A method and a kit for detecting genome editing and application thereof belongs to the field of genome editing efficiency detection, and the getPCR method for determining genome editing efficiency includes quantifying wild-type DNA in a genome to be tested and calculating the percentage of the wild-type DNA to determine the genome editing efficiency. The method has been proved to have good detection accuracy and simple operation, and can be applied to all genome editing methods to quantify genome editing efficiency and screen single-cell clones.

Provided herein, in some embodiments, are enzymatic methods for producing an oligonucleotide comprising phosphoramidate-linked nucleotides, and compositions comprising the oligonucleotide thus produced.

Provided herein, in some embodiments, are enzymatic methods for producing an oligonucleotide comprising phosphoramidate-linked nucleotides, and compositions comprising the oligonucleotide thus produced.

Provided herein are modified Archaeal family B polymerases derived from the Archaeal microorganism Thermococcus sp. EP1 that exhibit improved incorporation of nucleotide analogues utilized in DNA sequences.

Provided herein are modified Archaeal family B polymerases derived from the Archaeal microorganism Thermococcus sp. EP1 that exhibit improved incorporation of nucleotide analogues utilized in DNA sequences.

The present invention relates to methods for the joint analysis of regulation of gene expression and gene expression in single cells. Provided are methods for obtaining gene expression information for a single nucleus, the methods comprising deriving a DNA library from the genomic DNA in one or more nuclei and deriving an RNA library from the RNA in one or more nuclei, sequencing the molecules in the RNA library and the DNA library, and correlating the RNA library and the DNA library for each of the one or more nuclei.

The present invention relates to methods for the joint analysis of regulation of gene expression and gene expression in single cells. Provided are methods for obtaining gene expression information for a single nucleus, the methods comprising deriving a DNA library from the genomic DNA in one or more nuclei and deriving an RNA library from the RNA in one or more nuclei, sequencing the molecules in the RNA library and the DNA library, and correlating the RNA library and the DNA library for each of the one or more nuclei.

De novo polynucleotide synthesis is performed with a substrate-bound polymerase. The polymerase is attached to a solid substrate such as a microelectrode array. The polymerase adds nucleotides to growing polynucleotides strands that are also attached to the solid substrate. Spatial control of polymerase activity is achieved by changing the rate of nucleotide polymerization at selected locations on the surface of the solid substrate. The rate of polymerization is changed by inhibiting or promoting activity of the polymerase. In some implementations, activation of electrodes in the microelectrode array changes the rate of nucleotide polymerization. Nucleotides are added to the growing polynucleotide strands at areas where the polymerase is active. By varying the locations where the substrate-bound polymerase is active and the species of nucleotide added, a population of polynucleotides with different, arbitrary sequences is synthesized on the surface of the solid substrate.

De novo polynucleotide synthesis is performed with a substrate-bound polymerase. The polymerase is attached to a solid substrate such as a microelectrode array. The polymerase adds nucleotides to growing polynucleotides strands that are also attached to the solid substrate. Spatial control of polymerase activity is achieved by changing the rate of nucleotide polymerization at selected locations on the surface of the solid substrate. The rate of polymerization is changed by inhibiting or promoting activity of the polymerase. In some implementations, activation of electrodes in the microelectrode array changes the rate of nucleotide polymerization. Nucleotides are added to the growing polynucleotide strands at areas where the polymerase is active. By varying the locations where the substrate-bound polymerase is active and the species of nucleotide added, a population of polynucleotides with different, arbitrary sequences is synthesized on the surface of the solid substrate.

The disclosure provides a high-fidelity polymerase with preference for gapped DNA and use thereof. The Klenow fragment (KlenDr) derived from Deinococcus radiodurans DNA polymerase I, which has the high-fidelity polymerization characteristics, is independent of 3′-5′ proofreading exonuclease activity, has the preference for binding gapped DNA, and is different from the existing commercial high-fidelity polymerase. Due to the specific affinity of KlenDr to gapped DNA substrate, the 3′ end of the forward primer will not be cut off, and the downstream nucleotide chain is rarely replaced.