Fifty-six reverse transcriptions followed by a polymerase chain reaction (RT-PCR) were developed and/or assessed to detect and to type turkey rhinotracheitis virus (TRTV). Twenty-seven primers corresponding to sequences either common to both A and B viruses, or type-specific were respectively defined in the fusion (F), attachment (G) and nucleocapsid (N) proteins genes. Only one N-based RT-PCR detected 21/21 TRTVs isolated in four countries since 1985. Molecular typing (RT-PCR) and antigenic typing (ELISA) showed that TRTV strains antigenically related either to the 3BOC18 (UK/85/1) or to the 86004 (Fr/86/1) viruses belonged to the A or B genomic type respectively. Neither typing approach allowed assignment of two 1985 French isolates (Fr/85/1 and Fr/85/2) to either type A or B, these strains might thus belong to a third type. RT-PCR assays on tracheal and nasal swabs sampled during experimental and field infections significantly outperformed concurrent virus isolation in tissue culture and ELISA: G- and N-based RT-PCRs detected more positive samples than conventional methods. Molecular and serological results were concordant and demonstrated that all the recent French field viruses belonged to type B. Thus, N- and G-based RT-PCR are respectively specific and sensitive tools for rapid diagnosis and typing of TRTV in field samples.
BackgroundInfectious bursal disease virus (IBDV) is a pathogen of worldwide significance to the poultry industry. IBDV has a bi-segmented double-stranded RNA genome. Segments A and B encode the capsid, ribonucleoprotein and non-structural proteins, or the virus polymerase (RdRp), respectively. Since the late eighties, very virulent (vv) IBDV strains have emerged in Europe inducing up to 60% mortality. Although some progress has been made in understanding the molecular biology of IBDV, the molecular basis for the pathogenicity of vvIBDV is still not fully understood.Methodology, Principal FindingsStrain 88180 belongs to a lineage of pathogenic IBDV phylogenetically related to vvIBDV. By reverse genetics, we rescued a molecular clone (mc88180), as pathogenic as its parent strain. To study the molecular basis for 88180 pathogenicity, we constructed and characterized in vivo reassortant or mosaic recombinant viruses derived from the 88180 and the attenuated Cu-1 IBDV strains. The reassortant virus rescued from segments A of 88180 (A88) and B of Cu-1 (BCU1) was milder than mc88180 showing that segment B is involved in 88180 pathogenicity. Next, the exchange of different regions of BCU1 with their counterparts in B88 in association with A88 did not fully restore a virulence equivalent to mc88180. This demonstrated that several regions if not the whole B88 are essential for the in vivo pathogenicity of 88180.Conclusion, SignificanceThe present results show that different domains of the RdRp, are essential for the in vivo pathogenicity of IBDV, independently of the replication efficiency of the mosaic viruses.
I nfluenza A viruses are enveloped viruses of the Alphainfluenzavirus genus in the Orthomyxoviridae family. Their negative-stranded RNA genome consists of 8 segments encoding a total of 10-14 proteins. Avian influenza viruses (AIVs) are classified on the basis of antigenic differences in their surface glycoproteins, hemagglutinin (H1-H16) and neuraminidase (N1-N9) (1). H5 and H7 subtypes can become highly pathogenic avian influenza (HPAI) viruses after the evolution of multiple basic amino acids in the cleavage site of hemagglutinin protein (2,3). This mutation enables the virus to replicate efficiently in all organs, causing a severe and often fatal systemic disease. In contrast, the cleavage site of hemagglutinin in low pathogenicity AIVs lacks these multiple amino acids, restricting viral replication to the respiratory and digestive tracts. Low pathogenicity AIVs cause subclinical or mild disease that can be aggravated by secondary infections (4,5). Because H5 and H7 AIVs can evolve to be highly pathogenic, the diseases caused by these subtypes are notifiable to national and international bodies (6). Since 1996, highly pathogenic H5 viruses of the A/goose/Guangdong/1/96 (Gs/GD/96) lineage have caused recurrent outbreaks with high death rates in birds. These HPAIs are categorized into 10 distinct clades (0-9) on the basis of hemagglutinin sequences (7). These clades are found in Asia; a few have spread to Africa, Europe, and North America (8-10). Europe experienced major introductions of H5N1 of clade 2.2 during 2005-2007 and H5N8 of clade 2.3.4.4 during 2014-2020 (11-14). Many reassortments were observed on Gs/Gd/1/96-like viruses, especially within clade 2.3.4.4. The reassortments generated several subtypes including H5N1, H5N2, H5N5, H5N6, and H5N8 (11,15-17). During winter 2016-17, twenty-nine countries in Europe reported 1,576 cases of Gs/Gd/1/96like H5N8 infections in wild birds and 1,134 in poultry, especially domestic ducks (18). During this outbreak, researchers identified 6 HPAI A(H5N8) genotypes in Europe; 2 of these genotypes were identified using 6 sequences from infected birds in France (19). France had 539 cases of HPAI A(H5N8) infections, 51 in wild birds and 488 in poultry flocks, most of which occurred at duck farms producing foie gras (18). A previous study used spatiotemporal analysis of clinical cases comprising 2 distinct epizootic periods in southwestern France (20). The first period spanned November 28, 2016-February 2, 2017 and comprised 4 spatiotemporal clusters (20). The second period spanned February 3-March 23, 2017 and comprised a single spatiotemporal cluster (20).
Although reovirus infection is one of the major virus diseases of muscovy ducks in France, no vaccine is available and nothing is known about the structure and function of the genes and proteins of the reovirus involved. The complete S3 genome segment of the muscovy duck reovirus strain 89026 has been cloned and the nucleotide and deduced amino acid sequences are reported here. The S3 genome segment is 1201 bp long and possesses the same terminal motifs (5h GCTTTTT and TATTCATC 3h) as the S3 genome segment of known chicken reovirus strains. It contains one open reading frame that encodes a protein of 367 amino acids with a molecular mass of 40n8 kDa. The gene, encoding the σB major outer-capsid protein, was cloned into two different baculovirus transfer vectors and expressed in insect cells as a glutathione S-transferase fusion protein or a non-fused protein. The antigenicity of the two recombinant proteins was demonstrated by immunoblot assay. The potential immunogenic role of σB protein was studied in a protection assay against reovirus infection of specific-pathogen-free muscovy ducks. No antibodies could be detected by ELISA or immunoblot in ducks immunized with the recombinant proteins and no significant protection was noted after the challenge. However, whereas the weights of wild-type baculovirus-infected and challenge-control ducks were significantly lower than those of unchallenged ducks, the weights of male ducks previously immunized with the σB recombinant proteins did not differ significantly from males of either group. This work is the first to provide molecular data for a duck reovirus.
In February 2006, a highly pathogenic avian influenza (HPAI) H5N1 virus was isolated from Common Pochards (Aythia ferina) in the Dombes region of France, an important migrating and wintering waterfowl area. Thereafter, HPAI H5N1 virus was isolated from 39 swab pools collected from dead waterfowl found in the Dombes, but only from three pooled samples collected outside of this area but located on the same migration flyway. A single turkey farm was infected in the Dombes. The epizootic lasted 2 mo and was restricted to the Dombes area. Virus-positive pools were detected in 20 of 1,200 ponds and infected Mute Swans (Cygnus olor) represented 82% of the virus-positive pools. Other infected species included Common Pochard (n=4), Grey Heron (Ardea cinerea, n=1), Eurasian Buzzard (Buteo buteo, n=1), and Greylag Goose (Anser anser, n=1). Despite intensive monitoring during and after the outbreak, HPAI H5N1 virus was not isolated from healthy wild birds. Our results are consistent with an HPAI H5N1-virus introduction into the Dombes via migrating ducks. These birds could have been pushed west by a severe cold spell in central Europe where the virus had already been detected. The Mute Swan served as an excellent epidemiologic sentinel during this outbreak; swans appear to be highly sensitive to infection with these viruses and swan mortality was easy to detect. During the outbreak, the mortality rates for wild birds remained moderate and the virus affected a limited number of species.
Control of H5/H7 low-pathogenic avian influenza (LPAI) virus circulation is a major issue regarding animal and public health consequences. To improve vaccines and to prevent vaccinated poultry from becoming infected and from shedding wild viruses, we initiated studies targeting prevention of H7 infection through DNA vaccines encoding H7 and M1 viral proteins from an Italian H7N1 LPAI virus isolated from poultry in 1999. More recently, we expressed recombinant H7 and M1 proteins in the baculovirus system to assess whether they might enhance immunity when given as a boost after DNA vaccination. The protection afforded by three vaccine combinations-DNA/DNA, DNA/protein, protein/protein-given 3 wk apart were experimentally compared in 20 specific-pathogen-free chickens per group. Ten days after the boost, chickens were challenged with a homologous (Italian H7N1 LPAI) or heterologous (French H7N1 LPAI isolated from mallards in 2001) virus. Tracheal and cloacal shedding was measured by a matrix gene (M)-based real-time reverse transcription polymerase chain reaction assay and compared with that displayed by unvaccinated infected controls. After the homologous challenge, chickens of every vaccinated group displayed a significant decrease in cloacal shedding, whereas tracheal shedding was not significantly reduced in the protein/protein group. After the heterologous challenge, only the DNA/DNA group showed a nonsignificant decrease in tracheal shedding. According to these two trials, prime-boost DNA/protein vaccination appeared be more advantageous. Further development could be aimed at improving protein expression, shifting subtype (H5), and assessing the interest of proteins as a boost of recombinant vaccines.
Prevalence of avian influenza infection in free-range mule ducks (a cross between Muscovy [Cairina moschata domesticus] and Pekin ducks [Anas platyrhychos domesticus]) is a matter of concern and deserves particular attention. Thus, cloacal swabs were collected blindly from 30 targeted mule flocks at 4, 8, and 12 wk of age between October 2004 and January 2005. They were stored until selection. On the basis of a positive H5 antibody detection at 12 wk of age with the use of four H5 antigens, the samples from eight flocks were selectively analyzed. Positive samples were first screened with a matrix gene-based real-time reverse transcriptase-polymerase chain reaction assay before virus isolation. Eight avian influenza subtypes (H5N1, H5N2, H5N3, H6N2, H6N8, and H11N9) and three avian paramyxovirus type 1 viruses were isolated. All 11 are characterized as low pathogenicity (LP) and avirulent, respectively, by in vivo tests and, when relevant, nucleotide sequencing of the hemagglutinin (or fusion [F]) protein cleavage site. Regarding H5 isolates, all of their eight genes belong to the avian lineage and some particular genetic traits were determined. H5 genes were fully sequenced and phylogenetically analyzed; they all belong to the Eurasian lineage, lack additional glycosylation sites, and do not cluster, suggesting separate introductions from the wild reservoir. None were grouped with the Asian isolates. The N1 gene (H5N1 isolate) was very close genetically to an Italian LP-H7N1 gene. Antigenic relationships between these H5 isolates and others were assessed comparatively by crossed hemagglutination inhibition tests. All these data are very useful to control the evolution of H5 viruses at the genetic and antigenic level to better understand the source of new outbreaks (new introductions from wild birds or the result of spread among poultry) and to assess the immunity afforded by available vaccines. These data are useful also to update antigens for avian influenza survey and to choose the most suitable vaccine in the case of preventive vaccination of ducks.
Eight monoclonal antibodies against the Ploufragan strain of Newcastle disease virus were used to characterize 58 virus strains including 29 French isolates. By combining ELISA and haemagglutination inhibition tests, PMV 1 strains were differentiated from other avian PMV 1 and grouped into 7 classes.
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