Disclosed herein are methods and compositions for generating a single-stranded break in a target sequence, which facilitates targeted integration of one or more exogenous sequences.

The instant disclosure relates to the use of engineered proteins such as Cas9, Cpfl, TALE and Zinc finger proteins attached with a viral integrases, recombinase, or transposase in order to deliver a DNA sequence of interest (or gene of interest) to a targeted site in a genome of a cell or organism. The use of a Cas9 that is inactive for its function in cutting DNA will allow the use of Cas9 proteins ability to target DNA by the use of RNA guides without causing DNA breaks as intended in other systems for homologous recombination. The use of zinc finger proteins or TALE (engineered proteins that bind specific sequences of DNA) attached to the viral integrase or the recombinase is also disclosed. The system may be used for laboratory and therapeutic purposes. A gene of interest can be included in a cell with a gene lacking the ability to produce its gene product to recover the normal gene product in the cell (e.g. gene product may be a protein or specialized RNA).

Nucleases and methods of using these nucleases for alteration of a CFTR gene and generation of cells and animal models.

Disclosed herein are methods and compositions for targeted integration of an exogenous sequence into the human PPP1R12C locus, for example, for expression of a polypeptide of interest.

Described herein are methods and compositions for genomic editing. Endonucleases for genomic editing involve inducing breaks in double stranded DNA, for which knock-ins are notoriously inefficient for relying on random integration of homologous DNA sequences into the break site by repair proteins. To address these issues, described herein are novel recombinant fusion proteins that actively recruit linear DNA inserts in closer proximity to the genomic cleavage site, increasing integration efficiency of large DNA fragments into the genome. Such improvements to genomic editing technology allow one to use lower linear DNA concentrations without sacrificing efficiency and can be further combined with other features, such as fluorescent protein reporting systems.

Described herein is a chimeric antigen receptor (CAR) platform with the ability to (a) serve as an ON/OFF switch (with the ability for tenability/titrability), (b) sense multiple antigens and perform logic computations, and/or (c) independently regulate multiple signaling pathways. The compositions provided herein permit the degree of control and discrimination necessary to optimize CAR T cell therapy. Also described herein are cells comprising such compositions and the use of these compositions and/or cells in the treatment of cancer.

The present invention provides methods of systems and methods of site specific methylation.

Provided herein are systems, compositions, and methods for the incorporation of unnatural amino acids into proteins via nonsense suppression or rare codon suppression. Nonsense codons and rare codons may be introduced into the coding sequence of a protein of interest using a CRISPR/Cas9-based nucleobase editor described herein. The nucleobase editors are able to be programmed by guide nucleotide sequences to edit the target codons in the coding sequence of the protein of interest. Also provided are application enabled by the technology described herein.

The present disclosure generally relates to, inter alia, a new class of chimeric Notch receptors containing a synthetic zinc finger transcriptional effector (synZTE) module, engineered to modulate gene expression and cellular activities in a ligand-dependent manner. The new Notch receptors surprisingly retain the ability to transduce signals in response to ligand binding despite that the Notch extracellular subunit (NEC), which includes the negative regulatory region (NRR) previously believed to be essential for the functioning of Notch receptors, is partly or completely deleted. In addition, the synZTE is designed to bind orthogonal DNA target sequences in target organisms which in turn facilitates precise regulation of therapeutic gene expression with minimal off-target activity. Also provided are compositions and methods useful for producing such receptors, nucleic acids encoding same, host cells genetically modified with the nucleic acids, as well as methods for modulating an activity of a cell and/or for the treatment of various health conditions such as cancers.

Provided are improved compositions and methods that are used for identifying interacting zinc fingers in a zinc finger and DNA sequence context. The compositions and methods provide a comprehensive approach that takes into account the effect of adjacent zinc fingers, in part by expanding the repertoire of F2 fingers that are varied at amino acid position 6.