When mature adipocytes are subjected to an in vitro dedifferentiation strategy referred to as ceiling culture, these mature adipocytes can revert to a more primitive phenotype and gain cell proliferative ability. We refer to these cells as dedifferentiated fat (DFAT) cells. In the present study, we examined the multilineage differentiation potential of DFAT cells. DFAT cells obtained from adipose tissues of 18 donors exhibited a fibroblast-like morphology and sustained high proliferative activity. Flow cytometric analysis revealed that DFAT cells comprised a highly homogeneous cell population compared with that of adipose-derived stem/stromal cells (ASCs), although the cell-surface antigen profile of DFAT cells was very similar to that of ASCs. DFAT cells lost expression of mature adipocytes marker genes but retained or gained expression of mesenchymal lineage-committed marker genes such as peroxisome proliferator-activated receptor gamma (PPARgamma), RUNX2, and SOX9. In vitro differentiation analysis revealed that DFAT cells could differentiate into adipocytes, chondrocytes, and osteoblasts under appropriate culture conditions. DFAT cells also formed osteoid matrix when implanted subcutaneously into nude mice. In addition, clonally expanded porcine DFAT cells showed the ability to differentiate into multiple mesenchymal cell lineages. These results indicate that DFAT cells represent a type of multipotent progenitor cell. The accessibility and ease of culture of DFAT cells support their potential application for cell-based therapies.
A novel method for multiplex TaqMan PCR in nanoliter volumes on a highly integrated silicon microchamber array is described. Three different gene targets, related to beta-actin, sex-determining region Y (SRY), and Rhesus D (RhD) were amplified and detected simultaneously on the same chip by using three different types of human genomic DNA as the templates. The lack of cross-contamination and carryover was shown using alternate dispensing of mineral oil-coated microchambers containing template and those without template. To confirm the specificity of our system to beta-actin, SRY, and RhD genes, we employed the larger volume PCR samples to a commercial real-time PCR system, SmartCycler. The samples were cycled with the same sustaining temperatures as with the microchamber array. Instead of the conventional method of DNA quantification, counting the number of the fluorescence released microchambers in consequence to TaqMan PCR was employed to our chip. This simple method of observing the end point signal had provided a dynamic quantitative range. Stochastic amplification of 0.4 copies/reaction chamber was achieved. The microfabricated PCR chip demonstrated a rapid and highly sensitive response for simultaneous multiple-target detection, which is a promising step toward the development of a fully integrated device for the "lab-on-a-chip" DNA analysis.
An ectopic neural retina is formed at the outer layer of the retina in the silver homozygote (B/B) of the Japanese quail. In situ hybridization and immunohistochemical analysis revealed that cells in the outer layer of retina first expressed a pigment-cell-specific gene, mmp115, and then began to express a neural marker in B/B embryos, indicating that the ectopic neural retina is formed via transdifferentiation of differentiated pigmented epithelial cells (PECs). An in vitro study revealed that cultured retinal PECs (rPECs) from B/B embryos exhibit less pigment granule and a higher growth rate than cells from heterozygotes (B/+). B/+ PECs stopped proliferating when confluency was reached, while B/B PECs continued to proliferate. Some B/B cells overlaid other B/B cells and formed lentoid bodies. Immunological analysis revealed that B/B rPECs transdifferentiated to lens cells and neural cells in vitro with no addition of basic FGF (bFGF), while B/+ rPECs required bFGF to transdifferentiate. Expression of PEC-specific genes, mmp115, tyrosinase, and TRP-1, was downregulated, but that of Mitf and pax6 was upregulated in B/B PECs. Antibody against Mitf stained the nucleus of B/+ PECs but not that of B/B cells, suggesting that the normal Mitf is not present in the silver homozygote due to mutation. Sequence analysis revealed that Mitf from the silver homozygote has an amino acid substitution in the basic region and is truncated in the C-terminal region. Transient transfection analysis revealed that Mitf from the silver homozygote exhibits a lower level of activity than wild-type Mitf with respect to transactivation of the mmp115 promoter. Furthermore, overexpression of chicken Mitf induced normal pigmentation in B/B rPECs. These results strongly suggest that the silver phenotype is caused by the mutation of Mitf and that Mitf plays a critical role in rPEC differentiation and transdifferentiation.
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