Vertebrate reproductive stem cells: recent insights and technological advances

How limited is the ability of stem cells to generate gametes or differentiated somatic cells? Recent outcomes of research with stem cells from both embryonic and adult origin will be discussed with particular attention to results that challenge conventional wisdom about the presence of reproductive stem cells in adults and the plasticity of adult stem cell types. The ability of embryonic germ cells, primordial germ cells, oogonia, gonocytes and spermatogonial stem cells to differentiate or dedifferentiate into overlapping cell types is described as well as the implications of generating differentiated somatic cells of multiple lineages from adult reproductive stem cells.     

Identification of c-Kit receptor as a regulator of adult neural stem cells in the mammalian eye: interactions with Notch signaling

Neural stem cells are present in specific regions of the adult central nervous system (CNS). Recent evidence suggests that the ciliary epithelium (CE), a CNS derivative, in the adult mammalian eye, harbors a quiescent population of neural stem cells. Here, we report the identification of c-Kit signaling as one of the regulators of adult CE neural stem cells in vitro. c-Kit receptors are expressed in proliferating adult CE neural stem cells and colocalized with neural progenitor markers. Perturbation of c-Kit signaling influences the self-renewal and differentiation of CE neural stem cells, thus demonstrating the role of c-Kit signaling in the maintenance of these cells. In addition, we observed an influence of c-Kit-mediated signaling on the expression of Notch1, another critical regulator of neural stem cells. Our observations suggest that, given the importance of preservation of a stem cell pool for generating different cell types at different times, multiple signaling pathways act in concert for the maintenance of neural stem cells.     

Origin of new glial cells in intact and injured adult spinal cord

Several distinct cell types in the adult central nervous system have been suggested to act as stem or progenitor cells generating new cells under physiological or pathological conditions. We have assessed the origin of new cells in the adult mouse spinal cord by genetic fate mapping. Oligodendrocyte progenitors self-renew, give rise to new mature oligodendrocytes, and constitute the dominating proliferating cell population in the intact adult spinal cord. In contrast, astrocytes and ependymal cells, which are restricted to limited self-duplication in the intact spinal cord, generate the largest number of cells after spinal cord injury. Only ependymal cells generate progeny of multiple fates, and neural stem cell activity in the intact and injured adult spinal cord is confined to this cell population. We provide an integrated view of how several distinct cell types contribute in complementary ways to cell maintenance and the reaction to injury.     

Zebrafish adult pigment stem cells are multipotent and form pigment cells by a progressive fate restriction process

Skin pigment pattern formation is a paradigmatic example of pattern formation. In zebrafish, the adult body stripes are generated by coordinated rearrangement of three distinct pigment cell‐types, black melanocytes, shiny iridophores and yellow xanthophores. A stem cell origin of melanocytes and iridophores has been proposed although the potency of those stem cells has remained unclear. Xanthophores, however, seemed to originate predominantly from proliferation of embryonic xanthophores. Now, data from Singh et al. shows that all three cell‐types derive from shared stem cells, and that these cells generate peripheral neural cell‐types too. Furthermore, clonal compositions are best explained by a progressive fate restriction model generating the individual cell‐types. The numbers of adult pigment stem cells associated with the dorsal root ganglia remain low, but progenitor numbers increase significantly during larval development up to metamorphosis, likely via production of partially restricted progenitors on the spinal nerves.     

Epigenetic regulation in adult stem cells and cancers

Adult stem cells maintain tissue homeostasis by their ability to both self-renew and differentiate to distinct cell types. Multiple signaling pathways have been shown to play essential roles as extrinsic cues in maintaining adult stem cell identity and activity. Recent studies also show dynamic regulation by epigenetic mechanisms as intrinsic factors in multiple adult stem cell lineages. Emerging evidence demonstrates intimate crosstalk between these two mechanisms. Misregulation of adult stem cell activity could lead to tumorigenesis, and it has been proposed that cancer stem cells may be responsible for tumor growth and metastasis. However, it is unclear whether cancer stem cells share commonalities with normal adult stem cells. In this review, we will focus on recent discoveries of epigenetic regulation in multiple adult stem cell lineages. We will also discuss how epigenetic mechanisms regulate cancer stem cell activity and probe the common and different features between cancer stem cells and normal adult stem cells.     

The stem cells of early embryos

Cells resident in an organism that possess the dual capacity for self-renewal and differentiation into a spectrum of subtypes are referred to as stem cells. In the past decade, basic research performed on stem cells has shed light on the molecular pathways operating in vivo which can be harnessed in vitro for the establishment of cell lines mirroring the stem cells in the organism. The attractiveness of stem cells as in vitro models of organotypic differentiation and their potential application in a clinical context holds great promise and is only beginning to be exploited. Stem cells can be broadly grouped into two categories based on their origin from either the embryonic or the adult. Only the early embryo possesses truly pluripotent cells that can give rise to all the cell types present in the embryo proper and adult. The adult, on the other hand, possesses specialized, tissue- or organ-specific stem cell types, which can give rise to the differentiated cell types of that specific organ and have in some instances been shown to transdifferentiate. However, no stem cell obtained from an adult organism has yet been shown to exhibit developmental potential matching the breadth of that of stem cells obtained from embryos. This review focuses on the different types of stem cells that are resident in early stage mammalian embryos, detailing their derivation and propagation in addition to highlighting their developmental potential and opportunities for future applications.     

Stem cells in diabetes: what has been achieved

Beta-cell replacement therapy via islet transplantation has received renewed interest due to the recent improved success. In order to make such a therapy available to more than a few of the thousands of patients with diabetes, new sources of insulin-producing cells must be readily available. The most promising sources are stem cells, with efforts of deriving new beta-cells from both embryonic and adult stem cells. Several groups have reported generating insulin-producing cells from mouse embryonic stem cells. The strategies in the first two acclaimed reports were very different. One strategy, used by Soria's group, is gene trapping in which an introduced antibiotic resistance under the control of the insulin promoter allowed the selection of insulin-expressing cells that had spontaneously differentiated within embryoid bodies. Another strategy, used by McKay's group, manipulated culture conditions in a multistep protocol used for generating neural cells but with changed final conditions. Since these reports, there have been modifications of the protocols in efforts to improve the yields and maturity of the resulting cells. While it is unclear if the insulin-producing cells in any of these studies are truly mature beta-cells, these studies show the clear potential of embryonic stem cells and support optimism that similar results will be possible with human embryonic stem cells. We know that new beta-cells are generated throughout adult life, but the identity of adult pancreatic stem cells has been elusive. The potential for expansion and differentiation of pluripotent adult stem cells, whether from bone marrow or as non-pancreas tissue resident SP cells, is being explored but has not yet yielded insulin-producing tissue. In contrast, insulin-producing cells have been generated in vitro from adult pancreatic tissues. We have been examining the hypothesis that the functional source for new beta-cells in the adult pancreas are mature duct epithelial cells that have regressed or lost their mature phenotype after replication. Others have isolated putative stem cells from islets and ducts. For adult cells the issue of expansion as well as of differentiation is a question. The field of generating new beta-cells from stem cells, either embryonic or adult, is still in its infancy. Each new report has been met with a mixture of excitement and skepticism. With continued efforts and rigorous assessments, hopefully the potential of generating enough new beta-cells from stem cells will be realized.     

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。     

Potential applications of germline cell-derived pluripotent stem cells in organ regeneration

Impressive progress has been made since the turn of the century in the field of stem cells. Different types of stem cells have now been isolated from different types of tissues. Pluripotent stem cells are the most promising cell source for organ regeneration. One such cell type is the germline cell-derived pluripotent cell, which is derived from adult spermatogonial stem cells. The germline cell-derived pluripotent stem cells have been obtained from both human and mouse and, importantly, are adult stem cells with embryonic stem cell-like properties that do not require specific manipulations for pluripotency acquisition, hence bypassing problems related to induced pluripotent stem cells and embryonic stem cells. The germline cell-derived pluripotent stem cells have been induced to differentiate into cells deriving from the three germ layers and shown to be functional in vitro. This review will discuss the plasticity of the germline cell-derived pluripotent stem cells and their potential applications in human organ regeneration, with special emphasis on liver regeneration. Potential problems related to their use are also highlighted.     

干细胞治疗感音神经性耳聋

治疗内耳疾病的主要困难之一是找到耳蜗毛细胞或者螺旋神经元丢失所导致的听力损失的治疗方法。本文讨论使用干细胞替代感觉细胞丢失为目的的几个治疗策略。作者最近在成年内耳中发现了可以分化为毛细胞的干细胞,发现了胚胎干细胞可在体外转化为毛细胞并表达毛细胞标记物。在动物模型中,成年内耳干细胞、神经干细胞和胚胎干细胞来源的前体细胞可分化成为毛细胞和神经细胞。本文将讨论使用干细胞再生损伤毛细胞的不同方法,介绍几种可行的动物模型,并讨论发展基于干细胞的细胞替代疗法治疗内耳损伤中存在的困难。     

Stem cells and genetic disease

Abstract.  Stem cell research is now a very broad field encompassing cells derived from all stages of life from the embryonic stem cells of the early blastocyst through to the adult stem cells of many tissues of the body. Adult stem cells from a variety of tissues are proving to be pluripotent and can differentiate into cell types different from the tissues from which they derive. Pre-clinical animal models indicate that adult stem cells do not cause tumours, not even, teratomas when transplanted. These properties, combined with the possibility of autologous transplantation, indicate significant advantages over embryonic stem cells in many proposed clinical applications.     

潜在的成体肝干/祖细胞

研究者在50年前提出“成体肝组织内存在肝干细胞”这一假说.肝干/祖细胞研究对干细胞基础研究及其临床治疗研究都有着重要的意义.研究者也已从损伤的人类和啮齿动物的肝组织中分离到激活的肝干/祖细胞,并建立了相应的培养体系.目前的研究表明,肝内存在多个具有干细胞特性的细胞,且它们位于肝内不同的区域.另外,潜在的肝干/祖细胞的分子表达谱也已得到一定的阐述.本文结合肝干/祖细胞的研究,对成体肝干/祖细胞的潜在类型、来源与定位作一回顾.     

成体干细胞的生物学特点及应用前景

成体干细胞存在于人和哺乳动物组织中,具有自我更新和一定的分化潜能,现已从骨髓,软骨,血液,神经,肌肉,脂肪,皮肤,角膜缘,肝脏,胰腺等许多组织中获得成体干细胞,发现部分组织成体干细胞具有多向分化潜能,成体干细胞的研究在再生医学中有十分广阔的应用前景。     

成体干细胞多能性研究进展

成体干细胞是存在于机体组织的一类原始状态细胞,它们能够进行自我复制和特异分化,用于维持新陈代谢和创伤修复,年珲来越来越多的实验表明成体干细胞多向分化潜能,一种组织的干细胞可以分化成其他组织类型的细胞。作者介绍了国际上对成体干细胞概念的新看法,讨论了成体干细胞多能性的调控机理及与之相关的研究方法,还简要概括了成体干细胞在理论和临床应用上的重要意义。     

Mechanical characterization of adult stem cells from bone marrow and perivascular niches

Therapies using adult stem cells often require mechanical manipulation such as injection or incorporation into scaffolds. However, force-induced rupture and mechanosensitivity of cells during manipulation is largely ignored. Here, we image cell mechanical structures and perform a biophysical characterization of three different types of human adult stem cells: bone marrow CD34+ hematopoietic, bone marrow mesenchymal and perivascular mesenchymal stem cells. We use micropipette aspiration to characterize cell mechanics and quantify deformation of subcellular structures under force and its contribution to global cell deformation. Our results suggest that CD34+ cells are mechanically suitable for injection systems since cells transition from solid- to fluid-like at constant aspiration pressure, probably due to a poorly developed actin cytoskeleton. Conversely, mesenchymal stem cells from the bone marrow and perivascular niches are more suitable for seeding into biomaterial scaffolds since they are mechanically robust and have developed cytoskeletal structures that may allow cellular stable attachment and motility through solid porous environments. Among these, perivascular stem cells cultured in 6% oxygen show a developed cytoskeleton but a more compliant nucleus, which can facilitate the penetration into pores of tissues or scaffolds. We confirm the relevance of our measurements using cell motility and migration assays and measure survival of injected cells. Since different types of adult stem cells can be used for similar applications, we suggest considering mechanical properties of stem cells to match optimal mechanical characteristics of therapies.     

Adult neural stem cells: plasticity and developmental potential.

Stem cells play an essential role during the processes of embryonic tissue formation and development and in the maintenance of tissue integrity and renewal throughout adulthood. The differentiation potential of stem cells in adult tissues has been thought to be limited to cell lineages present in the organ from which they derive, but there is evidence that somatic stem cells may display a broader differentiation repertoire. This has been documented for bone marrow stem cells (which can give rise to muscle, hepatic and brain cells) and for muscle precursors, which can turn into blood cells. The adult central nervous system (CNS) has long been considered incapable of cell renewal and structural remodeling. Recent findings indicate that, even in postnatal and adult mammals, neurogenesis does occur in different brain regions and that these regions actually contain adult stem cells. These cells can be expanded both in vivo and ex vivo by exposure to different combinations of growth factors and subsequently give rise to a differentiated progeny comprising the major cell types of the CNS. Almost paradoxically, adult neural stem cells display a multipotency much broader than expected, since they can differentiate into non-CNS mesodermal-derivatives, such as blood cells and skeletal muscle cells. We review the recent findings documenting this unforeseen plasticity and unexpected developmental potential of somatic stem cells in general and of neural stem cells in particular. To better introduce these concepts, some basic notions on the functional properties of adult neural stem cells will also be discussed, particularly focusing on the emerging role of the microenvironment in determining and maintaining their peculiar characteristics.     

精原干细胞的生命历程

精原干细胞是动物体内的一种成体干细胞,在睾丸微环境中可以像胚胎干细胞一样具有增殖、分化潜能。近年来借助于各种细胞学技术,人们对精原干细胞在不同睾丸微环境中的分化和发育状况进行了深入研究,睾丸内不同种类细胞间的相互作用以及特定微环境对干细胞转分化的影响,已成为本领域的热点核心内容。将从精原干细胞生命历程的角度讨论该过程中所取得的研究成果和存在的问题。     

Generation of new islets from stem cells

Spain ranks number one in organ donors (35 per million per yr). Although the prevalence of diabetes is low (100,000 type 1 diabetic patients and 2 million type 2 diabetic patients), the expected number of patients receiving islet transplants should be estimated at 200 per year. Islet replacement represents a promising cure for diabetes and has been successfully applied in a limited number of type 1 diabetic patients, resulting in insulin independence for periods longer than 3 yr. However, it has been difficult to obtain sufficient numbers of islets from cadaveric donors. Interesting alternatives include acquiring renewable sources of cells using either embryonic or adult stem cells to overcome the islet scarcity problem. Stem cells are capable of extensive proliferation rates and are capable of differentiating into other cell types of the body. In particular, totipotent stem cells are capable of differentiating into all cell types in the body, whereas pluripotent stem cells are limited to the development of a certain number of differentiated cell types. Insulin-producing cells have been obtained from both embryonic and adult stem cells using several approaches. In animal models of diabetes, the therapeutic application of bioengineered insulin-secreting cells derived from stem cells has delivered promising results. This review will summarize the different approaches that have been used to obtain insulin-producing cells from embryonic and adult stem cells and highlights the key points that will allow in vitro differentiation and subsequent transplantation in the future.     

Skin-derived human adult stem cells surprisingly share many features with human pancreatic stem cells

Multiple tissue niches in the human body are now recognised to harbour stem cells. Here, we have asked how different adult stem cell populations, isolated from two ontogenetically distinct human organs (skin, pancreas), actually are with respect to a panel of standard markers/characteristics. Here we show that an easily accessible adult human tissue such as skin may serve as a convenient source of adult stem cell-like populations that share markers with stem cells derived from an internal, exocrine organ. Surprisingly, both, human pancreas- and skin-derived stem/progenitor cells demonstrate differentiation patterns across lineage boundaries into cell types of ectoderm (e.g. PGP 9.5+ and GFAP+), mesoderm (e.g. alpha-SMA+) and entoderm (e.g. amylase+ and albumin+). This intriguing differentiation capability warrants systemic follow-up, since it raises the theoretical possibility that an adult human skin-derived progenitor cell population could be envisioned for possible application in cell replacement therapies.