Embryonale Stammzellen der Maus Eigenschaften, Potenzial und Verwendung

During the last few years research on embryonic stem cells has received much public attention due to the fact that these cells are able to differentiate in vitro into many specialized cells and thus may serve as a source for a variety of tissues. The following article focuses on mouse embryonic stem cells (murine ES cells), because research on these cells has given insight into the potential of embryonic stem cells. Murine ES cells are permanent cell lines established from the inner cell mass (ICM) of early embryos (blastocysts). ES cells are undifferentiated pluripotent cells that are able to undergo an unlimited number of cell divisions without loosing the undifferentiated phenotype. The same is true for mouse primordial germ cell lines (murine EG cell lines), that where established from the fetal progenitor cells of primordial germ cells. Mouse embryonic stem cells are used for different purposes. In basic research they are used to study the consequences of mutations within genes that control embryonic development and/or the development of diseases. Because of their ability to differentiate into a variety of specialized cell types, murine ES cells also serve as model systems to establish specific differentiation protocols. In the last few years protocols were established for the in vitro development of undifferentiated embryonic stem cells into differentiated cardiac, skeletal muscle, neural, adipogenic, haematopoietic, endothelial, chondrogenic or vascular smooth muscle cells. Last but not least, studies on mouse ES cells have demonstrated that embryonic cells and their differentiated derivatives can be used to analyse the effects of toxic substances or of pharmaceutical drugs.     

干细胞向雌性生殖细胞分化的研究进展

干细胞是一类具有自我更新和多向分化潜能的细胞。根据其来源不同,干细胞可分为胚胎干细胞、成体干细胞以及诱导性多能干细胞。生殖细胞系负责跨代传递遗传和表观遗传信息,以确保新的正常个体产生。人类辅助生殖技术(ART)虽可解决部分难治性不孕不育患者的生育问题,但尚不能解决由于卵巢早衰生殖细胞缺乏导致的不孕,如果在体外可以将干细胞定向诱导分化为生殖细胞,则可能通过ART帮助卵巢早衰患者获得健康后代。雌性配子发育经历了多个严格、复杂的过程,包括原始生殖细胞(PGC)特化、增殖、迁移到生殖嵴并最终分化为成熟的卵母细胞。然而具体过程尚不明确。近年来学者已建立了干细胞向雌性生殖细胞分化的体外模型,并取得了长足进步。     

Stem cell sources for cardiac regeneration

Cell-based cardiac repair has the ambitious aim to replace the malfunctioning cardiac muscle developed after myocardial infarction, with new contractile cardiomyocytes and vessels. Different stem cell populations have been intensively studied in the last decade as a potential source of new cardiomyocytes to ameliorate the injured myocardium, compensate for the loss of ventricular mass and contractility and eventually restore cardiac function. An array of cell types has been explored in this respect, including skeletal muscle, bone marrow derived stem cells, embryonic stem cells (ESC) and more recently cardiac progenitor cells. The best-studied cell types are mouse and human ESC cells, which have undisputedly been demonstrated to differentiate into cardiomyocyte and vascular lineages and have been of great help to understand the differentiation process of pluripotent cells. However, due to their immunogenicity, risk of tumor development and the ethical challenge arising from their embryonic origin, they do not provide a suitable cell source for a regenerative therapy approach. A better option, overcoming ethical and allogenicity problems, seems to be provided by bone marrow derived cells and by the recently identified cardiac precursors. This report will overview current knowledge on these different cell types and their application in cardiac regeneration and address issues like implementation of delivery methods, including tissue engineering approaches that need to be developed alongside.     

Enrichment of blood from embryonic stem cells in vitro

Murine embryonic stem (ES) cells are pluripotent. When injected into blastocysts they can give rise to every cell type of a derived chimeric mouse including germ cells. Embryonic stem cells also possess remarkable in vitro differentiation potential. When removed from stromal support and leukaemia inhibitory factor (LIF), ES cells differentiate into structures known as embryoid bodies (EBs), in which all three germ layers develop and interact. As ES cells from humans become available there is increasing interest in the potential for EBs to provide an unlimited supply of stem cells for somatic transplantation therapies. Realisation of this potential will require greater understanding of the molecular determinants of cell fate within EBs. Also, culture techniques for selective expansion of cell lineages of interest will reduce the risks associated with transplantation of EB-derived cells. In this paper the kinetics of expression of mRNA and protein for early mesoderm markers within EBs is reported. In addition, a three-step culture system incorporating co-cultivation on the bone marrow derived stromal cell line, MC3T3-G2/PA6 (PA6), is explored as a way to select for haematopoietic progenitor cells (HPCs) and against undifferentiated ES cells. A system like this could enhance purification of haematopoietic stem cells (HSCs) from ES cells for bone marrow transplantation.     

Cellular therapy--the possible future of regenerative medicine

Stem cells are a unique cell population capable of self-renewal and differentiation into different cell lines. There are two main types of stem cells: embryonic stem cells (pluripotent) and somatic/adult stem cells (multipotent cells differentiated into the specific types of the tissue they originate from). Scientists are now interested in finding the sources of cells that can be used for therapeutic cloning as a method of saving human life and a new trend in regenerative medicine. Reproductive cloning, which aims at creating genetically identical human beings, is prohibited and is subject to national legislation in each country. Mesenchymal stem cells, with their capability to elude detection by the host's immune system and their relative ease of expansion in culture, are a very promising source of stem cells for regenerative medicine. This is the vast potential of cellular therapy for treating damaged and degenerating tissues.     

Therapeutic cloning: far from application at this stage]

Therapeutic cloning has become possible since the discovery that nuclei from somatic cells of adult animal tissue can successfully be used for cloning and the fact that human embryonic stem cell lines have been established from preimplantation embryos. When nuclei from healthy tissue of a patient are transplanted into enucleated oocytes, these oocytes can be artificially activated so that embryos develop from which embryonic stem cells of the donor can be derived. These embryonic stem cells can be cultured as permanent lines in unlimited numbers and remain pluripotent, i.e. they can be induced to differentiate into the required cell type by adding one or more specific factors. These cells can then be transplanted back into the patient suffering from either a lack or dysfunction of these cells. This approach prevents the rejection of the transplanted cells by the patient's immunological system. As this type of cloning has a very low efficiency, a large number of unfertilized donor oocytes is required. It is questionable whether enough donors are or will be available for this purpose. The cultured cells must satisfy certain conditions before they can be used for transplantation. They must be checked for chromosomal abnormalities, and a complete differentiation of the embryonic stem cells into the cells types needed by the patient is necessary as after the transplantation, undifferentiated stem cells will form teratomas. Furthermore, it is difficult to ensure that the cells end up in the right place and to ensure that they fully integrate into the existing tissue to form functional connections. Due to this array of technical problems the question remains as to whether therapeutic cloning will become feasible in the near future.     

Plasticity of tissue stem cells

In the early stages of embryonic development, cells have the capability of dividing indefinitely and then differentiating into any type of cell in the body. Recent studies have revealed that much of this remarkable developmental potential of stem cells is retained by small populations of cells within most tissues in the adult. Intercellular signals that control the proliferation, differentiation and survival of tissue stem cells in their niches are being identified and include a diverse array of morphogens, cytokines, chemokines and cell adhesion molecules. Adult tissue stem cells, moreover, can also differentiate into developmentally unrelated cell types, such as nerve stem cells into blood cells. Currently, we can only speculate about the mechanisms involved in such dramatic changes in cell fate. For example, the emergence of, say, hematopoietic stem cells from brain neurospheres could involve either transdifferentiation (brain-->blood) or dedifferentiation (brain-->pluripotent cells), or by the actions of rare, but residual pluripotent stem cells. This issue is central to understanding the molecular basis of commitment and lies at the heart of debates about plasticity and the reversibility of developmental restriction.     

Maintenance of pluripotential embryonic stem cells by stem cell selection

As gastrulation proceeds, pluripotential stem cells with the capacity to contribute to all primary germ layers disappear from the mammalian embryo. The extinction of pluripotency also occurs during the formation of embryoid bodies from embryonic stem (ES) cells. In this report we show that if the initial differentiated progeny are removed from ES cell aggregates, further differentiation does not proceed and the stem cell population persists and expands. Significantly, the presence of even minor populations of differentiated cells lead to the complete loss of stem cells from the cultures. This finding implies that the normal elimination of pluripotent cells is dictated by inductive signals provided by differentiated progeny. We have exploited this observation to develop a strategy for the isolation of pluripotential cells. This approach, termed stem cell selection, may have widespread applicability to the derivation and propagation of stem cells.     

Stem cell strategies for Alzheimer's disease therapy

We have found much evidence that the brain is capable of regenerating neurons after maturation. In our previous study, human neural stem cells (HNSCs) transplanted into aged rat brains differentiated into neural cells and significantly improved the cognitive functions of the animals, indicating that HNSCs may be a promising candidate for cell-replacement therapies for neurodegenerative diseases including Alzheimer's disease (AD). However, ethical and practical issues associated with HNSCs compel us to explore alternative strategies. Here, we report novel technologies to differentiate adult human mesenchymal stem cells, a subset of stromal cells in the bone marrow, into neural cells by modifying DNA methylation or over expression of nanog, a homeobox gene expressed in embryonic stem cells. We also report peripheral administrations of a pyrimidine derivative that increases endogenous stem cell proliferation improves cognitive function of the aged animal. Although these results may promise a bright future for clinical applications used towards stem cell strategies in AD therapy, we must acknowledge the complexity of AD. We found that glial differentiation takes place in stem cells transplanted into amyloid-( precursor protein (APP) transgenic mice. We also found that over expression of APP gene or recombinant APP treatment causes glial differentiation of stem cells. Although further detailed mechanistic studies may be required, RNA interference of APP or reduction of APP levels in the brain can significantly reduced glial differentiation of stem cells and may be useful in promoting neurogenesis after stem cell transplantation.     

胚胎干细胞向肝细胞的诱导分化研究

胚胎干细胞在体外一定条件下能够分化为与原代培养肝细胞表型相似,并表达部分成熟肝细胞功能的类肝细胞.尽管目前在诱导条件的优化、分化过程的调控及临床应用的安全性等方面仍面临一系列问题,但研究胚胎干细胞向肝系的诱导分化及纯化,为终末期肝病的细胞移植治疗、生物人工肝及药物代谢和毒理研究提供了丰富的细胞来源.     

Differentiation of embryonic and adult stem cells into insulin producing cells

Replacement of insulin producing cells represents an almost ideal treatment for patients with diabetes mellitus type 1. Transplantation of pancreatic islets of Langerhans is successful in experienced centers. The wider application of this therapy, however, is limited by the lack of donor organs. Insulin producing cells generated from stem cells represent an attractive alternative. Stem cells with the potential to differentiate into insulin producing cells include embryonic stem cells (ESC) as well as adult stem cells from various tissues including the pancreas, liver, bone marrow and adipose tissue. The use of human ESC is hampered by ethical concerns but research with human ESC may help us to decipher important steps in the differentiation process in vitro since almost all information available on pancreas development are based on animal studies. The present review summarizes the current knowledge on the development of insulin producing cells from embryonic and adult stem cells with special emphasis on pancreatic, hepatic and human mesenchymal stem cells.     

From fibroblasts and stem cells: implications for cell therapies and somatic cloning

Pluripotent embryonic stem cells (ESCs) from the inner cell mass of early murine and human embryos exhibit extensive self-renewal in culture and maintain their ability to differentiate into all cell lineages. These features make ESCs a suitable candidate for cell-replacement therapy. However, the use of early embryos has provoked considerable public debate based on ethical considerations. From this standpoint, stem cells derived from adult tissues are a more easily accepted alternative. Recent results suggest that adult stem cells have a broader range of potency than imagined initially. Although some claims have been called into question by the discovery that fusion between the stem cells and differentiated cells can occur spontaneously, in other cases somatic stem cells have been induced to commit to various lineages by the extra- or intracellular environment. Recent data from our laboratory suggest that changes in culture conditions can expand a subpopulation of cells with a pluripotent phenotype from primary fibroblast cultures. The present paper critically reviews recent data on the potency of somatic stem cells, methods to modify the potency of somatic cells and implications for cell-based therapies.     

Stem cells in the amniotic fluid: the new chance of regenerative medicine

Amniotic fluid has been used in prenatal diagnosis for more than decades. It yields a simple and reliable screening and diagnostic tool for a variety of congenital malformations and genetic diseases such as chromosomal aberrations, neural tube defects or storage diseases. Nowadays the widening knowledge provides evidence that amniotic fluid is not only a screening and diagnostic tool, but it may be also the source of the effective therapy of several congenital and adult disorders. A subset of cells, the so-called stem cells were found in the amniotic fluid as well as the placenta, and they proved to be capable of maintaining prolonged undifferentiated proliferation. Stem cells are able to differentiate into multiple tissue types, originating from the three germ layers. In the near future stem cells isolated from amniotic fluid or placenta and stored by cryopreservation may play a significant role in regenerative medicine. Congenital malformations as well as certain diseases in adults might be treated by tissues coming from progenitor cells of amniotic fluid stem cell origin. This study gives a summary of the main characteristics of amniotic fluid stem cells and it also presents important examples of their possible clinical application.     

Derivation characteristics and perspectives for mammalian pluripotential stem cells

Pluripotential stem cells have been derived in mice and primates from preimplantation embryos, postimplantation embryos and bone marrow stroma. Embryonic stem cells established from the inner cell mass of the mouse and human blastocyst can be maintained in an undifferentiated state for a long time by continuous passage on embryonic fibroblasts or in the presence of specific inhibitors of differentiation. Pluripotential stem cells can be induced to differentiate into all the tissues of the body and are able to colonise tissues of interest after transplantation. In mouse models of disease, there are numerous examples of improved tissue function and correction of pathological phenotype. Embryonic stem cells can be derived by nuclear transfer to establish genome-specific cell lines and, in mice, it has been shown that embryonic stem cells are more successfully reprogrammed for development by nuclear transfer than somatic cells. Pluripotential stem cells are a very valuable research resource for the analysis of differentiation pathways, functional genomics, tissue engineering and drug screening. Clinical applications may include both cell therapy and gene therapy for a wide range of tissue injury and degeneration. There is considerable interest in the development of pluripotential stem cell lines in many mammalian species for similar research interests and applications.     

脐带多能干细胞与女性卵巢功能维护

卵巢作为女性的性腺,在女性体内负责生殖和内分泌的功能,卵巢功能障碍会严重影响女性生理和身心健康。干细胞能可分化成多种组织细胞,其在早衰卵巢的微环境下能“因地制宜”的分化为卵巢细胞,发挥卵巢细胞正常功能,维持卵巢的正常形态,防止卵巢萎缩变形。此外,干细胞再生的卵巢细胞可以对脑垂体分泌的促性腺激素做出及时、正确的反应,维护内激素水平处于平衡状态。     

Comparison of neurosphere cells with cumulus cells after fusion with embryonic stem cells: reprogramming potential

Embryonic stem cells (ESCs) are the pluripotent cells that also have the capacity to induce the genomic reprogramming of differentiated somatic cells. The progressively restricted genomic potential of somatic cells observed during embryonic development can be reverted to a pluripotent state by the formation of cell hybrids with ESCs. To assess the reprogramming potential of ESCs, we investigated the reprogramming of one of two different somatic cell populations, neurosphere cells (NSCs) and cumulus cells (CCs), after fusion with ESCs. Specifically, hybrid cells were produced by cell fusion of E14 ESCs with either NSCs or CCs containing the neo/lacZ and Oct4-GFP transgenes. The first reprogramming event, observed by the presence of Oct4-GFP in the hybrid cells, could be identified on Day 2, at approximately 45 h after fusion in both ESC-NSC and ESC-CC hybrids. In addition, the two ESC-somatic cell hybrids exhibit a similar reprogramming rate and share characteristics with the E14 ESC line: (1) expression of pluripotent markers (Oct4, Rex-1 and nanog); (2) inactivation of differentiated tissue-specific gene expression; and (3) the capacity to differentiate into all three germ layers. Taken together, our results suggest that the ESC-somatic cell hybrids have fully acquired ESC characteristics and that somatic cells of different tissue origin have the same potential to be reprogrammed after fusion with ESCs.     

Retinoids induce differentiation of type A spermatogonia in vitro: organ culture of mouse cryptorchid testes

To study the effects of retinoids on testicular germ cell differentiation, especially on stem cells, artificially induced cryptorchid testes of adult mice were cultured in vitro inasmuch as they contain only stem cells, type A spermatogonia. We report here that retinol, retinal, retinol acetate, even retinoic acid, activated cell division in type A spermatogonia and stimulated them to differentiate. These findings are the first demonstration of the in vitro induction of early stage of spermatogenesis by retinoids and also retinoic acid, which is considered to be a biochemically inactive compound for mammalian testicular function.     

Stem cell research: licit or complicit? Is a medical breakthrough based on embryonic and fetal tissue compatible with Catholic teaching?

In November 1998 biologists announced that they had discovered a way to isolate and preserve human stem cells. Since stem cells are capable of developing into any kind of human tissue or organ, this was a great scientific coup. Researchers envision using the cells to replace damaged organs and to restore tissue destroyed by, for example, Parkinson's disease, diabetes, or even Alzheimer's. But, since stem cells are taken from aborted embryonic and fetal tissue or "leftover" in vitro embryos, their use raises large ethical issues. The National Institutes of Health (NIH) recently decided to fund research employing, not stem cells, but "cell lines" derived from them. The NIH has essentially made an ethical determination, finding sufficient "distance" between cell lines and abortion. Can Catholic universities sponsoring biological research agree with this finding? Probably not. In Catholic teaching, the concept of "complicity" would likely preclude such research. However, Catholic teaching would probably allow research done with stem cells obtained from postpartum placental tissue and from adult bone marrow and tissue. These cells, which lack the pluripotency of embryonic and fetal stem cells, are nevertheless scientifically promising and do not involve the destruction of human life.     

A European discussion about stem cells for therapeutic use

Stem cells as a source material for growing cellular transplants to repair dysfunctional organs appear to be a new challenge for medical science. Though stem cells are also present in foetal and adult organs, embryonic stem cells from the pre-implantation embryo in particular have the potency to proliferate easily in vitro and the capacity to differentiate into all the body's organ-specific cells. Therefore, these are the ideal cells for developing new cell transplantation therapies for diseases such as Parkinson's disease, diabetes mellitus and heart failure. The use of spare in vitro fertilization (IVF) embryos or pre-implantation embryos specially created to harvest human embryonic stem cells is, however, controversial and an ethical problem. In a European discussion platform organised by the European Commission Research Directorate-General, the status quo of the progress was presented and subsequently commented upon and discussed in terms of medical-ethical, social, industrial and patient interests. The expectations of this new medical technology were high, but clinical trials seem only acceptable once the in vitro differentiation of stem cells can be adequately controlled and once it is known how in vitro prepared stem cells behave after implantation. The ethical justification of the use of in vitro pre-implantation embryos remains controversial. The prevailing view is that the interests of severely ill patients for whom no adequate therapy exists, surmounts the interest of protection of a human in vitro pre-implantation embryo, regardless of whether it was the result of IVF or of transplantation of a somatic cell nucleus of the patient in an enucleated donor egg cell (therapeutic cloning).