Sequencing adaptors and methods are provided for preparation of polynucleotides for sequencing. The sequencing adaptors contain a portion of a recognition sequence for a methyl-dependent endonuclease. Unwanted adaptor dimers that form during ligation of adaptors to target polynucleotides produce a complete restriction sequence and are cleaved by the endonuclease, followed by exonuclease digestion, thereby removing the dimers.

Sequencing adaptors and methods are provided for preparation of polynucleotides for sequencing. The sequencing adaptors contain a portion of a recognition sequence for a methyl-dependent endonuclease. Unwanted adaptor dimers that form during ligation of adaptors to target polynucleotides produce a complete restriction sequence and are cleaved by the endonuclease, followed by exonuclease digestion, thereby removing the dimers.

The present disclosure is directed to methods of producing a modified nucleic acid comprising a precise deletion in a target nucleic acid in a cell comprising generating, within the cell, a first single strand break on a first strand of the target nucleic acid and a second single strand break on a second strand of the target nucleic acid, thereby forming a double strand break in the target nucleic acid having a first 3′ overhang and a second 3′ overhang; processing the first 3′ overhang and the second 3′ overhang with an exonuclease molecule, thereby deleting the segment of the target nucleic acid that was located between the first single strand break and the second single strand break, and forming a processed double strand break; and allowing the processed double strand break to be repaired by at least one DNA repair pathway, thereby producing the modified nucleic acid comprising the precise deletion in the target nucleic acid in the cell. Gene editing systems, vectors, polynucleotides, and methods of treatment are also disclosed herein.

A composition used in targeted mutagenesis is provided, which includes a first expression cassette comprising a nucleotide sequence which encodes a CAS9 endonuclease; a second expression cassette comprising a nucleotide sequence which encodes a guide RNA sequence, wherein the guide RNA sequence is complementary to a target genome nucleotide sequence in a cell; and a third expression cassette comprising a nucleotide sequence which encodes a Trex2 exonuclease (Trex2) gene. The first, second, and third expression cassettes may be a part or a portion of one or more expression vectors.

Provided herein are methods, systems, and compositions for seamless nucleic acid assembly. Methods, systems, and compositions as provided herein provide for efficient assembly of nucleic acids without primer removal. Methods, systems, and compositions for seamless nucleic acid assembly comprise use of an endonuclease or exonuclease, optionally in conjunction with additional enzymes to assemble nucleic acids or polynucleotides.

The disclosure provides, for example, single stranded, covalently closed DNA that does not form a double stranded structure longer than 100 base pairs. The ssDNA may encode an effector sequence, for instance a therapeutic protein. The ssDNA may comprise a nuclear targeting sequence (NTS). In some embodiments, the ssDNA shows decreased activation of the innate immune system compared to an otherwise similar dsDNA.

Various embodiments are directed to using nuclease expression in tissues that influences cell-free DNA end signatures/motifs and size of overhang between DNA strands. Embodiments can identify a nuclease that is being differentially regulated in abnormal cells relative to normal cells. Embodiments can determine that the nuclease preferentially cuts DNA into DNA molecules having: (i) a particular sequence end signature; or (ii) a specified length of overhang between a first strand and a second strand. A parameter can be determined for a biological sample based on an amount of DNA molecules that include an end sequence corresponding to the particular sequence end signature and/or a measured property correlating to the specified length of overhang. The parameter can be used to determine a characteristic of a tissue type, a fractional concentration of clinically-relevant DNA molecules, or a level of abnormality of a tissue type in the biological sample.

The present disclosure is directed to methods of producing a modified nucleic acid comprising a precise deletion in a target nucleic acid in a cell comprising generating, within the cell, a first single strand break on a first strand of the target nucleic acid and a second single strand break on a second strand of the target nucleic acid, thereby forming a double strand break in the target nucleic acid having a first 3′ overhang and a second 3′ overhang; processing the first 3′ overhang and the second 3′ overhang with an exonuclease molecule, thereby deleting the segment of the target nucleic acid that was located between the first single strand break and the second single strand break, and forming a processed double strand break; and allowing the processed double strand break to be repaired by at least one DNA repair pathway, thereby producing the modified nucleic acid comprising the precise deletion in the target nucleic acid in the cell. Gene editing systems, vectors, polynucleotides, and methods of treatment are also disclosed herein.

Provided herein are methods, systems, and compositions for seamless nucleic acid assembly. Methods, systems, and compositions as provided herein provide for efficient assembly of nucleic acids without primer removal. Methods, systems, and compositions for seamless nucleic acid assembly comprise use of an endonuclease or exonuclease, optionally in conjunction with additional enzymes to assemble nucleic acids or polynucleotides.

Provided herein are methods, systems, and compositions for seamless nucleic acid assembly. Methods, systems, and compositions as provided herein provide for efficient assembly of nucleic acids without primer removal. Methods, systems, and compositions for seamless nucleic acid assembly comprise use of an endonuclease or exonuclease, optionally in conjunction with additional enzymes to assemble nucleic acids or polynucleotides.