Generating a proteomic profile of neurogenesis, through the use of human foetal neural stem cells

Garnett, Shaun

18 February 2020

Introduction Neurogenesis, the development of new neurons, starts soon after the formation of the neural tube and is largely completed by birth. Development of the brain after birth is mainly reliant on the formation of new connections between surviving neurons. However, adult neurogenesis does continue in the subgranular zone of the hippocampus from quiescent adult neural stem cells. Traditionally neural stem cells were cultured as neurospheres, a heterogeneous agglomeration of neural cells at various stages of differentiation. This heterogeneity prevented accurate quantitative analysis. In 2008 Sun et al produced the first non-immortalised human foetal neural stem (NS) cell line from nine week old human foetal cortex. These cells are cultured as monolayers, have a radial glia like appearance, self renew and form all three neural cell types, neurons, astrocytes and oligodendrocytes upon differentiation. More recently human foetal neuroepithelial like (NES) stem cells have been produced from five week old human foetal hind-brain, they resemble neuroepithelial cells, with characteristic rosettes, upon differentiation they appear to form a pure population of neurons. These homogeneous monolayer cultures enable quantitative proteomic analysis, to increase our understanding of early brain development Methods Three NES and two NS cell lines were available for analysis. They proliferate by stimulation from FGF and EGF, removal of these growth factors results in spontaneous differentiation. Proliferating NES and NS cells were compared using SILAC labelling. In addition, each cell line was differentiated for 12 days, 6 timepoints were taken and compared using label free quantitation. Results 4677 proteins were quantitated with 473 differentially expressed, revealing fundamental differences between NES and NS cells. NES cells are less differentiated, expressing SOX2 and LIN28, have active cell cycle processes, DNA elongation, histone modification and miRNA mediated gene silencing. Whereas NS cells are more developmentally defined, express multiple membrane proteins, have activated focal adhesion, thereby increasing their binding and interaction with their environment. NS metabolism is more oxidative, utilises lipid metabolism, the pentose phosphate pathway and produces creatine phosphate. Upon differentiation the cell cycle processes are downregulated and neurogenic and gliogenic processes increased. Conclusion This work represent a detailed in vitro characterisation of non immortalised human foetal neural stem cells, it describes the regulatory, metabolic and structural changes occurring within neural stem cells in early brain development. The information herein points towards de-differentiation potentially through LIN28-let7, as a means to produce more neurogenic neural stem cells in vitro thus aiding regenerative therapies, as well as provides a wealth of information for better understanding neurological developmental disorders.

neural stem cells

neuroepithelia

radial glia

MAPPING ASTROCYTE DEVELOPMENT IN THE DORSAL CORTEX OF THE MOUSE BRAIN

Smith, Maria Civita

23 August 2013

No description available.

Neurosciences

transgenic

astrocytes

astrocyte progenitor

corticogenesis

radial glia

brain development

Effects of Zika virus on neural precursor cell types and microencephaly in a model of direct embryonic murine brain infection

Shelton, Samantha

22 June 2021

Prenatal exposure to Zika virus (ZIKV) can result in microencephaly and congenital Zika syndrome but why some brain cells and structures are initially spared by the virus is unknown. Here, a novel murine model of ZIKV infection incorporating in utero electroporation with cell type specific promotors was used to identify the time course of ZIKV infection and to determine which neural precursor cells are initially infected or spared. In vivo time course studies revealed early presence of ZIKV in apical radial glial cells (aRGCs) while infection of basal intermediate progenitor cells climbed after three days of virus exposure. ZIKV-exposed fetal brains exhibited microencephaly as early as 1 day post injection, caused by apoptosis and reduced proliferation, and this change in brain size persisted until birth regardless of developmental age at infection. During infection, 60% of aRGC basal fibers were perturbed while 40% retained normal morphology, indicating that aRGCs are not uniformly vulnerable to ZIKV infection. To evaluate this heterogeneous vulnerability, we generated cell type-specific fate mapping plasmid probes using a previously published single cell RNA-Seq dataset on the E15.5 mouse neocortical wall. The results indicate that one class of aRGC preferentially expresses the putative ZIKV entry receptor AXL, and that these cells are more vulnerable to ZIKV infection than the other aRGC subtypes with low AXL expression. Together, these data highlight important temporal and cellular details of ZIKV fetal brain infection and may be important for prevention strategies and for management of congenital Zika syndrome.

Neurosciences

Microcephaly

Microencephaly

Neural precursor

Radial glia

Zika

Common features of neural progenitor cells and cortical organization revealed by single cell transcriptome analyses of ferret cortical development / フェレット大脳皮質の単一細胞トランスクリプトーム解析による複雑脳形成過程における神経前駆細胞パターンと皮質構築の共通性の解明

Bilgic, Merve

24 November 2023

京都大学 / 新制・課程博士 / 博士(生命科学) / 甲第24985号 / 生博第514号 / 新制||生||68(附属図書館) / 京都大学大学院生命科学研究科高次生命科学専攻 / (主査)教授 北島 智也, 教授 見学 美根子, 教授 今吉 格 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM

brain development

truncated radial glia

ferret

ependyma

neurogenesis

460

Origine et physiopathologie d' une malformation du cortex cérébral : L' hétérotopie nodulaire périventriculaire liée à des mutations du gène Filamine A. / Origin and physiopathology of cortical malformation : periventricular nodular heterotopia due to mutations in FLNA gene.

Carabalona, Aurélie

08 October 2012

Les hétérotopies nodulaires périventriculaires (HNP) correspondent aux malformations cérébrales les plus fréquemment découvertes à l'âge adulte. Survenant au cours de la migration, elles consistent en l'apparition de nodules de neurones ectopiques positionnés le long de la paroi des ventricules latéraux. Sur le plan clinique, les HNP associent une épilepsie et/ou un retard mental. Les mutations dans le gène FLNA (Xq28) représentent la cause majeure des HNP. Une forme récessive rare d'HNP liée à des mutations du gène ARFGEF2 (20q13) et des réarrangements chromosomiques identifiés chez des patients présentant une HNP ont également été rapportés. Alors que le lien entre les HNP associées à des mutations du gène FLNA et leurs manifestations cliniques a été clairement établi, les mécanismes physiopathologiques sous-jacents restent à ce jour inconnus. Deux lignées de souris knockout pour FlnA ont été développées mais aucune de ces deux lignées n'a développé d'HNP. Nous avons donc choisi de créer un nouveau modèle, chez le rat, par inactivation in utero du gène FlnA en utilisant la technique de l'ARN interférence (RNAi). Par cette approche, nous avons reproduit avec succès un phénotype d'HNP chez le rat comparable à celui observé chez les patients. Sur ce modèle, nous avons montré que l'HNP est associée à une désorganisation de la glie radiaire et à une incapacité des progéniteurs neuronaux de progresser dans le cycle cellulaire. En accord avec ces observations, une désorganisation de la glie radiaire a été également observée dans des cerveaux post-mortem de deux patientes présentant une HNP associée à une mutation de FLNA. / Periventricular nodular heterotopia (PNH) is a brain malformation caused by defective neuronal migration resulting in ectopic neuronal nodules lining the lateral ventricles. Most patients have epilepsy, with normal to borderline cognitive function. Mutations in FLNA are the main cause of PH. A rare recessive form caused by mutations in the ARFGEF2 gene (20q13) and chromosomal rearrangements identified in patients with PNH have been reported. The link between FLNA-trelated PH and clinical manifestattions has been wee established but the underlying pathological mechanism remains unknown. Though two FlnA knockout mice strains have been developed, progress has been hindered by the fact that none of them showed the presence of ectopic nodules. Therefore, to recapitulate the loss of FlnA function in the developing rat brain, we used an in utero RNA interference (RNAi)-mediated knockdown approach and successfully reproduced a PNH phenotype in rats comparable to that observed in patients. Using this FlnA knockdown rodent model, we demonstrated that PNH is associated with a disruption in radial glial scaffold integrity in the ventricular zone and also an inability for neuroprogenitor cells to progress adequately through the cell cycle.Consistent with the observations made in rodents, we found similar alterations of radial glia in postmortem brains of two PNH patients harboring distinct FLNA mutations. These data highlights the complexity of the pathogenesis of PNH, the likelihood that several mechanisms are coalescing to lead to disrupted neuronal migration.

Migration neuronale

Glie radiaire

Adhésion

Filamine A

Neuronal migration

Radial glia

Adhesion

Filamin A

Identification, regulation and lineage tracing of embryonic olfactory progenitors

Murdoch, Barbara

11 1900

Neurogenesis occurs in exclusive regions in the adult nervous system, the subventricular zone and dentate gyrus in the brain, and olfactory epithelium (OE) in the periphery. Cell replacement after death or injury, occurs to varying degrees in neural tissue, and is thought to be dependent upon the biological responses of stem and/or progenitor cells. Despite the progress made to identify adult OE and central nervous system (CNS) progenitors and lineage trace their progeny, our spatial and temporal understanding of embryonic OE neuroglial progenitors has been stalled by the paucity of identifiable genes able to distinguish individual candidate progenitors. In the developing CNS, radial glia serve as both neural progenitors and scaffolding for migrating neuroblasts and are identified by the expression of a select group of antigens, including nestin. Here, I show that the embryonic OE contains a novel radial glial-like progenitor (RGLP) that is not detected in adult OE. RGLPs express the radial glial antigens nestin, GLAST and RC2, but not brain lipid binding protein (BLBP), which, distinct from CNS radial glia, is instead found in olfactory ensheathing cells, a result confirmed using lineage tracing with BLBP-cre mice. Nestin-cre-mediated lineage tracing with three different reporters reveals that only a subpopulation of nestin-expressing RGLPs activate the “CNS-specific” nestin regulatory elements, and produce spatially restricted neurons in the OE and vomeronasal organ. The dorsal-medial restriction of transgene-activating cells is also seen in the embryonic OE of Nestin-GFP transgenic mice, where GFP is found in a subpopulation of GFP+ Mash1+ neuronal progenitors, despite the fact that endogenous nestin expression is found in RGLPs throughout the OE. In vitro, embryonic OE progenitors produce three biologically distinct colony subtypes, that when generated from Nestin-cre/ZEG mice, produce GFP+ neurons, recapitulating their in vivo phenotype, and are enriched for the most neurogenic colony subtype. Neurogenesis in vitro is driven by the proliferation of nestin+ progenitors in response to FGF2. I thus provide evidence for a novel neurogenic precursor, the RGLP of the OE, that can be regulated by FGF2, and provide the first evidence for intrinsic differences in the origin and spatiotemporal potential of distinct progenitors during OE development.

Nestin

Neural stem cells

Fibroblast growth factor

Olfactory

Radial glia

Neurogenesis

Identification, regulation and lineage tracing of embryonic olfactory progenitors

Murdoch, Barbara

11 1900

Neurogenesis occurs in exclusive regions in the adult nervous system, the subventricular zone and dentate gyrus in the brain, and olfactory epithelium (OE) in the periphery. Cell replacement after death or injury, occurs to varying degrees in neural tissue, and is thought to be dependent upon the biological responses of stem and/or progenitor cells. Despite the progress made to identify adult OE and central nervous system (CNS) progenitors and lineage trace their progeny, our spatial and temporal understanding of embryonic OE neuroglial progenitors has been stalled by the paucity of identifiable genes able to distinguish individual candidate progenitors. In the developing CNS, radial glia serve as both neural progenitors and scaffolding for migrating neuroblasts and are identified by the expression of a select group of antigens, including nestin. Here, I show that the embryonic OE contains a novel radial glial-like progenitor (RGLP) that is not detected in adult OE. RGLPs express the radial glial antigens nestin, GLAST and RC2, but not brain lipid binding protein (BLBP), which, distinct from CNS radial glia, is instead found in olfactory ensheathing cells, a result confirmed using lineage tracing with BLBP-cre mice. Nestin-cre-mediated lineage tracing with three different reporters reveals that only a subpopulation of nestin-expressing RGLPs activate the “CNS-specific” nestin regulatory elements, and produce spatially restricted neurons in the OE and vomeronasal organ. The dorsal-medial restriction of transgene-activating cells is also seen in the embryonic OE of Nestin-GFP transgenic mice, where GFP is found in a subpopulation of GFP+ Mash1+ neuronal progenitors, despite the fact that endogenous nestin expression is found in RGLPs throughout the OE. In vitro, embryonic OE progenitors produce three biologically distinct colony subtypes, that when generated from Nestin-cre/ZEG mice, produce GFP+ neurons, recapitulating their in vivo phenotype, and are enriched for the most neurogenic colony subtype. Neurogenesis in vitro is driven by the proliferation of nestin+ progenitors in response to FGF2. I thus provide evidence for a novel neurogenic precursor, the RGLP of the OE, that can be regulated by FGF2, and provide the first evidence for intrinsic differences in the origin and spatiotemporal potential of distinct progenitors during OE development.

Nestin

Neural stem cells

Fibroblast growth factor

Olfactory

Radial glia

Neurogenesis

Identification, regulation and lineage tracing of embryonic olfactory progenitors

Murdoch, Barbara

11 1900

Neurogenesis occurs in exclusive regions in the adult nervous system, the subventricular zone and dentate gyrus in the brain, and olfactory epithelium (OE) in the periphery. Cell replacement after death or injury, occurs to varying degrees in neural tissue, and is thought to be dependent upon the biological responses of stem and/or progenitor cells. Despite the progress made to identify adult OE and central nervous system (CNS) progenitors and lineage trace their progeny, our spatial and temporal understanding of embryonic OE neuroglial progenitors has been stalled by the paucity of identifiable genes able to distinguish individual candidate progenitors. In the developing CNS, radial glia serve as both neural progenitors and scaffolding for migrating neuroblasts and are identified by the expression of a select group of antigens, including nestin. Here, I show that the embryonic OE contains a novel radial glial-like progenitor (RGLP) that is not detected in adult OE. RGLPs express the radial glial antigens nestin, GLAST and RC2, but not brain lipid binding protein (BLBP), which, distinct from CNS radial glia, is instead found in olfactory ensheathing cells, a result confirmed using lineage tracing with BLBP-cre mice. Nestin-cre-mediated lineage tracing with three different reporters reveals that only a subpopulation of nestin-expressing RGLPs activate the “CNS-specific” nestin regulatory elements, and produce spatially restricted neurons in the OE and vomeronasal organ. The dorsal-medial restriction of transgene-activating cells is also seen in the embryonic OE of Nestin-GFP transgenic mice, where GFP is found in a subpopulation of GFP+ Mash1+ neuronal progenitors, despite the fact that endogenous nestin expression is found in RGLPs throughout the OE. In vitro, embryonic OE progenitors produce three biologically distinct colony subtypes, that when generated from Nestin-cre/ZEG mice, produce GFP+ neurons, recapitulating their in vivo phenotype, and are enriched for the most neurogenic colony subtype. Neurogenesis in vitro is driven by the proliferation of nestin+ progenitors in response to FGF2. I thus provide evidence for a novel neurogenic precursor, the RGLP of the OE, that can be regulated by FGF2, and provide the first evidence for intrinsic differences in the origin and spatiotemporal potential of distinct progenitors during OE development. / Medicine, Faculty of / Medicine, Department of / Experimental Medicine, Division of / Graduate

Nestin

Neural stem cells

Fibroblast growth factor

Olfactory

Radial glia

Neurogenesis

Self-organization of axial polarity, inside-out layer pattern and species-specific progenitor dynamics in human ES cell-derived neocortex / 自己組織化によって構築されたヒトES細胞由来大脳皮質組織における軸極性の獲得、インサイド-アウトの層形成、および種特異的な神経幹細胞の再現

Kadoshima, Taisuke

24 March 2014

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第18183号 / 医博第3903号 / 新制||医||1004(附属図書館) / 31041 / 京都大学大学院医学研究科医学専攻 / (主査)教授 渡邉 大, 教授 髙橋 良輔, 教授 髙橋 淳, 教授 江藤 浩之 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

human ES cell

3D culture

self-organization

corticogenesis

stratification

outer radial glia

490

Purinergic Regulation of Neurogenesis Following Spinal Cord Injury in Danio Rerio

Stefanova, Eva

January 2022

In contrast to mammals, adult zebrafish undergo successful neural regeneration following spinal cord injury (SCI). Radial glia (RG) lining the zebrafish central canal undergo injury-induced proliferation and subsequent neuronal differentiation to replace damaged cells and restore motor function. However, the molecular mechanisms that underlie these processes remain elusive. Here, we demonstrate that signaling through the evolutionarily conserved purinergic P2X7 receptor is involved. Within the zebrafish spinal cord, P2X7 receptors have widespread distribution with specific localization to neurons and radial glia. At the protein level, the predominant P2X7 receptor isoforms in zebrafish did not include the full-length variant expressed throughout the murine central nervous system, but two truncated splice variants. In response to SCI, protein expression of the 50 kDa isoform became downregulated at 7 dpi and returned to basal levels of expression at 14 and 21 dpi when compared to naïve controls. Meanwhile, expression of the 37 kDa isoform did not change following injury. Pharmacological activation of P2X7 following SCI resulted in a greater number of proliferating cells around the central canal by 7 dpi, while P2X7 inhibition appeared to have no effect. At 14 dpi, these treatments did not have a significant effect on the number of neurons within the injured spinal cord. This data indicates that P2X7 receptor activation is sufficient to induce cellular proliferation, but not a necessary mediator of either proliferation or neurogenesis following SCI in adult zebrafish. Our findings suggest that unlike in humans, P2X7 signaling may not play a maladaptive role following SCI in adult zebrafish. / Thesis / Master of Science (MSc) / Spinal cord injury in mammals causes widespread neuronal cell death and paralysis. In comparison, zebrafish regenerate damaged neurons and restore motor function. Radial glial cells within the zebrafish spinal cord maintain stem-cell properties. Following injury, these cells divide and replace motor neurons. Since mammals have similar cell-types within the spinal cord, understanding the molecular cues driving this adaptive response is of great interest. Here, we examined the evolutionarily conserved purinergic signaling system and found that the expression of the P2X7 receptor varies significantly from mammals and promotes radial glia division following injury.

Spinal Cord Injury

Purinergic Signaling

P2X7

Neurogenesis

Zebrafish

Proliferation

Radial Glia

Regeneration