Methods compositions and kits are provided for performing a chromatin or chromosome conformation capture assay in partitions.

Methods compositions and kits are provided for performing a chromatin or chromosome conformation capture assay in partitions.

Methods, polynucleotides, kits, and reaction mixtures are disclosed for the enriching of short polynucleotide molecules that have a length within a desired target length range. A Type IIS or Type III restriction enzyme is used to cleave polynucleotides at cleavage sites located at a distance from the restriction enzyme recognition sites. For example, a mixture of polynucleotides can be formed by inserting DNA molecules between a recognition site for the restriction enzyme and a region of non-naturally-occurring nucleotides that block cleavage by the restriction enzymes. If a polynucleotide contains a DNA molecule with a length within a target range, then the cleavage site will be within the blocking region, and cleavage will not occur. Polynucleotides containing DNA molecules with lengths outside the target range can be cleaved. By selectively enriching, through PCR or other means, polynucleotides that are intact, a concentrated population of polynucleotides of a target length can be formed.

Methods, polynucleotides, kits, and reaction mixtures are disclosed for the enriching of short polynucleotide molecules that have a length within a desired target length range. A Type IIS or Type III restriction enzyme is used to cleave polynucleotides at cleavage sites located at a distance from the restriction enzyme recognition sites. For example, a mixture of polynucleotides can be formed by inserting DNA molecules between a recognition site for the restriction enzyme and a region of non-naturally-occurring nucleotides that block cleavage by the restriction enzymes. If a polynucleotide contains a DNA molecule with a length within a target range, then the cleavage site will be within the blocking region, and cleavage will not occur. Polynucleotides containing DNA molecules with lengths outside the target range can be cleaved. By selectively enriching, through PCR or other means, polynucleotides that are intact, a concentrated population of polynucleotides of a target length can be formed.

A method for one-pot one-step assembly of two or more DNA molecules to form at least one recombinant DNA molecule, and a substrate and a kit for this purpose. A simple and cost-effective assembly method for DNA molecules. A method for one-pot one-step assembly of two or more DNA molecules to form at least one recombinant DNA molecule is provided, wherein the two or more DNA molecules to be assembled are brought together in dry form with a suitable reaction medium on at least one substrate present in a reaction vessel.

A method for one-pot one-step assembly of two or more DNA molecules to form at least one recombinant DNA molecule, and a substrate and a kit for this purpose. A simple and cost-effective assembly method for DNA molecules. A method for one-pot one-step assembly of two or more DNA molecules to form at least one recombinant DNA molecule is provided, wherein the two or more DNA molecules to be assembled are brought together in dry form with a suitable reaction medium on at least one substrate present in a reaction vessel.

Methods for producing a paired tag from a nucleic acid sequence are provided in which the paired tag comprises the 5′ end tag and 3′ end tag of the nucleic acid sequence. In one embodiment, the nucleic acid sequence comprises two restriction endonuclease recognition sites specific for a restriction endonuclease that cleaves the nucleic acid sequence distally to the restriction endonuclease recognition sites. In another embodiment, the nucleic acid sequence further comprises restriction endonuclease recognition sites specific for a rare cutting restriction endonuclease. Methods of using paired tags are also provided. In one embodiment, paired tags are used to characterize a nucleic acid sequence. In a particular embodiment, the nucleic acid sequence is a genome. In one embodiment, the characterization of a nucleic acid sequence is karyotyping. Alternatively, in another embodiment, the characterization of a nucleic acid sequence is mapping of the sequence. In a further embodiment, a method is provided for identifying nucleic acid sequences that encode at least two interacting proteins.

Methods for producing a paired tag from a nucleic acid sequence are provided in which the paired tag comprises the 5′ end tag and 3′ end tag of the nucleic acid sequence. In one embodiment, the nucleic acid sequence comprises two restriction endonuclease recognition sites specific for a restriction endonuclease that cleaves the nucleic acid sequence distally to the restriction endonuclease recognition sites. In another embodiment, the nucleic acid sequence further comprises restriction endonuclease recognition sites specific for a rare cutting restriction endonuclease. Methods of using paired tags are also provided. In one embodiment, paired tags are used to characterize a nucleic acid sequence. In a particular embodiment, the nucleic acid sequence is a genome. In one embodiment, the characterization of a nucleic acid sequence is karyotyping. Alternatively, in another embodiment, the characterization of a nucleic acid sequence is mapping of the sequence. In a further embodiment, a method is provided for identifying nucleic acid sequences that encode at least two interacting proteins.

The present invention relates to functionalized single stranded oligonucleotides and in particular to a method for producing functionalized single stranded oligonucleotides comprising: (a) providing a circular DNA molecule comprising an oligonucleotide sequence bordered by cleavage domains; (b) performing a rolling circle amplification (RCA) reaction with the circular DNA molecule of (a) as a template and one or more functionalized nucleotides (dNTPs); and (c) enzymatically cleaving the product of the RCA reaction at the cleavage domains to release the single stranded functionalized oligonucleotides.

The present invention relates to functionalized single stranded oligonucleotides and in particular to a method for producing functionalized single stranded oligonucleotides comprising: (a) providing a circular DNA molecule comprising an oligonucleotide sequence bordered by cleavage domains; (b) performing a rolling circle amplification (RCA) reaction with the circular DNA molecule of (a) as a template and one or more functionalized nucleotides (dNTPs); and (c) enzymatically cleaving the product of the RCA reaction at the cleavage domains to release the single stranded functionalized oligonucleotides.