The present invention relates to vesicular stomatitis virus (VSV) matrix (M) protein mutants. One mutant M protein includes a glycine changed to a glutamic acid at position 21, a leucine changed to a phenylalanine at position 111 and a methionine changed to an arginine at position 51. Another M protein mutant includes a glycine changed to a glutamic acid at position 22 and a methionine changed to an arginine at positions 48 and 51. Yet another VSV M protein mutant includes a glycine changed to a glutamic acid at position 22, a leucine changed to a phenylalanine at position 110 and a methionine changed to an arginine at positions 48 and 51. The present invention is directed also to recombinant VSVs (rVSV) having these M mutants and to vaccines based on the rVSV having the M mutants of the present invention. These new rVSVs having the mutant M were significantly attenuated and lost virulence, including neurovirulence, and are capable of inducing an immune responses against an antigen of interest. In addition, a rVSV serotype Indiana having the first described M mutant is capable of efficient replication at 31 C., and of poor replication or incapable of replication at about 37 C. or higher.

The invention relates to peptides comprising part or all of a conserved element within a Center-of-Tree (COT) sequence derived from a family of polypeptides encoded by naturally occurring variants of HIV. The invention also relates to immunogenic compositions and vaccines comprising said peptides. The invention also relates to methods for the identification of HIV controller patients based on the detection of the T cells of the patient to mount a cytotoxic T cell response against said peptides and to methods for the identification of immunogenic peptides within a family of variant polypeptides.

Methods are disclosed for producing defective ribosomal products (DRiPs) in blebs (DRibbles) by contacting cells with a proteasome inhibitor, and in some examples also an autophagy inducer, thereby producing treated cells. DRibbles can be used to load antigen presenting cells (APCs), thereby allowing the APCs to present the DRiPs and antigenic fragments thereof. Immunogenic compositions that include treated cells, isolated DRibbles, or DRibble-loaded APCs are also disclosed. Methods are also provided for using treated cells, isolated DRibbles, or DRibble-loaded APCs to stimulate an immune response, for example in a subject. For example, DRibbles obtained from a tumor cell can be used to stimulate an immune response against the same type of tumor cells in the subject. In another example, DRibbles obtained from a pathogen-infected cell or cell engineered to express one or more antigens of a pathogen can be used to stimulate an immune response against the pathogen in the subject.

The present invention relates to the prevention and/or treatment of ADA-SCID, in a patient.

The present specification discloses an immunogenic composition comprising polypeptide, wherein each of the polypeptides has no more than 100 amino acids, which polypeptides comprises one or more sequences having at least 60% homology with any of SEQ ID 1-4, or comprises two or more epitopes having 7 amino acids or more, each epitope having at least 60% homology with a sub-sequence of any of SEQ ID 1-4 that has the same length as the epitope, wherein, the polypeptide is immunogenic in a vertebrate expressing a major histocompatibility complex (MHC) allele, and wherein the polypeptide is not a complete HIV virus protein.

Disclosed herein are compositions comprising a Human Immunodeficiency Virus (HIV) trans-activator of transcription (Tat) derivative polypeptide with increased immunostimulatory properties relative to the native Tat polypeptide, pharmaceutical compositions comprising the Tat derivative polypeptide, and methods of treating cancer using the Tat derivative polypeptide.

The present invention relates to vesicular stomatitis virus (VSV) matrix (M) protein mutants. One mutant M protein includes a glycine changed to a glutamic acid at position 21, a leucine changed to a phenylalanine at position 111 and a methionine changed to an arginine at position 51. Another M protein mutant includes a glycine changed to a glutamic acid at position 22 and a methionine changed to an arginine at positions 48 and 51. Yet another VSV M protein mutant includes a glycine changed to a glutamic acid at position 22, a leucine changed to a phenylalanine at position 110 and a methionine changed to an arginine at positions 48 and 51. The present invention is directed also to recombinant VSVs (rVSV) having these M mutants and to vaccines based on the rVSV having the M mutants of the present invention. These new rVSVs having the mutant M were significantly attenuated and lost virulence, including neurovirulence, and are capable of inducing an immune responses against an antigen of interest. In addition, a rVSV serotype Indiana having the first described M mutant is capable of efficient replication at 31 C., and of poor replication or incapable of replication at about 37 C. or higher.

The present invention relates to vesicular stomatitis virus (VSV) matrix (M) protein mutants. One mutant M protein includes a glycine changed to a glutamic acid at position 21, a leucine changed to a phenylalanine at position 111 and a methionine changed to an arginine at position 51. Another M protein mutant includes a glycine changed to a glutamic acid at position 22 and a methionine changed to an arginine at positions 48 and 51. Yet another VSV M protein mutant includes a glycine changed to a glutamic acid at position 22, a leucine changed to a phenylalanine at position 110 and a methionine changed to an arginine at positions 48 and 51. The present invention is directed also to recombinant VSVs (rVSV) having these M mutants and to vaccines based on the rVSV having the M mutants of the present invention. These new rVSVs having the mutant M were significantly attenuated and lost virulence, including neurovirulence, and are capable of inducing an immune responses against an antigen of interest. In addition, a rVSV serotype Indiana having the first described M mutant is capable of efficient replication at 31 C., and of poor replication or incapable of replication at about 37 C. or higher.

The present invention relates to vesicular stomatitis virus (VSV) matrix (M) protein mutants. One mutant M protein includes a glycine changed to a glutamic acid at position (21), a leucine changed to a phenylalanine at position (111) and a methionine changed to an arginine at position (51). Another M protein mutant includes a glycine changed to a glutamic acid at position (22) and a methionine changed to an arginine at positions (48) and (51). Yet another VSV M protein mutant includes a glycine changed to a glutamic acid at position (22), a leucine changed to a phenylalanine at position (110) and a methionine changed to an arginine at positions (48) and (51). The present invention is directed also to recombinant VSVs (rVSV) having these M mutants and to vaccines based on the rVSV having the M mutants of the present invention. These new rVSVs having the mutant M were significantly attenuated and lost virulence, including neurovirulence, and are capable of inducing an immune responses against an antigen of interest. In addition, a rVSV serotype Indiana having the first described M mutant is capable of efficient replication at 31 C., and of poor replication or incapable of replication at about 37 C. or higher.

The present invention relates to (isolated) recombinant proteins, also referred to as improved MAT (iMAT) molecules, comprising at least one translocation module, at least one targeting module and at least one antigen module, wherein at least one cysteine residue is substituted with a different amino acid residue. Such iMAT molecules are useful specifically as vaccines, e.g. for therapy and/or prevention of allergies and/or infectious diseases and/or prevention of transmission of infectious diseases in animals, more preferably ruminants, pigs, dogs and/or cats, but excluding equines. The present invention further relates to nucleic acids encoding such iMAT molecules, corresponding vectors and primary cells or cell lines.