Development and Evaluation of the Protective Efficacy of Novel Marek's Disease Virus Rispens Vector Vaccines Against Infectious Bursal Disease.

Infectious bursal disease (IBD) is a major disease affecting the poultry industry and is caused by infection with IBD virus (IBDV). To develop a novel vaccine to prevent IBD in chickens, recombinant Marek's disease virus Rispens viruses carrying the VP2 gene of IBDV driven by five different promoters (Rispens/IBD) were constructed using homologous recombination and a bacterial artificial chromosome (BAC). Rispens/IBD driven by the chicken beta-actin (Bac) promoter (Rispens/Bac-IBD), Rous sarcoma virus promoter, or simian virus 40 promoter were administered to 1-day-old SPF chicks, and the protective efficacy against IBDV was evaluated by challenging chicks with virulent IBDV. As a result, Rispens/Bac-IBD showed the best protection (87%). Next, we constructed the virus driven by the Bac-derived Coa5 promoter (Rispens/Coa5-IBD) for a secondary in vivo trial using commercial layer chickens since Rispens/Bac-IBD was thought to be genetically unstable. Rispens/Coa5-IBD showed stability in vitro and exhibited better antibody production and protection during challenge against virulent IBDV at both 5 (95%) and 7 wk of age (91%) compared with that of Rispens/Bac-IBD (90% at 5 wk of age and 84% at 7 wk of age). Thus, Rispens/Coa5-IBD may be a novel promising vaccine against IBD and virulent Marek's disease.

Combination of Two Marek's Disease Virus Vectors Shows Effective Vaccination Against Marek's Disease, Infectious Bursal Disease, and Newcastle Disease.

Herpesvirus of turkeys (HVT) is a widely used vector for poultry vaccines. However, different HVTs expressing different foreign antigens cannot always be used simultaneously because of the risk of recombination and interference. In this study, we inoculated a mixture of an HVT-expressing the antigen of Newcastle disease virus (NDV; HVT/ND) and Marek's disease virus (MDV) serotype 1 Rispens virus expressing the antigen of infectious bursal disease virus (IBD; Ripens/IBD) into chickens. This mixture showed 94%, 100%, or 94% protection against MDV, IBDV, or NDV challenge, respectively. In conclusion, the combination of Rispens/IBD and HVT/ND is effective for vaccination against MDV, IBDV, and NDV without significant interference.

Removal of Inserted BAC after linearizatiON (RIBON)-a novel strategy to excise the mini-F sequences from viral BAC vectors.

The bacterial artificial chromosome (BAC) technology has been a mainstay approach for generating recombinant viruses, and several methods for excision of the mini-F sequences from the viral BAC vectors have been developed. However, these strategies either require complicated procedures or leave scars of inserted sequences. To overcome these problems, a new method to excise the mini-F sequences from viral BAC vectors based on the Removal of Inserted BAC after linearizatiON (RIBON) strategy was developed in this study for herpesvirus of turkeys (HVT). Enhanced green fluorescent protein (eGFP) DNA and the mini-F sequences were inserted into the gene encoding HVT thymidine kinase (TK) by homologous recombination in chicken embryo fibroblasts (CEFs), and the constructed HVT-BAC vector was used to transform Escherichia coli (pHVT-BAC). To remove the inserted eGFP and mini-F sequences, pHVT-BAC was linearized using a homing endonuclease I-SceI and used to cotransfect CEFs together with a plasmid containing the TK gene of HVT. The obtained viruses (44%) did not express eGFP, and DNA sequencing of isolated clones revealed that they were completely free of the inserted BAC sequences. Moreover, growth kinetics and plaque morphology of reconstituted viruses were comparable with those of the parental HVT. The results of this study demonstrate that the novel RIBON approach to remove mini-F sequences from the viral genome is simple and effective.

Vaccine protection of chickens against antigenically diverse H5 highly pathogenic avian influenza isolates with a live HVT vector vaccine expressing the influenza hemagglutinin gene derived from a clade 2.2 avian influenza virus.

Vaccination is an important tool in the protection of poultry against avian influenza (AI). For field use, the overwhelming majority of AI vaccines produced are inactivated whole virus formulated into an oil emulsion. However, recombinant vectored vaccines are gaining use for their ability to induce protection against heterologous isolates and ability to overcome maternal antibody interference. In these studies, we compared protection of chickens provided by a turkey herpesvirus (HVT) vector vaccine expressing the hemagglutinin (HA) gene from a clade 2.2 H5N1 strain (A/swan/Hungary/4999/2006) against homologous H5N1 as well as heterologous H5N1 and H5N2 highly pathogenic (HP) AI challenge. The results demonstrated all vaccinated birds were protected from clinical signs of disease and mortality following homologous challenge. In addition, oral and cloacal swabs taken from challenged birds demonstrated that vaccinated birds had lower incidence and titers of viral shedding compared to sham-vaccinated birds. Following heterologous H5N1 or H5N2 HPAI challenge, 80-95% of birds receiving the HVT vector AI vaccine at day of age survived challenge with fewer birds shedding virus after challenge than sham vaccinated birds. In vitro cytotoxicity analysis demonstrated that splenic T lymphocytes from HVT-vector-AI vaccinated chickens recognized MHC-matched target cells infected with H5, as well as H6, H7, or H9 AI virus. Taken together, these studies provide support for the use of HVT vector vaccines expressing HA to protect poultry against multiple lineages of HPAI, and that both humoral and cellular immunity induced by live vaccines likely contributes to protection.

Protection and antibody response caused by turkey herpesvirus vector Newcastle disease vaccine.

Newcastle disease (ND) is prevalent worldwide and causes significant clinical and economic losses to the poultry industry. Current vaccine programs using live attenuated vaccines and inactivated vaccines have limitations, and new vaccines with distinct features are needed. To offer an alternative solution to control ND, a turkey herpesvirus vector Newcastle disease vaccine (HVT/ND) expressing the fusion gene of Newcastle disease virus (NDV) has been developed. First, immunogenicity of the HVT/ND was evaluated in specific-pathogen-free layer chickens after vaccination by the in ovo route to 18-day-old embryos or by the subcutaneous route to 1-day-old chicks. Antibodies against NDV were detected at 24 days of age using a commercial NDV enzyme-linked immunosorbent assay (ELISA) kit and the hemagglutination inhibition test. At least 90% of chickens were protected against challenge with velogenic neurotropic NDV Texas GB strain (genotype II; pathotype velogenic) at 4 wk of age, while none of the nonvaccinated, challenged controls were protected from challenge. Second, the age at which a vaccinated chicken elicits an immunologic response to the HVT/ND prepared for this study, and thus is protected from ND virus, was assessed in commercial broiler chickens after in ovo vaccination of 18-day-old embryos. Challenge was conducted using a low-virulence NDV strain (genotype II; pathotype lentogenic) via the respiratory tract each week between 1 and 5 wk of age, in order to mimic the situation in areas where virulent NDV strains do not normally exist and low-virulence strains cause mild respiratory symptoms leading to economic losses. Protection was evaluated by the presence or absence of isolated virus from tracheal swabs at 5 days postchallenge. Partial protection was observed at 3 wk of age, when 6 out of 10 (60%) chickens were protected. Full protection was obtained at 4 and 5 wk of age, when 9 out of 10 (90%) and 10 out of 10 (100%) chickens were protected, respectively. Finally, protection against challenge with virulent Texas GB strain at 19 wk of age was evaluated in commercial female layer chickens vaccinated at 1 day of age with HVT/ND. All of the vaccinated chickens were protected, while all of the challenge controls succumbed to the challenge. Furthermore, anti-NDV antibodies measured by ELISA were maintained through 50 wk of age.

Safety and efficacy of a turkey herpesvirus vector laryngotracheitis vaccine for chickens.

Turkey herpesvirus vector laryngotracheitis vaccine (HVT/LT) expressing the glycoprotein B gene of laryngotracheitis virus (LTV) has been developed. In vitro growth kinetics of HVT/LT were similar to those of parental turkey herpesvirus (HVT), FC-126 strain. Genetic and phenotypic stabilities of HVT/LT after in vitro (in cell culture) or in vivo (in chickens) passage were confirmed by various assays, including Southern blot analysis, western blot analysis, and an indirect immunofluorescence assay. Safety of HVT/LT was assessed by an overdose study as well as by a backpassage study in specific-pathogen-free (SPF) chickens. The overdose study indicated that HVT/LT did not cause any adverse effects in chickens. The backpassage study confirmed that HVT/LT does not revert to virulence after five passages in chickens. The vaccine did not transmit laterally from vaccinated chickens to commingled nonvaccinated chickens. Efficacy of HVT/LT was evaluated in SPF layer chickens after vaccination by the subcutaneous route at 1 day of age. The majority of the vaccinated chickens (92%-100%) were protected against challenge with virulent LTV at 7 wk of age. Efficacy of HVT/LT was further evaluated in broiler chickens from a commercial source after in ovo vaccination to embryos at 18 days of incubation. After challenge with virulent LTV at 21 and 35 days of age, 67% and 87% of HVT/LT-vaccinated chickens did not develop LT clinical signs, respectively, while 100% (21 days of age) and 73% (35 days of age) of the challenge control chickens showed clinical signs of LT. These results suggest that HVT/LT is a safe and efficacious vaccine for control of laryngotracheitis (LT).

Binding properties of Bacillus thuringiensis Cry1C delta-endotoxin to the midgut epithelial membranes of Culex pipiens.

The Cry1C delta-endotoxin from Bacillus thuringiensis is toxic to both lepidopteran and dipteran insect larvae. To analyze the dipteran-specific insecticidal mechanisms, we investigated the properties of Cry1C binding to the epithelial cell membrane of the larval midgut from the mosquito Culex pipiens in comparison with dipteran-specific Cry4A. Immunohistochemical staining of the larval midgut sections from Culex pipiens showed that Cry1C and Cry4A bound to the microvilli of the epithelial cells. The Cry1C binding to brush border membrane vesicles from the mosquito larvae was specific and irreversible, and did not compete with Cry4A. By ligand blotting analyses, we detected several Cry1C-binding proteins, the Cry1C binding to which did compete with excess unlabeled Cry4A. These results suggested that Cry1C and Cry4A recognized the same binding site(s) on the epithelial cell surface but that their interaction with the target membrane differed.