison of the deduced G-protein amino acid sequence of aMPV/C with those of aMPV serotypes A, B, and D, as well as hRSV revealed overall predicted amino acid sequence identities ranging from 4 to 16.5%, suggesting a distant relationship. However, G-protein sequence identities ranged from 72 to 97% when aMPV/C was compared to other members within the aMPV/C subtype or 21% for the recently identified human MPV (hMPV) G protein. Ratios of nonsynonymous to synonymous nucleotide changes were greater than one in the G gene when comparing the more recent Minnesota isolates to the original Colorado isolate. Epidemiologically, this indicates positive selection among U.S. isolates since the first outbreak of TRT in the United States.