Isolation and Fusion of Sperm Cells in Several Bicellular Pollen Species

Living sperm cells were isolated in large quantities from the pollen tubes, grown by the in vivo-in vitro technique in 8 bicellular pollen species belonging to 5 families. An “osmotic shook weak enzyme treatment” method could effectively release sperms from pollen tubes and favor sub sequent purification. The viable sperm yields were up to 82.9% in Zephyranthes candida and 78.2% in Hemerocallis minor. Fusions were successfully induced by polyethylene glycol (PEG) according to the "small-scale fusion" procedure in various combinations, viz., between the same sperm cells in 5 species, between sperm cells of Gladiolus gandavensis and Hippeastrum vitta turn, between sperm cells and microspore protoplasts in Hemerocallis minor, and between sperm cells of H. vittatum and microspore protoplasts of Hemerocallis fulva. Test with fluorochrome reaction, more than 85% of the fusion products of sperm cells in Z. candida were viable. The yieid of viable fusion products between sperm cells and microspore protoplasts in Hemerocallis minor was about 75% and half of them could survive after culture for 24h. The induction of fusion between sperm cells and petal protoplasts in G. gandavensis by a combined PEG-dimethyl sulfoxide (DMSO) treatment was investigated in detail. About 90% of the fusion products thus obtamed were viable. Several critical factors affecting the fusion efficiency were studied. These included the ratio of sperm cell number to petal protoplast number in the mixture, concentrations of PEG and DMSO, and duration of incubation in the inducing solution. It appeared that addition of DMSO could significantly increase the fusion frequency, and that there may be a synergistic effect between PEG and DMSO. This is the first attempt to use isolated sperm cells for fusion studies in bicellular pollen species.     

Proteomics of neural stem cells

The isolation of neural stem cells from fetal and adult mammalian CNS and the demonstration of functional neurogenesis in adult CNS have offered perspectives for treatment of many devastating hereditary and acquired neurological diseases. Due to this enormous potential, neural stem cells are a subject of extensive molecular profiling studies with a search for new markers and regulatory pathways governing their self-renewal as opposed to differentiation. Several in-depth proteomic studies have been conducted on primary or immortalized cultures of neural stem cells and neural progenitor cells, and yet more remains to be done. Additionally, neurons and glial cells have been obtained from embryonic stem cells and mesenchymal stem cells, and proteins associated with the differentiation process have been characterized to a certain degree with a view to further investigations. This review summarizes recent findings relevant to the proteomics of neural stem cells and discusses major proteins significantly regulated during neural stem cell differentiation with a view to their future use in cell-based regenerative and reparative therapy.     

重新认识神经胶质细胞

在神经生物学研究领域,胶质细胞过去被认为仅仅是为神经元提供支持而受到冷落。近年来的研究使人们认识到,胶质细胞在整个神经系统中发挥着远比以往所知的更为活跃、更为重要的作用。     

神经干细胞研究进展

神经干细胞研究是当今生命科学研究的热点之一。神经干细胞是神经系统发育过程中保留下来的具有自我更新和多分化潜能的原始细胞。随着对神经干细胞认识的不断深入,其临床应用前景与价值得到了越来越多研究者的肯定。从神经干细胞的生物学特征、来源、培养鉴定、分化及应用等几个方面对目前的研究做一概述。     

Sphingolipid metabolism in neural cells

Sphingolipids were discovered more than a century ago in the brain. Cerebrosides and sphingomyelins were named so because they were first isolated from neural tissue. Although glycosphingolipids and especially those containing sialic acid in their oligosaccharide moiety are particularly abundant in the brain, sphingolipids are ubiquitous cellular membrane components. They form cell- and species-specific profiles at the cell surfaces that characteristically change in development, differentiation, and oncogenic transformation, indicating the significance of these lipid molecules for cell-cell and cell-matrix interactions as well as for cell adhesion, modulation of membrane receptors and signal transduction. This review summarizes sphingolipid metabolism with emphasis on aspects particularly relevant in neural cell types, including neurons, oligodendrocytes and neuroblastoma cells. In addition, the reader is briefly introduced into the methodology of lipid evaluation techniques and also into the putative physiological functions of glycosphingolipids and their metabolites in neural tissue.     

Counting human neural stem cells

Knowledge of the exact number of viable cells in a given volume of a cell suspension is required for many routine tissue culture manipulations, such as plating cells for immunocytochemistry or for cell transfections. This protocol describes a straightforward and fast method for differentiating between live and dead cells and quantifying the cell concentration and total cell number using a hemacytometer. This procedure first requires detaching cells from a growth surface and resuspending them in media. Next, the cells are diluted in a solution of Trypan blue (ideally to a concentration that will give 20-50 cells per quadrant) and placed in the hemacytometer. Finally, averaging the counts of viable cells in several randomly selected quadrants, dividing the average by the volume of one 1 mm(2) quadrant (0.1 microl) and multiplying by the dilution factor gives the number of cells per l. Multiplying this cell concentration by the total volume in microl gives the total cell number. This protocol describes counting human neural stem/precursor cells (hNSPCs), but can also be used for many other cell types.     

Isolation and Purification of Viable Sperm Cells from Stored Bicellular Pollen of Lilium davidii Duch.

A successful mass isolation of viable sperm cells from stored bicellular pollen of Lilium davidii Duch. was reported. When fresh pollen was cultured in BKS 15 medium, 87 % germinated in which the generative cells of the fresh pollen underwent mitosis and formed sperm cells within 28 hours. For pollen stored at -20℃ and -70℃ for 6 months, only less than 20 % germinated; but the germination percentage rose to 80 % after they have been hydrated and gradually warmed. Pollen grains of L. davidii which have been stored at -70 ℃ for 6 months, after being thawed were firstly germinated in a 15% sucrose medium for 28 hours, and then osmotically shocked with 10 % sucrose Solution. The solution was later adjusted to a final sucrose concentration of 15%. After density gradient centrifugation, 4 mL suspension of purified sperm cells with a density of 6 × 106 cells/mL were obtained at the interphase of 5%—15% percoll, with a 12% yield of viable sperm cells. The purified sperm cells had a diameter of 13—15 μm and reacted positive to fluorochrome, indicating that they have intact plasma membrane.     

Passaging human neural stem cells

The ability to manipulate human neural stem/precursor cells (hNSPCs) in vitro provides a means to investigate their utility as cell transplants for therapeutic purposes as well as to explore many fundamental processes of human neural development and pathology. This protocol presents a simple method of culturing and passaging hNSPCs in hopes of standardizing this technique and increasing reproducibility of human stem cell research. The hNSPCs we use were isolated from cadaveric postnatal brain cortices by the National Human Neural Stem Cell Resource and grown as adherent cultures on flasks coated with fibronectin (Palmer et al., 2001; Schwartz et al., 2003). We culture our hNSPCs in a DMEM:F12 serum-free media supplemented with EGF, FGF, and PDGF and passage them 1:2 approximately every seven days. Using these conditions, the majority of the cells in the culture maintain a bipolar morphology and express markers of undifferentiated neural stem cells (such as nestin and sox2).     

Sphingolipid metabolism in neural cells

Sphingolipids were discovered more than a century ago in the brain. Cerebrosides and sphingomyelins were named so because they were first isolated from neural tissue. Although glycosphingolipids and especially those containing sialic acid in their oligosaccharide moiety are particularly abundant in the brain, sphingolipids are ubiquitous cellular membrane components. They form cell- and species-specific profiles at the cell surfaces that characteristically change in development, differentiation, and oncogenic transformation, indicating the significance of these lipid molecules for cell-cell and cell-matrix interactions as well as for cell adhesion, modulation of membrane receptors and signal transduction. This review summarizes sphingolipid metabolism with emphasis on aspects particularly relevant in neural cell types, including neurons, oligodendrocytes and neuroblastoma cells. In addition, the reader is briefly introduced into the methodology of lipid evaluation techniques and also into the putative physiological functions of glycosphingolipids and their metabolites in neural tissue.     

Differentiation of insulin-producing cells from human neural progenitor cells

BackgroundSuccess in islet-transplantation-based therapies for type 1 diabetes, coupled with a worldwide shortage of transplant-ready islets, has motivated efforts to develop renewable sources of islet-replacement tissue. Islets and neurons share features, including common developmental programs, and in some species brain neurons are the principal source of systemic insulin.Methods and FindingsHere we show that brain-derived human neural progenitor cells, exposed to a series of signals that regulate in vivo pancreatic islet development, form clusters of glucose-responsive insulin-producing cells (IPCs). During in vitro differentiation of neural progenitor cells with this novel method, genes encoding essential known in vivo regulators of pancreatic islet development were expressed. Following transplantation into immunocompromised mice, IPCs released insulin C-peptide upon glucose challenge, remained differentiated, and did not form detectable tumors.ConclusionProduction of IPCs solely through extracellular factor modulation in the absence of genetic manipulations may promote strategies to derive transplantable islet-replacement tissues from human neural progenitor cells and other types of multipotent human stem cells.     

Antidepressants encounter autophagy in neural cells

The prevailing view of antidepressants’ (ADs) mode of action primarily focuses on their impact on neurotransmitter circuits, since the corresponding transporters and receptors are common targets of ADs. However, mounting evidence points to additional target structures, which may either support the beneficial effects or account for undesired side effects of ADs. Recently, we analyzed the influence of three ADs of different classes on autophagy-related processes in primary astrocytes and neurons. While amitriptyline (AMI) and citalopram (CIT) upregulate the expression of autophagic markers such as LC3B-II or Beclin 1, venlafaxine fails to exert these effects. Autophagy triggered by AMI and CIT is functional in terms of autophagic flux, and is partially mediated by class III PtdIns 3-kinase- and ROS dependent-pathways. Together, our study’s results highlight a novel mode of action of ADs beyond monoaminergic neurotransmission.     

Nutrient control of neural stem cells

The physiological status of an organism is able to influence stem cell behaviour to ensure that stem cells meet the needs of the organism during growth, and in response to injury and environmental changes. In particular, the brain is sensitive to metabolic fluctuations. Here we discuss how nutritional status is able to regulate systemic and local insulin/IGF signalling so as to control aspects of neural stem behaviour. Recent results have begun to reveal how systemic signals are relayed to neural stem cells through local interactions with a glial niche. Although much still remains to be discovered, emerging parallels between the regulation of Drosophila and mammalian stem cells suggest a conserved mechanism for how the brain responds to changes in nutritional state.     

Radial glia and neural stem cells

During the last decade, the role of radial glia has been radically revisited. Rather than being considered a mere structural component serving to guide newborn neurons towards their final destinations, radial glia is now known to be the main source of neurons in several regions of the central nervous system, notably in the cerebral cortex. Radial glial cells differentiate from neuroepithelial progenitors at the beginning of neurogenesis and share with their ancestors the bipolar shape and the expression of some molecular markers. Radial glia, however, can be distinguished from neuroepithelial progenitors by the expression of astroglial markers. Clonal analyses showed that radial glia is a heterogeneous population, comprising both pluripotent and different lineage-restricted neural progenitors. At late-embryonic and postnatal stages, radial glial cells give rise to the neural stem cells responsible for adult neurogenesis. Embryonic pluripotent radial glia and adult neural stem cells may be clonally linked, thus representing a lineage displaying stem cell features in both the developing and mature central nervous system. This work was supported by AIRC (Associazione Italiana per la Ricerca sul Cancro) NUSUG grant (In vivo screening for genes implicated in glioma formation and development of new animal models of glial tumors) and by Fondazione CARIGE grant (Basi molecolari e cellulari dei gliomi: individuazione di marcatori diagnostici e di nuovi bersagli terapeutici).     

神经干细胞研究介绍

神经干细胞研究是近年脑科学研究的热点，本文综述了神经干细胞的分离培养方法、脑内迁移路线、发育分化的影响因素以及可能的应用前景。