Methods of assembling modified adenoviruses, libraries of adenoviral gene modules and compositions thereof are provided herein.

Methods and constructs for engineering circular RNA are disclosed. In some embodiments, the methods and constructs comprise a vector for making circular RNA, the vector comprising the following elements operably connected to each other and arranged in the following sequence: a.) a 5′ homology arm, b.) a 3′ group I intron fragment containing a 3′ splice site dinucleotide, c.) optionally, a 5′ spacer sequence, d.) a protein coding or noncoding region, e.) optionally, a 3′ spacer sequence, f) a 5′ Group I intron fragment containing a 5′ splice site dinucleotide, and g.) a 3′ homology arm, the vector allowing production of a circular RNA that is translatable or biologically active inside eukaryotic cells. Methods for purifying the circular RNA produced by the vector and the use of nucleoside modifications in circular RNA produced by the vector are also disclosed.

The present application describes structures, systems, and methods for modeling and analysis of single-strand break (SSB) signaling and repair in a cell-free system. Also provided are methods of making the SSB structures and SSB signaling and repair systems. Methods and systems for identifying modulators of DNA damage response (DDR) activity for SSB repair are also described as well as methods of inhibiting SSB repair.

Simultaneous expression of a plurality of foreign genes by using a stealthy RNA gene expression system that is a complex that does not activate the innate immune mechanism and is formed from an RNA-dependent RNA polymerase, a single-strand RNA binding protein, and negative-sense single-strand RNAs including the following (1) to (8): (1) a target RNA sequence that codes for any protein or functional RNA; (2) an RNA sequence forming a noncoding region and derived from mRNA; (3) a transcription initiation signal sequence recognized by the RNA-dependent RNA polymerase; (4) a transcription termination signal sequence recognized by the polymerase; (5) an RNA sequence containing a replication origin recognized by the polymerase; (6) an RNA sequence that codes for the polymerase; (7) an RNA sequence that codes for a protein for regulating the activity of the polymerase; and (8) an RNA sequence that codes for the single-strand RNA binding protein.

The disclosure provides methods and compositions for the integration (insertion) of a donor DNA molecule into a target DNA molecule. In general, the methods include contacting a target DNA molecule with a linear donor DNA molecule and a Cas 1 protein, where the target DNA molecule includes an AT-rich region (e.g., in some cases positioned 5 and within 50 nucleotides of a region that forms a DNA cruciform structure), where the contacting is not in a bacterial or archaeal cell (e.g., the contacting is in vitro outside of a cell, inside of a eukaryotic cell, etc.), and provides for integration of the donor DNA molecule into the target DNA molecule.

Adeno-associated virus (AAV) Clade F vectors or AAV vector variants (relative to AAV9) for precise editing of the genome of a cell and methods and kits thereof are provided. Targeted genome editing using the AAV Clade F vectors or AAV vector variants provided herein occurred at frequencies that were shown to be 1,000 to 100,000 fold more efficient than has previously been reported. Also provided are methods of treating a disease or disorder in a subject by editing the genome of a cell of the subject via transducing the cell with an AAV Clade F vector or AAV vector variant as described herein and further transplanting the transduced cell into the subject to treat the disease or disorder of the subject. Also provided herein are methods of treating a disease or disorder in a subject by in vivo genome editing by directly administering the AAV Clade F vector or AAV vector variant as described herein to the subject.

The present disclosure discloses polynucleotide sequences that can be used to regulate gene expression in plants. Terminator sequences from Sorghum bicolor and Oryza sativa that are functional in plants are disclosed. Nucleic acid molecules, recombinant expression constructs, plants and seed comprising these terminator sequences are further disclosed.

Methods and constructs for engineering circular RNA are disclosed. In some embodiments, the methods and constructs comprise a vector for making circular RNA, the vector comprising the following elements operably connected to each other and arranged in the following sequence: a.) a 5′ homology arm, b.) a 3′ group I intron fragment containing a 3′ splice site dinucleotide, c.) optionally, a 5′ spacer sequence, d.) a protein coding or noncoding region, e.) optionally, a 3′ spacer sequence, f.) a 5′ Group I intron fragment containing a 5′ splice site dinucleotide, and g.) a 3′ homology arm, the vector allowing production of a circular RNA that is translatable or biologically active inside eukaryotic cells. Methods for purifying the circular RNA produced by the vector and the use of nucleoside modifications in circular RNA produced by the vector are also disclosed.

Methods and constructs for engineering circular RNA are disclosed. In some embodiments, the methods and constructs comprise a vector for making circular RNA, the vector comprising the following elements operably connected to each other and arranged in the following sequence: a.) a 5′ homology arm, b.) a 3′ group I intron fragment containing a 3′ splice site dinucleotide, c.) optionally, a 5′ spacer sequence, d.) a protein coding or noncoding region, e.) optionally, a 3′ spacer sequence, f) a 5′ Group I intron fragment containing a 5′ splice site dinucleotide, and g.) a 3′ homology arm, the vector allowing production of a circular RNA that is translatable or biologically active inside eukaryotic cells. Methods for purifying the circular RNA produced by the vector and the use of nucleoside modifications in circular RNA produced by the vector are also disclosed.

There is disclosed an improved, safer and commercially efficient process for developing genetically engineered cells. More specifically, there is disclosed a process comprises introducing a donor DNA construct, a guide RNA, and an RNA-guided nuclease with the host cells to he transfected; and introducing the three components into the host cell. There is further disclosed a donor DNA construct designed for inserting a CAR (chimeric antigen receptor) into a defined genomic site of a host cell. Further, the present disclosure provides a host cell transfected with a CAR that lacks viral vectors that can present a safety concern. The disclosure provides for more efficient and more cost-effective process for engineering T cells to express CAR constructs.