Systems and methods for targeted gene modification, targeted insertion, perturbation of gene transcripts, and nucleic acid editing. Novel nucleic acid targeting systems comprise components of CRISPR systems, reverse transcriptase, pegRNAs, paired pegRNAs or modified pegRNAs, DNA processing proteins, recombinases, proteins for inhibiting nucleases, and proteins for promoting ssDNA annealing.

The present invention refers to a fusion protein or a protein complex comprising a DNA binding protein (DnaBP), a nucleobase modifying protein (NMP), and a Base Excision Repair associated protein (BERAP. Also, described herein are a method of replacing a cytosine with a guanine on a DNA strand in a cell and a method of treating a subject having or suspected of having a disease or disorder.

A DNA methylation editing kit comprises: (1) a fusion protein of inactivated CRISPR-associated endonuclease Cas9 (dCas9) having no nuclease activity and a tag peptide array in which plural tag peptides are linked by linkers, or an RNA or DNA coding therefor; (2) a fusion protein(s) of a tag peptide-binding portion and a methylase or demethylase, or an RNA(s) or DNA(s) coding therefor; and (3) a guide RNA(s) (gRNA(s)) comprising a sequence complementary to a DNA sequence within 1 kb of a desired site of methylation or demethylation, or a DNA(s) expressing the gRNA(s).

This document provides methods and materials for assembling nucleic acid constructs (e.g., TALENs). For example, methods for assembling TALEs that are rapid, flexible for use in many cloning scaffolds (such as common nuclease and nickase backbones), and achievable with standard molecular biology laboratory tools, thereby making TALEs a more accessible genome system, are provided.

Engineered CRISPR-Cas9 nucleases with altered and improved PAM specificities and their use in genomic engineering, epigenomic engineering, and genome targeting.

Disclosed herein are polypeptides, polynucleotides encoding, cells and organisms comprising novel DNA-binding domains, including TALE DNA-binding domains. Also disclosed are methods of using these novel DNA-binding domains for modulation of gene expression and/or genomic editing of endogenous cellular sequences.

Fusion constructs encoding RNase-H-like domain containing compositions are disclosed. Disclosed are also compositions and methods utilizing RNase-H-like domain containing compositions for the treatment of cancer. Also disclosed are the methods of making and using the RNase-H-like domain containing compositions in treating various diseases, conditions, and cancer.

Provided herein are genetic circuits and cell state classifiers for detecting the microRNA profile of a cell. The cell state classifiers of the present disclosure utilize phosphorylation state of a transcription factor to control classifier output. Kinases and phosphatase pairs that function in phosphorylating or dephosphorylating the transcription factor are integrated into the circuit, their expression tuned by the presence of microRNAs of interest (e.g., in a cell). The genetic circuits and cell state classifiers may be used in various applications (e.g., therapeutic or diagnostic applications).

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.

The present disclosure relates to base-editing systems including a fusion protein including a DNA-binding domain and a cytidine deaminase domain and a non-protein uracil-DNA glycosylase inhibitor, and methods of using the same. The DNA-binding domains of base-editing systems of the present disclosure include domains with a variety of target region possibilities, which increase the number and type of sequences that can be edited. The npUGIs of the base-editing systems of the present disclosure improve UDG inhibition (e.g., UDG inhibition is more complete) and are suitable for use in a wide range of organisms.