新生小鼠神经干细胞的分离、培养和鉴定

目的：探讨新生小鼠神经干细胞(NSCs)分离、培养以及鉴定的方法。方法：分离新生昆明种小鼠(出生24h内)的大脑组织,经胰酶消化加机械吹打后,利用无血清培养基悬浮培养细胞,获得具有自我增殖能力的细胞克隆,并将细胞克隆贴壁培养测其分化能力。应用抗Ncstin、Musashi、SSEA-1、NSE免疫细胞化学方法及BrdU标记方法鉴定细胞克隆。结果：从新生昆明种小鼠大脑组织分离的细胞悬液,经悬浮培养,生成大量具有增殖能力的细胞,可形成神经球(neurosphercs),抗Nestin、Musashi、SSEA-1阳性,BrdU标记也呈阳性。细胞克隆贴壁培养后神经球分化为神经细胞,抗NSE阳性。结论：上述方法分离的细胞具有自我更新、自我复制及分化为神经细胞的能力,属于中枢神经系统干细胞。     

神经干细胞及其临床应用潜能

近年来神经干细胞已在成年哺乳动物中的中枢神经系统中分离成功。神经干细胞的最基本特征是具有分化为神经元、星状胶质细胞和少突胶质细胞的潜能，具有自我更新能力，并足以维持整个大脑所需。神经干细胞在修复受伤神经组织及治疗神经系统退行性疾病，如帕金森病、阿尔茨海默病、和亨庭顿病等方面有很好的应用前景。但在达到临床实际应用之前仍有一系列问题需要解决，最首要的是搞清神经干细胞的分化机制。     

Cell lineages generating axial muscle in the zebrafish embryo

Cell lineage may contribute to determining the numbers, positions and types of cells formed during embryogenesis. In vitro clonal analyses show that vertebrate cells can autonomously maintain lineage commitments to single fates and that terminal development may include an invariant sequence of cell divisions. In addition, in vivo studies with Xenopus led to the proposal that clonal restrictions to spatial 'compartmental' domains arise during early development, analogous to what is observed in insects. In the zebrafish, individual gastrula cells generate clones of progeny that are confined within single tissues, but spatial restrictions have not been described. We now have examined the in vivo terminal cell lineages of zebrafish axial muscles. We obtained no evidence either for strict developmental regulation of division pattern or for spatial compartmentation within muscle lineages.     

Anti-idiotypic cytotoxic T cells in rats with graft-versus-host disease

Transfer of parental strain T lymphocytes into F1 hybrid rats differing with respect to gene products of the major histocompatibility complex (MHC) causes a graft-versus-host (GvH) reaction. This reaction results from recognition of host allogeneic MHC gene products by specific clones of donor T cells. When given systemically in sufficient numbers, these donor T cells cause a progressive, generally fatal wasting syndrome, an early feature of which includes extensive splenomegaly. A more local, non-fatal GvH reaction, marked by extensive enlargement of the draining lymph nodes, ensues when donor T cells are administered via the footpad. Here, we demonstrate that cells derived from the enlarged draining lymph nodes of A/B F1 animals undergoing local GvH disease caused by donor A T cells contain a subpopulation of host-derived killer T-cell precursors which can be activated to lyse specific blast cells, derived from mixed lymphocyte culture (MLC), reactive to host MHCb alloantigens. These 'anti-idiotypic' cytolytic T cells lyse A anti-MHCb MLC blasts, and also, they lyse anti-MHCb MLC blasts from MHC different, third party rat strains.     

Selective dendritic transport of RNA in hippocampal neurons in culture

Typical neurons of the central nervous system (CNS) elaborate tens of thousands of membrane specializations at sites of synaptic contacts on their dendrites. To construct, maintain, and modify these specializations, neurons must produce and deliver the appropriate molecular constituents to particular synaptic sites. Previous studies have revealed that polyribosomes are selectively positioned beneath postsynaptic sites, suggesting that in neurons, as in other cell types, protein synthetic machinery is located at or near the sites where particular proteins are needed. The mechanisms that deliver ribosomes and messenger RNA to their specific destinations in cells are therefore of considerable interest. Here we describe a system for RNA transport in dendrites that could provide a mechanism for the delivery of ribosomes and mRNA to synaptic sites in dendrites. Hippocampal neurons grown in culture incorporate 3H-uridine in the nucleus, then selectively transport the newly synthesized RNA into dendrites at a rate of about 0.5 mm day-1. The transport is inhibited by metabolic poisons, suggesting that it is an active, energy-dependent process. The RNA may be transported in association with the cytoskeleton.     

Identified neurones isolated from leech CNS make selective connections in culture.

Neurones cultured in vitro offer distinct advantages for studying how processes grow towards their targets and form synaptic connections. In contrast to the complex events occurring during the development of the nervous system, synapse formation in culture can be analysed in a few neurones at a time and under controlled conditions. We have now dissected out and cultured single identified neurones from the central nervous system (CNS) of the adult leech. Various types of sensory cells, motor cells, and interneurones can be identified in leech ganglia--each with a stereotyped set of properties, including: (1) the electrical characteristics of its membrane, (2) the arborisation of its branches and the morphology of its terminals and (3) the pattern of connections it makes with other identified neurones, skin or muscle. Thus, cultured cells can be compared in detail with their counterparts in situ. We have found that isolated cells survive for several weeks, maintain their membrane properties, sprout and form selective connections.     

A neuronal clone derived from a Rous sarcoma virus-transformed quail embryo neuroretina established culture

Neuroretina (NR) is an evagination of the central nervous system (CNS) which is composed of photoreceptors, glial (Müller) cells and horizontal, bipolar, amacrine and ganglion neuronal cells. We describe here the usefulness of Rous sarcoma virus (RSV) in the establishment of a neuronal clone from quail embryo neuroretina. When primary cultures of chick and quail embryo neuroretina cells are transformed by RSV, neuronal markers such as ribbon synapses, choline acetyltransferase (CAT) and glutamic acid decarboxylase (GAD) specific activity are present. These RSV-transformed primary cultures can be established into permanent cell lines from which neuronal clones have been isolated. One of them, clone QNR/D, can generate tetrodotoxin(TTX)-inhibitable action potentials on electrical stimulation, has a high GAD activity and binds monoclonal antibodies raised against chick embryo neuroretina. The presence of these neuronal markers suggests that the QNR/D clone is derived from cells of the amacrine or ganglionic lineage. This is the first time that a neuronal cell clone of defined origin has been obtained from the CNS. The neuronal markers of the QNR/D clone are expressed at both the permissive and the non-permissive temperatures for transformation.     

Ependymal cells of chordate larvae are stem-like cells that form the adult nervous system

In ascidian tunicates, the metamorphic transition from larva to adult is accompanied by dynamic changes in the body plan. For instance, the central nervous system (CNS) is subjected to extensive rearrangement because its regulating larval organs are lost and new adult organs are created. To understand how the adult CNS is reconstructed, we traced the fate of larval CNS cells during ascidian metamorphosis by using transgenic animals and imaging technologies with photoconvertible fluorescent proteins. Here we show that most parts of the ascidian larval CNS, except for the tail nerve cord, are maintained during metamorphosis and recruited to form the adult CNS. We also show that most of the larval neurons disappear and only a subset of cholinergic motor neurons and glutamatergic neurons are retained. Finally, we demonstrate that ependymal cells of the larval CNS contribute to the construction of the adult CNS and that some differentiate into neurons in the adult CNS. An unexpected role of ependymal cells highlighted by this study is that they serve as neural stem-like cells to reconstruct the adult nervous network during chordate metamorphosis. Consequently, the plasticity of non-neuronal ependymal cells and neuronal cells in chordates should be re-examined by future studies.     

Interferon inhibits transformation by murine sarcoma viruses before integration of provirus

Neoplastic transformation by C-type retroviruses requires synthesis of a DNA copy (the provirus) of the RNA genome and its integration into the host cell DNA. We have previously shown that interferon (IFN) can stably prevent transformation of murine fibroblasts by the Kirsten strain of murine sarcoma virus (KiMSV), a murine leukaemia virus (MLV). A series of cell clones (IFN clones), isolated in the presence of IFN (10(4) U ml-1) from cultures of NIH-3T3 cells which had been treated with IFN, and then infected with KiMSV (KiMLV) in conditions where every cell was infected, were shown to be phenotypically untransformed. These untransformed cells did not produce virus or contain rescuable KiMSV. However, cells isolated using an identical procedure, but in the absence of IFN, were uniformly transformed and all produced KiMSV (KiMLV) or contained rescuable KiMSV. It was concluded that IFN either prevents synthesis or integration of the provirus, or else that in the presence of IFN the provirus is integrated such that it is not expressed. We now show that five representative clones contain no detectable KiMSV proviral DNA, and also that the initial stages of infection by KiMSV (KiMLV) are inhibited by IFN treatment. IFN seems to act before integration, preventing either the synthesis or the integration of proviral DNA.     

Differentiation of a bipotential glial progenitor cell in a single cell microculture

Although it is known that most cells of the vertebrate central nervous system (CNS) are derived from the neuroepithelial cells of the neural tube, the factors determining whether an individual neuroepithelial cell develops into a particular type of neurone or glial cell remain unknown. A promising model for studying this problem is the bipotential glial progenitor cell in the developing rat optic nerve; this cell differentiates into a particular type of astrocyte (a type-2 astrocyte) if cultured in 10% fetal calf serum (FCS) and into an oligodendrocyte if cultured in serum-free medium. As the oligodendrocyte-type-2 astrocyte (0-2A) progenitor cell can differentiate along either glial pathway in neurone-free cultures, living axons clearly are not required for its differentiation, at least in vitro. However, the studies on 0-2A progenitor cells were carried out in bulk cultures of optic nerve, and so it was possible that other cell-cell interactions were required for differentiation in culture. We show here that 0-2A progenitor cells can differentiate into type-2 astrocytes or oligodendrocytes when grown as isolated cells in microculture, indicating that differentiation along either glial pathway in vitro does not require signals from other CNS cells, apart from the signals provided by components of the culture medium. We also show that single 0-2A progenitor cells can differentiate along either pathway without dividing, supporting our previous studies using 3H-thymidine and suggesting that DNA replication is not required for these cells to choose between the two differentiation programmes.     

Purification of a pluripotent neural stem cell from the adult mouse brain

The adult mammalian central nervous system (CNS) contains a population of neural stem cells (NSCs) with properties said to include the generation of non-neural progeny. However, the precise identity, location and potential of the NSC in situ remain unclear. We purified NSCs from the adult mouse brain by flow cytometry, and directly examined the cells' properties. Here we show that one type of NSC, which expresses the protein nestin but only low levels of PNA-binding and HSA proteins, is found in both ependymal and subventricular zones and accounts for about 63% of the total NSC activity. Furthermore, the selective depletion of the population of this stem cell in querkopf mutant mice (which are deficient in production of olfactory neurons) suggests that it acts as a major functional stem cell in vivo. Most freshly isolated NSCs, when co-cultured with a muscle cell line, rapidly differentiated in vitro into myocytes that contain myosin heavy chain (MyHC). This demonstrates that a predominant, functional type of stem cell exists in the periventricular region of the adult brain with the intrinsic ability to generate neural and non-neural cells.     

Interleukin-3 supports growth of mouse pre-B-cell clones in vitro

Study of the differentiation of immunoglobulin-producing B lymphocytes has been hampered by the inability to maintain homogeneous populations of precursor cells in vitro. We describe here that interleukin-3 supports the growth of freshly isolated fetal liver pre-B cells and the long-term culture of interleukin-3 dependent pre-B-cell clones that can be induced to mature into antibody secreting cells in vitro.     

Thymic cortical epithelial cells lack full capacity for antigen presentation

Several recent studies have suggested that interactions between thymocytes and thymic stromal cells are essential for the development and elimination of antigen-reactive T lymphocytes. It is important, therefore, to characterize the stromal cells involved in presentation of antigen in the thymus. In a previous report, we demonstrated, using T-cell hybridomas, that three distinct types of antigen presenting cells in the thymus (cortical epithelial cells, macrophages, and dendritic cells) constitutively expressed self haemoglobin/Ia complexes. Here we report that one of these cell types, the cortical epithelial cell, does not induce stimulation of T-lymphocyte clones even though the antigen/Ia complex required for antigen-specific recognition is present. This lack of response occurs with both TH1 and TH2 clones. Responsiveness of the TH2 clone can be restored by adding the murine lymphokine interleukin-1 beta to the culture system.     

Structure, expression and function of a schwannoma-derived growth factor

During the development of the nervous system, cells require growth factors that regulate their division and survival. To identify new growth factors, serum-free growth-conditioned media from many clonal cell lines were screened for the presence of mitogens for central nervous system glial cells. A cell line secreting a potent glial mitogen was established from a tumour (or 'schwannoma') derived from the sheath of the sciatic nerve. The cells of the tumour, named JS1 cells, were adapted to clonal culture and identified as Schwann cells. Schwann cells secrete an autocrine mitogen and human schwannoma extracts have mitogenic activity on glial cells. Until now, neither mitogen has been purified. Here we report the purification and characterization of a mitogenic molecule, designated schwannoma-derived growth factor (SDGF), from the growth-conditioned medium of the JS1 Schwann cell line. SDGF belongs to the epidermal growth factor family, and is an autocrine growth factor as well as a mitogen for astrocytes, Schwann cells and fibroblasts.     

Bipotential precursors of B cells and macrophages in murine fetal liver.

LYMPHOCYTES (B and T cells) derive continuously from the same multipotential stem cells that produce myeloid cells, including erythrocytes, granulocytes and macrophages. Tri- and bipotential myeloid intermediates between the multipotential stem cells and later unipotential cells have been identified using clonal methods in culture. Although similar methods have detected committed pre-B cells in mouse fetal liver, earlier progenitors with additional non-B lineage options have not been demonstrated in normal tissues. We report the characterization and purification of fetal liver cells that generate clones containing both macrophages and B cells, identified biochemically and morphologically. The common origin of the two cell types was shown by culture of single precursor cells. Their dual potential and unrearranged immunoglobulin loci place the precursors before exclusive B-lineage commitment in the haematopoietic hierarchy. The availability of such cells in purified form will allow direct study of lineage choice in cells having both lymphoid and non-lymphoid options.     

Neurons derived from radial glial cells establish radial units in neocortex

The neocortex of the adult brain consists of neurons and glia that are generated by precursor cells of the embryonic ventricular zone. In general, glia are generated after neurons during development, but radial glia are an exception to this rule. Radial glia are generated before neurogenesis and guide neuronal migration. Radial glia are mitotically active throughout neurogenesis, and disappear or become astrocytes when neuronal migration is complete. Although the lineage relationships of cortical neurons and glia have been explored, the clonal relationship of radial glia to other cortical cells remains unknown. It has been suggested that radial glia may be neuronal precursors, but this has not been demonstrated in vivo. We have used a retroviral vector encoding enhanced green fluorescent protein to label precursor cells in vivo and have examined clones 1-3 days later using morphological, immunohistochemical and electrophysiological techniques. Here we show that clones consist of mitotic radial glia and postmitotic neurons, and that neurons migrate along clonally related radial glia. Time-lapse images show that proliferative radial glia generate neurons. Our results support the concept that a lineage relationship between neurons and proliferative radial glia may underlie the radial organization of neocortex.     

Regeneration by supernumerary axons with synaptic terminals in spinal motoneurons of cats

Axons in the central nervous system (CNS) of mammals do not normally regrow if they are cut, which severely limits restoration of function after injury. We have studied the reactions of adult cat spinal alpha-motoneurons after chronic transection of their axons in the periphery by labelling single cells with horseradish peroxidase. Twelve weeks after the operation, about a third of the axotomized cells had developed a 'supernumerary' axon originating from the cell-body region. These supernumerary axons had variable trajectories and termination fields in the ipsilateral spinal cord but generally anomalous projections. Ultrastructural examination shows that they give rise to boutons that form morphologically normal synaptic contacts with neuronal profiles, although they contain dense-cored vesicles not normally seen in central terminals of alpha-motor axons. We conclude that axotomized neurons in the mammalian CNS may be able to form new synaptic contacts by means of supernumerary axons in the absence of local damage.     

小鼠精原干细胞的体外培养与鉴定

建立一种简单、有效体外分离和培养精原干细胞（Spermatogonia stem cell,SSCs）的方法。采用酶消化6—8d新生小鼠睾丸制备睾丸细胞悬液后进行培养,碱性磷酸酶（AKP）染色和间接免疫荧光对培养的细胞进行鉴定;结果显示：SSCs培养3～5天可观察到细胞克隆的产生,AKP染色强阳性;间接免疫荧光显示GCNF阴性,oct-4、c—kit均呈阳性反应。由此可知以DMEM＋15％胎牛血清＋白血病抑制因子（leukemia inhibitory factor,LIF）＋L-谷氨酰胺等为培养基,成功建立了精原干细胞的体外培养体系。     

Cell lineage analysis reveals multipotency of some avian neural crest cells

A major question in developmental biology is how precursor cells give rise to diverse sets of differentiated cell types. In most systems, it remains unclear whether the precursors can form many or all cell types (multipotent or totipotent), or only a single cell type (predetermined). The question of cell lineage is central to the neural crest because it gives rise to numerous and diverse derivatives including peripheral neurons, glial and Schwann cells, pigment cells, and cartilage. Although the sets of derivatives arising from different populations of neural crest cells have been well-documented, relatively little is known about the developmental potentials of individual neural crest cells. We have iontophoretically microinjected the vital dye, lysinated rhodamine dextran (LRD) into individual dorsal neural tube cells to mark unambiguously their descendants. Many of the resulting labelled clones consisted of multiple cell types, as judged by both their location and morphology. Cells as diverse as sensory neurons, presumptive pigment cells, ganglionic supportive cells, adrenomedullary cells and neural tube cells were found within individual clones. Our results indicate that at least some neural crest cells are multipotent before their departure from the neural tube.