Nuclear organization has an important role in determining genome function; however, it is not clear how spatiotemporal organization of the genome relates to functionality. To elucidate this relationship, a method for tracking any locus of interest is desirable. Recently clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein 9 (Cas9) or transcription activator-like effectors were adapted for imaging endogenous loci; however, they are mostly limited to visualization of repetitive regions. Here, we report an efficient and scalable method named SHACKTeR (Short Homology and CRISPR/Cas9-mediated Knock-in of a TetO Repeat) for live cell imaging of specific chromosomal regions without the need for a pre-existing repetitive sequence. SHACKTeR requires only two modifications to the genome: CRISPR/Cas9-mediated knock-in of an optimized TetO repeat and its visualization by TetR-EGFP expression. Our simplified knock-in protocol, utilizing short homology arms integrated by polymerase chain reaction, was successful at labeling 10 different loci in HCT116 cells. We also showed the feasibility of knock-in into lamina-associated, heterochromatin regions, demonstrating that these regions prefer non-homologous end joining for knock-in. Using SHACKTeR, we were able to observe DNA replication at a specific locus by long-term live cell imaging. We anticipate the general applicability and scalability of our method will enhance causative analyses between gene function and compartmentalization in a high-throughput manner.
Nuclear organization has an important role in determining genome function; however, it is not clear how spatiotemporal organization of the genome relates to functionality. To elucidate this relationship, a high-throughput method for tracking any locus of interest is desirable. Here, we report an efficient and scalable method named SHACKTeR (Short Homology and CRISPR/Cas9-mediated Knock-in of a TetO Repeat) for live cell imaging of specific chromosomal regions. Compared to alternatives, our method does not require a nearby repetitive sequence and it requires only two modifications to the genome: CRISPR/Cas9-mediated knock-in of an optimized TetO repeat and its visualization by TetR-EGFP expression. Our simplified knock-in protocol, utilizing short homology arms integrated by PCR, was successful at labeling 9 different loci in HCT116 cells with up to 20% efficiency. These loci included both nuclear speckle-associated, euchromatin regions and nuclear lamina-associated, heterochromatin regions. We anticipate the general applicability and scalability of our method will enhance causative analyses between gene function and compartmentalization in a high-throughput manner.
Duchenne/Becker muscular dystrophy (DMD/ BMD), the most common X-linked muscular dystrophy is caused by mutations in the enormously large DMD gene. We screened this gene in 51 unrelated Bulgarian DMD/BMD patients and four families with no living index patient available, by multiplex ligation-dependent probe amplification (MLPA) analysis, which is a powerful tool for detecting deletion/duplication along the DMD gene. This, in combination with direct sequencing, characterized the mutation in all patients, which comprised 42 deletions (82%), six duplications (12%) and three point mutations (6%), and precisely determined all deletion/duplication borders. In all the families with no living index patient available, deletions were detected by direct analysis on the patients' mothers and sisters, proving the value of MLPA for carrier status determination.
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