Cell surface changes in transformed human lymphocytes : I. ConA and E-PHA induced unique changes in surface topography

Binding studies with six purified plant lectins were used to investigate membrane alterations that occur in lymphocyte transformation. Normal human peripheral blood lymphocytes transformed with E-Phytohemagglutinin (E-PHA) or concanavalin-A (Con-A) generally possessed increased numbers of lectin receptors. When this increase was corrected for the expanded surface area of transformed lymphocytes, it appeared that E-PHA and ConA each produced a unique and complex reorganization of cell surface topography. Surface alterations occurred independently of DNA synthesis, cell proliferation, and microtubule or microfilament function. Puromycin inhibited emergence of new lectin receptors on cells transformed with E-PHA, but not with ConA. Lymphocytes incubated with either lectin showed increased incorporation of [¹⁴C]galactose into trypsin-sensitive cell surface glycoproteins. This incorporation was abolished by puromycin in cells stimulated by E-PHA but not by ConA. These studies demonstrate that although both lectins induce similar morphological alterations in human lymphocytes, at the molecular level the structural changes induced in the cell membrane by these two lectins differ considerably. Furthermore, these structural alterations are mediated via different mechanisms in the two groups of cells. De novo protein synthesis is required for cell surface reorganization in PHA-stimulated cells, but not in cells stimulated by ConA. The effect of ConA appears to be to enhance attachment of saccharide structures to pre-synthesized membrane proteins.     

Differing lectin binding profiles among human embryonic stem cells and derivatives aid in the isolation of neural progenitor cells

Human embryonic stem cells (hESCs) and their differentiated progeny allow for investigation of important changes/events during normal embryonic development. Currently most of the research is focused on proteinacous changes occurring as a result of differentiation of stem cells and little is known about changes in cell surface glycosylation patterns. Identification of cell lineage specific glycans can help in understanding their role in maintenance, proliferation and differentiation. Furthermore, these glycans can serve as markers for isolation of homogenous populations of cells. Using a panel of eight biotinylated lectins, the glycan expression of hESCs, hESCs-derived human neural progenitors (hNP) cells, and hESCs-derived mesenchymal progenitor (hMP) cells was investigated. Our goal was to identify glycans that are unique for hNP cells and use the corresponding lectins for cell isolation. Flow cytometry and immunocytochemistry were used to determine expression and localization of glycans, respectively, in each cell type. These results show that the glycan expression changes upon differentiation of hESCs and is different for neural and mesenchymal lineage. For example, binding of PHA-L lectin is low in hESCs (14±4.4%) but significantly higher in differentiated hNP cells (99±0.4%) and hMP cells (90±3%). Three lectins: VVA, DBA and LTL have low binding in hESCs and hMP cells, but significantly higher binding in hNP cells. Finally, VVA lectin binding was used to isolate hNP cells from a mixed population of hESCs, hNP cells and hMP cells. This is the first report that compares glycan expression across these human stem cell lineages and identifies significant differences. Also, this is the first study that uses VVA lectin for isolation for human neural progenitor cells.     

Copine1 regulates neural stem cell functions during brain development

Copine 1 (CPNE1) is a well-known phospholipid binding protein in plasma membrane of various cell types. In brain cells, CPNE1 is closely associated with AKT signaling pathway, which is important for neural stem cell (NSC) functions during brain development. Here, we investigated the role of CPNE1 in the regulation of brain NSC functions during brain development and determined its underlying mechanism. In this study, abundant expression of CPNE1 was observed in neural lineage cells including NSCs and immature neurons in human. With mouse brain tissues in various developmental stages, we found that CPNE1 expression was higher at early embryonic stages compared to postnatal and adult stages. To model developing brain in vitro, we used primary NSCs derived from mouse embryonic hippocampus. Our in vitro study shows decreased proliferation and multi-lineage differentiation potential in CPNE1 deficient NSCs. Finally, we found that the deficiency of CPNE1 downregulated mTOR signaling in embryonic NSCs. These data demonstrate that CPNE1 plays a key role in the regulation of NSC functions through the activation of AKT-mTOR signaling pathway during brain development.     

Cell surface N-glycans-mediated isolation of mouse neural stem cells

The isolation of neural stem cells (NSCs) has been hampered by the lack of valid cell-surface antigens on NSCs, and novel valuable markers have been proposed. Glycan (oligosaccharide chain) is a potential candidate as a marker to isolate NSCs, because the species and the combination order of saccharides in glycan generate remarkable structural diversity and specificity. At present, the expression of hundreds of glycoconjugates with glycans have been found in the NSCs; however, just a few glycan-epitopes have been identified as valuable cell-surface markers. This review focused on the isolation of NSC using glycoprotein, especially complex type N-glycans. The cell-surface N-glycan-mediated isolation of NSCs is therefore expected to provide a comprehensive understanding of the biologic characteristics of NSCs in the brain, and thereby help to develop novel strategies in the field of regenerative medicine.     

Plant lectins detect age and region specific differences in cell surface carbohydrates and cell reassociation behavior of embryonic mouse cerebellar cells

When plated at high cell density in a microwell culture system, freshly dissociated embryonic mouse cerebellar cells assemble into reproducible, 3-dimensional patterns. The addition of the dimeric lectin Succinyl Concanavalin A blocks reversibly the formation of the microwell pattern, suggesting that cell surface carbohydrates affect the reassociation behavior of embryonic mouse cerebellar cells. Agglutination studes of dissociated cell populations harvested from different regions of the embryonic brain reveal that different lectins agglutinate cell populations from different embryonic brain regions. Cells from E13 cerebellum are agglutinated with Concanavalin A, wheat germ agglutinin, Ricinus communis agglutinin, mol wt 60,000, Ricinus communis agglutinin, mol wt 120,000, and Lens culinaris, but not by soybean agglutinin or a fucose-binding protein. Cells from the midbrain are agglutinated only with Concanavalin A, Ricinus communis agglutinin, mol wt 60,000 and Ricinus communis agglutinin, mol wt 120,000; those from the cerebral cortex are agglutinated only with Lens culinaris; and those from the medulla are agglutinated only with Ricinus communis agglutinin, mol wt 60,000, and Ricinus communis agglutinin, mol wt 120,000. In addition, agglutination of cerebellar cells with Concanavalin A, wheat germ agglutinin, and Ricinus communis agglutinin is diminished over the course of development from embryonic day 13 to postnatal day 7. These studies suggest regional differences in the cell surfaces of the developling brain that are further modulated during the differentiation of the tissues. On a poly(D-lysine) treated substrate in microwell cultures, cell migration is unique to the cerebellum of the 4 brain regions studied. Surfaces treated with carbohydrate-derivatized poly(D-lysine) are currently being tested for their efficacy as substrates for differential cell migration.     

Cell reassociation behavior and lectin-induced agglutination of embryonic mouse cells from different brain regions

Cells from dissociated embryonic mouse cerebellum, when plated at high cell density in a 10 μl microwell, assembled into a reproducible three-dimensional pattern of reaggregates containing 2–10000 cells each and interconnecting cables of processes. The details of this pattern were modifiable by coating the culture substratum with poly-d-lysine and by the use of different types of serum in the growth medium. Formation of interconnecting cables was inhibited reversibly by the dimeric lectin Succinyl Concanavalin A (Succ-ConA). Cells from cerebellum, midbrain, medulla and cerebral cortex, cultured separately in microwells, formed distinguishable patterns that appeared to be more region-specific than developmental stage-specific.With lectins as probes of carbohydrate-containing surface macromolecules, cells harvested from different tissue regions had different cell surface properties. In addition the concentration of concanavalin A (ConA) or wheat germ agglutinin (WGA) required for half maximal agglutination was greatly increased for cerebellar cells harvested later than embryonic day 16. These observations suggest both regional and age-specific alterations in cell surface elements required for lectin-induced agglutination during mouse brain development.     

Quantitative agglutination of specific populations of sea urchin embryo cells with concanavalin A

It has been demonstrated that specific changes in carbohydrate-containing cell surface lectin receptor sites occur with differentiation and maturation of sea urchin embryo cells. In this study, evidence is presented, using a quantitative electronic particle counter assay to measure agglutination, which indicates that concanavalin A (Con A) mediated agglutination of dissociated 32/64 cell sea urchin embryos differs dramatically with respect to specific cell populations. The migratory cell type, the micromere, is significantly more agglutinable with Con A than the other cell types and colchicine treatment markedly increases sea urchin embryo cell agglutinability. The results indicate that like many malignant cells which display extensive migratory behavior, specific migratory populations of embryonic cells are agglutinable with Con A. The results are discussed with respect to the possible nature of lectin receptor sites on specific populations of embryonic cells and the possible role of colchicine-sensitive structures in controlling the display patterns of these sites.     

Extensive determination of glycan heterogeneity reveals an unusual abundance of high mannose glycans in enriched plasma membranes of human embryonic stem cells

Most cell membrane proteins are known or predicted to be glycosylated in eukaryotic organisms, where surface glycans are essential in many biological processes including cell development and differentiation. Nonetheless, the glycosylation on cell membranes remains not well characterized because of the lack of sensitive analytical methods. This study introduces a technique for the rapid profiling and quantitation of N- and O-glycans on cell membranes using membrane enrichment and nanoflow liquid chromatography/mass spectrometry of native structures. Using this new method, the glycome analysis of cell membranes isolated from human embryonic stem cells and somatic cell lines was performed. Human embryonic stem cells were found to have high levels of high mannose glycans, which contrasts with IMR-90 fibroblasts and a human normal breast cell line, where complex glycans are by far the most abundant and high mannose glycans are minor components. O-Glycosylation affects relatively minor components of cell surfaces. To verify the quantitation and localization of glycans on the human embryonic stem cell membranes, flow cytometry and immunocytochemistry were performed. Proteomics analyses were also performed and confirmed enrichment of plasma membrane proteins with some contamination from endoplasmic reticulum and other membranes. These findings suggest that high mannose glycans are the major component of cell surface glycosylation with even terminal glucoses. High mannose glycans are not commonly presented on the surfaces of mammalian cells or in serum yet may play important roles in stem cell biology. The results also mean that distinguishing stem cells from other mammalian cells may be facilitated by the major difference in the glycosylation of the cell membrane. The deep structural analysis enabled by this new method will enable future mechanistic studies on the biological significance of high mannose glycans on stem cell membranes and provide a general tool to examine cell surface glycosylation.     

Neural stem cells confer unique pinwheel architecture to the ventricular surface in neurogenic regions of the adult brain

Neural stem cells (NSCs, B1 cells) are retained in the walls of the adult lateral ventricles but, unlike embryonic NSCs, are displaced from the ventricular zone (VZ) into the subventricular zone (SVZ) by ependymal cells. Apical and basal compartments, which in embryonic NSCs play essential roles in self-renewal and differentiation, are not evident in adult NSCs. Here we show that SVZ B1 cells in adult mice extend a minute apical ending to directly contact the ventricle and a long basal process ending on blood vessels. A closer look at the ventricular surface reveals a striking pinwheel organization specific to regions of adult neurogenesis. The pinwheel's core contains the apical endings of B1 cells and in its periphery two types of ependymal cells: multiciliated (E1) and a type (E2) characterized by only two cilia and extraordinarily complex basal bodies. These results reveal that adult NSCs retain fundamental epithelial properties, including apical and basal compartmentalization, significantly reshaping our understanding of this adult neurogenic niche.     

Neural stem cells: involvement in adult neurogenesis and CNS repair

Recent advances in stem cell research, including the selective expansion of neural stem cells (NSCs) in vitro, the induction of particular neural cells from embryonic stem cells in vitro, the identification of NSCs or NSC-like cells in the adult brain and the detection of neurogenesis in the adult brain (adult neurogenesis), have laid the groundwork for the development of novel therapies aimed at inducing regeneration in the damaged central nervous system (CNS). There are two major strategies for inducing regeneration in the damaged CNS: (i) activation of the endogenous regenerative capacity and (ii) cell transplantation therapy. In this review, we summarize the recent findings from our group and others on NSCs, with respect to their role in insult-induced neurogenesis (activation of adult NSCs, proliferation of transit-amplifying cells, migration of neuroblasts and survival and maturation of the newborn neurons), and implications for therapeutic interventions, together with tactics for using cell transplantation therapy to treat the damaged CNS.     

Polyadenylation of nascent RNA during the embryogenesis of Ilyanassa obsoleta.

It has been demonstrated that specific changes in carbohydrate-containing cell surface lectin receptor sites occur with differentiation and maturation of sea urchin embryo cells. In this study, evidence is presented, using a quantitative electronic particle counter assay to measure agglutination, which indicates that concanavalin A (Con A) mediated agglutination of dissociated $\text{32}\text{64}$ cell sea urchin embryos differs dramatically with respect to specific cell populations. The migratory cell type, the micromere, is significantly more agglutinable with Con A than the other cell types and colchicine treatment markedly increases sea urchin embryo cell agglutinability. The results indicate that like many malignant cells which display extensive migratory behavior, specific migratory populations of embryonic cells are agglutinable with Con A. The results are discussed with respect to the possible nature of lectin receptor sites on specific populations of embryonic cells and the possible role of colchicine-sensitive structures in controlling the display patterns of these sites.     

Binding of Erythroagglutinating Phytohemagglutinin Lectin from Phaseolus vulgaris to the Epidermal Growth Factor Receptor Inhibits Receptor Function in the Human Glioma Cell Line, U373 MG

Abstract: Little is known about the role of the N -linked oligosaccharides in the function of the epidermal growth factor (EGF) receptor (EGF-R). In a human glioma cell line, U373 MG, EGF-Rs contain the bisecting N -linked oligosaccharide sequence recognized by erythroagglutinating phytohemagglutinin lectin from Phaseolus vulgaris (E-PHA). Incubation of E-PHA with cultured U373 MG cells results in inhibition of EGF binding to its receptor and consequently inhibition of EGF-induced autophosphorylation of the receptor. Consistent with the inhibitory effects on the EGF-R, phenotypic events that depend on EGF-R signaling, such as cell spreading and proliferation, were also found to be modified. The effect of this lectin seems to be specific because leukoagglutinating phytohemagglutinin lectin from P. vulgaris (L-PHA), an isolectin of E-PHA, had no effect on EGF-R activity or the biological functions of these cells even though L-PHA was able to bind to the EGF-R. These findings suggest the presence of an important bisecting N -linked oligosaccharide structure in close proximity to the EGF binding site on the receptor. Furthermore, these results suggest the possibility that E-PHA lectin binding may provide an additional approach to blocking EGF-dependent glioma cell growth.     

Oct4-induced reprogramming is required for adult brain neural stem cell differentiation into midbrain dopaminergic neurons

Neural stem cells (NSCs) lose their competency to generate region-specific neuronal populations at an early stage during embryonic brain development. Here we investigated whether epigenetic modifications can reverse the regional restriction of mouse adult brain subventricular zone (SVZ) NSCs. Using a variety of chemicals that interfere with DNA methylation and histone acetylation, we showed that such epigenetic modifications increased neuronal differentiation but did not enable specific regional patterning, such as midbrain dopaminergic (DA) neuron generation. Only after Oct-4 overexpression did adult NSCs acquire a pluripotent state that allowed differentiation into midbrain DA neurons. DA neurons derived from Oct4-reprogrammed NSCs improved behavioural motor deficits in a rat model of Parkinson's disease (PD) upon intrastriatal transplantation. Here we report for the first time the successful differentiation of SVZ adult NSCs into functional region-specific midbrain DA neurons, by means of Oct-4 induced pluripotency.     

胚胎大鼠脑和脊髓神经干细胞的分离和培养

研究采用显微解剖、无血清细胞培养和免疫荧光细胞化学染色等实验技术 ,成功地建立了胚胎大鼠脑和脊髓神经干细胞 (NSCs)的分离和培养方法。结果显示 ,( 1)在含成纤维细胞生长因子 2 (FGF 2 )和表皮生长因子(EGF)的无血清培养液中 ,两种来源的NSCs经体外培养 8- 10代后 ,其细胞数呈指数级增加 ,其中脑来源的NSCs数由原代培养时的 1× 10 6 增加至 1× 10 12 ,脊髓来源的NSCs数从 1× 10 6 增加至 1× 10 11。增殖的细胞表达神经上皮干细胞蛋白 (nestin) ;( 2 )在含 1%胎牛血清 (FBS)的培养条件下 ,它们都能被诱导分化为神经元、少突胶质细胞和星型胶质细胞。但其分化比例可随细胞传代次数的增加而改变 ,其中 ,大脑来源的NSCs分化为神经元的比例从第二代 (P2 )的 11 95± 2 5 %下降至第五代 (P5)的 1 97± 1 16% (P <0 0 1) ,而少突胶质细胞的分化比例则基本保持不变 ,这一分化格局同样可在脊髓来源的NSCs中发现。结果表明 ,我们所分离和培养的细胞在体外经多次传代后仍具有很强的增殖能力和多向分化潜能 ,它们都表达nestin ,属于中枢神经系统的干细胞     

Establishing Embryonic Mouse Neural Stem Cell Culture Using the Neurosphere Assay

In mammalians, stem cells acts as a source of undifferentiated cells to maintain cell genesis and renewal in different tissues and organs during the life span of the animal. They can potentially replace cells that are lost in the aging process or in the process of injury and disease. The existence of neural stem cells (NSCs) was first described by Reynolds and Weiss (1992) in the adult mammalian central nervous system (CNS) using a novel serum‐free culture system, the neurosphere assay (NSA). Using this assay, it is also feasible to isolate and expand NSCs from different regions of the embryonic CNS. These in vitro expanded NSCs are multipotent and can give rise to the three major cell types of the CNS. While the NSA seems relatively simple to perform, attention to the procedures demonstrated here is required in order to achieve reliable and consistent results. This video practically demonstrates NSA to generate and expand NSCs from embryonic day 14-mouse brain tissue and provides technical details so one can achieve reproducible neurosphere cultures. The procedure includes harvesting E14 mouse embryos, brain microdissection to harvest the ganglionic eminences, dissociation of the harvested tissue in NSC medium to gain a single cell suspension, and finally plating cells in NSA culture. After 5-7 days in culture, the resulting primary neurospheres are passaged to further expand the number of the NSCs for future experiments.Download video file.^{(69M, mov)}     

HNK-1 Epitope-carrying Tenascin-C Spliced Variant Regulates the Proliferation of Mouse Embryonic Neural Stem Cells

Neural stem cells (NSCs) possess high proliferative potential and the capacity for self-renewal with retention of multipotency to differentiate into neuronal and glial cells. NSCs are the source for neurogenesis during central nervous system development from fetal and adult stages. Although the human natural killer-1 (HNK-1) carbohydrate epitope is expressed predominantly in the nervous system and involved in intercellular adhesion, cell migration, and synaptic plasticity, the expression patterns and functional roles of HNK-1-containing glycoconjugates in NSCs have not been fully recognized. We found that HNK-1 was expressed in embryonic mouse NSCs and that this expression was lost during the process of differentiation. Based on proteomics analysis, it was revealed that the HNK-1 epitopes were almost exclusively displayed on an extracellular matrix protein, tenascin-C (TNC), in the mouse embryonic NSCs. Furthermore, the HNK-1 epitope was found to be present only on the largest isoform of the TNC molecules. In addition, the expression of HNK-1 was dependent on expression of the largest TNC variant but not by enzymes involved in the biosynthesis of HNK-1. By knocking down HNK-1 sulfotransferase or TNC by small interfering RNA, we further demonstrated that HNK-1 on TNC was involved in the proliferation of NSCs via modulation of the expression level of the epidermal growth factor receptor. Our finding provides insights into the function of HNK-1 carbohydrate epitopes in NSCs to maintain stemness during neural development.     

Lewis X-carrying N-glycans regulate the proliferation of mouse embryonic neural stem cells via the Notch signaling pathway

Neural stem cells (NSCs) possess high proliferative potential and the capacity for self-renewal with retention of multipotency to differentiate into brain-forming cells. Several signaling pathways have been shown to be involved in the fate determination process of NSCs, but the molecular mechanisms underlying the maintenance of neural cell stemness remain largely unknown. Our previous study showed that human natural killer carbohydrate epitopes expressed specifically by mouse NSCs modulate the Ras-MAPK pathway, raising the possibility of regulatory roles of glycoprotein glycans in the specific signaling pathways involved in NSC fate determination. To address this issue, we performed comparative N-glycosylation profiling of NSCs before and after differentiation in a comprehensive and quantitative manner. We found that Lewis X-carrying N-glycans were specifically displayed on undifferentiated cells, whereas pauci-mannose-type N-glycans were predominantly expressed on differentiated cells. Furthermore, by knocking down a fucosyltransferase 9 with short interfering RNA, we demonstrated that the Lewis X-carrying N-glycans were actively involved in the proliferation of NSCs via modulation of the expression level of Musashi-1, which is an activator of the Notch signaling pathway. Our findings suggest that Lewis X carbohydrates, which have so far been characterized as undifferentiation markers, actually operate as activators of the Notch signaling pathway for the maintenance of NSC stemness during brain development.     

Neuregulin-1 increases the proliferation of neuronal progenitors from embryonic neural stem cells

Neuregulins are a family of proteins expressed in the developing brain and in brain regions that continue to undergo neurogenesis in adult animals. We investigated the effects of neuregulins on embryonic neural stem cells (NSCs) isolated from E11 mouse telencephalon. Treatment of basic fibroblast growth factor (bFGF)-expanded neurosphere cultures with the EGF-like domain of neuregulin1-beta1 (NRG-1(177-244)) resulted in a 4-fold increase of bromodeoxyuridine (BrDU)-labeled cells, suggesting that NRG-1 stimulated proliferation. The majority of the BrdU-positive cells co-labeled with an antibody against MAP2, indicating that the proliferating cells were neuronal. No BrDU labeling was seen in GFAP- or O4-positive cells. In NRG-1-treated cultures, many of the MAP2-positive cells co-labeled with an anti-nestin antibody, suggesting that these cells are neuron-restricted progenitors (NRPs). Few MAP2/nestin-positive cells were seen in control cultures. The increase in the number of neuronal cells in NRG-1-treated cultures was due to increased proliferation of MAP2-positive cells rather than the regulation of cell survival or fate determination. These results suggest that neuregulins are mitogenic to NRPs, thus endogenous neuregulins may play important roles during CNS neurogenesis.     

Brain histogenesis in vitro: Reconstruction of brain tissue from dissociated cells

Summary Comparative studies of the aggregative behavior of cells dissociated from different areas of embryonic chick and mouse brains show that each of the regionally differentiated lobes (cerebrum, optic tectum, and cerebellum), and the stem areas (diencephalon and medulla), form characteristic aggregates distinctive in size and shape. Bispecific co-aggregates are produced by commingling dissociated mouse cerebrum cells with chick cells from various brain regions, or from non-nervous tissues; the size of these co-aggregates and the extent of internal sorting out of cell types is closely related to the degree of homology between the interacting cell populations, e.g. co-aggregates of the closely homologous mouse and chick cerebral cell types contain homogeneous tissue fabrics of intermingled mouse and chick cells. Cell surface constituents involved in selective recognition and association of nerve cells were sought and cell-free supernatant preparations were obtained from short-term monolayer cultures of embryonic cerebrum cells (of either mouse or chick origin) which caused a striking, specific enhancement of aggregation of homologous cerebrum cells. These materials had no such effect on heterologous tissues tested: optic tectum, cerebellum, medulla, neural retina, liver, kidney or limb bud. These findings are discussed in relation to control mechanisms governing normal brain histogenesis and to the specificity of neural associations. This work was supported by United States Public Health Service research grant HD-01253 to Aron Moscona and by the Louis Block Fund of the University of Chicago.     

Telomere shortening and chromosomal instability abrogates proliferation of adult but not embryonic neural stem cells

Chromosome integrity is essential for cell viability and, therefore, highly proliferative cell types require active telomere elongation mechanisms to grow indefinitely. Consistently, deletion of telomerase activity in a genetically modified mouse strain results in growth impairments in all highly proliferative cell populations analyzed so far. We show that telomere attrition dramatically impairs the in vitro proliferation of adult neural stem cells (NSCs) isolated from the subventricular zone (SVZ) of telomerase-deficient adult mice. Reduced proliferation of postnatal neurogenic progenitors was also observed in vivo, in the absence of exogenous mitogenic stimulation. Strikingly, severe telomere erosion resulting in chromosomal abnormalities and nuclear accumulation of p53 did not affect the in vitro proliferative potential of embryonic NSCs. These results suggest that intrinsic differences exist between embryonic and adult neural progenitor cells in their response to telomere shortening, and that some populations of tissue-specific stem cells can bypass DNA damage check points.