Culture of skin-derived precursors and their differentiation into neurons

To investigate the culture method of skin-derived precursors (SKPs) and to explore a new cell sourcefor cell transplantation of central nervous system.     

Pluripotent fates and tissue regenerative potential of adult olfactory bulb neural stem and progenitor cells

Neural stem cells and progenitor cells reside in the adult olfactory bulb (OB) core of mouse, rat, and human. Adult rodent OB core cells have the capacities for self-renewal and multipotency and form neurospheres. The differentiation fates of these neurosphere-forming cells were studied in vitro and in vivo. Adult OB neurospheres were comprised of stem cells and neuronal and glial progenitor cells. OB neurospheres in co-culture with primary embryonic striatal neurons and cortical neurons generated cells with morphological and neurochemical phenotypes of striatal and cortical neurons, respectively. Transplanted OB cells, delivered as dissociated cells or as intact neurospheres, dispersed, survived for long-term, extended neurites, migrated, expressed neuronal or glial markers, and formed synapses with host neurons when placed into the environment of the nonlesioned and lesioned central nervous system (CNS). Grafted cells in the CNS also showed angiogenic capacity by forming blood vessels. In a model of spinal motor neuron degeneration, adult OB neurosphere cells transplanted into lesioned spinal cord adopted phenotypes of motor neurons and had a robust potential to become oligodendrocytes. OB core cells in co-culture with skeletal myoblasts generated skeletal muscle cells. Chimeric skeletal muscle was formed when mouse OB neurospheres were transplanted into rat skeletal muscle. Within skeletal muscle, adult OB neurosphere cells became myogenic progenitor cells to form myotubes de novo. We conclude that the adult mammalian OB is a source of pluripotent neural stem cells and progenitor cells that have the potential to become, in a context-dependent manner, specific types of cells for regeneration of tissues in brain, spinal cord, and muscle.     

Clonogenic colony-forming ability of flow cytometrically isolated hepatic progenitor cells in the murine fetal liver

Stem cells are defined as cells having multilineage differentiation potential and self-renewal capability. Hepatic stem cells have aroused considerable interest not only because of their developmental importance but also for their therapeutic potential. However, their presence in the liver has not yet been demonstrated. With the use of a fluorescence-activated cell sorter (FACS) and monoclonal antibodies, we attempted to ascertain whether hepatic stem cells are present in the murine fetal liver. For this purpose, we optimized a cell isolation technique for FACS sorting of fetal liver cells. When isolated CD45 TER119 cells (the non-blood cell fraction in the fetal liver) were tested for their clonogenic colony-forming ability, mechanical dissociation (pipetting) was the most suitable cell isolation technique for FACS sorting. We confirmed that these colonies contained not only cells expressing hepatocyte markers but also cells expressing cholangiocyte markers. To identify hepatic stem cells, studies must focus on CD45TER119- cells in the murine fetal liver.     

Selective differentiation of central nervous system-derived stem cells in response to cues from specific regions of the developing brain

OBJECT: Each region of the brain is distinguished by specific and distinct markers and functions. The authors hypothesized that each region possesses unique trophic properties that dictate and maintain its development. To test this hypothesis, they isolated central nervous system (CNS) stem cells from fetal rodents, and these rat CNS-derived stem cells (RSCs) were placed in coculture with primary cultures of the developing neonatal hippocampus and hypothalamus to determine whether region-specific primary cells would direct the differentiation of stem cells in a region-specific manner. METHODS: Primary cultures were first established from the neonatal (3-7 days postnatal) hippocampus and hypothalamus. Rodent CNS stem cells, which had been genetically engineered to express green fluorescent protein, were then placed in coculture with the primary CNS cells. The expression of region-specific markers in the RSCs was then evaluated after 2 weeks using immunocytochemistry. Data from previous studies have indicated that primary adult cells lack a differentiation-inducing capacity. RESULTS: When placed in coculture with primary CNS cells, RSCs began to express both neuronal (MAP2) and glial (glial fibrillary acidic protein) markers. Those that were placed in coculture with hippocampal cells expressed region-specific markers such as gamma-aminobutyric acid, whereas those placed in coculture with hypothalamic cells expressed growth hormone-releasing hormone primarily in the hypothalamus. Conclusions. Pluripotential RSCs were induced to express region-specific phenotypes on coculture with primary cells derived from the developing hippocampus and hypothalamus. The differentiation of RSCs into specific lineages on exposure to specific cell types is likely modulated through direct cell-cell contact. Secreted factors from the primary neural cells may also play a role in this induction. Such a differentiation influence is also likely age dependent.     

Conditioned medium of fetal mouse long bone rudiments stimulates the formation of osteoclast precursor-like cells from mouse bone marrow

We studied the influence of skeletal tissue on expression of the osteoclastic phenotype in the mouse, in vivo and in vitro. In various soft and hard tissues of adult and fetal mice the distribution of mono- and multinucleate cells showing tartrate-resistant acid phosphatase was studied, using enzyme histochemistry on undecalcified plastic sections. Cells with strong TRAcP activity were only observed in mineralized tissues. Multinucleate TRAcP cells were exclusively found in close correlation with mineral resorption. In fetal bones mononuclear TRAcP cells appeared in the surrounding soft tissue prior to osteoclast formation. In addition, conditioned media of fetal long bone rudiments (FBCM) increased the number of mononuclear cells showing strong TRAcP activity in 7 d cultures of adult bone marrow. FBCM stimulated DNA synthesis in TRAcP cells and induced their multi-nuclearity. Pretreatment with FBCM increased the capacity of bone marrow cultures to form osteoclasts in coculture with fetal bone rudiments. However, FBCM did not change the number of cells with tartrate-sensitive acid phosphate activity (TSAcP cells). The activity of FBCM was heat labile and was not detectable in CM of killed bones. CM of embryonic mouse fibroblasts which contains M-CSF activity, strongly increased the number of TSAcP cells but reduced the number of TRAcP cells. These data suggest that fetal mouse bone tissue induces the differentiation of osteoclast precursors. In addition, fetal bone rudiments but not embryonic fibroblasts seem to produce a factor(s) which stimulate(s) the formation of cells showing characteristics of osteoclast precursor cells. Osteoclasts and macrophages seem to have different growth requirements, indicating that they represent separate cell lines which may nevertheless derive from a common progenitor.     

Neurite growth capability of rat fetal neuronal cells against matured CNS myelin in vitro

Reconstruction of neurocircuits by transplanted cells is expected to become an effective therapy for brain damage. In order to establish the transplantation therapy, it is necessary to find transplantable cells capable of reconstructing the lesioned neurocircuitry. We have reported that the younger neuronal cells such as neural stem cells are useful transplant materials because of their vigorous capacity for forming abundant neurites. On the other hand, it was reported that myelin-associated neurite growth inhibitor prevents neurite regeneration. In this study, we used rat fetal neuronal cells to examine the neurite growth capacity in the presence of mature CNS myelin. Crude CNS myelin was prepared from the brains of adult Wistar rats using previously described procedures. Testing wells were precoated with poly-L-lysine and additionally by over-night drying of a suspension containing 0, 5, 10, 15, or 20 microg/cm2 of the crude myelin protein. On embryonic days 10, 12, 15, and 17 (E10, E12, E15, and E17) embryos were surgically removed, mesencephalic neural plates were dissected out from the E10 embryos, and midbrain cells were taken from the E12, E15, and E17 embryos. The neural plates and midbrain cells were placed on the myelin-coated wells. After 24 h of culture (72 h in the case of neural plates), the number of surviving cells and the length of the neurites were examined immunocytochemically using anti-neurofilament (NF) antibody. Neurite length was measured by image analyzer Luzex-F. The mesencephalic neural plate was able to grow neurites even on 20 microg/cm2 central myelin. Almost the same number of midbrain cells attached themselves to the wells without myelin in every culture obtained from various stages of embryos. The number of cells attached on the myelin-coated wells decreased with the concentration of myelin. The number of NF-positive cells was higher in cultures of materials obtained from older embryos than in cultures obtained from younger embryos. The younger cells grew longer neurites than the older cells in the myelin noncoated wells. Neurite growth was inhibited strongly when the concentration of the central myelin was 10 microg/cm2 or greater, but on the 5 microg/cm2 myelin, the younger the cells were, the longer neurites they had. When the length of the longest neurites in one field of the image analyzer was further examined in the same way, the younger the cells were, the longer their axons grew on 0 and 5 microg/cm2 myelin. Thus, CNS myelin was seen to be a significant inhibitor of the recovery of injured neural tissue of the adult CNS. Younger cells grew longer neurites than older cells on CNS myelin, and so it was suggested that neural stem cells or younger neurons may serve as tissue for transplantation therapy.     

Making stem cell lines suitable for transplantation

Human stem cells, progenitor cells, and cell lines have been derived from embryonic, fetal, and adult sources in the search for graft tissue suitable for the treatment of CNS disorders. An increasing number of experimental studies have shown that grafts from several sources survive, differentiate into distinct cell types, and exert positive functional effects in experimental animal models, but little attention has been given to developing cells under conditions of good manufacturing practice (GMP) that can be scaled up for mass treatment. The capacity for continued division of stem cells in culture offers the opportunity to expand their production to meet the widespread clinical demands posed by neurodegenerative diseases. However, maintaining stem cell division in culture long term, while ensuring differentiation after transplantation, requires genetic and/ or oncogenetic manipulations, which may affect the genetic stability and in vivo survival of cells. This review outlines the stages, selection criteria, problems, and ultimately the successes arising in the development of conditionally immortal clinical grade stem cell lines, which divide in vitro, differentiate in vivo, and exert positive functional effects. These processes are specifically exemplified by the murine MHP36 cell line, conditionally immortalized by a temperature-sensitive mutant of the SV40 large T antigen, and cell lines transfected with the c-myc protein fused with a mutated estrogen receptor (c-mycERTAM), regulated by a tamoxifen metabolite, but the issues raised are common to all routes for the development of effective clinical grade cells.     

A model utilizing adult murine stem cells for creation of personalized islets for transplantation

Clinical islet cell transplantation has demonstrated great promise for diabetes treatment. Two major obstacles are the organ donor shortage and the immunoresponse. The purpose of this study was to create a model using the patient's own adult stem cell sources, possibly in combination with non-self cells, such as pancreatic, hepatic, or embryonic stem cells, to create "personalized" islets. We hypothesize that the reconstructed islets have the normal capability to produce insulin and glucagon with reduced immunoresponses after transplantation. Stem cells are a proliferating population of master cells that have the ability for self-renewal and multilineage differentiation. The recently developed photolithograph-based, biologic, microelectromechanic system (BioMEMS) technique supplies a useful tool for biomedical applications. Our lab has developed a novel method that integrates the adult stem cell and BioMEMS to reconstruct personalized islets. We selected islet-derived progenitor cells (IPC) for repairing and reconstructing STZ-diabetic islets. A6(+)/PYY(+) or A6(+)/ngn3(+) cells were selected to manipulate the neoislets. After 3 to 4 weeks in culture, the reconstructed cells formed islet-like clusters containing insulin or glucagon producing cells. The pilot results showed the ability of these reconstructed islets to correct hyperglycemia when transplanted into a STZ-diabetic isograft mouse model. Although several technical problems remain with the mouse model, namely, the difficulty to collect enough islets from a single mouse because of animal size, the mouse isograft model is suitable for personalized islet development.     

精原干细胞微环境的生物学特性

成体干细胞的自我更新和分化与其微环境关系密切。精原干细胞(spermatogonial stem cells,SSCs)是体内自然状态下唯一能将遗传信息传至子代的成体干细胞。探讨SSCs更新和分化的调控机制有助于精子发生机理的阐明,并为探究其他成体干细胞增殖分化的调节机制提供依据。因此,SSCs系统为成体干细胞微环境研究提供了理想模型。资料表明,SSCs的更新和分化受其微环境的调控。基于本室的工作,参考最新文献,本文主要从SSCs微环境的基本特性、构成及其产生的各种调控因子等角度,评述了SSCs微环境的生物学特性及其与SSCs更新和分化间的关系,以期为本领域研究及其他成体干细胞相关研究提供借鉴。     

Adenovirus-Mediated CTLA4Ig Gene Transfer Improves the Survival of Grafted Human Hepatic Progenitors in Mouse Liver

The invasive nature of surgery and limited numbers of donor livers for end-stage patients has prompted the search for alternative cell therapies for intractable hepatic disease. Hepatocyte ransplantations have been performed for a variety of indications, but sustained benefits have not been observed in most cases. Rat fetal liver epithelial cells (liver stem cells) have demonstrated self-renewal in vivo and functional repopulation of the liver. We have previously isolated and expanded epithelial progenitor cells (EPC) from the human fetal liver to investigate their differentiation potential. In this study, we applied suppression of immunorejection by adenoviral CTLA4Ig gene delivery mediated to examine the survival and differentiation of human fetal EPC transplanted into normal mouse liver. The grafted EPC showed extensive proliferation at both 1 and 2 months after transplantation compared with controls. Moreover, most EPC differentiated into hepatocytes, while a small fraction became bile ductular cells. This finding suggested that human fetal EPC may be a ideal source of cell-based therapy for various liver diseases.     

Muscle-derived stem cells for musculoskeletal tissue regeneration and repair

Muscle recently has been identified as a good source of adult stem cells that can differentiate into cells of different lineages. The most well-known muscle progenitor cells are satellite cells, which not only contribute to the replenishment of the myogenic cell pool but also can become osteoblasts, adipocytes and chondrocytes. Other populations of stem cells that appear to be distinct from satellite cells also have been discovered recently. Muscle-derived stem cells (MDSCs) can be divided into two major categories based on these cells' varied abilities to differentiate into myogenic lineages. Interestingly, MDSCs that can differentiate readily into myogenic cells are usually CD45-. In contrast, MDSCs with less myogenic potential are CD45+. Various lines of evidence suggest that different populations of MDSCs are closely related. Furthermore, MDSCs appear to be closely related to endothelial cells or pericytes of the capillaries surrounding myofibers. When used in tissue engineering applications, MDSCs--particularly those genetically engineered to express growth factors--have been demonstrated to possess great potential for the regeneration and repair of muscle, bone and cartilage. Further research is necessary to delineate the relationship between different populations of MDSCs and between MDSCs and other adult stem cells, to investigate their developmental origin, and to determine the regulatory pathways and factors that control stem cell self-renewal, proliferation and differentiation. This knowledge could greatly enhance the usefulness of muscle-derived stem cells, as well as other adult stem cells, for tissue repair and regeneration applications.     

Differential hematopoietic supportive potential and gene expression of stroma cell lines from midgestation mouse placenta and adult bone marrow

During mouse embryogenesis, hematopoietic development takes place in several distinct anatomic locations. The microenvironment of different hematopoietic organs plays an important role in the proliferation and maturation of the hematopoietic cells. We hypothesized that fetal stromal cells would be distinct to adult bone marrow (BM)-derived stromal cells because the BM contributes mainly to the homeostasis of hematopoietic stem cells (HSCs), while extensive expansion of HSCs occurs during fetal development. Here we report the establishment of stromal cell lines from fetal hematopoietic organs, namely aorta-gonad-mesonephros (AGM), midgestation placenta (PL), and fetal liver (FL) together with adult bone marrow (BM). The growth patterns and hematopoietic supportive potential were studied. Their phenotypic and molecular gene expression profiles were also determined. Stromal cell lines from each tissue were able to support cobblestone area formation of BM c-Kit(+)Sca-1(+) hematopoietic cells: 22 (22/47) from AGM, three (3/4) from PL, three (3/4) from FL, and three (3/3) from BM. There were similar levels of expansion of total mononuclear cells (TMNs) when HSCs were cocultured with fetal stroma and adult BM stroma. However, PL-derived stromal cells supported higher levels of generation of colony-forming progenitor cell (CFU-C), indicated by more colonies and colonies with significantly larger size. Flow cytometric analysis of the PL1 cells demonstrated a phenotype of CD45(-), CD105(+), Sca-1(+), CD34(+), and CD49d(+), compared to adult BM1 cells, which were CD45(-), CD105(+), Sca-1(+), CD34(-), and CD49d(-). Using Affymetrix microarray analysis, we identified that genes specifically express in endothelial cells, such as Tie1, Tek, Kdr, Flt4, Emcn, Pecam1, Icam2, Cdh5, Esam1, Prom1, Cd34, and Sele were highly expressed in stroma PL1, consistent with an endothelial phenotype, while BM1 expressed a mesenchymal stromal phenotype. In summary, these data demonstrate distinct characteristics of stromal cells that provide insights into the microenvironmental control of HSCs.     

The characterization of epithelial and stromal subsets of candidate stem/progenitor cells in the human adult prostate

OBJECTIVES: Questions regarding the cell source and mechanisms in the initiation and progression of prostate cancer are today still open for debate. Indeed, our knowledge regarding prostate cell regulation, self-renewal, and cytodifferentiation is presently rather limited. In this study, we investigated these processes in the normal adult human prostate. METHODS: Dynamic expression patterns in prostate stem/progenitor cells, intermediate/transit-amplifying cells, and cell lineages were immunohistochemically identified in an in situ explant renewal model of the human normal/benign adult prostate (n=6). RESULTS: Cells with a basal phenotype proliferated significantly in explant cultures, whereas luminal cells went into apoptosis. Results further show down-regulation in tissue cultures of the basal and hypothetical stem cell marker Bcl-2 in the majority of cells, except in rare putative epithelial stem cells. Investigation of established (AC133) and novel candidate prostate stem/progenitor markers, including the cell surface receptor tyrosine kinase KIT and its ligand stem cell factor (SCF), showed that these rare epithelial cells are AC133(+)/CD133(low)/Bcl-2(high)/cytokeratin(+)/vimentin(-)/KIT(low)/SCF(low). In addition, we report on a stromal population that expresses the mesenchymal marker vimentin and that is AC133(-)/CD133(high)/Bcl-2(-)/cytokeratin(-)/KIT(high)/SCF(high). CONCLUSIONS: We provide evidence for epithelial renewal in response to tissue culture and for basal and epithelial stem/progenitor cell recruitment leading to an expansion of an intermediate luminal precursor phenotype. Data further suggest that SCF regulates prostate epithelial stem/progenitor cells in an autocrine manner and that all or a subset of the identified novel stromal phenotype represents prostate stromal progenitor cells or interstitial pacemaker cells or both.     

The role of stem cells in neural injury — emerging paradigms

Stem cells capable of proliferating along neuronal and glial lines persist in the adult central nervous system (CNS). These cells are found pedominantly in the subventricular zones and in the hippocampus. The therapeutic potential of both endogenous and exogenous stem cells in achieving repair of the injured CNS is being explored. Stem cells from embyonal lines, mescnchymal stromal cells and neural stem cells are being investigated for their potential role in the management of neural loss due to traumatic hypoxic or inflammatory insult.     

Interleukin-3-dependent hematopoietic stem cell lines capable of osteoclast formation in vitro.

Recently we reported that the osteoclast originates from the pluripotent hematopoietic stem cell. However, a detailed analysis of the progenitor and precursor stages of the osteoclast lineage is hard to perform with primary cultures of stem cells. In the present investigation interleukin-3 (IL-3)-dependent multipotent hematopoietic stem cell lines (FDCP-mix), which have many characteristics in common with freshly isolated hematopoietic stem cell lines (FDCP-mix), which have many characteristics in common with freshly isolated hematopoietic stem cells, were assayed for their osteoclast formation capacity. FDCP-mix cell lines A4, C2GM, and 15S were cocultured with periosteum-free 17-day-old fetal metatarsal bones. The effects of culture time, medium composition, and addition of WEHI-3b-conditioned medium (an unpurified IL-3 preparation) on osteoclast formation were studied. 15S cells never differentiated into osteoclasts. Both A4 and C2GM cells were able to generate osteoclasts. Osteoclast formation was visualized by staining for tartrate-resistant acid phosphatase activity and confirmed by 45Ca release assays and electron microscopic studies. Medium supplemented with fetal calf serum clearly supported osteoclast formation from A4 cells better than medium supplemented with cock serum. The difference between fetal calf serum and horse serum is generally less pronounced. C2GM cells formed osteoclasts more readily and, generally, earlier than A4 under all culture conditions. WEHI-3b-conditioned medium addition increased the numbers of osteoclasts and their resorption activity. The coculture of stripped metatarsal bones with FDCP-mix cell lines therefore offers a model system with many possibilities for the study of osteoclastogenesis and its regulation.     

Alternative sources of neurons and glia from somatic stem cells

Stem cell populations have been shown to be extremely versatile: they can generate differentiated cells specific to the tissue in which they reside and descendents that are of different germ layer origin. This raises the possibility of obtaining neuronal cells from new biological source of the same adult human subjects. In this study, we found that epidermal growth factor (EGF) and basic fibroblast growth factor (bFGF) cooperated to induce the proliferation, self-renewal, and expansion of neural stem cell-like population isolated from several newborn and adult mouse tissues: muscle and hematopoietic tissues. This population, in both primary culture and secondary expanded clones, formed spheres of undifferentiated cells that were induced to differentiate into neurons, astrocytes, and oligodendrocytes. Brain engraftment of the somatic-derived neural stem cells generated neuronal phenotypes, demonstrating the great plasticity of these cells with potential clinical application.