Abstract: Some embodiments of the methods and compositions provided herein relate to the selective cleavage of a target nucleic acid. Some such embodiments include the selective cleavage of a target nucleic acid that is associated with a DNA-binding protein or comprises a methylated CpG island, with a recombinant nuclease. In some embodiments, the DNA-binding protein comprises a chromatin protein. Some embodiments also include the enrichment of non-target nucleic acids in a sample by selective cleavage of target nucleic acids in the sample, and removal of the cleaved target nucleic acids from the sample.

Abstract: Some embodiments of the methods and compositions provided herein relate to the selective cleavage of a target nucleic acid. Some such embodiments include the selective cleavage of a target nucleic acid that is associated with a DNA-binding protein or comprises a methylated CpG island, with a recombinant nuclease. In some embodiments, the DNA-binding protein comprises a chromatin protein. Some embodiments also include the enrichment of non-target nucleic acids in a sample by selective cleavage of target nucleic acids in the sample, and removal of the cleaved target nucleic acids from the sample.

Abstract: Embodiments of the methods and compositions provided herein relate to the selective cleavage of target nucleic acids. Some embodiments include recombinase-mediated selective cleavage of target nucleic acids with single-stranded nucleic acid probes and a recombinase. Some embodiments also include the enrichment of non-target nucleic acids in a sample by selective cleavage of target nucleic acids in the sample, and removal of the cleaved target nucleic acids from the sample.

Abstract: Embodiments of the methods and compositions provided herein relate to the selective cleavage of target nucleic acids. Some embodiments include recombinase-mediated selective cleavage of target nucleic acids with single-stranded nucleic acid probes and a recombinase. Some embodiments also include the enrichment of non-target nucleic acids in a sample by selective cleavage of target nucleic acids in the sample, and removal of the cleaved target nucleic acids from the sample.

Abstract: In an example, a target material is immobilized on two opposed sequencing surfaces of a flow cell using first and second fluids. The first fluid has a density less than a target material density and the second fluid has a density greater than the target material density; or the second fluid has a density less than the target material density and the first fluid has a density greater than the target material density. The first fluid (including the target material) is introduced into the flow cell, whereby at least some of the target material becomes immobilized by capture sites on one of the sequencing surfaces. The first fluid and non-immobilized target material are removed. The second fluid (including target material) is introduced into the flow cell, whereby at least some of the target material becomes immobilized by capture sites on another of the sequencing surfaces.

Abstract: The disclosure relates to methods, compositions, and kits for the identification and analysis of microorganisms in a sample using nucleoside or nucleotide analogs.

Abstract: Some embodiments of the methods and compositions provided herein relate to the selective cleavage of a target nucleic acid. Some such embodiments include the selective cleavage of a target nucleic acid that is associated with a DNA-binding protein or comprises a methylated CpG island, with a recombinant nuclease. In some embodiments, the DNA-binding protein comprises a chromatin protein. Some embodiments also include the enrichment of non-target nucleic acids in a sample by selective cleavage of target nucleic acids in the sample, and removal of the cleaved target nucleic acids from the sample.

Abstract: Embodiments of the methods and compositions provided herein relate to the selective cleavage of target nucleic acids. Some embodiments include recombinase-mediated selective cleavage of target nucleic acids with single-stranded nucleic acid probes and a recombinase. Some embodiments also include the enrichment of non-target nucleic acids in a sample by selective cleavage of target nucleic acids in the sample, and removal of the cleaved target nucleic acids from the sample.

Abstract: An example of a biotin-streptavidin cleavage composition includes a formamide reagent and a salt buffer. The formamide reagent is present in the biotin-streptavidin cleavage composition in an amount ranging from about 10% to about 50%, based on a total volume of the biotin-streptavidin cleavage composition. The salt buffer makes up the balance of the biotin-streptavidin cleavage composition. In some examples, the biotin-streptavidin cleavage composition is used to cleave library fragments from a solid support. In other examples, other mechanisms are used to cleave library fragments from a solid support.

Abstract: Compositions and methods are provided for user-specified fine-tuned protein expression levels, by controlling the initiation of protein translation; and a model for analysis of expression. This method of control can be used to vary, tune, and optimize protein production in genetically engineered organisms, cells, or devices.

Abstract: The invention features methods and compositions for introducing mutations in an endogenous host cell gene. In one embodiment, the invention features identification of genes that, when mutated, result in production of a phenotype of interest, e.g., tumor formation. In general, the invention provides a random mutagenesis system wherein a non-oncogenic, replicating vector acts as a vehicle to randomly introduce a construct comprising a hypermutation-inducing element into the genome of a host cell. Introduction of the hypermutation element in the host cell genome induces mutations (e.g., point mutations, small deletions, and/or small insertions) in genes adjacent to the integrated hypermutation element.