Disclosed are extracellular vesicles comprising an engineered targeting protein for targeting the extracellular vesicles to target cells. The targeting protein is a fusion protein that includes a ligand, an engineered glycosylation site, and an exosome-targeting domain. Exemplary extracellular vesicles may include but are not limited to exosomes.

A targeted therapeutic including a lysosomal enzyme and a lysosomal targeting moiety that is a peptide containing at least one N-linked glycosylation site. Methods of producing the targeted therapeutic may include nucleotide acids encoding the same and host cells co-expressing GNPT. Pharmaceutical compositions comprising the targeted therapeutic and methods of using the same to treat a lysosomal storage disease.

Provided herein is a construct comprising, in combination: an EphA3, EphA2 and/or EphB2 binding ligand; and at least one effector molecule. In some embodiments, the at least one effector molecule comprises a therapeutic agent, a nanoparticle, a detectable group, a lipid, or a liposome. In some embodiments, the construct is a fusion protein and/or a covalent conjugate. Further provided is a construct comprising, in combination: a ligand that binds to EphA2, EphA3 and/or EphB2; a ligand that binds to IL-13R2; and at least one effector molecule. Also provided are methods of use thereof for treating cancer.

Compositions, methods, and uses of recombinant nucleic acids to elicit Th1- or Th2-biased immune responses in an individual are presented. In some embodiments, the nucleic acid includes a first nucleic acid segment encoding a MHC-II trafficking signal and a second nucleic acid segment encoding a polytope peptide and a Th1-specific polarizing epitope or a Th2-specific polarizing epitope. Optionally, the Th1-specific polarizing epitope or the Th2-specific polarizing epitope is part of the polytope peptide. The recombinant nucleic acid can be inserted in a viral, bacterial, or yeast expression vector so that the recombinant protein encoded by the recombinant nucleic acid can be expressed in an antigen presenting cell of an individual to elicit Th1- or Th2-biased immune response in the individual.

Disclosed are exosomes that include a packaging protein and a cargo RNA in which the packaging protein binds specifically to the cargo RNA. The packaging protein is a fusion protein that includes an RNA-binding domain and an exosome-targeting domain. The cargo RNA includes an RNA-motif that the RNA-binding domain of the fusion protein binds specifically such that the cargo RNA is packaged in the lumen of the exosomes.

A CRISPR/Cas system and method for editing or regulating transcription of a genome of a cell are provided, wherein the system includes a Cas endonuclease fused with one or more degron sequences and at least one activatable cognate single guide RNA harboring an inactivation sequence in a non-essential region of the cognate sgRNA, wherein said inactivation sequence comprises one or more endonuclease recognition sites of, e.g., a ribozyme.

Systems and methods are presented that allow for selection of tumor neoepitopes that are then used to generate a recombinant polytope that is optimized for proper trafficking and processing. In preferred methods, the polytope is encoded in a viral expression system that is used as a therapeutic agent.

A peptide can have a sequence of one of SEQ ID NOs: 78-91. A conformationally-constrained kinked peptide includes: a conformationally-constraining portion and a kinked portion linked to the conformationally-constraining portion that conformationally constrains the kinked portion having a peptide sequence of one of SEQ NOs: 78-97. A cell-targeting compound can include a conformationally-constrained kinked peptide having a peptide sequence of one of SEQ ID NOs: 78-97. The peptide sequence can be one of SEQ ID NOs: 78-97, or 78-91, or 92-97. A cell-targeting compound can include a conformationally-constrained kinked peptide linked to a branched linker with one branch arm linked to a specific targeting moiety and one branch arm linked to a general targeting moiety. The specific targeting moiety can be an antibody. The general targeting moiety can be a lipid or cholesterol derivative.

The present invention relates to the use of immunogenic peptides comprising a T-cell epitope derived from an allograft antigen and a redox motif such as C-(X)2-[CST] (SEQ ID NO: 18) or [CST]-(X)2-C(SEQ ID NO: 19) in the prevention and/or treatment of allograft rejection and in the manufacture of medicaments therefore.

Provided herein is a construct comprising, in combination: an EphA3, EphA2 and/or EphB2 binding ligand; and at least one effector molecule. In some embodiments, the at least one effector molecule comprises a therapeutic agent, a nanoparticle, a detectable group, a lipid, or a liposome. In some embodiments, the construct is a fusion protein and/or a covalent conjugate. Further provided is a construct comprising, in combination: a ligand that binds to EphA2, EphA3 and/or EphB2; a ligand that binds to IL-13R2; and at least one effector molecule. Also provided are methods of use thereof for treating cancer.