The present invention refers to methods for selectively recognizing a base pair in a DNA sequence by a polypeptide, to modified polypeptides which specifically recognize one or more base pairs in a DNA sequence and, to DNA which is modified so that it can be specifically recognized by a polypeptide and to uses of the polypeptide and DNA in specific DNA targeting as well as to methods of modulating expression of target genes in a cell.

A C9orf72 DNA repeat expansion can be detected using a CRISPR Arrayed Repeat Detection System (CARDS). Based upon the compositions and methods supporting this platform primary cell cultures and/or blood cell smears can be tested under conventional clinical diagnostic laboratory conditions to diagnose genetically-based diseases having DNA repeat expansions, including but not limited to ALS. dCas9 constructs are also contemplated as having fluorescent proteins bound to any or all stem loop sequences, wherein detection of a plurality of dCas9 constructs having different colored fluorescent proteins can simultaneously detect at least six (6) different gene target loci.

A C9orf72 DNA repeat expansion can be detected using a CRISPR Arrayed Repeat Detection System (CARDS). Based upon the compositions and methods supporting this platform primary cell cultures and/or blood cell smears can be tested under conventional clinical diagnostic laboratory conditions to diagnose genetically-based diseases having DNA repeat expansions, including but not limited to ALS. dCas9 constructs are also contemplated as having fluorescent proteins bound to any or all stem loop sequences, wherein detection of a plurality of dCas9 constructs having different colored fluorescent proteins can simultaneously detect at least six (6) different gene target loci.

Methods of accurately determining DNA barcodes using a cylindrical nanopore system. The methods include steps of leveraging the average velocity of a double-stranded DNA segment passing through a single cylindrical nanopore that is measured through repeated scanning to accurately determine protein tag locations on the double-stranded DNA segment. As such, the methods provide for the accurate calculation of a barcode for the double-stranded DNA segment based on protein tag locations without underestimation or overestimate issues. The underlying concept and the methods are equally applicable to other multi-nanopore systems which use the dwell time and time of flight velocities to measure the barcodes.

Methods of accurately determining DNA barcodes using a cylindrical nanopore system. The methods include steps of leveraging the average velocity of a double-stranded DNA segment passing through a single cylindrical nanopore that is measured through repeated scanning to accurately determine protein tag locations on the double-stranded DNA segment. As such, the methods provide for the accurate calculation of a barcode for the double-stranded DNA segment based on protein tag locations without underestimation or overestimate issues. The underlying concept and the methods are equally applicable to other multi-nanopore systems which use the dwell time and time of flight velocities to measure the barcodes.

The present invention refers to methods for selectively recognizing a base pair in a DNA sequence by a polypeptide, to modified polypeptides which specifically recognize one or more base pairs in a DNA sequence and, to DNA which is modified so that it can be specifically recognized by a polypeptide and to uses of the polypeptide and DNA in specific DNA targeting as well as to methods of modulating expression of target genes in a cell.

The present invention refers to methods for selectively recognizing a base pair in a DNA sequence by a polypeptide, to modified polypeptides which specifically recognize one or more base pairs in a DNA sequence and, to DNA which is modified so that it can be specifically recognized by a polypeptide and to uses of the polypeptide and DNA in specific DNA targeting as well as to methods of modulating expression of target genes in a cell.

The present invention concerns compositions and processes that use affinity tags for isolating, and detecting or quantifying analytes, including nucleic acids, proteins and polypeptides. Compositions include nucleic acid compositions and protein compositions with affinity binding pairs, including metal binding peptides and immobilized metals, or peptide affinity groups.

The present invention concerns compositions and processes that use affinity tags for isolating, and detecting or quantifying analytes, including nucleic acids, proteins and polypeptides. Compositions include nucleic acid compositions and protein compositions with affinity binding pairs, including metal binding peptides and immobilized metals, or peptide affinity groups.

The present invention relates to a method and kit for amplifying and detecting a quantity of nucleic acid. The invention is particularly relevant to isothermal amplification techniques carried out on a flow based assay device. The amplified nucleic acid may be detected on the device using an optical read-out.