This invention pertains to optimized protein fusion linkers for creating multi-functional chimeric proteins and methods of using the same. Additionally, the invention pertains to chimeric proteins for use in guided endonuclease systems.

The present disclosure encompasses engineered meganucleases that bind and cleave recognition sequences within a dystrophin gene. The present disclosure also encompasses methods of using such engineered meganucleases to make genetically modified cells. Further, the disclosure encompasses pharmaceutical compositions comprising engineered meganuclease proteins, or polynucleotides encoding engineered meganucleases of the disclosure, and the use of such compositions for the modification of a dystrophin gene in a subject, or for treatment of Duchenne Muscular Dystrophy.

The present disclosure encompasses engineered meganucleases that bind and cleave recognition sequences within a dystrophin gene. The present disclosure also encompasses methods of using such engineered meganucleases to make genetically modified cells. Further, the disclosure encompasses pharmaceutical compositions comprising engineered meganuclease proteins, or polynucleotides encoding engineered meganucleases of the disclosure, and the use of such compositions for the modification of a dystrophin gene in a subject, or for treatment of Duchenne Muscular Dystrophy.

Methods for manufacturing genetically engineered T cells expressing a chimeric antigen receptor (CAR), such as a CAR that binds human CD19, BCMA, or CD70, and having multiple additional gene edits, for example, a disrupted Regnase-1 gene, a disrupted TGFBRII gene, a disrupted TRAC gene, a disrupted β2M gene, or a combination thereof, using CRISPR/Cas gene editing systems.

Methods for manufacturing genetically engineered T cells expressing a chimeric antigen receptor (CAR), such as a CAR that binds human CD19, BCMA, or CD70, and having multiple additional gene edits, for example, a disrupted Regnase-1 gene, a disrupted TGFBRII gene, a disrupted TRAC gene, a disrupted β2M gene, or a combination thereof, using CRISPR/Cas gene editing systems.

The present disclosure relates to systems, compositions and methods for modifying target nucleic acid sequences.

The present disclosure relates to systems, compositions and methods for modifying target nucleic acid sequences.

Described is an assay termed Programmable Enzyme-Assisted Selective Exponential Amplification (PASEA) that concurrently amplifies both wild type and mutant alleles while selectively cleaving the former. With time, the rare mutant alleles dominate, and are readily detectable by direct detection, Sanger sequencing, and other readily available methods. Also described are point-of-care assays and microfluidic devices for performing PASEA.

Described is an assay termed Programmable Enzyme-Assisted Selective Exponential Amplification (PASEA) that concurrently amplifies both wild type and mutant alleles while selectively cleaving the former. With time, the rare mutant alleles dominate, and are readily detectable by direct detection, Sanger sequencing, and other readily available methods. Also described are point-of-care assays and microfluidic devices for performing PASEA.

Materials and methods are provided for making plants (e.g., Nicotiana varieties) that are suitable for producing therapeutic polypeptides suitable for administration to humans and animals, particularly by making TAL effector endonuclease-induced mutations in genes encoding xylosyltransferases and fucosyltransferases.