The present disclosure provides shuttle vectors for editing exogenous polynucleotides in heterologous live cells, as well as automated methods, modules, and multi-module cell editing instruments and systems for performing the editing methods.

The present invention relates to a method for treating ocular disease in a subject in need thereof comprising a step of administering to said subject a therapeutically amount of an inhibitor of SOX21 gene expression and/or activity. By studying a mouse model of congenital microcoria, the inventors demonstrate that this ultra-rare and purely ocular disease is due to unanticipated complex mechanisms linked with 3D regulation of gene expression. They propose that the disease is due to the illegitimate expression of a transcription factor, SOX21, induced by the adoption of a DCT enhancer(s). They show that SOX21 binds to a regulatory region of the Tgfβ2 gene and the inventors demonstrate overexpression of this trophic factor in the iris and accumulation of its product in the aqueous humor of the mouse carrying the minimal MCOR deletion which recapitulates the observed accumulation in patients with POAG and one of our patient with MCOR.

The present invention relates to an engineered Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) system comprising engineered dual guide nucleic acids (e.g., RNAs) capable of activating a CRISPR-Associated (Cas) nuclease, such as a type V-A Cas nuclease. Also provided are methods of targeting, editing, and/or modifying a nucleic acid using the engineered CRISPR system, and compositions and cells comprising the engineered CRISPR system.

The present disclosure provides adenine base editors (ABEs) that are variants of known adenine base editors. The adenosine deaminase domain of a known ABE was modified to produce adenosine deaminase variants. The deaminase variants provided herein have broader compatibility with diverse napDNAbp domains, such as Cas homologs, for base editing applications. The ABEs provided herein comprise a deaminase variant and a napDNAbp domain. The ABEs provided herein exhibit reduced off-target editing effects while retaining high on-target editing efficiencies. These ABEs exhibit reduced off-target DNA editing effects and reduced off-target editing effects in cellular mRNA. In addition, methods for targeted nucleic acid editing are provided. Further provided are pharmaceutical compositions comprising the ABEs. Also provided are vectors and kits useful for the generation and delivery of the ABEs, including vector systems for engineering the ABEs through directed evolution. Cells containing such vectors and ABEs are also provided. Further provided are methods of treatment comprising administering the ABEs.

CRISPR/Cas-related compositions and methods which provide for efficient gene editing of eukaryotic cells using modified gRNAs.

The present invention includes methods and compositions for elimination of polyomaviruses, such as John Cunningham Virus (JVC), from host cells, and the treatment of polyomavirus related diseases, such as progressive multifocal leukoencephalopathy (PML). The compositions include isolated nucleic acid sequences comprising an CRISPR-associated endonuclease and a guide RNA, wherein the guide RNA is complementary to a target sequence in a polyomavirus.

Compositions and methods for binding to a target sequence of interest are provided. The compositions find use in cleaving or modifying a target sequence of interest, visualization of a target sequence of interest, and modifying the expression of a sequence of interest. Compositions comprise RNA-guided nuclease (RGN) polypeptides, CRISPR RNAs, trans-activating CRISPR RNAs, guide RNAs, and nucleic acid molecules encoding the same. Vectors and host cells comprising the nucleic acid molecules are also provided. Further provided are RGN systems for binding a target sequence of interest, wherein the RGN system comprises an RNA-guided nuclease polypeptide and one or more guide RNAs.

The present invention provides a use of a Cas protein, and a method and a kit for detecting target nucleic acid molecules. The method for detecting target nucleic acid molecules comprises adding a guide RNA, a Cas12a, and a nucleic acid probe into a reaction system containing target nucleic acid molecules to be detected, and detecting it after the reaction is completed.

Disclosed are new nucleic acid base-editing systems comprising fusion proteins comprising a) an RNA-programmable nucleic acid recognition module or other suitable nucleic acid recognition module, b) a light inducible reactive oxygen generator. Further disclosed are methods and kits to modify or mutagenize a target DNA region in prokaryotic or eukaryotic cells or organisms.

The present disclosure provides treatment modalities, e.g., strategies, treatment methods, patient stratification methods, combinations, and compositions that are useful for the treatment of disorders, e.g., proliferative disorders, such as certain cancer. Some aspects of this disclosure provide treatment modalities, methods, strategies, compositions, combinations, and dosage forms for the treatment of cell proliferative disorders, e.g., cancers with decreased activity or function, or loss of function, of SMARCA4 with a SMARCA2 antagonist.