Abstract: Provided herein is a polymerase-free enzyme mix (FRAG) for fragmenting double-stranded DNA. In some embodiments the enzyme mix may comprise a double-stranded DNA nickase and at least one of a DNA ligase capable of sealing a nick within a DNA, and a single-strand specific DNA nuclease. Methods for fragmenting double-stranded DNA are also provided.

Abstract: Provided herein is a polymerase-free enzyme mix (FRAG) for fragmenting double-stranded DNA. In some embodiments the enzyme mix may comprise a double-stranded DNA nickase and at least one of a DNA ligase capable of sealing a nick within a DNA, and a single-strand specific DNA nuclease. Methods for fragmenting double-stranded DNA are also provided.

Abstract: Provided herein is a polymerase-free enzyme mix (FRAG) for fragmenting double-stranded DNA. In some embodiments the enzyme mix may comprise a double-stranded DNA nickase and at least one of a DNA ligase capable of sealing a nick within a DNA, and a single-strand specific DNA nuclease. Methods for fragmenting double-stranded DNA are also provided.

Abstract: Laminar flow of a carrier liquid and polymeric molecules through micro-channels is used to straighten the polymeric molecules and attach the straightened molecules to a wall of the micro-channel for subsequent treatment and analysis. Micro-channels can be manufactured using an elastic molding material. One micro-channel embodiment provides fluid flow using a standard laboratory centrifuge.

Abstract: Laminar flow of a carrier liquid and polymeric molecules through micro-channels is used to straighten, align, separate, and/or sort the polymeric molecules. The polymeric molecules may be analyzed and/or manipulated in the carrier liquid or attached to a wall of the micro-channel for subsequent treatment and analysis. Micro-channels can be manufactured using an elastic molding material. One micro-channel embodiment provides fluid flow using a standard laboratory centrifuge.

Abstract: Disclosed are consensus optical contig maps of an entire genome of an organism and methods of using the maps to verify, validate, refute and/or access the accuracy of a known nucleic acid sequence or full genomic sequence. The maps are constructed using optical methods wherein DNA is elongated and fixed along their length onto a solid planar surface so that the DNA molecules are individually analyzable and accessible for enzymatic reactions. The DNA molecules are then reacted with a restriction enzyme to yield cleaved fragments of discernable length fixed to the surface. The lengths of the fragments are then determined, using optical methods. From the lengths determined, an optical contig map is assembled and can be compared to a corresponding known sequence, for example, a genomic sequence.