A broad spectrum HVT-H5 avian influenza vector vaccine which induces a rapid onset of immunity.

Current methods to combat highly pathogenic avian influenza (HPAI) outbreaks in poultry rely on stamping out and preventive culling, which can lead to high economic losses and invoke ethical resistance. Emergency vaccination could be an alternative as vaccination is one of the most efficient and cost-effective measures to protect poultry from HPAI infection, preventing spreading to other poultry and greatly reducing the potential transmission to humans. Current conventional inactivated AI vaccines may be useful for combating AI outbreaks, but do not fulfil all targets of an ideal AI vaccine, including mass applicability and rapid onset of immunity. We aimed to further investigate the potential of Herpesvirus of Turkeys (HVT) as a vector containing a recombinant H5 hemagglutinin of HPAI H5N1. This HVT-H5 vector was analysed in vitro, tested for onset of immunity against AI challenge, breadth of protection, reduction of virus shedding, and induction of both antibody and cellular responses in SPF layers or broiler chicks containing maternal derived antibodies (MDA+). In SPF layers HVT-H5 provided full protection to lethal challenges with 4 antigenically diverse HPAI H5N1 strains from 2 weeks post vaccination (w.p.v.), while in MDA+ birds full protection was provided from 3 w.p.v. to homologous challenge. Also shedding of challenge virus was reduced in both SPF and MDA+ birds. HVT-H5 induced a protective HI titre (≥4) to 11 HPAI H5N1 strains at 3 w.p.v. in 3-week-old SPF layers and to HPAI H5N8 A/ch/Neth/14015531/2014. Besides inducing a protective antibody response HVT-H5 also induced an influenza-specific T cell response. This data demonstrates that HVT-H5 vaccine appears to fulfil many of the criteria for an ideal AI vaccine including early onset of immunity, a broad protection, reduced virus shedding, protection in presence of AI-MDA and could be a useful tool in the combat of AI outbreaks worldwide.

A novel series of positive modulators of the AMPA receptor: discovery and structure based hit-to-lead studies.

Starting from an HTS derived hit 1, application of biostructural data facilitated rapid optimization to lead 22, a novel AMPA receptor modulator. This is the first demonstration of how structure based drug design can be exploited in an optimization program for a glutamate receptor.

Master donor viruses A/Leningrad/134/17/57 (H2N2) and B/USSR/60/69 and derived reassortants used in live attenuated influenza vaccine (LAIV) do not display neurovirulent properties in a mouse model.

Demonstration of the absence of neurovirulent properties of reassortant viruses contained in live attenuated influenza vaccine (LAIV) is a regulatory requirement. A mouse model was used to detect neurovirulent properties of the cold-adapted, temperature-sensitive and attenuated influenza master donor viruses (MDVs) A/Leningrad/134/17/57 (H2N2) and B/USSR/60/69 and derived reassortant influenza viruses. A/NWS/33 (H1N1), which is known to be neurovirulent in mice, was used as a positive control. Under conditions where the positive control virus induced symptoms of disease and showed viral replication in the upper respiratory tract as well as in the brain, replication of the influenza master donor viruses and reassortant influenza A and B viruses was limited to the upper respiratory tract where they were administered. None of the mice inoculated with MDVs or reassortant influenza viruses suffered from disease, and no virus or viral replication was observed in the brains of these mice. The results demonstrate the absence of neurovirulent properties of the MDVs and reassortant influenza viruses derived therefrom used in LAIV.

PB2 and PA genes control the expression of the temperature-sensitive phenotype of cold-adapted B/USSR/60/69 influenza master donor virus.

The cold-adapted (ca) and temperature-sensitive (ts) influenza master donor virus (MDV) B/USSR/60/69 was derived from its wild-type parental virus after successive passages in eggs at 32 degrees C and 25 degrees C. This strain is currently in use for preparing reassortant influenza B vaccine viruses which are used in the Russian trivalent live attenuated influenza vaccine. Vaccine viruses are obtained by classical reassortment of MDV and a currently circulating wild-type virus. The phenotypic properties cold adaptation and temperature sensitivity are inherited from the six genes encoding the internal proteins of the MDV. However, the role of the individual gene segments in temperature sensitivity and thus attenuation is not known. In this study, 35 reassortant viruses of B/USSR/60/69 MDV with current wild-type non-ts influenza B viruses were generated in eggs or MDCK cells and studied in order to identify the genes responsible for their ts phenotype. For each virus the exact genome composition was determined as well as its ts phenotype. The results demonstrated that the polymerase PB2 and PA gene segments of B/USSR/60/69 MDV independently controlled expression of the ts phenotype of B/USSR/60/69 MDV-based reassortant viruses. The other genes coding for internal proteins played no role in this respect. This suggests that mutations in the polymerase genes PB2 and PA play an essential role in attenuation of B/USSR/60/69 MDV-based reassortant influenza B vaccine viruses.