How neural stem cells contribute to neocortex development

Xing, Lixin; Wilsch‐Bräuninger, Michaela; Huttner, Wieland B.

doi:10.1042/bst20200923

Cited by 25 publications

(22 citation statements)

References 64 publications

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“…Symmetric cell divisions of NSCs generate two daughter cells sharing the same identity, which is also the same as that of the mother cell. In asymmetric self-renewing cell division, the two daughter cells generated from an NSC have different identities, but one of them shares the same identity as that of the mother cell [ 40 ]. In addition, NSCs can differentiate into lineage-specific cells, such as neurons, oligodendrocytes, and astrocytes [ 41 ].…”

Section: Discussionmentioning

confidence: 99%

Water-Soluble, Alanine-Modified Fullerene C60 Promotes the Proliferation and Neuronal Differentiation of Neural Stem Cells

Ren

Peng

et al. 2022

IJMS

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As carbon-based nanomaterials, water-soluble C60 derivatives have potential applications in various fields of biomedicine. In this study, a water-soluble fullerene C60 derivative bearing alanine residues (Ala-C60) was synthesized. The effects of Ala-C60 on neural stem cells (NSCs) as seed cells were explored. Ala-C60 can promote the proliferation of NSCs, induce NSCs to differentiate into neurons, and inhibit the migration of NSCs. Most importantly, the Ala-C60 can significantly increase the cell viability of NSCs treated with hydrogen peroxide (H2O2). The glutathioneperoxidase (GSH-Px) and superoxide dismutase (SOD) activities and glutathione (GSH) content increased significantly in NSCs treated even by 20 μM Ala-C60. These findings strongly indicate that Ala-C60 has high potential to be applied as a scaffold with NSCs for regeneration in nerve tissue engineering for diseases related to the nervous system.

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Section: Discussionmentioning

confidence: 99%

Water-Soluble, Alanine-Modified Fullerene C60 Promotes the Proliferation and Neuronal Differentiation of Neural Stem Cells

Ren

Peng

et al. 2022

IJMS

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“…aRG can either self-renew through a series of proliferative symmetric divisions, or divide asymmetrically in a proliferative and consumptive manner. Asymmetric proliferative division generates one daughter cell that is identical to its mother aRG, and another daughter cell that is either an immature postmitotic neuron ( direct neurogenesis ), or one of the two main types of more committed BPs: (1) transit-amplifying progenitors or intermediate progenitor cells (IPCs), or (2) outer radial glial cells or basal radial glia (bRG) ( indirect neurogenesis ) ( Kriegstein et al, 2006 ; Lui et al, 2011 ; Xing et al, 2021 ). As a result of this enormous accumulation of BP, the neocortex becomes even thicker and is comprised of distinct developmental regions: the VZ, the subventricular zone (SVZ), the intermediate zone (IZ), the subplate (SP), the cortical plate (CP), and the marginal zone (MZ).…”

Section: Post-transcriptional Regulation Mrnas Poised For Translation and Rna-binding Proteinsmentioning

confidence: 99%

“…In the small-brained lissencephalic mammals (e.g., rodents), IPC are the most abundant population of BP in the SVZ with restricted mitotic capacity as they typically undergo one terminal symmetric consumptive division to give rise to two immature neurons ( Haubensak et al, 2004 ; Miyata et al, 2004 ; Xing et al, 2021 ). The remaining rare population of rodent BP belongs to bRG, which are localized more toward the upper region of the still undifferentiated SVZ ( Wang et al, 2011 ; Vaid et al, 2018 ).…”

Section: Implication Of Rna-binding Proteins In Expansion Of the Mammalian Neocortexmentioning

confidence: 99%

“…The iSVZ of gyrencephalic mammals is composed mostly of the IPC population during neurogenesis, and it is comparable in its thickness to the still undifferentiated SVZ of the lissencephalic mammal. However, the primate oSVZ is the largest proliferative compartment due to the presence of highly proliferative and neurogenic bRG, which tend to use the available area of the thickening SVZ for symmetric proliferative (two daughter bRG) or asymmetric proliferative divisions (one daughter bRG with self-renewal capacity, and another daughter IPC or neuron) ( Smart, 2002 ; Kriegstein et al, 2006 ; Fietz et al, 2010 ; Silbereis et al, 2016 ; Xing et al, 2021 ). While the cell cycle kinetics of the lissencephalic progenitors generally decrease overtime ( Takahashi et al, 1995 ), the peak expansion of superficial-layer neurons occurs during the later stages of primate neurogenesis in tandem with the upsurge of bRG proliferation ( Figure 11 ), as well as the transformation of aRG into more truncated morphologies.…”

Section: Implication Of Rna-binding Proteins In Expansion Of the Mammalian Neocortexmentioning

confidence: 99%

“…The prenatal neurogenesis is finalized once aRG and BP begin symmetric or asymmetric consumptative divisions, giving rise to postmitotic neurons. The progenitors then shift to gliogenesis, which is a process that completely depletes the progenitor pool by generating astrocytes and oligodendrocytes ( Xing et al, 2021 ).…”

Section: Implication Of Rna-binding Proteins In Expansion Of the Mammalian Neocortexmentioning

confidence: 99%

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Evolution of the Neocortex Through RNA-Binding Proteins and Post-transcriptional Regulation

Salamon

Rašin

2022

Front. Neurosci.

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The human neocortex is undoubtedly considered a supreme accomplishment in mammalian evolution. It features a prenatally established six-layered structure which remains plastic to the myriad of changes throughout an organism’s lifetime. A fundamental feature of neocortical evolution and development is the abundance and diversity of the progenitor cell population and their neuronal and glial progeny. These evolutionary upgrades are partially enabled due to the progenitors’ higher proliferative capacity, compartmentalization of proliferative regions, and specification of neuronal temporal identities. The driving force of these processes may be explained by temporal molecular patterning, by which progenitors have intrinsic capacity to change their competence as neocortical neurogenesis proceeds. Thus, neurogenesis can be conceptualized along two timescales of progenitors’ capacity to (1) self-renew or differentiate into basal progenitors (BPs) or neurons or (2) specify their fate into distinct neuronal and glial subtypes which participate in the formation of six-layers. Neocortical development then proceeds through sequential phases of proliferation, differentiation, neuronal migration, and maturation. Temporal molecular patterning, therefore, relies on the precise regulation of spatiotemporal gene expression. An extensive transcriptional regulatory network is accompanied by post-transcriptional regulation that is frequently mediated by the regulatory interplay between RNA-binding proteins (RBPs). RBPs exhibit important roles in every step of mRNA life cycle in any system, from splicing, polyadenylation, editing, transport, stability, localization, to translation (protein synthesis). Here, we underscore the importance of RBP functions at multiple time-restricted steps of early neurogenesis, starting from the cell fate transition of transcriptionally primed cortical progenitors. A particular emphasis will be placed on RBPs with mostly conserved but also divergent evolutionary functions in neural progenitors across different species. RBPs, when considered in the context of the fascinating process of neocortical development, deserve to be main protagonists in the story of the evolution and development of the neocortex.

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Human Neocortical Evolution and Neurological Disorders

SeanHill,

Walsh

2023

Neocortical Neurogenesis in Development and Evolution

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How neural stem cells contribute to neocortex development

Cited by 25 publications

References 64 publications

Water-Soluble, Alanine-Modified Fullerene C60 Promotes the Proliferation and Neuronal Differentiation of Neural Stem Cells

Water-Soluble, Alanine-Modified Fullerene C60 Promotes the Proliferation and Neuronal Differentiation of Neural Stem Cells

Evolution of the Neocortex Through RNA-Binding Proteins and Post-transcriptional Regulation

Human Neocortical Evolution and Neurological Disorders

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