In certain aspects, the invention disclosed herein relates to the isothermal amplification of probe linkage products to generate specific amplified signals. In some aspects, the invention provides methods, reagents, and kits for carrying out such amplification via the isothermal chain reaction (ICR).

The present invention provides a sequencing library, and the sequencing library has an inserted fragment which is an equidirectional alternating concatemer of a sequence to be tested and a tag sequence. The present invention further provides a method for preparing the sequencing library. The present invention also provides a sequencing method. The sequencing library and sequencing method as provided in the present invention are capable of removing DNA amplification errors and sequencing errors under any sequencing depths, so that mutations of DNA molecules could be ultra-accurately determined. The sequencing library of the present invention is suitable for construction of a sequencing library of trace short DNA fragments and even of single-strand DNAs.

Polynucleotide sequencing methods include incubating unlabeled nucleotides with a cluster of template polynucleotide strands having the same sequence when the identity of the previously added labeled nucleotide is being detected. The detection step provides time for the addition of the unlabeled nucleotides to be incorporated into the copy strands in which the previously added labeled nucleotide did not get incorporated. Thus, at the end of the detection step, all or most of the copy strands will be in phase and ready to incorporate the appropriate labeled nucleotide in the subsequence incorporate step.

Polynucleotide sequencing methods include incubating unlabeled nucleotides with a cluster of template polynucleotide strands having the same sequence when the identity of the previously added labeled nucleotide is being detected. The detection step provides time for the addition of the unlabeled nucleotides to be incorporated into the copy strands in which the previously added labeled nucleotide did not get incorporated. Thus, at the end of the detection step, all or most of the copy strands will be in phase and ready to incorporate the appropriate labeled nucleotide in the subsequence incorporate step.

The invention relates to methods and compositions for the detection and quantification of nucleotide sequence variants, such as genetic polymorphisms, with decreased error and increased sensitivity, including single molecule detection. Detection of genetic polymorphisms, including single nucleotide polymorphisms (SNPs), is highly useful for the study of physiology, disease, phylogeny and forensics. Current methods for the detection and identification of nucleic acid sequence variants, such as genetic polymorphisms, lack the sensitivity to accurately detect low incidence mutations sequence variants or alleles. Detection techniques for highly multiplexed single molecule identification and quantification of analytes using optical systems are disclosed. Analytes include, but are not limited to, nucleic acid, such as DNA and RNA molecules, with and without modifications. Techniques described herein include use of specific and non-specific probes complementary to nucleic acids of interest for detailed characterization of nucleotide sequence variants and highly multiplexed single molecule identification and quantification.

The invention relates to methods and compositions for the detection and quantification of nucleotide sequence variants, such as genetic polymorphisms, with decreased error and increased sensitivity, including single molecule detection. Detection of genetic polymorphisms, including single nucleotide polymorphisms (SNPs), is highly useful for the study of physiology, disease, phylogeny and forensics. Current methods for the detection and identification of nucleic acid sequence variants, such as genetic polymorphisms, lack the sensitivity to accurately detect low incidence mutations sequence variants or alleles. Detection techniques for highly multiplexed single molecule identification and quantification of analytes using optical systems are disclosed. Analytes include, but are not limited to, nucleic acid, such as DNA and RNA molecules, with and without modifications. Techniques described herein include use of specific and non-specific probes complementary to nucleic acids of interest for detailed characterization of nucleotide sequence variants and highly multiplexed single molecule identification and quantification.

In certain aspects, the invention disclosed herein relates to the isothermal amplification of probe linkage products to generate specific amplified signals. In some aspects, the invention provides methods, reagents, and kits for carrying out such amplification via the isothermal chain reaction (ICR).

In certain aspects, the invention disclosed herein relates to the isothermal amplification of probe linkage products to generate specific amplified signals. In some aspects, the invention provides methods, reagents, and kits for carrying out such amplification via the isothermal chain reaction (ICR).

The invention relates to a process for parallel high throughput sequencing of nucleic acid molecules, in particular in the single molecule format.

The invention relates to a process for parallel high throughput sequencing of nucleic acid molecules, in particular in the single molecule format.