A method of simultaneously analyzing RNA and DNA in a sample, the method comprising the step (a) contacting the sample with a reverse primer from a first primer pair directed to a target RNA region to effect reverse transcription of RNA into cDNA with a reverse transcriptase; (b) subsequently contacting the sample with (i) a forward primer from the first primer pair directed to a second cDNA region, (ii) a forward and a reverse primers from a second primer pair targeted to a DNA region, and (ii) a DNA polymerase to simultaneously amplify the target cDNA and target DNA region; and (c) analyzing the amplified target cDNA region and/or amplified target DNA region. Also encompassed are uses of the method to analyze gene expression and mutations, kits comprising primers, enzymes, buffers.

A method of simultaneously analyzing RNA and DNA in a sample, the method comprising the step (a) contacting the sample with a reverse primer from a first primer pair directed to a target RNA region to effect reverse transcription of RNA into cDNA with a reverse transcriptase; (b) subsequently contacting the sample with (i) a forward primer from the first primer pair directed to a second cDNA region, (ii) a forward and a reverse primers from a second primer pair targeted to a DNA region, and (ii) a DNA polymerase to simultaneously amplify the target cDNA and target DNA region; and (c) analyzing the amplified target cDNA region and/or amplified target DNA region. Also encompassed are uses of the method to analyze gene expression and mutations, kits comprising primers, enzymes, buffers.

The present invention relates to identification of an abnormal splice site. Provided are methods of identifying an abnormal splice site. Methods of classifying the risk of abnormal splicing of a splice site are also provided. Databases for use in the methods provided herein are also disclosed.

The present invention relates to identification of an abnormal splice site. Provided are methods of identifying an abnormal splice site. Methods of classifying the risk of abnormal splicing of a splice site are also provided. Databases for use in the methods provided herein are also disclosed.

The present disclosure provides methods and systems for analyzing agents (e.g., therapeutic agents) in a biological sample having a three-dimensional matrix.

The present disclosure provides methods and systems for analyzing agents (e.g., therapeutic agents) in a biological sample having a three-dimensional matrix.

Described herein are methods and kits for detecting the presence or absence of gene dysregulations such as those arising from gene fusions and/or chromosomal abnormalities, e.g. translocations, insertions, inversions and deletions. The methods, compositions and kits are useful for detecting mutations that cause the differential expression of a 5′ portion of a target gene relative to the 3′ region of the target gene. The average expression of the 5′ portion of the target gene is compared with the average expression of the 3′ portion of the target gene to determine an intragenic differential expression (IDE). The IDE can then be used to determine if a dysregulation or a particular disease (or susceptibility to a disease) is present or absent in a subject or sample.

Described herein are methods and kits for detecting the presence or absence of gene dysregulations such as those arising from gene fusions and/or chromosomal abnormalities, e.g. translocations, insertions, inversions and deletions. The methods, compositions and kits are useful for detecting mutations that cause the differential expression of a 5′ portion of a target gene relative to the 3′ region of the target gene. The average expression of the 5′ portion of the target gene is compared with the average expression of the 3′ portion of the target gene to determine an intragenic differential expression (IDE). The IDE can then be used to determine if a dysregulation or a particular disease (or susceptibility to a disease) is present or absent in a subject or sample.

Systems and method for identifying long deletions can obtain sequencing information for a plurality of amplicons in and around a potential region from a nucleic acid sample. The sequencing information can include a plurality of reads that can be mapped to a reference sequence. Using information, such as where reads map to a reference sequence and relative abundance of reads for the amplicons, structural variants can be identified and a determination can be made if the nucleic acid sample is homozygous or heterozygous for the structural variant.

Systems and method for identifying long deletions can obtain sequencing information for a plurality of amplicons in and around a potential region from a nucleic acid sample. The sequencing information can include a plurality of reads that can be mapped to a reference sequence. Using information, such as where reads map to a reference sequence and relative abundance of reads for the amplicons, structural variants can be identified and a determination can be made if the nucleic acid sample is homozygous or heterozygous for the structural variant.