Abstract: A method of detecting a target nucleic acid sequence comprising providing a stem-and-loop structured nucleic acid for measurement wherein the nucleic acid comprises complementary sequence portions located at both terminals and a target sequence portion therebetween as well as a double-stranded portion formed by hybridization of the complementary sequence portions located at both terminals and a remaining looped single-stranded portion, providing a probe nucleic acid having a sequence complementary to the target sequence portion wherein one end of the probe nucleic acid being immobilized to a solid substrate surface, reacting the nucleic acid for measurement with the probe nucleic acid to specifically hybridize the target sequence portion of the nucleic acid for measurement to the probe nucleic acid, and detecting presence or absence of the nucleic acid for measurement hybridized to the probe nucleic acid.

Abstract: A nucleic acid detection method involving the direct generation of a measurable signal, by the action of an enzyme with 3?-5? nuclease activity, and the applications for it, the signal generated can be detectable and quantifiable and can be carried out in real-time, in this method, the nucleic acid is placed in contact with at least one oligonucleotide that does not hybridize perfectly with it, so that the enzyme will split it at the unpaired bases generating the signal, the oligonucleotide can be labeled.

Abstract: The present invention provides methods and kits useful for enriching, identifying and quantifying methylated DNA3 particularly hypermethylated CpG islands by digesting a sample with a methylation-sensitive restriction endonuclease and capturing methylated restriction fragments with a methyl-binding capture reagent. The methods of the invention may be used in the detection of cancer, particularly detection of prostate cancer.

Abstract: Disclosed are methods and compositions for detecting variation in nucleic acids. The disclosed method compares the sequence of a nucleic acid of interest with the sequence of a reference nucleic acid to sensitively identify variations between the sequence of a nucleic acid of interest and the sequence of a reference nucleic acid. The disclosed method generally involves excision and replacement of selected nucleotides in nucleic acid strands hybridized to other strands. In the method, if the excised nucleotide was mismatched with the nucleotide in the other, hybridized strand, then the replacement nucleotide will not be mismatched. If the excised nucleotide was not mismatched with the nucleotide in the other, hybridized strand, then the excised nucleotide is not replaced. This difference allows detection of variation in the nucleic acid of interest.

Abstract: The invention relates to an extraction method for isolating target molecules from a sample using a microfluidic carrier.

Abstract: Arrays for genome-wide analysis of methylation are disclosed. In a preferred aspect arrays comprising a plurality of probes complementary to a plurality of identified CpG islands in the human, mouse and rat genome are disclosed. The arrays may be used to detect methylation within CpG islands in samples from human, mouse and rat genomes.

Abstract: Methods, systems and compositions where a target nucleic acid includes a registration sequence disposed therein for identification of the number or relative position of determined sequence from the template sequence. Particularly preferred aspects include a registration sequence in a circular template nucleic acid sequence which is, in turn, used in sequence by incorporation processes that rely upon template dependent, polymerase mediated primer extension in the identification of the sequence of the template.

Abstract: The invention provides methods for sequencing a polynucleotide comprising stopping an extension cycle in a sequence by synthesis reaction before the reaction has run to near or fill completion.

Abstract: The present invention provides for a method of drying and spreading chromosomes from various biological samples to yield optimal chromosomal spreading. The method requires preparing a biological sample for treatment, providing a cytogenetic chamber capable of setting predetermined conditions, pre-testing a portion of the biological sample in the cytogenetic chamber, and finally treating the remaining biological sample. The method is useful to yield metaphase chromosomes that are small and rounded, with very few overlapping or scattered chromosomes. Furthermore, the method is uses restricted ranges of temperature and relative humidity to achieve consistent chromosomal spreading. The morphologies of the chromosomes are preserved in order to execute banding techniques at 550 bands and chromosomal analysis on high-resolution chromosomes.

Abstract: Provided are methods of determining differences between nucleic acids in a test sample and a reference sample. In certain embodiments the methods are used for detecting and mapping chromosomal or genetic abnormalities associated with various diseases or with predisposition to various diseases, or to detecting the phenomena of large scale copy number variants. In particular, provided are advanced methods of performing array-based comparative hybridization that allow reproducibility between samples and enhanced sensitivity by using the same detectable label for both test sample and reference sample nucleic acids. Invention methods are useful for the detection or diagnosis of particular disease conditions such as cancer, and detecting predisposition to cancer based on detection of chromosomal or genetic abnormalities and gene expression level. Invention methods are also useful for the detection or diagnosis of hereditary genetic disorders or predisposition thereto, especially in prenatal samples.

Abstract: The present invention relates to an improved process for isolating DNA from biological samples, particularly from human whole blood.

Abstract: Since conventional DNA sequence analyzing technologies are based on the fundamental principle of fluorescent detection, expensive, complex optical systems and laser sources have been necessary. A field-effect device for gene detection of the present invention analyzes a base sequence by immobilizing a single-strand nucleic acid probe at a gate portion, inducing hybridization at the gate portion to form a double-stranded DNA, inducing elongation reaction by adding a DNA polymerase and one of the substrates, and measuring the electrical characteristic of the field-effect device caused by elongation reaction. Since the elongation reaction of one base induced at the gate portion can be directly converted to an electrical signal, expensive lasers or complex optical systems are not needed. Thus, a small gene polymorphism detection system that can conduct measurement at high precision can be provided.

Abstract: The invention relates to a method of determining whether a human subject is suffering from or at risk for developing pancreatic cancer by determining the methylation level of an ID4 gene promoter or the expression level of an ID4 gene in a biological sample from a human subject. Also disclosed are a method of analyzing the methylation level of an ID4 gene promoter or the expression level of an ID4 gene in a pancreatic cancer cell, and a method of inhibiting the methylation of an ID4 gene promoter or enhancing the expression of an ID4 gene by contacting a pancreatic cancer cell with a compound that decreases the methylation level of an ID4 gene promoter or increases the expression level of an ID4 gene in the cell.

Abstract: The present invention includes methods diagnosising of cancer by analysis of a patient sample, particularly for the presence of a methylated SPARC nucleic acid molecule, and particularly for the diagnosis of pancreatic cancer. The invention also includes therapeutic methods for treating cancers by administering to cancers patients therapeutically effective amounts of demethylating agents.

Abstract: The present invention relates to a method for extracting nucleic acids from biological samples. More specifically the invention relates to a universal method for extracting nucleic acids from unidentified biological samples. An advantage of the presently invented method is its ability to effectively and efficiently extract nucleic acids from a variety of different cell types including but not limited to prokaryotic or eukaryotic cells and/or recalcitrant organisms (i.e. spores). Unlike prior art methods which are focused on extracting nucleic acids from vegetative cell or spores, the present invention effectively extracts nucleic acids from spores, multiple cell types or mixtures thereof using a single method. Important that the invented method has demonstrated an ability to extract nucleic acids from spores and vegetative bacterial cells with similar levels effectiveness.

Abstract: This invention provides methods for nucleic acid analysis. A closed complex of nucleic acid template, nucleotide and polymerase can be formed during polymerase reaction, absent divalent metal ion. This is used to trap the labeled nucleotide complementary to the next template nucleotide in the closed complex. Detection of the label allows determination of the identity of this next correct nucleotide. Identification can be either in place, as part of the complex, or as the dye is eluted from the complex when the reaction cycle is completed by the addition of divalent metal ion. In this way, sequential nucleotides of a DNA can be identified, effectively determining the DNA sequence. This method can be applied to nucleic acid single molecules or to collections of identical or nearly identical sequence such as PCR products or clones. Multiple templates can be sequenced in parallel, particularly if they are immobilized on a solid support.

Abstract: A nanoprobe for sequencing of nucleic acid molecules is provided, as well as methods for using the nanoprobe. In particular examples, the probe includes a polymerizing agent and one or more molecular linkers that carry a chemical moiety capable of reversibly binding to the template strand of a nucleic acid molecule, without being detached from the linker, by specifically binding with a complementary nucleotide in the target nucleic acid molecule. The reversible binding of the chemical moiety on the linker with a complementary nucleotide in the target nucleic acid molecule is indicated by emission of a characteristic signal that indicates pairing of the chemical moiety on the linker with its complementary nucleotide. An example of such a chemical moiety is a nonhydrolyzable nucleotide analog. In particular examples, the polymerizing agent and the chemical moiety are associated with a tag, such as a donor fluorophore and acceptor fluorophore characteristic of the particular type of chemical moiety.

Abstract: To solve a problem occurring in the PALSAR method that a polymer would be formed in the state of unbound to a captured test gene and thus affect the quantitative characteristics as a nonspecific signal, it is intended to develop a technique whereby the polymer formation is controlled in the step of forming an assembly (polymer) of probes so that the polymer is formed exclusively on a test gene to thereby improve the sensitivity and quantitative characteristics. It is found that the polymer can be quantitatively formed and a nonspecific reaction can be inhibited by, in the step of forming a polymer by reacting plural kinds of probes having abilities to complementarily bind to each other, not adding or reacting these probes at once but starting with the reaction of a first probe in one group, and then reacting the second probe in the other group followed by the reactions of probes one by one (i.e., the first probe, the second probe, and so on).

Abstract: The present invention relates to a method for detecting analytes in a sample comprising the steps of providing a solid support, providing capture probes being bound or capable of binding to the solid support, which capture probes are also capable of binding to the analytes, thus concentrating the analytes on the solid support, providing detection probes which are capable of binding to the analytes, contacting the sample with the detection probes, the solid support and the capture probes, and detecting through use of confocal observation the analytes which are bound to the detection probes.

Abstract: Use of helper probes in dipstick assays is described. In a dipstick assay to test for the presence of a target nucleic acid in a sample solution, the sample solution is contacted with the contact end of the dipstick to cause the sample solution to move by capillary action to a capture zone of the dipstick at which target nucleic acid is captured. The target nucleic acid may be captured at the capture zone by a capture probe capable of hybridising to the target nucleic acid. A labelled detection probe capable of hybridising to the target nucleic acid may be used to detect the target nucleic acid at the capture zone. A helper probe may be used to enhance the binding of the capture and/or detection probe to the target nucleic acid, thereby improving the sensitivity of target nucleic acid detection. Dipsticks and kits are also described.