Enhanced Protection by Recombinant Newcastle Disease Virus Expressing Infectious Bronchitis Virus Spike Ectodomain and Chicken Granulocyte-Macrophage Colony-Stimulating Factor.

We previously reported that recombinant Newcastle disease virus LaSota (rLS) expressing infectious bronchitis virus (IBV) Arkansas (Ark)-type trimeric spike (S) ectodomain (Se; rLS/ArkSe) provides suboptimal protection against IBV challenge. We have now developed rLS expressing chicken granulocyte-macrophage colony-stimulating factor (GMCSF) and IBV Ark Se in an attempt to enhance vaccine effectiveness. In the current study, we first compared protection conferred by vaccination with rLS/ArkSe and rLS/ArkSe.GMCSF. Vaccinated chickens were challenged with virulent Ark, and protection was determined by clinical signs, viral load, and tracheal histomorphometry. Results showed that coexpression of GMCSF and the Se from rLS significantly reduced tracheal viral load and tracheal lesions compared with chickens vaccinated with rLS/ArkSe. In a second experiment, we evaluated enhancement of cross-protection of a Massachusetts (Mass) attenuated vaccine by priming or boosting with rLS/ArkSe.GMCSF. Vaccinated chickens were challenged with Ark, and protection was evaluated. Results show that priming or boosting with the recombinant virus significantly increased cross-protection conferred by Mass against Ark virulent challenge. Greater reductions of viral loads in both trachea and lachrymal fluids were observed in chickens primed with rLS/ArkSe.GMCSF and boosted with Mass. Consistently, Ark Se antibody levels measured with recombinant Ark Se protein-coated ELISA plates 14 days after boost were significantly higher in these chickens. Unexpectedly, the inverse vaccination scheme, that is, priming with Mass and boosting with the recombinant vaccine, proved somewhat less effective. We concluded that a prime and boost strategy by using rLS/ArkSe.GMCSF and the worldwide ubiquitous Mass attenuated vaccine provides enhanced cross-protection. Thus, rLS/GMCSF coexpressing the Se of regionally relevant IBV serotypes could be used in combination with live Mass to protect against regionally circulating IBV variant strains.

Protección incrementada por el virus recombinante de la enfermedad de Newcastle que expresa el ectodominio de la espícula del virus de la bronquitis infecciosa y el factor estimulante de colonias de granulocitos y macrófagos del pollo. Anteriormente se reportó que la cepa LaSota recombinante del virus de la enfermedad de Newcastle (rLS) que expresa el ectodominio de la espícula trimérica (S) de tipo Arkansas (Ark) del virus de la bronquitis infecciosa (IBV) (Se; rLS/ArkSe) proporciona una protección subóptima contra la exposición al virus de la bronquitis infecciosa. Ahora se ha desarrollado hemos desarrollado una cepa LaSota recombinante (rLS) que expresa el factor estimulante de colonias de granulocitos y macrófagos de pollo (GMCSF) y la espícula del virus de bronquitis Arkansas en un intento para mejorar la efectividad de la vacuna. En el estudio actual, primero se comparó la protección conferida por la vacunación con los virus rLS/ArkSe y rLS/ArkSe.GMCSF. Los pollos vacunados se desafiaron con un virus Arkansas virulento y la protección se determinó mediante los signos clínicos, la carga viral y la histomorfometría de la tráquea. Los resultados mostraron que la coexpresión del factor estimulante de colonias de granulocitos y macrófagos de pollo y la espícula de la cepa recombinante LaSota redujo significativamente la carga viral traqueal y las lesiones traqueales en comparación con los pollos vacunados con el virus rLS/ArkSe. En un segundo experimento, se evaluó el incremento en la protección cruzada por una vacuna atenuada de Massachusetts (Mass) mediante la primovacunación o la vacunación de refuerzo con rLS/ArkSe.GMCSF. Los pollos vacunados fueron desafiados con el virus Arkansas y se evaluó la protección. Los resultados mostraron que la primovacunación o la vacunación de refuerzo con el virus recombinante aumentó significativamente la protección cruzada conferida por el virus Massachusetts contra el desafío virulento con el virus Arkansas. Se observaron mayores reducciones de las cargas virales en los fluidos traqueales y lagrimales en pollos primovacunadoss con rLS/ArkSe.GMCSF y con vacunación de refuerzo con Massachusetts. De manera consistente, los niveles de anticuerpos Ark Se medidos con placas de ELISA recubiertas con proteína Ark Se recombinante a los 14 días después del refuerzo fueron significativamente más altos en estos pollos. De manera inesperada, el esquema de vacunación inverso, es decir, la primovacunación con Massachusetts y el refuerzo con la vacuna recombinante, resultó menos efectivo. Se concluye que una estrategia de primovacunación y refuerzo mediante el uso de rLS/ArkSe.GMCSF y la vacuna atenuada con Massachusetts usada en todo el mundo proporciona una protección cruzada aumentada. Por tanto, el virus rLS/GMCSF que coexpresa la proteína de la espícula de los serotipos regionales relevantes de bronquitis infecciosa podría usarse en combinación con una vacuna viva Massachusetts para proteger contra cepas variantes del virus de la bronquitis infecciosa que circulan regionalmente.

Infectious Bronchitis Virus Immune Responses in the Harderian Gland upon Initial Vaccination.

In recent years, Arkansas Delmarva Poultry Industry (ArkDPI)-derived infectious bronchitis (IB) virus (IBV) vaccines have been used to characterize the immune responses of chickens subsequent to vaccination on day of hatch or beyond. Perhaps because ArkDPI vaccines display increased heterogeneity, the results on cell immune responses have shown ambiguity. In the current study, we investigated the effects of vaccination with a highly stable and homogeneous Massachusetts (Mass)-type vaccine on days 1 or 7 of age on Harderian gland (HG) responses. Confirming previous studies, both IBV serum antibodies and lachrymal IgA levels were greater upon vaccination on day 7 compared with vaccination on day 1 of age. Unlike results with ArkDPI viruses, a clear trend was detected for both B and T cells in the HG after Mass-type vaccination. Consistent with antibody responses, B- and T-helper (CD3+CD4+) cell frequencies were higher in birds vaccinated on day 7 of age. Cytotoxic T cells (CD3+CD8+) were also increased compared with chickens vaccinated on day 1 of age. Depending on the most likely age of IB outbreaks to occur in a particular region, postponing the first IBV vaccination may optimize immune responses.

Nota de Investigación- Respuestas inmunes al virus de la bronquitis infecciosa en la glándula de Harder después de una vacunación inicial En los últimos años, las vacunas contra el virus de la bronquitis infecciosa (IB) derivadas de la cepa Arkansas Industria Avícola de Delmarva (ArkDPI) se han utilizado para caracterizar las respuestas inmunes de los pollos después de la vacunación en el día de la eclosión o en días posteriores. Posiblemente debido a que las vacunas ArkDPI muestran una mayor heterogeneidad, los resultados sobre las respuestas inmunes celulares han mostrado ambigüedad. En el presente estudio, se investigaron los efectos de la vacunación con una vacuna de tipo Massachusetts (Mass) que es altamente estable y homogénea en los días uno o siete de edad con relación a las respuestas en la glándula de Harder (HG). Confirmando estudios previos, tanto los anticuerpos séricos contra el virus de la bronquitis infecciosa como los niveles de IgA lacrimal fueron mayores tras la vacunación al día siete en comparación con la vacunación al primer día de edad. A diferencia de los resultados con los virus ArkDPI, se detectó una clara tendencia para las células B y T en la glándula de Harder después de la vacunación con el tipo Mass. De acuerdo con las respuestas de anticuerpos, las frecuencias de células B y T cooperadoras (CD3+ CD4+) fueron más altas en las aves vacunadas en el día siete de edad. Las células T citotóxicas (CD3+CD8+) también aumentaron en comparación con los pollos vacunados en el primer día de edad. Dependiendo de la edad más probable en que ocurran brotes por bronquitis infecciosa en una región en particular, posponer la primera vacuna contra el IBV puede optimizar las respuestas inmunes.

Kidney Cell-Adapted Infectious Bronchitis ArkDPI Vaccine is Stable and Protective.

We previously demonstrated that adaptation of an embryo-attenuated infectious bronchitis virus (IBV) Arkansas (Ark) Delmarva Poultry Industry (DPI)-derived vaccine to chicken embryo kidney (CEK) cells (CEKp7) shifted the virus population towards homogeneity in spike (S) and nonstructural protein genes. Moreover, the typical Ark vaccine subpopulations emerging in chickens vaccinated with commercial Ark vaccines were not detected in chickens vaccinated with CEKp7, indicating that kidney-cell adaptation drastically increased the stability of the vaccine virus population in chickens. In the current study both conventional and next-generation sequencing results show that the changes achieved during CEK adaptation remained after five back passages in embryonated chicken egg (ECE). In a first protection study 1-day-old chickens were vaccinated with 104.0 or 105.0 50% embryo infectious doses (EID50)/chicken of the second ECE back passage of CEKp7 (CEKp7e2) and demonstrated protection against Ark virulent (106.0 EID50) challenge. In a second protection trial, protection by CEKp7e2 was compared with protection conferred by an attenuated commercial ArkDPI-derived vaccine different from that which the CEK-adapted virus originated. All vaccinated chicken groups showed a significant reduction of respiratory signs and viral load after Ark virulent challenge compared to unvaccinated-challenged controls. In CEKp7e2 vaccinated chickens viral subpopulations different from the challenge virus were detected after challenge in a marginal number (7%-8%) of chickens. In contrast, IBV S1 sequences that differed from the predominant population in the challenge virus were detected after challenge in a large number (77%) of chickens vaccinated with the commercial Ark attenuated vaccine. The CEK-adapted IBV ArkDPI-derived vaccine is a stable and effective vaccine, which drastically reduces the emergence of Ark-like viruses both at vaccination and after challenge.

Inactivation of Avian Influenza Virus in Nonpelleted Chicken Feed.

Corn stored outside could become contaminated with avian influenza virus (AIV) from wild bird droppings. AIV-contaminated ingredients could pass into the poultry flocks in nonpelleted chicken feed. The efficacy of two disinfectants at inactivating AIV in chicken feed was evaluated. Both Termin-8 (a blend of formaldehyde, propionic acid, terpenes, and surfactant) and Finio (a blend of approved phytochemicals and carboxylic acids) effectively inactivated AIV in chicken feed. Because stability of infectious AIV in chicken feed is limited, we evaluated addition of protein (skim milk powder) to the virus suspension. Protein prolonged the stability of AIV in untreated feed to 24 hr at 24 C. However, both feed disinfectants were able to inactivate the virus in feed even when protected by skim milk powder.

Effects of Adaptation of Infectious Bronchitis Virus Arkansas Attenuated Vaccine to Embryonic Kidney Cells.

The population structure of an embryo-attenuated infectious bronchitis virus (IBV) Arkansas (Ark) Delmarva Poultry Industry (DPI)-derived vaccine was characterized during serial passages in chicken embryo kidney (CEK) cells and after back-passage in embryonated chicken eggs (ECE) and in chickens. Both conventional and deep-sequencing results consistently showed population changes occurred during adaptation to CEK cells. Specifically, 13 amino acid (aa) positions seemed to be targets of selection when comparing the vaccine genome prior to and after seven passages in CEK (CEKp7). Amino acid changes occurred at four positions in the spike (S) gene and, at two positions in the S gene, large shifts in frequencies of aa encoding were observed. CEK adaptation shifted the virus population towards homogeneity in S. The changes achieved in the S1 gene in CEKp7 were maintained after a back-passage in ECE. Outside the S gene, aa changes at three positions and large shifts in frequencies at four positions were observed. Synonymous nucleotide changes and changes in noncoding regions of the genome were observed at eight genome positions. Inoculation of early CEK passages into chickens induced higher antibody levels and CEKp4 induced increased respiratory signs compared to CEKp7. From an applied perspective, the fact that CEK adaptation of embryo-attenuated Ark vaccines reduces population heterogeneity, and that changes do not revert after one replication cycle in ECE or in chickens, provides an opportunity to improve commercial ArkDPI-derived vaccines.

S1 of distinct IBV population expressed from recombinant adenovirus confers protection against challenge.

Protective properties of three distinct infectious bronchitis virus (IBV) Ark Delmarva poultry industry (ArkDPI) S1 proteins encoded from replication-defective recombinant adenovirus vectors were investigated. Using a suboptimal dose of each recombinant virus, we demonstrated that IBV S1 amino acid sequences showing > or = 95.8% amino acid identity to the S1 of the challenge strain differed in their ability at conferring protection. Indeed, the S1 sequence of the IBV population previously designated C4 (AdIBVS1.C4), which protected the most poorly, differs from the S1 sequence of population C2 (AdIBVS1.C2), which provided the highest protection, only at amino acid position 56. The fact that a change in one amino acid in this region significantly altered the induction of a protective immune response against this protein provides evidence that the first portion of S1 displays relevant immunoprotective epitopes. Use of an optimal dose of AdIBVS1.C2 effectively protected chickens from clinical signs and significantly reduced viral load after IBV Ark virulent challenge. Moreover, increased numbers of both IgA and IgG IBV-specific antibody secreting lymphocytes were detected in the spleen after challenge. The increased response detected for both IgA and IgG lymphocytes after challenge might be explained by vaccine-induced B memory cells. The fact that a single vaccination with Ad/IBVS1.C2 provides protection against IBV challenge is promising, because Ad-vectored vaccines can be mass delivered by in ovo inoculation using automated in ovo injectors.

Avian influenza adenovirus-vectored in ovo vaccination: target embryo tissues and combination with Marek's disease vaccine.

We investigated embryo tissues targeted by replication competent adenovirus (Ad)-free recombinant Ad expressing a codon-optimized avian influenza (AI) H5 gene from A/turkey/WI/68 (AdH5) when injected into 18-day embryonated eggs. We also evaluated the effects of concurrent in ovo vaccination with the experimental AdH5 vaccine and commercially available Marek's disease virus (MDV) vaccine combinations Rispens/turkey herpesvirus (HVT) or HVT/SB-1. Computed tomography indicates that in ovo injection on day 18 of incubation places the solution in the amnion cavity, allantoic cavity, or both. Ad DNA was consistently detected in the chorioallantoic membranes as well as in the embryonic bursa of Fabricius, esophagus, and thymus 3 days postinoculation. H5 expression in these tissues also was detected by immunofluorescence assay. These results indicate possible swallowing of vaccine virus contained in the amnion. In contrast, vaccine localization in the allantoic fluid would have allowed bursal exposure through the cloaca. When the AdH5 vaccine was used in combination with MDV, chickens responding to the AdH5 vaccine had similar AI antibody levels compared with AdH5-only-vaccinated birds. However, combined vaccinated groups showed reduced vaccine coverage to AI, suggesting some level of interference. The combination of AdH5 with MDV Rispens/HVT affected the vaccine coverage to AI more severely. This result suggests that the replication rate of the more aggressive Rispens strain of serotype 1 may have interfered with the Ad-vectored vaccine. Increasing the Ad concentration produced similar AI antibody titers and AI vaccine coverage when applied alone or in combination with the HVT/SB-1 vaccine. Ad DNA was detected in hatched chickens 2 days after hatch but was undetectable on day 9 after hatch. MDV DNA was detected in feather follicles of all vaccinated birds at 12 days of age. Thus, Ad-vector vaccination does not interfere with the efficacy of MDV vaccination by using any of the commonly used vaccine strains.

Effects of chicken anemia virus and infectious bursal disease virus in commercial chickens.

The effects of chicken anemia virus (CAV) and infectious bursal disease virus (IBDV) coinfection in commercial layer-type and meat-type (broiler) chickens with specific maternal immunity were evaluated. In addition, the broiler progeny used had been vaccinated in ovo against IBDV. Layer chickens were inoculated intramuscularly on day 3 of age with CAV and orally on day 7 of age with an IBDV standard strain (APHIS). Broiler chickens were exposed to CAV and/or an IBDV variant strain (AL2) via the drinking water on days 3 and 14 of age. Following CAV and IBDV inoculation neither mortality nor overt clinical disease was observed in any layer or broiler group. In spite of maternal immunity against both IBDV and CAV, mean hematocrits of all layer groups inoculated with CAV (CAV, CAV + APHIS) were lower than uninfected chickens. IBDV APHIS alone or in combination with CAV did not affect the layer weight gain. However, on day 30 of age and concomitantly with maternal antibody decay, bursa lymphocyte depletion became evident in CAV + APHIS-infected layer chickens. These birds (CAV + APHIS) also seroconverted to IBDV on day 35 of age. CAV persisted at low levels in the layer chickens throughout the experimental period in CAV- and CAV+APHIS-infected chickens. Similarly, infected broiler chickens did not show changes in weight gain. Compared to CAV-infected or uninfected controls, CAV+AL2- and AL2-infected broiler chickens showed significant lymphocyte depletion in the bursa as assessed both by bursal indices and histomorphometry. Broilers also seroconverted to IBDV after day 30 of age confirming that bursal lymphocyte depletion was due to IBDV resuming replication. Thymus histomorphometry revealed significant lymphocyte depletion in all infected broiler groups at 30 days of age, but only in CAV+AL2-infected broiler chickens at 41 days of age, suggesting that IBDV infection delayed repopulation of the thymus.

New macrocyclic trichothecenes from Baccharis megapotamica.

The isolation and structural elucidation of biologically active baccharinoids B1 [11a], B2 [12a], B3 [5a], and B7 [6a] are reported with crystal structure determinations of baccharinoid B7 and of the triacetate of baccharinoid B2. All four compounds are isomeric with 11a/12a and 5a/6a being epimeric at C13'.