Abstract: 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.

Abstract: 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.

Abstract: The present disclosure relates to methods of and systems for modifying the transcriptional regulation of stem or progenitor cells to promote their differentiation or reprogramming of somatic cells. Further, the labeling and editing of human genomic loci in live cells with three orthogonal CRISPR/Cas9 components allow multicolor detection of genomic loci with high spatial resolution, which provides an avenue for barcoding elements of the human genome in the living state.

Abstract: 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.

Abstract: The present invention discloses a transcription activator-like effector-based strategy, termed “TALEColor”, for labeling specific repetitive DNA sequences in human chromosomes. TALEs were custom designed for human telomeric repeats and fused with any of numerous fluorescent proteins (FPs). TALE-telomere-FP fusion proteins were used to detect telomeric sequence in both living cells and fixed cells. Using human cells with different average telomere lengths, TALEColor signals correlated positively with telomere length. TALEs were also designed to detect centromeric sequences unique to specific chromosomes, enabling localization of these specific human chromosomes in live cells. These methods may have significant potential both for basic chromosome and genome research as well as in clinical applications.

Abstract: The present disclosure relates to methods of and systems for modifying the transcriptional regulation of stem or progenitor cells to promote their differentiation or reprogramming of somatic cells. Further, the labeling and editing of human genomic loci in live cells with three orthogonal CRISPR/Cas9 components allow multicolor detection of genomic loci with high spatial resolution, which provides an avenue for barcoding elements of the human genome in the living state.

Abstract: The present invention discloses a transcription activator-like effector-based strategy, termed “TALEColor”, for labeling specific repetitive DNA sequences in human chromosomes. TALEs were custom designed for human telomeric repeats and fused with any of numerous fluorescent proteins (FPs). TALE-telomere-FP fusion proteins were used to detect telomeric sequence in both living cells and fixed cells. Using human cells with different average telomere lengths, TALEColor signals correlated positively with telomere length. TALEs were also designed to detect centromeric sequences unique to specific chromosomes, enabling localization of these specific human chromosomes in live cells. These methods may have significant potential both for basic chromosome and genome research as well as in clinical applications.