The booster immunization using commercial vaccines effectively protect chickens against novel variants of infectious bursal disease virus (genotype A2dB1).

The novel variant IBDV (nVarIBDV, genotype A2dB1), characterized by bursal atrophy of fabricius and decreased lymphocytes, has been emerging on a large scale in Asia (including China) since late 2018. nVarIBDV is a new threat to the poultry industry, yet the currently licensed commercial vaccines, including the live viral vector vaccine, IBDV immune complex vaccine or VP2 subunit vaccine, are ineffective against nVarIBDV infection. In this study, specific-pathogen-free (SPF) chickens and broilers divided into 3 groups were vaccinated with the live viral vector vaccine, the VP2 subunit vaccine or the IBDV immune complex vaccine at 1 day-old, respectively. The SPF chickens received a secondary vaccination with the live B87 strain vaccine at 11-day-old. The bursa/body weight ratio, histopathology lesion of the bursa, and the differentiation between infected and vaccinated animals (DIVA) by qRT-PCR confirmed that the live viral vector vaccine or immune complex vaccine plus live B87 strain booster could provide at least 80% protection against the FJ2019-01 strain of nVarIBDV in SPF chickens. The broilers also received a secondary vaccination using a live W2512 G-61 strain vaccine at 14-day-old, and analyses showed that the VP2 subunit vaccine or immune complex vaccine plus the live W2512 G-61 strain booster also provided more than 80% protection against the FJ2019-01 strain of nVarIBDV. Unfortunately, the live viral vector vaccine plus live W2512 G-61 strain booster provided poor to moderate protection against FJ2019-01 in broilers. These findings suggest that combining commercial vaccines with rational booster immunization can effectively protect chickens against an nVarIBDV challenge.

Intranasal booster vaccination of beef steers reduces clinical signs following experimental coinfection with BRSV and BHV-1 without reducing shedding of BRD-associated bacteria.

OBJECTIVE: To determine the efficacy of primary or booster intranasal vaccination of beef steers on clinical protection and pathogen detection following simultaneous challenge with bovine respiratory syncytial virus and bovine herpes virus 1. METHODS: 30 beef steers were randomly allocated to 3 different treatment groups starting at 2 months of age. Group A (n = 10) was administered a single dose of a parenteral modified-live vaccine and was moved to a separate pasture. Groups B (n = 10) and C (10) remained unvaccinated. At 6 months of age, all steers were weaned and transported. Subsequently, groups A and B received a single dose of an intranasal modified-live vaccine vaccine while group C remained unvaccinated. Group C was housed separately until challenge. Two days following vaccination, all steers were challenged with bovine respiratory syncytial virus and bovine herpes virus 1 and housed in a single pen. Clinical and antibody response outcomes and the presence of nasal pathogens were evaluated. RESULTS: The odds of clinical disease were lower in group A compared with group C on day 7 postchallenge; however, antibody responses and pathogen detection were not significantly different between groups before and following viral challenge. All calves remained negative for Histophilus somni and Mycoplasma bovis; however, significantly greater loads of Mannheimia haemolytica and Pasteurella multocida were detected on day 7 postchallenge compared with day -2 prechallenge. CLINICAL RELEVANCE: Intranasal booster vaccination of beef steers at 6 months of age reduced clinical disease early after viral challenge. Weaning, transport, and viral infection promoted increased detection rates of M haemolytica and P multocida regardless of vaccination status.

Immune response after rabies pre-exposure prophylaxis and a booster dose in Australian bat carers.

Periodic vaccination against rabies is essential for individuals at continuing risk of rabies exposure. There is limited evidence on long-term immunogenicity after a 3-dose intramuscular (3IM) pre-exposure prophylaxis (PrEP) and single IM booster dose, thus current guideline recommendations differ in the interval for serology tests following PrEP and boosters. This study investigated post-PrEP and post-booster persistence of antibodies in Australian bat carers. Bat carers who received 3IM PrEP/booster doses and had post-PrEP/booster serology test results were included. The proportion of antibody-negative (<0.5 EU/mL) individuals after PrEP/booster dose were examined. Three hundred and five participants (65.6% females, median age at PrEP 43.1 years) were included. The proportion who were antibody-negative varied depending on the time between 3IM PrEP and the serology test: 8.0% <1 year, 29.8% 1-2 years, 21.2% 2-3 years and 7.7% >3 years. Ninety-one participants receiving booster doses were further assessed. Only one participant was antibody-negative at >3 years after receiving one IM booster dose. Our findings support that a serology test should be performed 1 year after 3IM PrEP, followed by first booster if required. Rabies antibodies persist for many years after receiving the booster doses. The interval between subsequent serology tests and the first booster dose should be no longer than 3 years. Future studies are required to provide more insight into the most appropriate timing of subsequent boosters.

Assessment of tetanus revaccination regimens in horses not vaccinated in the previous year.

A two-dose revaccination against tetanus is recommended for horses over 2 years old in Japan with no history of vaccination in the previous year. Here, the need for two-dose revaccination was evaluated in terms of antibody titers for each vaccine type, namely monovalent or multivalent. There was no difference in antibody titers between one- and two-dose regimens for up to 1 year, except at 8 weeks with the multivalent vaccine, and all horses had sufficient antibody titers for 1 year of tetanus prophylaxis. These results suggest that one-dose revaccination, regardless of the vaccine type, is as effective as two-dose in preventing tetanus for at least 1 year in horses not vaccinated in the previous year.

Controlled release vaccine implants for delivery of booster immunisations.

Most current animal vaccine regimes involve a primary vaccination followed sometime later by a booster vaccination. This presents challenges when vaccinating difficult to access animals such as livestock. Mustering livestock to deliver a vaccine boost is costly and stressful for animals. Thus, we have produced a platform system that can be administered at the same time as the priming immunisation and delivers payload after an appropriate delay time to boost the immune response, without need for further handling of animals. A 30 × 2 mm osmotically triggered polymer implant device with burst-release characteristics delivered the booster dose of a tetanus vaccine. Blood samples were collected from an experimental group that received the priming vaccine and implant on day 0 and control group that received the initial vaccine (tetanus toxoid) and then a bolus dose 28 days later via subcutaneous injection. The two groups showed identical weight gain curves. T cell proliferation following in vitro stimulation with antigen was identical between the two groups at all time points. However, serum IgG antibody responses to the tetanus toxoid antigen were significantly higher in the control group at weeks 8 and 12. The implant capsules stayed at the site of implantation and at week 12 there was evidence of tissue integration. No local reactions at the implant site were observed, other than mild thickening of the skin in half of the experimental group animals and no other adverse health events were recorded in either group.

Chitosan-based formulation of hemagglutinin antigens for oculo-nasal booster vaccination of chickens against influenza viruses.

Avian influenza viruses (AIVs) and especially highly pathogenic (HP) AIVs of the H5 and H7 subtypes are of both veterinary and public health concern worldwide. In response to the demand for effective vaccines against H5N1 HPAIVs, we produced recombinant protein based on hemagglutinin (HA), a protective viral antigen. A fragment of the HA ectodomain, with a multibasic cleavage site deletion, was expressed in Escherichia coli, refolded, and chromatographically purified from inclusion bodies. Finally, the protein was formulated in Tris-HCl buffer of pH 8.0 or PBS of pH 7.4 to obtain antigens denoted rH5-1 and rH5-2, respectively. The systemic prime and boost immunizations proved that rH5-1 adsorbed to aluminum hydroxide induces anti-H5 HA neutralizing antibodies and protective immune responses against H5N1 HPAIVs in chickens. The present studies were aimed at stimulating immune responses via the mucosal routes using the systemic prime-mucosal boost strategy. Efficacy trials were performed in commercial layer chickens. For systemic and mucosal immunizations, H5 HA antigens were adjuvanted with aluminum hydroxide and chitosan glutamate, respectively. The first dose of rH5-2 was administered subcutaneously, while its second dose was administered subcutaneously, intraocularly, oculo-nasally, or intranasally. rH5-1 was delivered to the subcutaneously primed chickens by the intranasal route. Post-vaccination sera were analyzed for anti-H5 HA antibodies, using homologous ELISA and heterologous FluAC H5 and hemagglutination inhibition tests. Intraocularly and oculo-nasally delivered rH5-2 mixed with chitosan glutamate was capable of stimulating anti-H5 HA IgY antibody responses in the subcutaneously primed chickens; however, it was ineffective when administered by the intranasal route. Efficient intranasal boosting was achieved using rH5-1. The enhanced production of antigen-specific antibodies was reflected in the development of H5-subtype specific and hemagglutination inhibiting antibodies. Conclusively, the subcutaneous prime and oculo-nasal boost vaccination is proposed as the target strategy for future optimization.

Feeding treats containing cannabidiol (CBD) did not alter canine immune response to immunization with a novel antigen.

Due to the potential risk for cannabidiol (CBD) to negatively impact the immune system, the objective of the current study was to evaluate the effect of CBD on the canine immune response to immunization with a novel antigen, keyhole limpet hemocyanin (KLH). Thirty-two dogs (22.4 ± 6.3 kg BW) were utilized in a completely randomized design with treatments consisting of 5 mg CBD/kg BW/d and a control administered orally via treats. After a 7-d acclimation to treatments, dogs were immunized with 10 mg/dog of KLH via intramuscular injection into the semimembranosus muscle region, which was repeated in 14 d. Blood samples were collected at baseline and weekly for 28 d after initial KLH immunization for analysis of hematology, serum chemistry, and immunoglobulins. Data were analyzed using the MIXED procedure in SAS including the fixed effects of treatment, day, and the treatment by day interaction. Both primary and secondary KLH immunization produced robust immune responses. Most hematological and serum chemistry variables remained within normal reference ranges for dogs across both treatments throughout the study. Alkaline phosphatase, while within normal reference range and similar between treatments at baseline and on d 7 (P = 0.994 and 0.183, respectively), was elevated for CBD-treated dogs versus control on d 14, 21, and 28 (P = 0.006, 0.027, and 0.014, respectively). Both total and KLH-specific IgG and IgM were similar between treatments throughout the study (P > 0.05), although total IgM peaked earlier in control dogs compared to those receiving CBD. Despite the minor shift in the timing of the total IgM peak, CBD did not appear to exhibit humoral immunosuppressive effects when supplemented at 5 mg/kg BW/d. However, this work does highlight the potential for CBD to alter liver function and the need for further safety evaluations of CBD use in dogs utilizing longer-term studies and multiple CBD doses.

Immunity and Protection Provided by Live Modified Vaccines Against Paratyphoid Salmonella in Poultry-An Applied Perspective.

Several serotypes of non-host-specific or paratyphoid Salmonella have been linked with contamination of poultry meat, and eggs, resulting in foodborne outbreaks in humans. Vaccination of poultry against paratyphoid Salmonella is a frequent strategy used to reduce the levels of infection and transmission, which ultimately can lead to lower rates of human infections. Live vaccines have been developed and used in poultry immediately after hatching as a result of their ability to colonize the gut, stimulate a mucosal immune response, induce a competitive inhibitory effect against homologous wild strains, and reduce colonization and excretion of Salmonella. Furthermore, vaccines can competitively exclude some heterologous strains of Salmonella from colonizing the gastrointestinal tract when young poultry are immunologically immature. In addition, various studies have suggested that booster vaccination with live vaccines a few weeks after initial vaccination is essential to increase the level of protection and achieve better cross-protective immunity. Vaccination of breeders, broilers, layers, and turkeys with modified live Salmonella vaccines is a common intervention that has become an important component in poultry companies' multistep prevention programs to meet increasingly demanding customer and regulatory food safety requirements. Both live and inactivated vaccines play a critical role in a comprehensive control program for chicken and turkey breeders and commercial layers. This review examines the response and protection conferred by live modified vaccines against non-host-specific Salmonella that can be considered for the design and implementation of vaccination strategies in poultry.

Artículo regular­Inmunidad y protección que brindan las vacunas vivas modificadas contra salmonelas paratíficas en la avicultura­Una perspectiva aplicada. Varios serotipos de Salmonella paratífica no específica de huésped se han relacionado con la contaminación de la carne de pollo y huevos lo que ha provocado brotes de origen alimentario en los seres humanos. La vacunación de aves comerciales contra Salmonella paratífica es una estrategia que se utiliza con frecuencia para reducir los niveles de infección y transmisión, que en última instancia puede conducir a tasas más bajas de infecciones en humanos. Se han desarrollado y utilizado vacunas vivas en aves comerciales inmediatamente después de la eclosión como resultado de su capacidad para colonizar el intestino, estimular una respuesta inmunitaria de la mucosa, inducir un efecto inhibidor competitivo contra cepas silvestres homólogas y reducir la colonización y excreción de Salmonella. Además, las vacunas pueden excluir competitivamente algunas cepas heterólogas de Salmonella de colonizar el tracto gastrointestinal cuando las aves jóvenes son inmunológicamente inmaduras. Además, varios estudios han sugerido que la vacunación de refuerzo con vacunas vivas unas semanas después de la vacunación inicial es esencial para aumentar el nivel de protección y lograr una mejor inmunidad de protección cruzada. La vacunación de reproductoras, pollos de engorde, aves de postura y pavos con vacunas vivas modificadas contra Salmonella es una intervención común que se ha convertido en un componente importante en los programas de prevención de múltiples pasos de las empresas avícolas para cumplir con los requisitos de los clientes y regulatorios de seguridad alimentaria. Tanto las vacunas vivas como las inactivadas desempeñan un papel fundamental en un programa de control integral para productores de pollos, pavos y aves ponedoras comerciales. Esta revisión examina la respuesta y la protección conferidas por las vacunas vivas modificadas contra Salmonella no específica del huésped que pueden ser consideradas para el diseño e implementación de estrategias de vacunación en la avicultura.

Comparison of the immune response following subcutaneous versus intranasal modified-live virus booster vaccination against bovine respiratory disease in pre-weaning beef calves that had received primary vaccination by the intranasal route.

This study was performed to elucidate whether the route of booster vaccination affects the immune response against respiratory vaccine viruses in pre-weaning beef calves that receive primary intranasal (IN) vaccination during the first month of life. The objective was to compare the serum neutralizing antibody (SNA) titers to BHV1, BRSV, and BPI3V, cytokine mRNA expression and mucosal BHV1- and BRSV-specific IgA in nasal secretions following administration of IN or subcutaneous (SC) modified-live virus (MLV) booster vaccines 60 days after primary IN vaccination in young beef calves. Twenty-one beef calves were administered 2 mL of an IN MLV vaccine containing BHV1, BRSV, and BPI3V (Inforce3®) between one and five weeks of age. Sixty days after primary vaccination, calves were randomly assigned to one of two groups: IN-MLV (n = 11): Calves received 2 mL of the same IN MLV vaccine used for primary vaccination and 2 mL of a SC MLV vaccine containing BVDV1 & 2 (Bovi- Shield GOLD® BVD). SC-MLV (n = 10): Calves were administered 2 mL of a MLV vaccine containing, BHV1, BRSV, BPI3V, and BVDV1 & 2 (Bovi-Shield GOLD® 5). Blood and nasal secretion samples were collected on days -61 (primary vaccination), -28, -14, 0 (booster vaccination), 14, 21, 28, 42 and 60 for determination of SNA titers, cytokine gene expression analysis and nasal virus-specific IgA concentrations. Statistical analysis was performed using a repeated measures analysis through PROC GLIMMIX of SAS®. Booster vaccination by neither IN nor SC routes induced a significant increase in SNA titers against BHV1, BRSV, and BPI3V. Subcutaneous booster vaccination induced significantly greater BRSV-specific SNA titers (on day 42) and IgA concentration in nasal secretions (on days 21 and 42) compared to calves receiving IN booster vaccination. Both IN and SC booster vaccination were able to stimulate the production of BHV1-specific IgA in nasal secretions. In summary, booster vaccination of young beef calves using either SC or IN route two months after IN MLV primary vaccination resulted in comparable SNA titers, cytokine gene expression profile and virus-specific IgA concentration in nasal secretions. Only a few differences in the systemic and mucosal immune response against BHV1 and BRSV were observed. Subcutaneous booster vaccination induced significantly greater BRSV-specific SNA and secretory IgA titers compared to IN booster vaccination.

Safety and Efficacy of Felid Herpesvirus-1 Deletion Mutants in Cats.

Felid herpesvirus-1 (FeHV-1) is an important respiratory and ocular pathogen of cats and current vaccines are limited in duration and efficacy because they do not prevent infection, viral nasal shedding and latency. To address these shortcomings, we have constructed FeHV-1 gE-TK- and FeHV-1 PK- deletion mutants (gE-TK- and PK-) using bacterial artificial chromosome (BAC) mutagenesis and shown safety and immunogenicity in vitro. Here, we compare the safety and efficacy of a prime boost FeHV-1 gE-TK- and FeHV-1 PK- vaccination regimen with commercial vaccination in cats. Cats in the vaccination groups were vaccinated at 3-week intervals and all cats were challenge infected 3 weeks after the last vaccination. Evaluations included clinical signs, nasal shedding, virus neutralizing antibodies (VN), cytokine mRNA gene expression, post-mortem histology and detection of latency establishment. Vaccination with gE-TK- and PK- mutants was safe and resulted in significantly reduced clinical disease scores, pathological changes, viral nasal shedding, and viral DNA in the trigeminal ganglia (the site of latency) following infection. Both mutants induced VN antibodies and interferons after immunization. In addition, after challenge infection, we observed a reduction of IL-1ß expression, and modulation of TNFα, TGFß and IL10 expression. In conclusion, this study shows the merits of using FeHV-1 deletion mutants for prevention of FeHV-1 infection in cats.

Immunogenicity of Newcastle Disease Vaccine in Southern Ground-hornbill (Bucorvus leadbeateri).

The southern ground-hornbill (Bucorvus leadbeateri; hereafter SGH) is endangered in South Africa, Namibia, and Swaziland. Through a conservation program established in South Africa by the Mabula Ground Hornbill Project, wild populations are being re-established by the reintroduction of captive-reared birds. The SGH is susceptible to infection with avian avulavirus 1, which causes Newcastle disease (ND). Four different vaccines to protect against ND were administered through various vaccination schedules and evaluated by serologic monitoring to assess the efficiency and safety of various combinations of vaccines (live versus inactivated/killed), vaccine strains (Ulster strain, live; Avivac Cellimune, live; VG/GA strain, live; and Avivac Struvac, killed), and administration routes (intraocular versus subcutaneous versus intramuscular injection versus oral). We vaccinated 75 individuals and evaluated antibody titers in 53 individuals (24 juveniles, 13 subadults, and 16 adult SGH; 26 males and 27 females) over a period of 9 years. Antibody titers to avian avulavirus 1 in sera were monitored by a hemagglutination inhibition test. Protective titers were generated with 3/6 vaccine regimes tested in the SGH. The highest vaccine titers were established in birds vaccinated with the Ulster strain in the conjunctiva and followed with an intramuscular Struvac injection (mean log2 titer 8.6 ± 2.6) booster. Our aim was 1) to assess whether optimal vaccination protocols could be developed and 2) to then be able, by oral administration, to remove the need to recapture free-roaming, reintroduced birds to administer the initial vaccine or booster, thus remove the threat or mortality associated with ND to this endangered avian species in both captive birds and birds released back into the wild.

Development and immunogenic potentials of chitosan-saponin encapsulated DNA vaccine against avian infectious bronchitis coronavirus.

Infectious Bronchitis (IB) is an economically important avian disease that considerably threatens the global poultry industry. This is partly, as a result of its negative consequences on egg production, weight gain as well as mortality rate.The disease is caused by a constantly evolving avian infectious bronchitis virus whose isolates are classified into several serotypes and genotypes that demonstrate little or no cross protection. In order to curb the menace of the disease therefore, broad based vaccines are urgently needed. The aim of this study was to develop a recombinant DNA vaccine candidate for improved protection of avian infectious bronchitis in poultry. Using bioinformatics and molecular cloning procedures, sets of monovalent and bivalent DNA vaccine constructs were developed based on the S1 glycoprotein from classical and variants IBV strains namely, M41 and CR88 respectively. The candidate vaccine was then encapsulated with a chitosan and saponin formulated nanoparticle for enhanced immunogenicity and protective capacity. RT-PCR assay and IFAT were used to confirm the transcriptional and translational expression of the encoded proteins respectively, while ELISA and Flow-cytometry were used to evaluate the immunogenicity of the candidate vaccine following immunization of various SPF chicken groups (A-F). Furthermore, histopathological changes and virus shedding were determined by quantitative realtime PCR assay and lesion scoring procedure respectively following challenge of various subgroups with respective wild-type IBV viruses. Results obtained from this study showed that, groups vaccinated with a bivalent DNA vaccine construct (pBudCR88-S1/M41-S1) had a significant increase in anti-IBV antibodies, CD3+ and CD8+ T-cells responses as compared to non-vaccinated groups. Likewise, the bivalent vaccine candidate significantly decreased the oropharyngeal and cloacal virus shedding (p < 0.05) compared to non-vaccinated control. Chickens immunized with the bivalent vaccine also exhibited milder clinical signs as well as low tracheal and kidney lesion scores following virus challenge when compared to control groups. Collectively, the present study demonstrated that bivalent DNA vaccine co-expressing dual S1 glycoprotein induced strong immune responses capable of protecting chickens against infection with both M41 and CR88 IBV strains. Moreso, it was evident that encapsulation of the vaccine with chitosan-saponin nanoparticle further enhanced immune responses and abrogates the need for multiple booster administration of vaccine. Therefore, the bivalent DNA vaccine could serve as efficient and effective alternative strategy for the control of IB in poultry.

Serum neutralising antibody titres against a lineage 2 neuroinvasive West Nile Virus strain in response to vaccination with an inactivated lineage 1 vaccine in a European endemic area.

In the last decade in Hungary and the neighbouring countries, West Nile Neuroinvasive Disease (WNND) has been caused in dramatically increasing numbers by lineage 2 West Nile Virus (WNV) strains both in horses and in humans. The disease in this geographical region is seasonal, so vaccination of horses should be carefully scheduled to maintain the highest antibody titres during outbreak periods. The objective of this study was to characterise the serum neutralising (SN) antibody titres against a lineage 2 WNV strain in response to vaccination with an inactivated lineage 1 vaccine (Equip® WNV). Thirty-two seronegative horses were enrolled in the study, 22 horses were allocated to the vaccinated group and 10 retained as unvaccinated controls. Horses were vaccinated according to the product's vaccination guidelines. A primary vaccination of two doses administered 28 days apart was initiated approximately 5 months before the WNV outbreak season, followed by a booster vaccination one year later. Blood samples were collected during a 2-year period to monitor production of SN antibodies against lineage 1 and the enzootic lineage 2 WNV strain. Mean antibody titres against lineage 1 WNV were significantly higher (P ≤ 0.05) in the vaccinated group compared to the control group at all-time points after the primary dose of vaccination. Similarly, mean antibody titres against lineage 2 WNV were significantly higher (P ≤ 0.05) in the vaccinated group compared to the control group at all time-points except at 6 months after the primary vaccination. SN antibody titres were significantly higher against lineage 1 than lineage 2 at all-time points. According to the results, vaccination with an inactivated lineage 1 vaccine induces antibodies against both WNV lineages 1 and 2 strains up to 2 years after booster vaccination, but in those geographical regions where lineage 2 strains are responsible for seasonal outbreaks, a booster vaccination should be considered earlier than 12 months after primary vaccination.

Heterologous prime-boost: an important candidate immunization strategy against Tembusu virus.

BACKGROUND: Tembusu virus (TMUV), a newly emerging pathogenic flavivirus, spreads rapidly between ducks, causing massive economic losses in the Chinese duck industry. Vaccination is the most effective method to prevent TMUV. Therefore, it is urgent to look for an effective vaccine strategy against TMUV. Heterologous prime-boost regimens priming with vaccines and boosting with recombinant adenovirus vaccines have been proven to be successful strategies for protecting against viruses in experimental animal models. METHODS: In this study, heterologous and homologous prime-boost strategies using an attenuated salmonella vaccine and a recombinant adenovirus vaccine expressing prM-E or the E gene of TMUV were evaluated to protect ducks against TMUV infection for the first time, including priming and boosting with the attenuated salmonella vaccine, priming and boosting with the recombinant adenovirus vaccine, and priming with the attenuated salmonella vaccine and boosting with the recombinant adenovirus vaccine. Humoral and cellular immune responses were detected and evaluated. We then challenged the ducks with TMUV at 12 days after boosting to assay for clinical symptoms, mortality, viral loads and histopathological lesions after these different strategies. RESULTS: Compared with the homologous prime-boost strategies, the heterologous prime-boost regimen produced higher levels of neutralizing antibodies and IgG antibodies against TMUV. Additionally, it could induce higher levels of IFN-γ than homologous prime-boost strategies in the later stage. Interestingly, the heterologous prime-boost strategy induced higher levels of IL-4 in the early stage, but the IL-4 levels gradually decreased and were even lower than those induced by the homologous prime-boost strategy in the later stage. Moreover, the heterologous prime-boost strategy could efficiently protect ducks, with low viral titres, no clinical symptoms and histopathological lesions in this experiment after challenge with TMUV, while slight clinical symptoms and histopathological lesions were observed with the homologous prime-boost strategies. CONCLUSIONS: Our results indicated that the heterologous prime-boost strategy induced higher levels of humoral and cellular immune responses and better protection against TMUV infection in ducks than the homologous prime-boost strategies, suggesting that the heterologous prime-boost strategy is an important candidate for the design of a novel vaccine strategy against TMUV.

[Oestrus suppression in a dairy herd by means of anti-GnRH vaccination Improvac®: A prospective field study]. / Brunstunterdrückung mittels Anti-GnRH-Impfung Improvac® in einem Milchviehbestand: Eine prospektive Feldstudie.

INTRODUCTION: The aim of this study was to evaluate the duration of estrus suppression after a double administration of the anti-GnRH vaccine Improvac® (Zoetis Schweiz GmbH, 2800 Delémont) in cows. Furthermore, it should be investigated, if a third administration could prolong the effect of the cycle suppression. A total of 21 cows (more than four weeks post partum) were vaccinated twice, at least 35 days apart, with 2 ml Improvac® (0.4 mg of a GnRH-analogon) subcutaneously on one side of the neck. Over a period of 368 days and in the course of 18 farm visits these cows were examined gynecologically and re-vaccinated if they showed signs of estrus behaviour or ovarian activity. After the second vaccination the cycle of the cows was suppressed for an average period of 114 days (59-175 days) and the effect could be prolonged by a booster of the vaccine for another 127 days in three cows. Estrus behaviour was absent for a longer period than ovarian activity was. The vaccine was tolerated well: apart from slight swelling at the injection site, no side effects were observed. Our results demonstrate that two immunizations with Improvac® are an easily applicable method for the suppression of cyclic activity in cows for a mean period of 114 days. The duration of cycle suppression was prolonged by a booster of the vaccination.

INTRODUCTION: Le but de cette étude était d'évaluer la durée de la suppression des chaleurs chez les vaches après une double administration du vaccin anti-GnRH Improvac® (Zoetis Schweiz GmbH, 2800 Delémont). En outre, on a recherché si une troisième administration pourrait prolonger l'effet de la suppression du cycle. Au total, 21 vaches (plus de quatre semaines après vèlage) ont été vaccinées deux fois, à au moins 35 jours d'intervalle, avec 2 ml d'Improvac® (0,4 mg d'analogue de la GnRH) par voie sous-cutanée d'un côté du cou. Sur une période de 368 jours et au cours de 18 visites à la ferme, ces vaches ont été examinées gynécologiquement et revaccinées si elles présentaient des signes de comportement œstral ou d'activité ovarienne. Après la deuxième vaccination, le cycle des vaches a été supprimé pendant une période moyenne de 114 jours (59 - 175 jours) et l'effet a pu être prolongé par un rappel du vaccin pendant 127 jours supplémentaires chez trois vaches. Le comportement d'œstrus était absent pendant une période plus longue que l'inactivité ovarienne. Le vaccin a été bien toléré: à part une légère enflure au site d'injection, aucun effet secondaire n'a été observé. Nos résultats démontrent que deux immunisations avec Improvac® sont une méthode facilement applicable pour la suppression de l'activité cyclique chez les vaches pendant une période moyenne de 114 jours. La durée de la suppression du cycle a été prolongée par un rappel de vaccination.

Triple La Sota re-vaccinations can protect laying chickens for 3 months against drop in egg production caused by velogenic viscerotropic Newcastle disease virus infection.

One hundred and ten Isa Brown layers were vaccinated with La Sota, once at point of lay at 18 weeks and three times at peak of lay which occurred at 27-29 weeks of age. Thereafter, they were weekly monitored for haemagglutination inhibition (HI) antibody decline. The first batch A of the layers were challenged with velogenic viscerotropic Newcastle disease (vvND) virus (vvNDV) on day 24 post-vaccination (PV), when the geometric mean titre (GMT) was 84.4, batch B were challenged on day 48 PV at GMT of 42.2, while batch C were challenged on day 97 PV at GMT of 21.1. The individual chicken HI antibody titres of the 10 layers in batch C at the day of challenge were: 7 layers had HI titres of 16, 2 layers had HI titres of 32 and 1 layer had HI titres of 64. Each challenge in the three batches produced no clinical signs including drop in egg production. But there was initial swelling of the spleen followed by atrophy with high antibody responses. The virus was recovered in all the cloacal swabs on days 3-9 post-challenge (PC) at low titres. On days 145 PV and 48, post-Batch C challenge the remaining hyperimmunized unchallenged layers demonstrated a drop in total % egg production (p < .05) and changes in egg quality. The HI GMT was 256. The virus was recovered in all the cloacal swabs on days 3-9 following appearance of clinical signs. There was no mortality in the experiment. Based on the above observations, it is concluded that triple La Sota re-vaccination can protect layers against a drop in egg production in areas where vvNDV infection is enzootic.

Assessment of the acid phosphatase CP01850 from Corynebacterium pseudotuberculosis in DNA and subunit vaccine formulations against caseous lymphadenitis / Avaliação da fosfatase ácida recombinante CP01850 de Corynebacterium pseudotuberculosis em formulações vacinais de subunidade e de DNA contra a linfadenite caseosa

The target cp1002_RS01850 from Corynebacterium pseudotuberculosis was used to construct a DNA and recombinant subunit vaccine against caseous lymphadenitis. Recombinant protein rCP01850 was expressed in Escherichia coli using pAE vector, and DNA vaccine was engineered with pTARGET vector. BALB/c mice were divided in five groups containing eight animals each, inoculated with: pTARGET/cp01850 as DNA vaccine (G1); rCP01850 plus Al (OH)3 as recombinant subunit vaccine (G2); pTARGET/cp01850 and a boost with rCP01850 plus Al (OH)3 (G3); pTARGET (G4); or Al (OH)3 (G5). Mice were inoculated and blood samples were collected on days 0, 21, and 42 for the analysis of total IgG, IgG1 and IgG2a by ELISA. In each group, five animals were challenged with Mic-6 C. pseudotuberculosis strain, and three were used for cytokine quantification by qPCR. Although no group has been protected by vaccines against lethal challenge, G2 showed an increase in the survival rate after challenge. Significantly higher levels of IL-4, IL-12, IFN-γ, total IgG, IgG1 and IgG2a were also detected for G2, evidencing a mixed Th1/Th2 immunological profile. In conclusion, despite no protection level provided by different vaccinal strategies using cp1002_RS01850 from C. pseudotuberculosis, G2 developed a Th1/Th2 immune response with an increase in survival rate.(AU)

O alvo cp1002_RS01850 de Corynebacterium pseudotuberculosis foi utilizado para construir uma vacina recombinante de subunidade e de DNA contra a linfadenite caseosa. A proteína recombinante rCP01850 foi expressa em Escherichia coli usando o vetor pAE, e a vacina de DNA foi construída com o vetor pTARGET. Camundongos BALB/c foram divididos em grupos de oito animais, inoculados com: pTARGET/cp01850 como vacina de DNA (G1); rCP01850 e Al (OH)3 como vacina recombinante de subunidade (G2); pTARGET/cp01850 e um boost com rCP01850 e Al (OH)3 (G3); pTARGET (G4); ou Al (OH)3 (G5). Os animais foram inoculados e amostras de sangue foram coletadas nos dias 0, 21, e 42 do experimento para a análise de IgG total, IgG1 e IgG2a por ELISA. De cada grupo, cinco animais foram desafiados com a cepa Mic-6 de C. pseudotuberculosis, e três foram usados para a quantificação de citocinas por qPCR. Apesar de nenhum grupo ter sido protegido pelas vacinas testadas contra o desafio letal, G2 apresentou taxa de sobrevida e níveis de IL-4, IL-12, IFN-γ, IgG total, IgG1 e IgG2a significativamente mais altos, evidenciando um perfil imunológico misto Th1/Th2. Conclui-se que apesar das diferentes estratégias vacinais utilizando cp1002_RS01850 de C. pseudotuberculosis não terem sido capazes de gerar proteção, G2 desenvolveu uma resposta Th1/Th2 e elevou a taxa de sobrevida.(AU)

Evaluating the sensitivity of the bovine BCG challenge model using a prime boost Ad85A vaccine regimen.

In the absence of biomarkers of protective immunity, newly developed vaccines against bovine tuberculosis need to be evaluated in virulent Mycobacterium bovis challenge experiments, which require the use of expensive and highly in demand Biological Safety Level 3 (BSL3) animal facilities. The recently developed bovine BCG challenge model offers a cheaper and faster way to test new vaccine candidates and additionally reduces the severity of the challenge compared to virulent M. bovis challenge in line with the remits of the NC3Rs. In this work we sought to establish the sensitivity of the BCG challenge model by testing a prime boost vaccine regimen that previously increased protection over BCG alone against M. bovis challenge. All animals, except the control group, were vaccinated subcutaneously with BCG Danish, and half of those were then boosted with a recombinant adenoviral vector expressing Antigen 85A, Ad85A. All animals were challenged with BCG Tokyo into the prescapular lymph node and the bacterial load within the lymph nodes was established. All vaccinated animals, independent of the vaccination regimen, cleared BCG significantly faster from the lymph node than control animals, suggesting a protective effect. There was however, no difference between the BCG and the BCG-Ad85A regimens. Additionally, we analysed humoral and cellular immune responses taken prior to challenge for possible predictors of protection. Cultured ELISpot identified significantly higher IFN-É£ responses in protected vaccinated animals, relative to controls, but not in unprotected vaccinated animals. Furthermore, a trend for protected animals to produce more IFN-É£ by quantitative PCR and intracellular staining was observed. Thus, this model can also be an attractive alternative to M. bovis challenge models for the discovery of protective biomarkers.

Protective efficacy of inactivated reverse genetics based equine influenza vaccine candidate adjuvanted with MontanideTM Pet Gel in murine model.

Equine influenza is a leading cause for respiratory illness in equines. Major control measures involve vaccination which requires continuous harmonization owing to antigenic drift. The present study focused on assessing the protective efficacy of an inactivated recombinant equine influenza virus (rgEIV) vaccine candidate adjuvanted with MontanideTM Pet Gel in murine model. The rgEIV was generated using reverse genetics by incorporating HA and NA segments from EIV/H3N8, clade 2-Florida sublineage in an A/WSN/33 /H1N1 backbone and inactivated by formalin. The vaccine was prepared by mixing inactivated rgEIV with MontanideTM Pet Gel adjuvant followed by intranasal inoculation into BALB/c mice intranasally. The immune responses and protective efficacy of the vaccine was evaluated by measurement of antibody titer, immunoglobulin subtyping, cytokines, clinical signs and pathological lesions after immunization and challenge with wild EIV. Serology and cytokine expression pattern indicated that the vaccine activated mixed Th1- and Th2-like responses of vaccine. Booster immunization stimulated strong antibody responses (HAI titre: 192 ± 28.6) at 42 days post immunization and the predominant antibody subtype was IgG1. Upregulation of interferon (IFN)-gamma, interleukin (IL)-12 and IL-2 levels indicates effective induction of Th1 type response. We found that vaccination has protected mice against equine influenza virus challenge as adjudged through a lack of nonappearance of visible clinical signs of disease, no loss of body weight loss, reduced pathology in the lungs and markedly reduced virus shedding from the respiratory tract. Therefore, we conclude that recombinant EIV vaccine candidate adjuvanted with MontanideTM Pet Gel could aid in quick harmonization of the vaccines through replacement of HA and NA genes for control of EIV outbreaks.

Newcastle disease virus vectors expressing consensus sequence of the H7 HA protein protect broiler chickens and turkeys against highly pathogenic H7N8 virus.

Continuous outbreaks of highly pathogenic avian influenza (HPAI) viruses in commercial poultry have caused devastating losses to domestic poultry with a raising public health concern. The outbreaks of HPAI viruses have increased worldwide, including the North America. Therefore, vaccination has been considered as an alternative strategy for an efficient control of HPAI viruses. In this study, we aimed to generate Newcastle disease virus (NDV) vectored H7 serotype-specific vaccines by expressing the consensus sequence of the HA protein. Conventional NDV strain LaSota vector and a chimeric NDV vector containing the avian paramyxovirus type-2 F and HN protein were able to express the consensus sequence of HA protein. The protective efficacy of vaccines was evaluated in broiler chickens and in turkeys. One-day-old poults were prime immunized with the chimeric vector expressing the HA protein followed by boost immunization with LaSota vector expressing the HA protein or co-expressing the HA and NA proteins. Our vaccine candidates provided complete protection of broiler chickens from mortality and shedding of H7N8 HPAI challenge virus. Turkeys were better protected by boosting with the LaSota vector co-expressing the HA and NA proteins than the LaSota vector expressing only the HA protein. Our study demonstrated a potential use of heterologous prime and boost vaccination strategy to protect poultry against H7 HPAI viruses.