Provided herein are modified Archaeal family B polymerases derived from the Archaeal microorganism Pyrococcus-abyssi that exhibit improved incorporation of nucleotide analogues utilized in DNA sequencing.

Presented herein are altered polymerase enzymes for improved incorporation of nucleotides and nucleotide analogues, in particular altered polymerases that maintain high fidelity under reduced incorporation times, as well as methods and kits using the same.

Provided are mutant polymerases having DNA polymerase activity and reverse transcriptase activity or strand displacement activity, along with target nucleic acid amplification methods employing such mutant polymerases.

This disclosure relates to thermophilic family B DNA polymerases comprising a neutral amino acid residue at a certain position near the C-terminus of the catalytic domain, which corresponds to a position occupied by a basic amino acid residue in wild-type Pfu polymerase. The thermophilic family B DNA polymerases provided herein also comprise an N-terminal domain comprising a uracil-binding pocket that has been modified to reduce template uracil binding. Related uses, methods, and compositions are also provided. In some embodiments, the polymerases comprise a 3′-5′ exonuclease domain and/or a sequence nonspecific dsDNA binding domain.

Presented herein are altered polymerase enzymes for improved incorporation of nucleotides and nucleotide analogues, in particular altered polymerases that maintain high fidelity under reduced incorporation times, as well as methods and kits using the same.

The present disclosure provides methods and systems for processing a nucleotide mixture. A nucleotide mixture can be purified. A nucleotide mixture can be processed for use in nucleic acid synthesis. A nucleotide mixture can be processed for use in nucleic acid sequencing.

Embodiments of the present disclosure relate to compositions and kits for use in sequencing by synthesis to improve fluorescent signal intensity and reduce signal decay caused by short wavelength light source during the imaging events. Methods of sequencing using the compositions and kits described herein are also provided.

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.

Providing herein, among other things, are kits, compositions and methods that relate to DNA fragmentation. An embodiment of a composition provides combining: one or more enzymes capable of nick translating activity, a dNTP mix comprising at least one dNTP having a modified base, and at least one modification-sensitive nicking endonuclease that is prevented from nicking DNA if its recognition site contains the modified base. When the composition is added to a sample comprising a double-stranded DNA template that comprises recognition sites for the modification-sensitive nicking endonuclease, a reaction mix was produced which could be incubated for any time period in excess of about 5 minutes to produce fragments of a desired size of the double-stranded DNA template. In this method, the fragments produced include the modified base and, as such, are not re-nicked by the nicking endonuclease.

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