Abstract: Genetically engineered Foot and Mouth Disease Virus (FMDV) and related engineered proteins and polynucleotides, nanolipoprotein particles, compositions, methods and systems are described. The genetically engineered FMDV is modified by the strategic insertion of a protein tag into select regions of the FMDV genome which encode viral proteins that are exposed on the surface of the FMDV viral capsid. The inserted protein tag is displayed as a decoration or attachment on the viral capsid surface.

Abstract: Genetically engineered Foot and Mouth Disease Virus (FMDV) and related engineered proteins and polynucleotides, nanolipoprotein particles, compositions, methods and systems are described. The genetically engineered FMDV is modified by the strategic insertion of a protein tag into select regions of the FMDV genome which encode viral proteins that are exposed on the surface of the FMDV viral capsid. The inserted protein tag is displayed as a decoration or attachment on the viral capsid surface.

Abstract: Genetically engineered Foot and Mouth Disease Virus (FMDV) and related engineered proteins and polynucleotides, nanolipoprotein particles, compositions, methods and systems are described. The genetically engineered FMDV is modified by the strategic insertion of a protein tag into select regions of the FMDV genome which encode viral proteins that are exposed on the surface of the FMDV viral capsid. The inserted protein tag is displayed as a decoration or attachment on the viral capsid surface.

Abstract: Genetically engineered Foot and Mouth Disease Virus (FMDV) and related engineered proteins and polynucleotides, nanolipoprotein particles, compositions, methods and systems are described. The genetically engineered FMDV is modified by the strategic insertion of a protein tag into select regions of the FMDV genome which encode viral proteins that are exposed on the surface of the FMDV viral capsid. The inserted protein tag is displayed as a decoration or attachment on the viral capsid surface.

Abstract: We have developed an ASFV Georgia strain adapted to grow in Vero cell line. The resulting virus, ASF-GVAV, efficiently grows in Vero cells although it still is able to significantly replicate in primary cell cultures of swine macrophages. ASF-GVAV virus was successfully used as parental virus to develop several recombinant ASF viruses. The development of an ASFV adapted to grow in an established cell line is a significant advance for research and development of vaccine candidate strains using genetic manipulation based in the process of homologous recombination. The GVAVS can be utilized as a basis for large scale production of ASF vaccines.

Abstract: We have generated novel molecularly marked FMDV A24LL3DYR and A24LL3BPVKV3DYR vaccine candidates. The mutant viruses contain a deletion of the leader coding region (LL) rendering the virus attenuated in vivo and negative antigenic markers introduced in one or both of the viral non-structural 3Dpol and 3B proteins. The vaccine platform includes unique restriction endonuclease sites for easy swapping of capsid proteins for different FMDV subtypes and serotypes. The mutant viruses produced no signs of FMD and no shedding of virulent virus in cattle. No clinical signs of disease or fever were observed and no transmission to in-contact animals was detected in pigs inoculated with live A24LL3DYR. Cattle immunized with chemically inactivated vaccine candidates showed an efficacy comparable to a polyvalent commercial FMDV vaccine. These vaccine candidates used in conjunction with a cELISA provide a suitable target for DIVA companion tests.

Abstract: We have generated novel molecularly marked FMDV A24LL3DYR and A24LL3BPVKV3DYR vaccine candidates. The mutant viruses contain a deletion of the leader coding region (LL) rendering the virus attenuated in vivo and negative antigenic markers introduced in one or both of the viral non-structural 3Dpol and 3B proteins. The vaccine platform includes unique restriction endonuclease sites for easy swapping of capsid proteins for different FMDV subtypes and serotypes. The mutant viruses produced no signs of FMD and no shedding of virulent virus in cattle. No clinical signs of disease or fever were observed and no transmission to in-contact animals was detected in pigs inoculated with live A24LL3DYR. Cattle immunized with chemically inactivated vaccine candidates showed an efficacy comparable to a polyvalent commercial FMDV vaccine. These vaccine candidates used in conjunction with a cELISA provide a suitable target for DIVA companion tests.

Abstract: We have generated novel molecularly marked FMDV A24LL3DYR and A24LL3BPVKV3DYR vaccine candidates. The mutant viruses contain a deletion of the leader coding region (LL) rendering the virus attenuated in vivo and negative antigenic markers introduced in one or both of the viral non-structural 3Dpol and 3B proteins. The vaccine platform includes unique restriction endonuclease sites for easy swapping of capsid proteins for different FMDV subtypes and serotypes. The mutant viruses produced no signs of FMD and no shedding of virulent virus in cattle. No clinical signs of disease or fever were observed and no transmission to in-contact animals was detected in pigs inoculated with live A24LL3DYR. Cattle immunized with chemically inactivated vaccine candidates showed an efficacy comparable to a polyvalent commercial FMDV vaccine. These vaccine candidates used in conjunction with a cELISA provide a suitable target for DIVA companion tests.