Provided herein are engineered variants of archaeal, prokaryotic, and eukaryotic polymerases that exhibit enhanced thermostability, enhanced incorporation of 3′ modified nucleotides, and improved uracil-tolerance, in polymerase-catalyzed nucleotide extension reactions relative to wild type polymerase enzymes. Also provided are uses of the engineered polymerases for forming complexed polymerases, forming binding complexes and forming ternary complexes, and uses for conducting nucleic acid sequencing reactions.

Recombinant DPO4-type DNA polymerase variants with amino acid substitutions that confer modified properties upon the polymerase for improved single molecule sequencing applications are provided. Such properties may include enhanced binding and accurate incorporation of bulky nucleotide analog substrates into daughter strands and the like. Also provided are compositions comprising such DPO4 variants and nucleotide analogs, as well as nucleic acids which encode the polymerases with the aforementioned phenotypes.

The disclosure provides systems, methods, and compositions for a target specific nuclease and a blunting enzyme to correct frameshift mutations for genome editing and treatment of diseases. In some embodiments, the target specific nuclease and the blunting enzyme are combined with a guide RNA and/or a microhomology-mediated end joining (MMEJ) inhibitor.

Disclosed are methods for isolating polymerase complexes from a mixture of polymerase complex components. The polymerase complexes can comprise a nanopore to provide isolated nanopore sequencing complexes. The methods relate to the positive and negative isolation of the polymerase complexes and/or nanopore sequencing complexes. Also disclosed is a nucleic acid adaptor for isolating active polymerase complexes, polymerase complexes comprising the nucleic acid adaptor, and methods for isolating active polymerase complexes using the nucleic acid adaptor.

The present disclosure includes compositions and methods for improved DNA amplification reactions. In particular, the present disclosure provides compositions and methods for hot-start PCR applications using DNA polymerase inhibitors that minimize non-specific DNA amplification by inactivating DNA polymerase at lower temperatures.

A method for purifying nucleotides is provided, that includes preparing a solution comprising (a) 3′-blocked nucleotides, (b) 3′-OH nucleotides, (c) a polishing polymerase, and (d) a template. The polishing polymerase and the template are used to selectively polymerize the 3′-OH nucleotides and thus reduce a concentration in the solution of the 3′-OH nucleotides relative to the 3′-blocked nucleotides.

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.

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.

Disclosed are compositions and methods that enable loop-mediated isothermal amplification (LAMP) of one or more nucleic acid targets without the need for conventional LAMP primer design customized to each target. A transduction reaction is performed upstream from the LAMP reaction. The transduction reaction generates a single stranded DNA (ssDNA) oligonucleotide when the target nucleic acid is present in the sample. The ssDNA generated in the transduction reaction functions as a required LAMP primer for a universal LAMP template. The ssDNA thus promotes the LAMP reaction. Analysis of the LAMP products can determine the presence of the one or more nucleic acid targets.

A method for synthesizing a nucleic acid includes providing an initiator having a 3′ end having an unprotected hydroxyl group, providing a nucleic acid polymerase having at least a conservative catalytic polymerase domain of a family-B DNA polymerase, providing a nucleotide monomer, and exposing the initiator to the nucleotide monomer in the presence of the nucleic acid polymerase and a metal cofactor which is a bivalent cation, and in the absence of a template, such that the nucleotide monomer is incorporated to the initiator. The kit includes the initiator, the nucleic acid polymerase, and the nucleotide monomer, and is used according to the method.