Abstract: The present invention regards a variety of methods and compositions for whole genome amplification. In a particular aspect of the present invention, there is a method of amplifying a genome in a non-biased manner utilizing adaptor-attached randomly generated fragments following modification of the DNA ends prior to the adaptor attachment. In an additional aspect of the present invention, there are methods and compositions for whole genome amplification regarding a one-step endonuclease cleavage and linker ligation reaction.

Abstract: The present invention regards a variety of methods and compositions for whole genome amplification and whole transcriptome amplification. In a particular aspect of the present invention, there is a method of amplifying a genome comprising a library generation step followed by a library amplification step. In specific embodiments, the library generating step utilizes specific primer mixtures and a DNA polymerase, wherein the specific primer mixtures are designed to eliminate ability to self-hybridize and/or hybridize to other primers within a mixture but efficiently and frequently prime nucleic acid templates.

Abstract: The present invention is directed to amplification of a single nucleotide polymorphism by utilizing a library of nick translate molecules. The methods are also directed to highly multiplexed amplification of a nucleic acid sequence to facilitate detection of a single nucleotide polymorphism.

Abstract: Improved methods and reagents for chromosome walking of nucleic acid are discussed herein. A library of amplifiable nick translation molecules is generated, and a chromosome walk is initiated from a known sequence in the nucleic acid by producing at least one nick translate molecule, sequencing part of the nick translate molecule, and producing a second nick translate molecule by initiating the primer extension from the region of the obtained sequence of the prior nick translate molecule.

Abstract: Disclosed are a number of methods that can be used in a variety of embodiments, including, creation of a nucleic acid terminated at one or more selected bases, sequence analysis of nucleic acids, mapping of sequence motifs within a nucleic acid, positional mapping of nucleic acid clones, and analysis of telomeric regions. The methods utilize double-stranded templates, and in most aspects involve a strand replacement reaction initiated at one or more random or specific locations created in a nucleic acid molecule, and in certain aspects utilizing an oligonucleotide primer.

Abstract: The present invention is directed to methods to prepare a DNA molecule or a plurality of DNA molecules by random fragmentation. In some embodiments, the present invention regards preparing a template for DNA sequencing by random fragmentation. In specific embodiments, the random fragmentation comprises chemical fragmentation, mechanical fragmentation, or enzymatic fragmentation. In further specific embodiments, a universal sequence is attached to the 3′ end of the DNA fragments, such as by ligation of an adaptor sequence or by homopolymeric tailing with terminal deoxynucleotidyltransferase. In other embodiments, a library is prepared with methods of the present invention.

Abstract: Improved methods and reagents for chromosome walking of nucleic acid are discussed herein. A library of amplifiable nick translation molecules is generated, and a chromosome walk is initiated from a known sequence in the nucleic acid by producing at least one nick translate molecule, sequencing part of the nick translate molecule, and producing a second nick translate molecule by initiating the primer extension from the region of the obtained sequence of the prior nick translate molecule.

Abstract: The disclosed invention relates to general and specific methods to use the Primer Extension/Nick Translation (PENT) reaction to create an amplifiable DNA strand, called a PENTAmer. A PENTAmers can be made for the purpose of amplifying a controlled length of DNA located at a controlled position within a DNA molecule, a process referred to as Positional Amplification by Nick Translation (PANT). In contrast to PCR, which amplifies DNA between two specific sequences, PANT can amplify DNA between two specific positions. PENTAmers can be created to amplify very large regions of DNA (up to 500,000 bp) as random mixtures (unordered positional libraries), or as molecules sorted according to position (ordered positional libraries). PANT is fast and economical, because PENTAmer preparation can be multiplexed. A single PENTAmer preparation can include very complex mixtures of DNA such as hundreds of large-insert clones, complete genomes, or cDNA libraries.

Abstract: Disclosed are a number of methods that can be used in a variety of embodiments, including, creation of a nucleic acid terminated at one or more selected bases, sequence analysis of nucleic acids, mapping of sequence motifs within a nucleic acid, positional mapping of nucleic acid clones, and analysis of telomeric regions. The methods utilize double-stranded templates, and in most aspects involve a strand replacement reaction initiated at one or more random or specific locations created in a nucleic acid molecule, and in certain aspects utilizing an oligonucleotide primer.

Abstract: Disclosed are a number of methods that can be used in a variety of embodiments, including, creation of a nucleic acid terminated at one or more selected bases, sequence analysis of nucleic acids, mapping of sequence motifs within a nucleic acid, positional mapping of nucleic acid clones, and analysis of telomeric regions. The methods utilize double-stranded templates, and in most aspects involve a strand replacement reaction initiated at one or more random or specific locations created in a nucleic acid molecule, and in certain aspects utilizing an oligonucleotide primer.