Stem cells and blastema cells

Recently much effort has resulted in papers on how stem cells can be generated from adult tissues in mice, but the salamanders do this routinely. Salamanders can regenerate most of their body parts, such as limbs, eyes, jaw, brain (and spinal cord), heart, etc. Regeneration in salamanders starts by dedifferentiation of the terminally differentiated tissues at the site of injury. The dedifferentiated cells can then differentiate to reconstitute the lost tissues. This transdifferentiation in an adult animal is unprecedented among vertebrates and does not involve recruitment of stem cells. One of the ideas is that such reprogramming of terminally differentiated cells might involve mechanisms that are similar to the maintenance of embryonic stem cells. In the stem cell field much emphasis has been recently given to the reprogramming of adult cells (such as skin fibroblasts) to revert to ES or pluripotent stem cells. It is our conviction that generation of dedifferentiated cells in salamanders and stem cells, such as the ones seen in repair in mammals share molecular signatures. This mini review will discuss these issues and ideas that could unite the stem cell biology with the classical regeneration models.     

Plasticity,niches, and the use of stem cells

Stem cells possess the ability to self-renew and generate multiple cell types of the tissues in which they reside. Several studies have reported transdifferentiation events between different somatic stem cells. These properties have created tremendous excitement about the prospect of using stem cells from easily accessible sources for tissue engineering. However, recently, the plasticity of stem cells has met with several strong challenges. In this meeting review, we will discuss issues surrounding reports of transdifferentiation, the molecular mechanisms that govern stem cell states, and progress toward putting stem cells to use.     

BM stem cells and cardiac repair: where do we stand in 2004?

Adult BM stem cells are being investigated for their potential to regenerate injured tissues by a process referred to as plasticity or transdifferentiation. Although data supporting stem cell plasticity is extensive, a controversy has emerged based on findings that propose cell-cell fusion as a more appropriate interpretation for this phenomenon. A major focus of this controversy is the claim that acutely infarcted myocardium in adult hearts can be regenerated by BM stem cells. Many researchers consider the adult heart to be a post-mitotic organ, whereas others believe that a low level of cardiomyocyte renewal occurs throughout life. If renewal occurs, it may be in response to cardiac stem cell activity or to stem cells that migrate from distant tissues. Post-mortem microscopic analysis of experimentally induced myocardial infarctions in several rodent models suggests that cardiomyocyte renewal is achieved by stem cells that infiltrate the damaged tissue. For a better understanding of the possible involvement of stem cells in myocardial regeneration, it is important to develop appropriate technologies to monitor myocardial repair over time with an emphasis on large animal models. Studies on non-human primate, swine and canine models of acute myocardial infarctions would enable investigators to utilize clinical quality cell-delivery devices, track labeled donor cells after precision transplantation and utilize non-invasive imaging for functional assays over time with clinical accuracy. In addition, if stem cell plasticity is to reach the next level of acceptance, it is important to identify the environmental cues needed for stem cell trafficking and to define the genetic and cellular mechanisms that initiate transdifferentiation. Only then will it be possible to determine if, and to what extent, BM stem cells are involved in myocardial regeneration and to begin to regulate precisely tissue repair.     

Nuclear reprogramming and adult stem cell potential

Cell-based therapy may represent a new strategy to treat a vast array of clinical disorders including neurodegenerative diseases. Recent observations indicate that adult somatic stem cells have the capacity to contribute to the regeneration of different tissues, suggesting that differentiative restrictions are not completely irreversible and can be reprogrammed. Cell fusion might account for some changed phenotype of adult cells but it seems to be biologically irrelevant for its extreme rarity. Other experimental evidences are compatible with the hypothesis of wide multipotency of well-defined stem cell populations, but also with transdifferentiation and/or dedifferentiation. Further studies on nuclear reprogramming mechanisms are necessary to fulfil the promise for developing autologous cellular therapies.     

New advances in stem cell biology: A perspective from gametogenesis

Regeneration of adult tissues relies on a small population of adult stem cells located in a specialized microenvironment. The adult stem cells divide continuously to produce new stem cells, as well as differentiated daughter cells to replenish lost cells due to damage or aging. The molecular mechanisms controlling their ability to divide, self-renew and differentiate remain largely undiscovered. The Drosophila reproductive systems have proven to be excellent models to understand the basic mechanisms regulating stem cell function. This report summarizes some of the recent advances in this field that were presented at the 49th Drosophila Research Conference held in San Diego in April 2008.     

New advances in stem cell biology: A perspective from gametogenesis

Regeneration of adult tissues relies on a small population of adult stem cells located in a specialized microenvironment. The adult stem cells divide continuously to produce new stem cells, as well as differentiated daughter cells to replenish lost cells due to damage or aging. The molecular mechanisms controlling their ability to divide, self-renew and differentiate remain largely undiscovered. The Drosophila reproductive systems have proven to be excellent models to understand the basic mechanisms regulating stem cell function. This report summarizes some of the recent advances in this field that were presented at the 49(th) Drosophila Research Conference held in San Diego in April 2008.     

The role of some donor-host cell interactions in conditions of the regenerative process microenvironment

The review is devoted to the analysis of experimental data about possible mechanisms of transdifferentiation or plasticity of tissue specific stem cells. Considerable attention is focused on the mechanisms and genetic consequences of fusion of different types of donor cells with the cells of recipient tissues which investigated on the models of cellular therapy of liver and heart diseases. The role of various kinds of cell contacts and their role in stem cells integration, reparation and regeneration of injured tissue and horizontal genes transfer are considered.     

How cells change their phenotype

Recent attention has focused on the remarkable ability of adult stem cells to produce differentiated cells from embryologically unrelated tissues. This phenomenon is an example of metaplasia and shows that embryological commitments can be reversed or erased under certain circumstances. In some cases, even fully differentiated cells can change their phenotype (transdifferentiation). This review examines recently discovered cases of metaplasia, and speculates on the potential molecular and cellular mechanisms that underlie the switches, and their significance to developmental biology and medicine.     

成体干细胞的可塑性:横向分化还是细胞融合?

近年来研究显示成体干细胞(adult stem cells)具有可塑性(plasticity),不仅可以生成它们所在组织的成熟细胞,而且在特定环境下能分化成其他组织类型细胞,这种跨系或跨胚层分化现象称为横向分化或转分化(transdifferentiation)。横向分化已为成体干细胞的研究和临床应用包括组织器官损伤的修复提供了新的思路和应用前景。然而,最近的一些研究进展又引出不同的解释,即成体干细胞的可塑性是由于细胞融合(cellfusion)的结果。在此,就成体干细胞的可塑性、横向分化、细胞融合等方面研究作一综述。     

Plasticity revisited

Despite some recent setbacks, it remains clear that adult stem cells under appropriate experimental conditions can at some frequency exhibit a wider range of differentiation potentials than previously appreciated. This is underscored by the recent demonstration of the extensive differentiation potential of mesenchymal stem cells. In terms of mechanism, it remains unclear in many cases to what extent plasticity reflects in vitro adaptation, transdifferentiation/cell-type switching or the persistence in adult tissues of stem cells with extensive endogenous or bona fide developmental potentials. These issues will need to be resolved before the full therapeutic potential of adult-derived stem cells can be realised.     

Basic fibroblast growth factor induces retinal pigment epithelium to generate neural retina in vitro.

During embryogenesis, the cells of the eye primordium are initially capable of giving rise to either neural retina or pigmented epithelium (PE), but become restricted to one of these potential cell fates. However, following surgical removal of the retina in embryonic chicks and larval amphibians, new neural retina is generated by the transdifferentiation, or phenotypic switching, of PE cells into neuronal progenitors. A recent study has shown that basic fibroblast growth factor (bFGF) stimulates this process in chicks in vivo. To characterize further the mechanisms by which this factor regulates the phenotype of retinal tissues, we added bFGF to enzymatically dissociated chick embryo PE. We found that bFGF stimulated proliferation and caused several morphological changes in the PE, including the loss of pigmentation; however, no transdifferentiation to neuronal phenotypes was observed. By contrast, when small sheets of PE were cultured as aggregates on a shaker device, preventing flattening and spreading on the substratum, we found that a large number of retinal progenitor cells were generated from the PE treated with bFGF. These results indicate that bFGF promotes retinal regeneration in vitro, as well as in ovo, and suggest that the ability of chick PE to undergo transdifferentiation to neuronal progenitors appears to be dependent on the physical configuration of the cells.     

间充质干细胞的生物学特性及心血管修复潜能的研究进展

间充质干细胞存在于成体组织中,来源于骨髓、脂肪组织等,在体外易分离和培养,是具有塑料粘附性的一群非均质细胞。它们具有分化的潜能,在适当的条件下可分化为心肌和血管。临床前期研究显示,在心脏损伤模型中移植间充质干细胞有利于心肌修复和心血管形成。其作用机制与间充质干细胞再生和旁分泌能力密切相关。在临床应用中,间充质干细胞具有免疫抑制作用,也可用于异体移植。总之,虽然间充质干细胞的研究尚有许多问题亟待解决,但是它在心脏疾病的细胞治疗和组织工程中已显示出广阔的前景。     

Therapeutic potential of bone marrow stem cells for liver diseases

Stem cells of the bone marrow, including hematopoietic stem cells (HSC), mesenchymal stem cells (MSC) and hepatic progenitors were reported to give rise to hepatocytes by both transdifferentiation and cellular fusion. Transdifferentiation was observed without liver damage although significant numbers of stem cell derived hepatocytes were not described. Cellular fusion was demonstrated in the presence of a proliferation stimulus in conjunction with impaired intrinsic liver regeneration capacity. Here, we review potential therapeutic applications of stem cell derived hepatocytes depending on how they emerge. Stem cells turning into hepatocytes by transdifferentiation introduce new functioning liver cells into a diseased organ, which can support intrinsic liver regeneration or bridge the time gap until a definitive treatment is available. When cellular fusion is the mechanism behind stem cell plasticity, however, no new cells emerge in the first place, whereas new genetic material is introduced. The fusion cell thereby acquires a selective advantage over resident hepatocytes allowing for extensive proliferation and liver repopulation. Therefore genetic deficiencies might be the predominant target for cell fusion therapies. We conclude that transdifferentiation and cellular fusion might be powerful tools for the therapy of liver diseases in the future and we propose the introduction of artificial cell fusion as well as stem cell differentiation as therapeutic options.     

Transdifferentiation, Metaplasia and Tissue Regeneration

Transdifferentiation is defined as the conversion of one cell type to another. It belongs to a wider class of cell type transformations called metaplasias which also includes cases in which stem cells of one tissue type switch to a completely different stem cell. Numerous examples of transdifferentiation exist within the literature. For example, isolated striated muscle of the invertebrate jellyfish (Anthomedusae) has enormous transdifferentiation potential and even functional organs (e.g., tentacles and the feeding organ (manubrium)) can be generated in vitro. In contrast, the potential for transdifferentiation in vertebrates is much reduced, at least under normal (nonpathological) conditions. But despite these limitations, there are some well-documented cases of transdifferentiation occurring in vertebrates. For example, in the newt, the lens of the eye can be formed from the epithelial cells of the iris. Other examples of transdifferentiation include the appearance of hepatic foci in the pancreas, the development of intestinal tissue at the lower end of the oesophagus and the formation of muscle, chondrocytes and neurons from neural precursor cells. Although controversial, recent results also suggest the ability of adult stem cells from different embryological germlayers to produce differentiated cells e.g., mesodermal stem cells forming ecto- or endodermally-derived cell types. This phenomenon may constitute an example of metaplasia. The current review examines in detail some well-documented examples of transdifferentiation, speculates on the potential molecular and cellular mechanisms that underlie the switches in phenotype, together with their significance to organogenesis and regenerative medicine.Key Words: transdifferentiation, metaplasia, tissue regeneration, stem cells, plasticity, reprogramming, regenerative medicine     

Transdifferentiation,Metaplasia and Tissue Regeneration

Transdifferentiation is defined as the conversion of one cell type to another. It belongs to a wider class of cell type transformations called metaplasias which also includes cases in which stem cells of one tissue type switch to a completely different stem cell. Numerous examples of transdifferentiation exist within the literature. For example, isolated striated muscle of the invertebrate jellyfish (Anthomedusae) has enormous transdifferentiation potential and even functional organs (e.g. tentacles and the feeding organ (manubrium) can be generated in-vitro. In contrast, the potential for transdifferentiation in vertebrates is much reduced, at least under normal (non-pathological) conditions. But despite these limitations, there are some well-documented cases of transdifferentiation occurring in vertebrates. For example, in the newt, the lens of the eye can be formed from the epithelial cells of the iris. Other examples of transdifferentiation include the appearance of hepatic foci in the pancreas, the development of intestinal tissue at the lower end of the oesophagus and the formation of muscle, chondrocytes and neurons from neural precursor cells. Although controversial, recent results also suggest the ability of adult stem cells from different embryological germlayers to produce differentiated cells e.g. mesodermal stem cells forming ecto- or endodermally-derived cell types. This phenomenon may constitute an example of metaplasia. The current review examines in detail some well-documented examples of transdifferentiation, speculates on the potential molecular and cellular mechanisms that underlie the switches in phenotype, together with their significance to organogenesis and regenerative medicine.     

Medical perspectives of adults and embryonic stem cells

In the last 30 years, allogeneic bone marrow transplantation has become the treatment of choice for many hematologic malignancies or inherited disorders and a number of changes have been registered in terms of long-term survival rate of transplanted patients as well as of available sources of hematopoietic stem cell (HSC). In parallel to the publication of better results in HSC transplantation, several recent discoveries have opened a scientific and ethical debate on the therapeutical potential of stem cells isolated from adult or embryonic tissues. One of the major discoveries in this field is the capacity of bone marrow-derived stem cells to treat a genetic liver disease in a mouse model, thus justifying the concept of transdifferentiation of adult stem cell and raising hopes on its possible therapeutical applications. We have tried here to summarise the advances in this field and to discuss the limits of these biological data.     

Potential of embryonic and adult stem cells in vitro

Recent developments in the field of stem cell research indicate their enormous potential as a source of tissue for regenerative therapies. The success of such applications will depend on the precise properties and potentials of stem cells isolated either from embryonic, fetal or adult tissues. Embryonic stem cells established from the inner cell mass of early mouse embryos are characterized by nearly unlimited proliferation, and the capacity to differentiate into derivatives of essentially all lineages. The recent isolation and culture of human embryonic stem cell lines presents new opportunities for reconstructive medicine. However, important problems remain; first, the derivation of human embryonic stem cells from in vitro fertilized blastocysts creates ethical problems, and second, the current techniques for the directed differentiation into somatic cell populations yield impure products with tumorigenic potential. Recent studies have also suggested an unexpectedly wide developmental potential of adult tissue-specific stem cells. Here too, many questions remain concerning the nature and status of adult stem cells both in vivo and in vitro and their proliferation and differentiation/transdifferentiation capacity. This review focuses on those issues of embryonic and adult stem cell biology most relevant to their in vitro propagation and differentiation. Questions and problems related to the use of human embryonic and adult stem cells in tissue regeneration and transplantation are discussed.     

Regeneration of the amphibian retina: role of tissue interaction and related signaling molecules on RPE transdifferentiation

Regeneration of eye tissue is one of the classic subjects in developmental biology and it is now being vigorously studied to reveal the cellular and molecular mechanisms involved. Although many experimental animal models have been studied, there may be a common basic mechanism that governs retinal regeneration. This can also control ocular development, suggesting the existence of a common principle between the development and regeneration of eye tissues. This notion is now becoming more widely accepted by recent studies on the genetic regulation of ocular development. Retinal regeneration can take place in a variety of vertebrates including fish, amphibians and birds. The newt, however, has been considered to be the sole animal that can regenerate the whole retina after the complete removal of the retina. We recently discovered that the anuran amphibian also retains a similar ability in the mature stage, suggesting the possibility that such a potential could be found in other animal species. In the present review article, retinal regeneration of amphibians (the newt and Xenopus laevis) and avian embryos are described, with a particular focus on transdifferentiation of retinal pigmented epithelium. One of the recent progresses in this field is the availability of tissue culture methods to analyze the initial process of transdifferentiation, and this enables us to compare the proliferation and neural differentiation of retinal pigmented epithelial cells from various animal species under the same conditions. It was revealed that tissue interactions between the retinal pigmented epithelium and underlying connective tissues (the choroid) play a substantial role in transdifferentiation and that this is mediated by a diffusible signal such as fibroblast growth factor 2. We propose that tissue interaction, particularly mesenchyme-neuroepithelial interaction, is considered to play a fundamental role both in retinal development and regeneration.