The advance of CRISPR/Cas9 technology has enabled us easily to generate gene knockout cell lines by introducing insertion/deletion mutations (indels) at the target site via the error-prone non-homologous end joining repair system. Frameshift-promoting indels can disrupt gene functions by generation of a premature stop codon. However, there is growing evidence that targeted genes are not always knocked-out by the indel-based gene disruption. Here, we established a pipeline of CRISPR-del, which induces a large chromosomal deletion by cutting two different target sites, to perform “complete” gene knockout efficiently in human diploid cells. Quantitative analyses show that the frequency of gene deletion with this approach is much higher than that of conventional CRISPR-del methods. The lengths of the deleted genomic regions demonstrated in this study are longer than those of 95% of the human protein-coding genes. Furthermore, the pipeline enables the generation of a model cell line having a bi-allelic cancer-associated chromosomal deletion. Overall, these data lead us to propose that the CRISPR-del pipeline is an efficient and practical approach for producing “complete” gene knockout cell lines in human diploid cells.
Phototoxicity is an important issue in fluorescence live imaging of light-sensitive cellular processes such as mitosis, especially in high spatiotemporal resolution microscopy that often requires high-intensity illumination. Among several approaches to reduce phototoxicity, the addition of antioxidants to the imaging media has been used as a simple and effective method. However, it remains unknown what are the optimal antioxidants that could prevent phototoxicity- induced defects during mitosis in fluorescence live cell microscopy. In this study, we analyzed the impact of phototoxicity on the mitotic progression in fluorescence live imaging of human diploid cells and performed a screen to identify the most efficient antioxidative agents that reduce it. Quantitative analysis shows that high amounts of light illumination cause various mitotic defects such as prolonged mitosis and delays of chromosome alignment and centrosome separation. Among several antioxidants known to reduce cellular phototoxicity, our screen reveals that ascorbic acid significantly alleviates these phototoxic effects in mitosis. Furthermore, we demonstrate that the addition of ascorbic acid to the imaging media enables fluorescence imaging of mitotic events at very high temporal resolution without obvious photodamage. Thus, this study provides a simple and practical method to effectively reduce the phototoxic effects on mitotic processes in fluorescence live cell imaging.
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