Provided herein are compositions and methods related to the treatment of an HPV infection and/or cancer in a subject.

The present disclosure provides materials and methods for treating a patient with Duchenne Muscular Dystrophy (DMD), e.g., through ex vivo and in vivo methods of genome editing. The present disclosure also relates to methods and compositions for use of self-inactivating/self-targeting CRISPR/Cas or CRISPR/Cpf1 systems to genetically modify cells, e.g., to modulate the expression, function, and/or activity of the dystrophin gene.

Recombinant adenovirus genomes that include an exogenous open reading frame (ORF) and a self-cleaving peptide coding sequence are described. Optimal placement of the exogenous genes for minimal impact on viral kinetics is further disclosed. Therapeutic applications of the recombinant adenoviruses are also described.

Recombinant adenovirus genomes that include an exogenous open reading frame (ORF) and a self-cleaving peptide coding sequence are described. Optimal placement of the exogenous genes for minimal impact on viral kinetics is further disclosed. Therapeutic applications of the recombinant adenoviruses are also described.

The present disclosure provides materials and methods for treating a patient with one or more conditions or disorders associated with ATXN2 whether ex vivo or in vivo. For example, the present disclosure provides materials and methods for treating a patient with Spinocerebellar ataxia type 1 (SCA2). Also provided are materials and methods for editing a ATXN2 gene in a cell by genome editing. The present disclosure also provides materials and methods for altering the contiguous genomic sequence of a ATXN2 gene in a cell. In addition, the present disclosure provides one or more gRNAs for editing a ATXN2 gene. Also provided are therapeutics comprising at least one or more gRNAs for editing a ATXN2 gene. In addition, the present disclosure provides therapeutics for treating patients with a ATXN2 related condition or disorder.

The present invention relates to a viral vector comprising a transposon and a nucleic acid encoding a transposase. The transposon comprises a transgene, or insertion site for a transgene, for integration into the genome of a target cell. The expression of the transposase is controlled such that the transposase is not expressed during production or packaging of the viral vector. Furthermore, the transposon comprises a packaging signal for the virus genome, thus preventing the packaging of any viral genome from which the transposon has been removed. Also provided is a process for producing a modified mammalian cell and a process for producing a mammalian cell with a modified genome, using a viral vector of the invention.

Systems and methods are presented that allow for selection of tumor neoepitopes that are then used to generate recombinant nucleic acids that encode one or more polytopes that are optimized for proper trafficking and processing. In preferred methods, the polytopes are encoded in a plasmid and/or a viral expression system for use as a therapeutic agent.

Systems and methods are presented that allow for selection of tumor neoepitopes that are then used to generate recombinant nucleic acids that encode one or more polytopes that are optimized for proper trafficking and processing. In preferred methods, the polytopes are encoded in a plasmid and/or a viral expression system for use as a therapeutic agent.

Recombinant adenovirus genomes that include an exogenous open reading frame (ORF) and a self-cleaving peptide coding sequence are described. Optimal placement of the exogenous genes for minimal impact on viral kinetics is further disclosed. Therapeutic applications of the recombinant adenoviruses are also described.

The present invention relates to a vaccine comprising the insertion of three genes, the TAA/ecdCD40L EA1 and CDA, driven by promoters L-plastin/cytosinedeaminase and CMV as a three gene, three transcription unit oncolytic virus as a conditionally replication competent adenoviral vector which replicates only in tumor cells. In these transcription units, the E1A gene of the adenoviral vector as well as the cytosine deaminase gene are under the control of the L-plastin promoter, while the TAA/ecdCD40L transcription unit is under control of a the CMV promoter.