Abstract: Disclosed are vaccines capable of achieving protection against RSV while avoiding vaccine-enhanced disease (VED). In particular, vaccine constructs have been molecularly designed and genetically engineered to comprise RSV fusion (F) protein displayed on the surface of a particle, such as a virus-like particles (VLP) and low temperature-prepared split RSV. In some embodiments, the RSV F protein is in a pre-fusion F conformation. Also disclosed a variants and combinations of split RSV and RSV F DNA vaccine with pre-fusion F and enhanced efficacy. In addition, disclosed split RSV vaccines containing pre-fusion F conformation and combination adjuvants MPL and CpG.

Abstract: Disclosed are vaccines capable of achieving protection against RSV while avoiding vaccine-enhanced disease (VED). In particular, vaccine constructs have been molecularly designed and genetically engineered to comprise RSV fusion (F) protein displayed on the surface of a particle, such as a virus-like particles (VLP) and low temperature-prepared split RSV. In some embodiments, the RSV F protein is in a pre-fusion F conformation. Also disclosed a variants and combinations of split RSV and RSV F DNA vaccine with pre-fusion F and enhanced efficacy. In addition, disclosed split RSV vaccines containing pre-fusion F conformation and combination adjuvants MPL and CpG.

Abstract: Disclosed are recombinant chimeric influenza virus vaccines and live attenuated influenza virus (LAIV) vaccines expressing foreign (RSV) neutralizing epitopes or conserved M2e epitopes that are capable of providing broader cross-protection against influenza virus and/or protecting against respiratory syncytial virus (RSV) without vaccine-enhanced RSV disease (ERD).

Abstract: Disclosed are universal influenza A vaccines capable of providing broader cross-protection. The vaccine contains a fusion protein comprising tandem repeats of heterologous M2e epitope sequences that have been molecularly and genetically designed to provide broad cross-protection. The fusion protein may be incorporated into virus-like particles (VLPs) or a replicating live attenuated influenza virus vaccine, and administered alone or in combination with other influenza vaccines.

Abstract: Briefly described, virus-like particles, methods of preparing virus-like particles, immunogenic compositions that include virus-like particles, and methods of eliciting an immune response using immunogenic compositions that include virus-like particles are described herein. A virus-like particle (VLP) can include a viral core protein that can self assemble into the VLP core and at least one viral surface envelope glycoprotein expressed on the surface of the VLP. The VLP can also optionally include at least one adjuvant molecule expressed on the surface of the VLP.

Abstract: Disclosed are universal influenza A vaccines capable of providing broader crossprotection. The vaccine contains a fusion protein comprising tandem repeats of heterologous M2e epitope sequences that have been molecularly and genetically designed to provide broad cross-protection. The fusion protein may be incorporated into virus-like particles (VLPs) or a replicating live attenuated influenza virus vaccine, and administered alone or in combination with other influenza vaccines.

Abstract: Disclosed are recombinant chimeric influenza virus vaccines and live attenuated influenza virus (LAIV) vaccines expressing foreign (RSV) neutralizing epitopes or conserved M2e epitopes that are capable of providing broader cross-protection against influenza virus and/or protecting against respiratory syncytial virus (RSV) without vaccine-enhanced RSV disease (ERD).

Abstract: Disclosed are universal influenza A vaccines capable of providing broader crossprotection. The vaccine contains a fusion protein comprising tandem repeats of heterologous M2e epitope sequences that have been molecularly and genetically designed to provide broad cross-protection. The fusion protein may be incorporated into virus-like particles (VLPs) or a replicating live attenuated influenza virus vaccine, and administered alone or in combination with other influenza vaccines.

Abstract: Briefly described, virus-like particles, methods of preparing virus-like particles, immunogenic compositions that include virus-like particles, and methods of eliciting an immune response using immunogenic compositions that include virus-like particles are described herein. A virus-like particle (VLP) can include a viral core protein that can self assemble into the VLP core and at least one viral surface envelope glycoprotein expressed on the surface of the VLP. The VLP can also optionally include at least one adjuvant molecule expressed on the surface of the VLP.

Abstract: Briefly described, virus-like particles, methods of preparing virus-like particles, immunogenic compositions that include virus-like particles, and methods of eliciting an immune response using immunogenic compositions that include virus-like particles are described herein. A virus-like particle (VLP) can include a viral core protein that can self assemble into the VLP core and at least one viral surface envelope glycoprotein expressed on the surface of the VLP. The VLP can also optionally include at least one adjuvant molecule expressed on the surface of the VLP.

Abstract: A cross-protective influenza virus vaccine has been designed based on the incorporation of the genetically engineered, highly conserved M2 influenza viral protein optionally in combination with an adjuvant such as a bacterial flagellin protein incorporated into the membrane of a virosome or virus-like particles. Immunogenicity and the breadth of cross protection efficacy are significantly enhanced using multiple copies of the influenza M2 protein as a membrane bound tetramer and/or in combination with a membrane bound adjuvant. A method for vaccinating a subject for influenza A has also been developed that results in broad and improved cross-protection against multiple subtypes of influenza A virus.

Abstract: Briefly described, virosomes, methods of preparing virosomes, immunogenic compositions that include virosomes, and methods of eliciting an immune response using immunogenic compositions that include virosomes are described herein. A virosome can include at least one viral surface envelope glycoprotein expressed on the surface of the virosome. The virosome can also optionally include at least one adjuvant molecule expressed on the surface of the virosome.

Abstract: Briefly described, virus-like particles, methods of preparing virus-like particles, immunogenic compositions that include virus-like particles, and methods of eliciting an immune response using immunogenic compositions that include virus-like particles are described herein. A virus-like particle (VLP) can include a viral core protein that can self assemble into the VLP core and at least one viral surface envelope glycoprotein expressed on the surface of the VLP. The VLP can also optionally include at least one adjuvant molecule expressed on the surface of the VLP.

Abstract: Briefly described, virus-like particles, methods of preparing virus-like particles, immunogenic compositions that include virus-like particles, and methods of liciting an immune response using immunogenic compositions that include virus-like particles are described herein. A virus-like particle (VLP) can include a viral core protein that can self assemble into the VLP core and at least one viral surface envelope glycoprotein expressed on the surface of the VLP. The viral protein and the viral surface envelope glycoprotein are from different viruses. Another VLP can include a viral core protein that can self assemble into a VLP core; at least one viral surface envelope glycoprotein expressed on the surface of the VLP; and at least one adjuvant molecule expressed on the surface of the VLP.