Live-cell imaging of subcellular structures for quantitative evaluation of pluripotent stem cells.

Pluripotent stem cells (PSCs) have various degrees of pluripotency, which necessitates selection of PSCs with high pluripotency before their application to regenerative medicine. However, the quality control processes for PSCs are costly and time-consuming, and it is essential to develop inexpensive and less laborious selection methods for translation of PSCs into clinical applications. Here we developed an imaging system, termed Phase Distribution (PD) imaging system, which visualizes subcellular structures quantitatively in unstained and unlabeled cells. The PD image and its derived PD index reflected the mitochondrial content, enabling quantitative evaluation of the degrees of somatic cell reprogramming and PSC differentiation. Moreover, the PD index allowed unbiased grouping of PSC colonies into those with high or low pluripotency without the aid of invasive methods. Finally, the PD imaging system produced three-dimensional images of PSC colonies, providing further criteria to evaluate pluripotency of PSCs. Thus, the PD imaging system may be utilized for screening of live PSCs with potentially high pluripotency prior to more rigorous quality control processes.

A Role for KLF4 in Promoting the Metabolic Shift via TCL1 during Induced Pluripotent Stem Cell Generation.

Reprogramming of somatic cells into induced pluripotent stem cells (iPSCs) is accompanied by morphological, functional, and metabolic alterations before acquisition of full pluripotency. Although the genome-wide effects of the reprogramming factors on gene expression are well documented, precise mechanisms by which gene expression changes evoke phenotypic responses remain to be determined. We used a Sendai virus-based system that permits reprogramming to progress in a strictly KLF4-dependent manner to screen for KLF4 target genes that are critical for the progression of reprogramming. The screening identified Tcl1 as a critical target gene that directs the metabolic shift from oxidative phosphorylation to glycolysis. KLF4-induced TCL1 employs a two-pronged mechanism, whereby TCL1 activates AKT to enhance glycolysis and counteracts PnPase to diminish oxidative phosphorylation. These regulatory mechanisms described here highlight a central role for a reprogramming factor in orchestrating the metabolic shift toward the acquisition of pluripotency during iPSC generation.

Target genes of the developmental regulator PRIB of the mushroom Lentinula edodes.

Using the method of genomic binding-site cloning, we identified three target genes of the developmental regulator, the product of priB gene (PRIB) in Lentinula edodes: the previously cloned priB and uck1 (UMP-CMP kinase gene) and a new gene, which we named mfbC. Identification of the former two genes was expected, because the promoter regions of priB and the gene encoding UMP-CMP kinase (uck1) have been shown to contain four or two consensus-like sequences of PRIB binding respectively. The mfbC gene contained two consensus-like sequences of PRIB binding in its promoter region and the PRIB protein bound them. The deduced 330 amino acid sequence of the product of mfbC gene (MFBC) was highly homologous to the 325 amino acid sequence of S. cerevisiae YJR070C/Lia1, the protein interacting with a putative translation initiation factor. Only the mature fruiting body of L. edodes was shown to contain the transcript of the mfbC gene almost exclusively, suggesting that mfbC may play a role in the final stage of fruiting-body formation.