Provided herein are compositions, systems, and methods using multiple ligases, wherein at least one of the ligases is an adenylation-deficient ATP-dependent ligase or an un-adenylated ATP-dependent ligase (e.g., present in an ATP free mixture). In certain embodiments, multiple ligases are used to ligate a pre-adenylated double stranded sequence to a non-adenylated double stranded sequence (e.g., the adenylation-deficient ATP-dependent ligase or un-adenylated ATP-dependent ligase ligates the first strand, and a second ligase ligates the second strand). In other embodiments, provided herein are mutant T4 ligases (e.g., K159S mutant or K159C mutant).

The invention relates to new methods of attaching one or more polynucleotide binding proteins to a target polynucleotide. The invention also related to new methods of characterising target polynucleotides.

The invention relates to new methods of attaching one or more polynucleotide binding proteins to a target polynucleotide. The invention also related to new methods of characterising target polynucleotides.

The present invention relates, e.g., to in vitro method, using isolated protein reagents, for joining two double stranded (ds) DNA molecules of interest, wherein the distal region of the first DNA molecule and the proximal region of the second DNA molecule share a region of sequence identity, comprising contacting the two DNA molecules in a reaction mixture with (a) a non-processive 5 exonuclease; (b) a single stranded DNA binding protein (SSB) which accelerates nucleic acid annealing; (c) a non strand-displacing DNA polymerase; and (d) a ligase, under conditions effective to join the two DNA molecules to form an intact double stranded DNA molecule, in which a single copy of the region of sequence identity is retained. The method allows the joining of a number of DNA fragments, in a predetermined order and orientation, without the use of restriction enzymes.

Methods, assays, compositions and kits for the ligation of short polynucleotides are presented herein. The short polynucleotides are optionally no more than 7 nucleotides in length, and can be as short as 3 or 4 nucleotides in length. The ligation is optionally performed by CV ligase.

Modified nucleotides, and methods to modify nucleotides with a moiety or label, such as biotin, that permits their detection and results in a modified nucleotide, and methods of use of the modified nucleotide in quantitative and qualitative assays.

A number of T4 DNA ligase mutants exhibiting enhanced ligation activity in the presence of high salt concentrations compared to the wild-type ligase were engineered, characterized, and selected via gel electrophoresis of ligation products from a standard ligation assay. Ligase catalyzes the formation of phosphodiester bonds between the 5 and 3 ends of complementary cohesive ends or blunt ends of duplex DNA, a process that is vital to numerous molecular biology processes including cloning and sequencing.

This disclosure relates to methods for increasing capture efficiency of a spatial array using rolling circle amplification of a padlock probe that hybridizes to a capture probe. Also provided are methods for using such spatial arrays to detect a biological analyte in a biological sample.

Provided herein are methods of identifying a location of an RNA in a sample that include: (a) contacting the sample with an array comprising capture probes, where a capture probe comprises a capture domain and a spatial barcode; (b) releasing the RNA from the sample; (c) extending a 3 end of the capture probe using the capture domain-bound RNA as a template; (d) generating nick(s) in the extended capture probe-hybridized RNA and performing random-primed DNA synthesis; (e) performing end repair on the second strand DNA molecule; (f) adding a single adenosine nucleotide to the 3 end of the extended capture probe; (g) ligating a double-stranded sequencing adaptor to the double-stranded DNA product; and (h) determining all or a part of the sequence of the RNA, and the sequence of the spatial barcode, or complements thereof, and using the determined sequences to identify the location of the RNA in the sample.

The present invention pertains to a novel method for the generation of highly diverse RNA expressing vectors and vector libraries for use in targeted gene knock out, knock down and genome modification approaches. The invention pertains to a method for generating such higher order libraries without the need of classical cloning technologies. This is particularly useful for libraries based on large vectors wherein a sequence cannot be easily mutated with classical mutagenesis methods. The vectors and libraries generated according to the methods of the invention are in particular for RNA assisted silencing technologies such as RNA interference, and for targeted genome editing using the clustered regularly interspaced short palindromic repeats (CRISPR)/Cas system or similar RNA/DNA-encoded gene perturbation systems which use small guide RNAs to target the CRISPR complex to a specific genomic sequence. The invention provides also kits comprising the materials for performing the methods of the invention.