Circulation and Molecular Characterization of Hemorrhagic Enteritis Virus in Commercial Turkey and Meat Chicken Flocks in Australia.

Currently, there is no available vaccine against hemorrhagic enteritis virus (HEV) in Australia. Although it is assumed that subclinical HEV infections occur and may be associated with an increase in colibacillosis in Australian commercial turkey flocks, the prevalence of infection with this virus in the country is largely unknown. The aims of this study were to determine the extent of HEV infection in commercial flocks in Australia and to investigate the diversity of Australian HEV strains. Serum and spleen samples were collected from breeder and grower turkeys and serum was collected from breeder and grower chickens by the two major poultry integrator companies in Australia. Of the turkey samples, 727/849 (86%) sera were positive for anti-HEV antibodies by ELISA. HEV DNA was detected in 215/278 (77%) spleen samples positive by PCR. Of the meat chicken sera, 115/144 (80%) samples were seropositive. Sequencing the whole genome of three HEV field isolates showed that the Australian strains are highly similar and cluster separately from strains from other geographic regions although several point mutations were shared with HEV strains considered to be virulent. In conclusion, HEV infection is ubiquitous in Australian commercial poultry flocks. The impact of the many genomic point mutations detected in Australian HEV strains on virus pathogenicity is unclear.

Circulación y caracterización molecular del virus de la enteritis hemorrágica en parvadas comerciales de pavo y pollos de engorde en Australia. Actualmente, no existe una vacuna disponible contra el virus de la enteritis hemorrágica (HEV) en Australia. Aunque se supone que se producen infecciones subclínicas por el virus de la enteritis hemorrágica y pueden estar asociadas con un aumento de la colibacilosis en las parvadas comerciales de pavos australianos, se desconoce en gran medida la prevalencia de la infección por este virus en el país. Los objetivos de este estudio fueron determinar la diseminación de la infección por el virus de la enteritis hemorrágica en parvadas comerciales en Australia e investigar la diversidad de cepas del virus de la enteritis hemorrágica australianas. Se recolectaron muestras de suero y bazo de pavos reproductores y de engorda y las dos principales empresas integradoras avícolas de Australia recolectaron suero de pollos reproductores y de engorde. De las muestras de pavo, 727/849 (86%) sueros fueron positivos para anticuerpos contra la enteritis hemorrágica por ELISA. Se detectó ADN del virus de la enteritis hemorrágica en 215/278 (77%) muestras de bazo positivas por PCR. De los sueros de carne de pollo, 115/144 (80%) muestras fueron seropositivas. La secuenciación del genoma completo de tres aislados de campo del virus de la enteritis hemorrágica mostró que las cepas australianas son muy similares y se agrupan por separado de las cepas de otras regiones geográficas, aunque se compartieron varias mutaciones puntuales con las cepas del virus de la enteritis hemorrágica consideradas virulentas. En conclusión, la infección por el virus de la enteritis hemorrágica es ubicua en las parvadas avícola comerciales australianas. No está claro el impacto de las diferentes mutaciones puntuales genómicas detectadas en las cepas australianas del virus de la enteritis hemorrágica sobre la patogenicidad del virus.

Comparison of tracheal and choanal cleft swabs and poultry dust samples for detection of Newcastle disease virus and infectious bronchitis virus genome in vaccinated meat chicken flocks.

This study assessed different methods (tracheal and choanal cleft swabs from individual birds, and poultry dust as a population level measure) to evaluate the shedding kinetics of infectious bronchitis virus (IBV) and Newcastle disease virus (NDV) genome in meat chicken flocks after spray vaccination at hatchery. Dust samples and tracheal and choanal cleft swabs were collected from four meat chicken flocks at 10, 14, 21 and 31 days post vaccination (dpv) and tested for IBV and NDV genome copies (GC) by reverse transcriptase (RT)-PCR. IBV and NDV GC were detected in all sample types throughout the study period. Detection rates for choanal cleft and tracheal swabs were comparable, with moderate and fair agreement between sample types for IBV (McNemar's = 0.27, kappa = 0.44) and NDV (McNemar's = 0.09; kappa = 0.31) GC respectively. There was no significant association for IBV GC in swabs and dust samples (R2 = 0.15, P = 0.13) but NDV detection rates and viral load in swabs were strongly associated with NDV GC in dust samples (R2 = 0.86 and R2 = 0.90, P<0.001). There was no difference in IBV and NDV GC in dust samples collected from different locations within a poultry house. In conclusion, dust samples collected from any location within poultry house show promise for monitoring IBV and NDV GC in meat chickens at a population level and choanal cleft swabs can be used for detection of IBV and NDV GC instead of tracheal swabs in individual birds.

Assessment of A20 infectious laryngotracheitis vaccine take in meat chickens using swab and dust samples following mass vaccination in drinking water.

Infectious laryngotracheitis, caused by the alphaherpesvirus infectious laryngotracheitis virus (ILTV), is an important disease of chickens. Partial control of this disease in meat chickens is commonly achieved by mass vaccination with live virus in drinking water. There is a need for a practical test to evaluate vaccination outcomes. For the Serva ILTV vaccine, quantitative real-time PCR (qPCR) enumeration of ILTV genome copies (GC) in flock level dust samples collected at 7-8 days post vaccination (dpv) can be used to differentiate flocks with poor and better vaccine take. This study aimed to validate this approach for A20, another widely used ILT vaccine in Australia. In four meat chicken flocks vaccinated with A20 in water using two different water stabilization times (20 or 40 min), swabs from the trachea and choanal cleft and dust samples were collected at 0, 7, 14 and 21 dpv. ILTV GC detection in swabs and dust was highest at 7 dpv and at this time ILTV GC load in dust was strongly and positively associated with vaccine take in individual birds assessed by swab samples. Choanal cleft swabs provided significantly fewer ILTV positive results than paired tracheal swab samples but the level of ILTV GC detected was similar. Water stabilization time had only minor effects on vaccination response in favour of the shorter time. Location of dust collection had no effect on viral load measured in dust samples. Dust samples collected at 0 and 7 dpv can be used to assess the vaccination status of flocks.