The embodiments disclosed herein relate to the design, engineering and production of replication-deficient gene delivery vectors that are based on aviadenoviruses. More particularly their use is described in the transfer of genes, genetic engineering of cells and animals, the expression of proteins the development of vaccines. In some embodiment, the designs and packaging of partially deleted aviadenovirus vectors are disclosed. In other embodiments, the designs and packaging of fully deleted aviadenovirus vectors, the propagation of replication-deficient aviadenovirus vectors, and the characteristic and engineering of host cells are disclosed. In other embodiments, the use of such vectors in veterinary medicine is described.

A recombinant vaccine comprising a serotype 9 fowl adenovirus vector (FAdV-9) having at least one exogenous nucleotide sequence inserted encoding at least one antigen of a disease of interest and replacing the adenovirus genome non-essential region, and a pharmaceutically acceptable vehicle, adjuvant and/or excipient, wherein the at least one exogenous nucleotide sequence encoding at least one antigen of a disease of interest and replacing the adenovirus genome non-essential region is located between the 491 and 2782 nucleotides.

The vector of this vaccine is stable for industrial scale production. Likewise, even when administering this vaccine in combination with a vaccine against Marek's disease, both vaccines produce an adequate immune response which is not affected by interference between each other. In the same way, effectiveness of the recombinant vaccine is not affected by maternal antibodies, and is capable of inducing both an early and lasting protective response, even with only one application.

Described are recombinant viral vectors obtained from fowl adenovirus 9 (FAdV-9) and associated methods. The recombinant FAdV-9 vectors may include one or more deletions at the left end and/or right end of the FAdV-9 genome. Optionally, the vectors include one or more exogenous nucleotide sequences, such as sequences encoding for a polypeptide of interest. The recombinant FAdV-9 vectors may be used as a dual delivery vector. Also described is the use of the vectors for generating an immunogenic response in a subject and/or for the prevention of disease.

The present disclosure provides compositions for viral gene therapy, e.g. Adeno-Associated virus-directed gene therapy, and methods of using the same for the treatment and/or prevention of cholesterol storage diseases or disorders, such as Niemann-Pick disease, Type C.

A recombinant vaccine comprising a serotype 9 fowl adenovirus vector (FAdV-9) having at least one exogenous nucleotide sequence inserted encoding at least one antigen of a disease of interest and replacing the adenovirus genome non-essential region, and a pharmaceutically acceptable vehicle, adjuvant and/or excipient, wherein the at least one exogenous nucleotide sequence encoding at least one antigen of a disease of interest and replacing the adenovirus genome non-essential region is located between the 491 and 2782 nucleotides. The vector of this vaccine is stable for industrial scale production. When administering this vaccine in combination with a vaccine against Marek's disease, both vaccines produce an adequate immune response which is not affected by interference between each other. In the same way, effectiveness of the recombinant vaccine is not affected by maternal antibodies, and is capable of inducing both an early and lasting protective response, even with only one application.

Described are recombinant viral vectors obtained from fowl adenovirus 9 (FAdV-9) and associated methods. The recombinant FAdV-9 vectors may include one or more deletions at the left end and/or right end of the FAdV-9 genome. Optionally, the vectors include one or more exogenous nucleotide sequences, such a sequences encoding for a polypeptide of interest. The recombinant FAdV-9 vectors may be used as a dual delivery vector. Also described is the use of the vectors for generating an immunogenic response in a subject and/or for the prevention of disease.

The present disclosure provides compositions for viral gene therapy, e.g. Adeno-Associated virus-directed gene therapy, and methods of using the same for the treatment and/or prevention of cholesterol storage diseases or disorders, such as Niemann-Pick disease, Type C.

The present disclosure provides compositions for viral gene therapy, e.g. Adeno-Associated virus-directed gene therapy, and methods of using the same for the treatment and/or prevention of cholesterol storage diseases or disorders, such as Niemann-Pick disease, Type C.

The present invention relates to the fusion proteins against a glycocalyx, found to be associated with several human post-translational modified proteins linked to cancer cell lines. The fusion proteins of the present invention are able to bind only to sialylated glycosphingolipids and sialylated glycoproteins and well as their independent constituents the monosaccharide sugars such as neu5ac, galnac and gal that constitute the glycocalyx. The products claimed can be used for diagnosis and treatment of various cancers. Apoptosis via Caspase 3 occurs in cancer cells when the fusion protein bound to targets is sequestered in lysosomes. The fusion protein is not seen in any other organelle of the cell except for lysosomes.