This finding implied that some kind of unknown OSK-downstream molecules might play a key role in our iCSCs, resulting in recapitulation of colon cancer tissues. Furthermore, if we identify the key molecules that are required for the development of actual colon CSCs, our iCSCs will help to establish CSC-targeting therapy by overcoming the sampling limitation of CSCs in clinical specimens. Therefore, a global analysis of the transcriptome, as well as carrying out proteomic and epigenomic studies could be useful to find such key molecules in future studies. It could be a point of interest that only a small subset of transduced cells became iCSCs, and understanding the reason for this might help to better understand the generation of iCSCs. Although we did not evaluate the exact percentage of cells that expressed exogenous OCT3/4, SOX2 and KLF4 in the current study, there seemed to be a discrepancy between the percentage of OSK-V50 cells and the retroviral transduction efficiency of OSK inferred from Figure S1B, in which around half of the cells infected with the retrovirus mixture carrying one of three factors expressed both eGFP and DsRed. Therefore, the efficiency of the generation of the iCSCs might not simply reflect the transduction efficiency of OSK. It is still to be elucidated whether there are any mechanisms associated with suppressing the process of iCSC generation, like those seen for iPSC generation. In addition, although we demonstrated that our iCSCs maintained their colon CSC nature in vivo, it is also still unclear whether the continuous presence of the exogenous OSK factors is needed for the maintenance of this colon CSC nature. To address this issue, it will be necessary to use a transient expression system for OSK in future studies. In summary, we were able to generate colon iCSCs from an established colon cancer cell line by forced expression of OSK, and collect the iCSCs based on their difference in dye efflux activity. The iCSCs-derived cells and tissues were similar to actual human colon cancer tissue. By overcoming the quantitative limitations of primary human CSC samples and by dynamic observation of the CSC development, this method will enable us to elucidate the molecular mechanisms involved in the development and maintenance of CSCs, and will help to establish new therapies and diagnostic technology targeting CSCs. Actin filaments are the primary structural determinant of spines, and their remodeling in response to NMDA-receptor activation is critical for spine plasticity. Several genes encoding postsynaptic molecules that regulate the architecture of the actin cytoskeleton are mutated in neurodevelopmental disorders. Thus, parsing the mechanisms that regulate actin filament organization in dendritic spines is Silmitasertib crucial to understanding the cellular foundation of cognition. Actin filament bundling by a-actinin is implicated in a variety of cellular structures such as stress fibers, adhesions, junctions, and dendritic spines. a-Actinin is an antiparallel homodimer with an actin-binding site on either end that mediates actin.