转分化研究进展

转分化是近几年发现的成体组织细胞改变其表型的一种现象 ,即在一定条件下控制发育方向的转录因子表达发生改变 ,从而使成体干细胞或分化细胞特定的分化状态也发生改变。随着体外诱导条件的成熟和理论研究的深入 ,转分化将会成为器官移植中获取具有修复细胞的重要手段。对近年来有关转分化的种类、理论基础、研究方法和研究进展及现实意义进行了综述。     

Mechanisms of transdifferentiation and their relation to induction and competence

The ways of transdifferentiation are considered: spontaneous and induced. Spontaneous transdifferentiation taking place after the disaggregation of cells in the clonal and cell cultures is determined by the competence of the transforming cells themselves. Induced transdifferentiation is determined not only by the competence but also by the effect of external inducing factors. It is suggested that the direction of induced transdifferentiation depends on the ratio between the external and internal inducing factors and on the character of cell cycles. It is probable that the inducing factors entering the cells during the early embryonic induction are reproduced in the cells in a dormant state and some of them do not reveal their presence until appropriate conditions are set. When the cells are isolated in the cultures, the ratio of these factors inside the cell changes and a competence to transdifferentiation is revealed which arises as early as during induction.     

PDGF,NT-3 and IGF-2 in Combination Induced Transdifferentiation of Muscle-Derived Stem Cells into Schwann Cell-Like Cells

Muscle-derived stem cells (MDSCs) are multipotent stem cells with a remarkable long-term self-renewal and regeneration capacity. Here, we show that postnatal MDSCs could be transdifferentiated into Schwann cell-like cells upon the combined treatment of three neurotrophic factors (PDGF, NT-3 and IGF-2). The transdifferentiation of MDSCs was initially induced by Schwann cell (SC) conditioned medium. MDSCs adopted a spindle-like morphology similar to SCs after the transdifferentiation. Immunocytochemistry and immunoblot showed clearly that the SC markers S100, GFAP and p75 were expressed highly only after the transdifferentiation. Flow cytometry assay showed that the portion of S100 expressed cells was more than 60 percent and over one fourth of the transdifferentiated cells expressed all the three SC markers, indicating an efficient transdifferentiation. We then tested neurotrophic factors in the conditioned medium and found it was PDGF, NT-3 and IGF-2 in combination that conducted the transdifferentiation. Our findings demonstrate that it is possible to use specific neurotrophic factors to transdifferentiate MDSCs into Schwann cell-like cells, which might be therapeutically useful for clinical applications.     

Microarray analyses of transdifferentiated mesenchymal stem cells

The molecular events associated with the age-related gain of fatty tissue in human bone marrow are still largely unknown. Besides enhanced adipogenic differentiation of mesenchymal stem cells (MSCs), transdifferentiation of osteoblast progenitors may contribute to bone-related diseases like osteopenia. Transdifferentiation of MSC-derived osteoblast progenitors into adipocytes and vice versa has previously been proven feasible in our cell culture system. Here, we focus on mRNA species that are regulated during transdifferentiation and represent possible control factors for the initiation of transdifferentiation. Microarray analyses comparing transdifferentiated cells with normally differentiated cells exhibited large numbers of reproducibly regulated genes for both, adipogenic and osteogenic transdifferentiation. To evaluate the relevance of individual genes, we designed a scoring scheme to rank genes according to reproducibility, regulation level, and reciprocity between the different transdifferentiation directions. Thereby, members of several signaling pathways like FGF, IGF, and Wnt signaling showed explicitly differential expression patterns. Additional bioinformatic analysis of microarray analyses allowed us to identify potential key factors associated with transdifferentiation of adipocytes and osteoblasts, respectively. Fibroblast growth factor 1 (FGF1) was scored as one of several lead candidate gene products to modulate the transdifferentiation process and is shown here to exert inhibitory effects on adipogenic commitment and differentiation.     

Activin signaling limits the competence for retinal regeneration from the pigmented epithelium

Regeneration of the retina in amphibians is initiated by the transdifferentiation of the retinal pigmented epithelium (RPE) into neural progenitors. A similar process occurs in the early embryonic chick, but the RPE soon loses this ability. The factors that limit the competence of RPE cells to regenerate neural retina are not understood; however, factors normally involved in the development of the eye (i.e. FGF and Pax6) have also been implicated in transdifferentiation. Therefore, we tested whether activin, a TGFbeta family signaling protein shown to be important in RPE development, contributes to the loss in competence of the RPE to regenerate retina. We have found that addition of activin blocks regeneration from the RPE, even during stages when the cells are competent. Conversely, a small molecule inhibitor of the activin/TGFbeta/nodal receptors can delay, and even reverse, the developmental restriction in FGF-stimulated neural retinal regeneration.     

From lens regeneration in the newt toin-vitrotransdifferentiation of vertebrate pigmented epithelial cells

Through studies to clarify the cellular origin of lens regeneration in the newt, the pigmented epithelial cells of the iris and the retina of many vertebrate species have been shown to possess a dormant potency to transdifferentiate into the lens. The method ofin-vitroculture of pigmented epithelial cells has been optimized to enable detailed studies of the transdifferentiation process by molecular techniques. Growth factors and extracellular matrix components are found to be important in the control of the transdifferentiation process. New systems forin-vitroculture are introduced, while prospects for renewedin-vivostudies using newts are given.     

Transdifferentiation of pancreas to liver

Transdifferentiation is the name used to describe the direct conversion of one differentiated cell type into another. Cells which have the potential to interconvert by transdifferentiation generally arise from adjacent regions in the developing embryo. For example, the liver and pancreas arise from the same region of the endoderm. The transdifferentiation of pancreas to liver (and vice versa) has been observed in animal experiments and in certain human pathologies. Understanding transdifferentiation is important to developmental biologists because it will help elucidate the cellular and molecular differences that distinguish neighbouring regions of the embryo. While the in vivo models for the transdifferentiation of liver to pancreas have been valuable, it is more difficult to extrapolate from these studies to individual changes at the cellular or molecular levels. The recent development of two in vitro systems (AR42J cells and embryonic pancreatic cultures) for the transdifferentiation of pancreas to liver has shown that an environmental change in the form of an exogenous glucocorticoid can cause the conversion of pancreatic exocrine cells into hepatocytes. The AR42J cell system has been used to elucidate the cell lineage and the molecular basis of transdifferentiation of pancreas to liver.     

Transdifferentiation in neoplastic development and its pathological implication

Transdifferentiation is a process in which a cell committed to a particular specialization changes to another quite distinct type. It occurs during embryological development and some pathological processes, and causes the tumor cells to express a phenotype different from that of their normal progenitors. Neoplastic transdifferentiation involves pathogenesis of cancer subtype, transition between neoplastic epithelia and neuroendocrine cell, transition between neoplastic epithelia and mesenchyme, as well as transition between non-neuroectodermal and neuroectodermal cells. We propose that differentiation disturbance of cancer cells should include not only lower-, un-, or de-differentiation, but also transdifferentiation. Tumor cell transdifferentiation results from genetic instabilities. In some type of neoplastic transition, the initiation may be induced by extracellular matrix and growth factors.     

Transdifferentiation--fact or artifact

Normal development appears to involve a progressive restriction in developmental potential. However, recent evidence suggests that this progressive restriction is not irreversible and can be altered to reveal novel phenotypic potentials of stem, progenitor, and even differentiated cells. While some of these results can be explained by the presence of contaminating cell populations, persistence of pluripotent stem cells, cell fusion, etc., several examples exist that are difficult to explain as anything other than "true transdifferentiation" and/or dedifferentiation. These examples of transdifferentiation are best explained by understanding how the normal process of progressive cell fate restriction occurs during development. We suggest that subversion of epigenetic controls regulating cell type specific gene expression likely underlies the process of transdifferentiation and it may be possible to identify specific factors to control the transdifferentiation process. We predict, however, that transdifferentiation will not be reliable or reproducible and will probably require complex manipulations.     

Transdifferentiation of esophageal smooth to skeletal muscle is myogenic bHLH factor-dependent

Previously, coexpression of smooth and skeletal differentiation markers, but not myogenic regulatory factors (MRFs), was observed from E16.5 mouse fetuses in a small percentage of diaphragm level esophageal muscle cells, suggesting that MRFs are not involved in the process of initiation of developmentally programmed transdifferentiation in the esophagus. To investigate smooth-to-skeletal esophageal muscle transition, we analyzed Myf5nlacZ knock-in mice, MyoD-lacZ and myogenin-lacZ transgenic embryos with a panel of the antibodies reactive with myogenic regulatory factors (MRFs) and smooth and skeletal muscle markers. We observed that lacZ-expressing myogenic precursors were not detected in the esophagus before E15.5, arguing against the hypothesis that muscle precursor cells populate the esophagus at an earlier stage of development. Rather, the expression of the MRFs initiated in smooth muscle cells in the upper esophagus of E15.5 mouse embryos and was immediately followed by the expression of skeletal muscle markers. Moreover, transdifferentiation was markedly delayed or absent only in the absence of Myf5, suggesting that appropriate initiation and progression of smooth-to-skeletal muscle transdifferentiation is Myf5-dependent. Accordingly, the esophagus of Myf5(-/-):MyoD(-/-)embryos completely failed to undergo skeletal myogenesis and consisted entirely of smooth muscle. Lastly, extensive proliferation of muscularis precursor cells, without programmed cell death, occurred concomitantly with esophageal smooth-to-skeletal muscle transdifferentiation. Taken together, these results indicate that transdifferentiation is the fate of all smooth muscle cells in the upper esophagus and is normally initiated by Myf5.     

Transdifferentiation of Adult Frog Iris in Retina or Lens by Exogeneous Influences

The mechanisms of transdifferentiation of iris epithelial cells of Rana temporaria (Anura) in culture depending on influences from different sources were studied. In terminally differentiated iris cells, the process of transdifferentiation is initiated by dedifferentiation. Melanosomes are shed from iris cells due to cell surface activity. After depigmentation, iris epithelial cells become capable of proliferating and competent to react to the influences of various exogenous factors. Under the influence of retinal factors secreted by lentectomized tadpole eyes, both dorsal and ventral irises are converted to neural retina. Under the influence of factors from eye vesicles, the irises are converted to neural retina as well. Similar results were obtained in transfilter experiments, in which a 3-day period of transfilter interaction between the irises and eye vesicles ensured depigmentation of the iris followed by transdifferentiation into complete NR with visual receptor. Lentoid formation occurred under the influence of adult frog lens epithelium. Immunofluorescent analysis confirmed the lens nature of the lentoids. In control experiments under the conditions of the tadpole eye orbit, in which programming influences were absent, iris epithelial cells remained unaffected.
The problem of true cell-reprogramming to new differentiation in contrast to expression of inherent properties of the iris epithelial cells is discussed.     

Slight up-regulation of Kir2.1 channel promotes endothelial progenitor cells to transdifferentiate into a pericyte phenotype by Akt/mTOR/Snail pathway

It was shown that endothelial progenitor cells (EPCs) have bidirectional differentiation potential and thus perform different biological functions. The purpose of this study was to investigate the effects of slight up-regulation of the Kir2.1 channel on EPC transdifferentiation and the potential mechanism on cell function and transformed cell type. First, we found that the slight up-regulation of Kir2.1 expression promoted the expression of the stem cell stemness factors ZFX and NS and inhibited the expression of senescence-associated β-galactosidase. Further studies showed the slightly increased expression of Kir2.1 could also improve the expression of pericyte molecular markers NG2, PDGFRβ and Desmin. Moreover, adenovirus-mediated Kir2.1 overexpression had an enhanced contractile response to norepinephrine of EPCs. These results suggest that the up-regulated expression of the Kir2.1 channel promotes EPC transdifferentiation into a pericyte phenotype. Furthermore, the mechanism of EPC transdifferentiation to mesenchymal cells (pericytes) was found to be closely related to the channel functional activity of Kir2.1 and revealed that this channel could promote EPC EndoMT by activating the Akt/mTOR/Snail signalling pathway. Overall, this study suggested that in the early stage of inflammatory response, regulating the Kir2.1 channel expression affects the biological function of EPCs, thereby determining the maturation and stability of neovascularization.