Neural stem cell

(Redirected from Neural stem cells)

Neural stem cells (NSCs) are self-renewing, multipotent cells that firstly generate the radial glial progenitor cells that generate the neurons and glia of the nervous system of all animals during embryonic development.[1] Some neural progenitor stem cells persist in highly restricted regions in the adult vertebrate brain and continue to produce neurons throughout life. Differences in the size of the central nervous system are among the most important distinctions between the species and thus mutations in the genes that regulate the size of the neural stem cell compartment are among the most important drivers of vertebrate evolution.[2]

Neural stem cell
Details
SystemNervous system
Identifiers
Latincellula nervosa praecursoria
MeSHD058953
THH2.00.01.0.00010
FMA86684
Anatomical terms of microanatomy

Stem cells are characterized by their capacity to differentiate into multiple cell types.[3] They undergo symmetric or asymmetric cell division into two daughter cells. In symmetric cell division, both daughter cells are also stem cells. In asymmetric division, a stem cell produces one stem cell and one specialized cell.[4] NSCs primarily differentiate into neurons, astrocytes, and oligodendrocytes.

Brain location

edit

In the adult mammalian brain, the subgranular zone in the hippocampal dentate gyrus, the subventricular zone around the lateral ventricles, and the hypothalamus (precisely in the dorsal α1, α2 region and the hypothalamic proliferative region, located in the adjacent median eminence) have been reported to contain neural stem cells.[5]

Development

edit

In vivo origin

edit
 
Neural stem cells differentiating to astrocytes (green) and sites of growth hormone receptor shown in red

There are two basic types of stem cell: adult stem cells, which are limited in their ability to differentiate, and embryonic stem cells (ESCs), which are pluripotent and have the capability of differentiating into any cell type.[3]

Neural stem cells are more specialized than ESCs because they only generate radial glial cells that give rise to the neurons and to glia of the central nervous system (CNS).[4] During the embryonic development of vertebrates, NSCs transition into radial glial cells (RGCs) also known as radial glial progenitor cells, (RGPs) and reside in a transient zone called the ventricular zone (VZ).[1][6] Neurons are generated in large numbers by (RGPs) during a specific period of embryonic development through the process of neurogenesis, and continue to be generated in adult life in restricted regions of the adult brain.[7] Adult NSCs differentiate into new neurons within the adult subventricular zone (SVZ), a remnant of the embryonic germinal neuroepithelium, as well as the dentate gyrus of the hippocampus.[7]

In vitro origin

edit

Adult NSCs were first isolated from mouse striatum in the early 1990s. They are capable of forming multipotent neurospheres when cultured in vitro. Neurospheres can produce self-renewing and proliferating specialized cells. These neurospheres can differentiate to form the specified neurons, glial cells, and oligodendrocytes.[7] In previous studies, cultured neurospheres have been transplanted into the brains of immunodeficient neonatal mice and have shown engraftment, proliferation, and neural differentiation.[7]

Communication and migration

edit

NSCs are stimulated to begin differentiation via exogenous cues from the microenvironment, or stem cell niche. Some neural cells are migrated from the SVZ along the rostral migratory stream which contains a marrow-like structure with ependymal cells and astrocytes when stimulated. The ependymal cells and astrocytes form glial tubes used by migrating neuroblasts. The astrocytes in the tubes provide support for the migrating cells as well as insulation from electrical and chemical signals released from surrounding cells. The astrocytes are the primary precursors for rapid cell amplification. The neuroblasts form tight chains and migrate towards the specified site of cell damage to repair or replace neural cells. One example is a neuroblast migrating towards the olfactory bulb to differentiate into periglomercular or granule neurons which have a radial migration pattern rather than a tangential one.[8]

Aging

edit

Neural stem cell proliferation declines as a consequence of aging.[9] Various approaches have been taken to counteract this age-related decline.[10] Because FOX proteins regulate neural stem cell homeostasis,[11] FOX proteins have been used to protect neural stem cells by inhibiting Wnt signaling.[12]

Function

edit

Epidermal growth factor (EGF) and fibroblast growth factor (FGF) are mitogens that promote neural progenitor and stem cell growth in vitro, though other factors synthesized by the neural progenitor and stem cell populations are also required for optimal growth.[13] It is hypothesized that neurogenesis in the adult brain originates from NSCs. The origin and identity of NSCs in the adult brain remain to be defined.

During differentiation

edit

The most widely accepted model of an adult NSC is a radial, glial fibrillary acidic protein-positive cell. Quiescent stem cells are Type B that are able to remain in the quiescent state due to the renewable tissue provided by the specific niches composed of blood vessels, astrocytes, microglia, ependymal cells, and extracellular matrix present within the brain. These niches provide nourishment, structural support, and protection for the stem cells until they are activated by external stimuli. Once activated, the Type B cells develop into Type C cells, active proliferating intermediate cells, which then divide into neuroblasts consisting of Type A cells. The undifferentiated neuroblasts form chains that migrate and develop into mature neurons. In the olfactory bulb, they mature into GABAergic granule neurons, while in the hippocampus they mature into dentate granule cells.[14]

Epigenetic modification

edit

Epigenetic modifications are important regulators of gene expression in differentiating neural stem cells. Key epigenetic modifications include DNA cytosine methylation to form 5-methylcytosine and 5-methylcytosine demethylation.[15][16] These types of modification are critical for cell fate determination in the developing and adult mammalian brain.

DNA cytosine methylation is catalyzed by DNA methyltransferases (DNMTs). Methylcytosine demethylation is catalyzed in several distinct steps by TET enzymes that carry out oxidative reactions (e.g. 5-methylcytosine to 5-hydroxymethylcytosine) and enzymes of the DNA base excision repair (BER) pathway.[15]

During disease

edit

NSCs have an important role during development producing the enormous diversity of neurons, astrocytes and oligodendrocytes in the developing CNS. They also have important role in adult animals, for instance in learning and hippocampal plasticity in the adult mice in addition to supplying neurons to the olfactory bulb in mice.[7]

Notably the role of NSCs during diseases is now being elucidated by several research groups around the world. The responses during stroke, multiple sclerosis, and Parkinson's disease in animal models and humans is part of the current investigation. The results of this ongoing investigation may have future applications to treat human neurological diseases.[7]

Neural stem cells have been shown to engage in migration and replacement of dying neurons in classical experiments performed by Sanjay Magavi and Jeffrey Macklis.[17] Using a laser-induced damage of cortical layers, Magavi showed that SVZ neural progenitors expressing Doublecortin, a critical molecule for migration of neuroblasts, migrated long distances to the area of damage and differentiated into mature neurons expressing NeuN marker. In addition, Masato Nakafuku's group from Japan showed for the first time the role of hippocampal stem cells during stroke in mice.[18] These results demonstrated that NSCs can engage in the adult brain as a result of injury. Furthermore, in 2004 Evan Y. Snyder's group showed that NSCs migrate to brain tumors in a directed fashion. Jaime Imitola, M.D and colleagues from Harvard demonstrated for the first time, a molecular mechanism for the responses of NSCs to injury. They showed that chemokines released during injury such as SDF-1a were responsible for the directed migration of human and mouse NSCs to areas of injury in mice.[19] Since then other molecules have been found to participate in the responses of NSCs to injury. All these results have been widely reproduced and expanded by other investigators joining the classical work of Richard L. Sidman in autoradiography to visualize neurogenesis during development, and neurogenesis in the adult by Joseph Altman in the 1960s, as evidence of the responses of adult NSCs activities and neurogenesis during homeostasis and injury.

The search for additional mechanisms that operate in the injury environment and how they influence the responses of NSCs during acute and chronic disease is matter of intense research.[20]

Research

edit

Regenerative therapy of the CNS

edit

Cell death is a characteristic of acute CNS disorders as well as neurodegenerative disease. The loss of cells is amplified by the lack of regenerative abilities for cell replacement and repair in the CNS. One way to circumvent this is to use cell replacement therapy via regenerative NSCs. NSCs can be cultured in vitro as neurospheres. These neurospheres are composed of neural stem cells and progenitors (NSPCs) with growth factors such as EGF and FGF. The withdrawal of these growth factors activate differentiation into neurons, astrocytes, or oligodendrocytes which can be transplanted within the brain at the site of injury. The benefits of this therapeutic approach have been examined in Parkinson's disease, Huntington's disease, and multiple sclerosis. NSPCs induce neural repair via intrinsic properties of neuroprotection and immunomodulation. Some possible routes of transplantation include intracerebral transplantation and xenotransplantation.[21][22]

For neurodegenerative diseases, another transplantation therapy arising in research is the directional induction of neural stem cells.[23] The direct transplantation of NCSs is limited and faces challenges due to low survival rate and irrational differentiation. To overcome the limitations, the direct induction of NCSs aims to manipulate the differentiation of NCS prior to transplantation. Currently NSCs are obtained from primary CNS tissues, the differentiation of pluripotent stem cells (PSC) and transdifferentiation from somatic cells. Induced NCSs can be reprogrammed from somatic cells. Hence, directional induction takes NSCs from different sources and forces them to differentiate into the desired neural lineage cells. An example of the therapeutic usage of this technique is the targeted differentiation of ventral midbrain dopaminergic (DAergenic) neurons into different models of PD.[23] Current therapies for the neurodegenerative disease Parkinson’s Disease (PD) include dopamine replacement therapy (DRT). This works to alleviate PD symptoms, but as the disease progresses, the alleviating mechanisms are affected in a nonlinear manner.[24]

An alternative therapeutic approach to the transplantation of NSPCs is the pharmacological activation of endogenous NSPCs (eNSPCs). Activated eNSPCs produce neurotrophic factors, several treatments that activate a pathway that involves the phosphorylation of STAT3 on the serine residue and subsequent elevation of Hes3 expression (STAT3-Ser/Hes3 Signaling Axis) oppose neuronal death and disease progression in models of neurological disorder.[25][26]

Generation of 3D in vitro models of the human CNS

edit

Human midbrain-derived neural progenitor cells (hmNPCs) have the ability to differentiate down multiple neural cell lineages that lead to neurospheres as well as multiple neural phenotypes. The hmNPC can be used to develop a 3D in vitro model of the human CNS. There are two ways to culture the hmNPCs, the adherent monolayer and the neurosphere culture systems. The neurosphere culture system has previously been used to isolate and expand CNS stem cells by its ability to aggregate and proliferate hmNPCs under serum-free media conditions as well as with the presence of epidermal growth factor (EGF) and fibroblast growth factor-2 (FGF2). Initially, the hmNPCs were isolated and expanded before performing a 2D differentiation which was used to produce a single-cell suspension. This single-cell suspension helped achieve a homogenous 3D structure of uniform aggregate size. The 3D aggregation formed neurospheres which was used to form an in vitro 3D CNS model.[27]

Bioactive scaffolds as traumatic brain injury treatment

edit

Traumatic brain injury (TBI) can deform the brain tissue, leading to necrosis primary damage which can then cascade and activate secondary damage such as excitotoxicity, inflammation, ischemia, and the breakdown of the blood-brain-barrier. Damage can escalate and eventually lead to apoptosis or cell death. Current treatments focus on preventing further damage by stabilizing bleeding, decreasing intracranial pressure and inflammation, and inhibiting pro-apoptotic cascades. In order to repair TBI damage, an upcoming therapeutic option involves the use of NSCs derived from the embryonic peri-ventricular region. Stem cells can be cultured in a favorable 3-dimensional, low cytotoxic environment, a hydrogel, that will increase NSC survival when injected into TBI patients. The intracerebrally injected, primed NSCs were seen to migrate to damaged tissue and differentiate into oligodendrocytes or neuronal cells that secreted neuroprotective factors.[28][29]

Galectin-1 in neural stem cells

edit

Galectin-1 is expressed in adult NSCs and has been shown to have a physiological role in the treatment of neurological disorders in animal models. There are two approaches to using NSCs as a therapeutic treatment: (1) stimulate intrinsic NSCs to promote proliferation in order to replace injured tissue, and (2) transplant NSCs into the damaged brain area in order to allow the NSCs to restore the tissue. Lentivirus vectors were used to infect human NSCs (hNSCs) with Galectin-1 which were later transplanted into the damaged tissue. The hGal-1-hNSCs induced better and faster brain recovery of the injured tissue as well as a reduction in motor and sensory deficits as compared to only hNSC transplantation.[8]

Assays

edit

Neural stem cells are routinely studied in vitro using a method referred to as the Neurosphere Assay (or Neurosphere culture system), first developed by Reynolds and Weiss.[30] Neurospheres are intrinsically heterogeneous cellular entities almost entirely formed by a small fraction (1 to 5%) of slowly dividing neural stem cells and by their progeny, a population of fast-dividing nestin-positive progenitor cells.[30][31][32] The total number of these progenitors determines the size of a neurosphere and, as a result, disparities in sphere size within different neurosphere populations may reflect alterations in the proliferation, survival and/or differentiation status of their neural progenitors. Indeed, it has been reported that loss of β1-integrin in a neurosphere culture does not significantly affect the capacity of β1-integrin deficient stem cells to form new neurospheres, but it influences the size of the neurosphere: β1-integrin deficient neurospheres were overall smaller due to increased cell death and reduced proliferation.[33]

While the Neurosphere Assay has been the method of choice for isolation, expansion and even the enumeration of neural stem and progenitor cells, several recent publications have highlighted some of the limitations of the neurosphere culture system as a method for determining neural stem cell frequencies.[34] In collaboration with Reynolds, STEMCELL Technologies has developed a collagen-based assay, called the Neural Colony-Forming Cell (NCFC) Assay, for the quantification of neural stem cells. Importantly, this assay allows discrimination between neural stem and progenitor cells.[35]

History

edit

The first evidence that neurogenesis occurs in certain regions of the adult mammalian brain came from [3H]-thymidine labeling studies conducted by Altman and Das in 1965 which showed postnatal hippocampal neurogenesis in young rats.[36] In 1989, Sally Temple described multipotent, self-renewing progenitor and stem cells in the subventricular zone (SVZ) of the mouse brain.[37] In 1992, Brent A. Reynolds and Samuel Weiss were the first to isolate neural progenitor and stem cells from the adult striatal tissue, including the SVZ — one of the neurogenic areas — of adult mice brain tissue.[30] In the same year the team of Constance Cepko and Evan Y. Snyder were the first to isolate multipotent cells from the mouse cerebellum and stably transfected them with the oncogene v-myc.[38] This molecule is one of the genes widely used now to reprogram adult non-stem cells into pluripotent stem cells. Since then, neural progenitor and stem cells have been isolated from various areas of the adult central nervous system, including non-neurogenic areas, such as the spinal cord, and from various species including humans.[39][40]

See also

edit

References

edit
  • Jaganathan, Arun; Tiwari, Meena; Phansekar, Rahul; Panta, Rajkumar; Huilgol, Nagraj (2011). "Intensity-modulated radiation to spare neural stem cells in brain tumors: A computational platform for evaluation of physical and biological dose metrics". Journal of Cancer Research and Therapeutics. 7 (1): 58–63. doi:10.4103/0973-1482.80463. PMID 21546744.
  1. ^ a b Beattie, R; Hippenmeyer, S (December 2017). "Mechanisms of radial glia progenitor cell lineage progression". FEBS Letters. 591 (24): 3993–4008. doi:10.1002/1873-3468.12906. PMC 5765500. PMID 29121403.
  2. ^ Liu P, Verhaar AP, Peppelenbosch MP (January 2019). "Signaling Size: Ankyrin and SOCS Box-Containing ASB E3 Ligases in Action". Trends in Biochemical Sciences. 44 (1): 64–74. doi:10.1016/j.tibs.2018.10.003. PMID 30446376. S2CID 53569740.
  3. ^ a b Clarke, D.; Johansson, C; Wilbertz, J; Veress, B; Nilsson, E; Karlstrom, H; Lendahl, U; Frisen, J (2000). "Generalized Potential of Adult Neural Stem Cells". Science. 288 (5471): 1660–63. Bibcode:2000Sci...288.1660C. doi:10.1126/science.288.5471.1660. PMID 10834848.
  4. ^ a b Gilbert, Scott F.; College, Swarthmore; Helsinki, the University of (2014). Developmental biology (Tenth ed.). Sunderland, Mass.: Sinauer. ISBN 978-0878939787.
  5. ^ Andreotti JP, Silva WN, Costa AC, Picoli CC, Bitencourt FC, Coimbra-Campos LM, Resende RR, Magno LA, Romano-Silva MA, Mintz A, Birbrair A (2019). "Neural stem cell niche heterogeneity". Semin Cell Dev Biol. 95: 42–53. doi:10.1016/j.semcdb.2019.01.005. PMC 6710163. PMID 30639325.
  6. ^ Rakic, P (October 2009). "Evolution of the neocortex: a perspective from developmental biology". Nature Reviews. Neuroscience. 10 (10): 724–35. doi:10.1038/nrn2719. PMC 2913577. PMID 19763105.
  7. ^ a b c d e f Paspala, S; Murthy, T; Mahaboob, V; Habeeb, M (2011). "Pluripotent stem cells – A review of the current status in neural regeneration". Neurology India. 59 (4): 558–65. doi:10.4103/0028-3886.84338. PMID 21891934.
  8. ^ a b Sakaguchi, M; Okano, H (2012). "Neural stem cells, adult neurogenesis, and galectin-1: From bench to bedside". Developmental Neurobiology. 72 (7): 1059–67. doi:10.1002/dneu.22023. PMID 22488739. S2CID 41548939.
  9. ^ Kuhn HG, Dickinson-Anson H, Gage FH (1996). "Neurogenesis in the dentate gyrus of the adult rat: age-related decrease of neuronal progenitor proliferation". Journal of Neuroscience. 16 (6): 2027–2033. doi:10.1523/JNEUROSCI.16-06-02027.1996. PMC 6578509. PMID 8604047.
  10. ^ Artegiani B, Calegari F; Calegari (2012). "Age-related cognitive decline: can neural stem cells help us?". Aging. 4 (3): 176–186. doi:10.18632/aging.100446. PMC 3348478. PMID 22466406.
  11. ^ Renault VM, Rafalski VA, Morgan AA, Salih DA, Brett JO, Webb AE, Villeda SA, Thekkat PU, Guillerey C, Denko NC, Palmer TD, Butte AJ, Brunet A (2009). "FoxO3 regulates neural stem cell homeostasis". Cell Stem Cell. 5 (5): 527–539. doi:10.1016/j.stem.2009.09.014. PMC 2775802. PMID 19896443.
  12. ^ Paik JH, Ding Z, Narurkar R, Ramkissoon S, Muller F, Kamoun WS, Chae SS, Zheng H, Ying H, Mahoney J, Hiller D, Jiang S, Protopopov A, Wong WH, Chin L, Ligon KL, DePinho RA (2009). "FoxOs cooperatively regulate diverse pathways governing neural stem cell homeostasis". Cell Stem Cell. 5 (5): 540–553. doi:10.1016/j.stem.2009.09.013. PMC 3285492. PMID 19896444.
  13. ^ Taupin, Philippe; Ray, Jasodhara; Fischer, Wolfgang H; Suhr, Steven T; Hakansson, Katarina; Grubb, Anders; Gage, Fred H (2000). "FGF-2-Responsive Neural Stem Cell Proliferation Requires CCg, a Novel Autocrine/Paracrine Cofactor". Neuron. 28 (2): 385–97. doi:10.1016/S0896-6273(00)00119-7. PMID 11144350. S2CID 16322048.
  14. ^ Bergstrom, T; Forsbery-Nilsson, K (2012). "Neural stem cells: Brain building blocks and beyond". Upsala Journal of Medical Sciences. 117 (2): 132–42. doi:10.3109/03009734.2012.665096. PMC 3339545. PMID 22512245.
  15. ^ a b Wang, Z; Tang, B; He, Y; Jin, P (Mar 2016). "DNA methylation dynamics in neurogenesis". Epigenomics. 8 (3): 401–14. doi:10.2217/epi.15.119. PMC 4864063. PMID 26950681.
  16. ^ Noack, F; Pataskar, A; Schneider, M; Buchholz, F; Tiwari, VK; Calegari, F (2019). "Assessment and site-specific manipulation of DNA (hydroxy-)methylation during mouse corticogenesis". Life Sci Alliance. 2 (2): e201900331. doi:10.26508/lsa.201900331. PMC 6394126. PMID 30814272.
  17. ^ MacKlis, Jeffrey D.; Magavi, Sanjay S.; Leavitt, Blair R. (2000). "Induction of neurogenesis in the neocortex of adult mice". Nature. 405 (6789): 951–5. Bibcode:2000Natur.405..951M. doi:10.1038/35016083. PMID 10879536. S2CID 4416694.
  18. ^ Nakatomi, Hirofumi; Kuriu, Toshihiko; Okabe, Shigeo; Yamamoto, Shin-Ichi; Hatano, Osamu; Kawahara, Nobutaka; Tamura, Akira; Kirino, Takaaki; Nakafuku, Masato (2002). "Regeneration of Hippocampal Pyramidal Neurons after Ischemic Brain Injury by Recruitment of Endogenous Neural Progenitors". Cell. 110 (4): 429–41. doi:10.1016/S0092-8674(02)00862-0. PMID 12202033. S2CID 15438187.
  19. ^ Imitola J, Raddassi K, Park KI, Mueller FJ, Nieto M, Teng YD, Frenkel D, Li J, Sidman RL, Walsh CA, Snyder EY, Khoury SJ (December 28, 2004). "Directed migration of neural stem cells to sites of CNS injury by the stromal cell-derived factor 1alpha/CXC chemokine receptor 4 pathway". Proc. Natl. Acad. Sci. U.S.A. 101 (52): 18117–22. Bibcode:2004PNAS..10118117I. doi:10.1073/pnas.0408258102. PMC 536055. PMID 15608062.
  20. ^ Sohur US, US.; Emsley JG; Mitchell BD; Macklis JD. (September 29, 2006). "Adult neurogenesis and cellular brain repair with neural progenitors, precursors and stem cells". Philosophical Transactions of the Royal Society of London B. 361 (1473): 1477–97. doi:10.1098/rstb.2006.1887. PMC 1664671. PMID 16939970.
  21. ^ Bonnamain, V; Neveu, I; Naveilhan, P (2012). "Neural stem/progenitor cells as promising candidates for regenerative therapy of the central nervous system". Frontiers in Cellular Neuroscience. 6: 17. doi:10.3389/fncel.2012.00017. PMC 3323829. PMID 22514520.
  22. ^ Xu, X; Warrington, A; Bieber, A; Rodriguez, M (2012). "Enhancing Central Nervous System Repair-The Challenges". CNS Drugs. 25 (7): 555–73. doi:10.2165/11587830-000000000-00000. PMC 3140701. PMID 21699269.
  23. ^ a b Nie, Luwei; Yao, Dabao; Chen, Shiling; Wang, Jingyi; Pan, Chao; Wu, Dongcheng; Liu, Na; Tang, Zhouping (2023-07-01). "Directional induction of neural stem cells, a new therapy for neurodegenerative diseases and ischemic stroke". Cell Death Discovery. 9 (1): 215. doi:10.1038/s41420-023-01532-9. ISSN 2058-7716. PMC 10314944. PMID 37393356.
  24. ^ Oz, Tuba; Kaushik, Ajeet; Kujawska, Małgorzata (2023-07-26). "Neural stem cells for Parkinson's disease management: Challenges, nanobased support, and prospects". World Journal of Stem Cells. 15 (7): 687–700. doi:10.4252/wjsc.v15.i7.687. PMC 10401423. PMID 37545757.
  25. ^ Androutsellis-Theotokis A, et al. (August 2006). "Notch signalling regulates stem cell numbers in vitro and in vivo". Nature. 442 (7104): 823–6. Bibcode:2006Natur.442..823A. doi:10.1038/nature04940. PMID 16799564. S2CID 4372065.
  26. ^ Androutsellis-Theotokis A, et al. (August 2009). "Targeting neural precursors in the adult brain rescues injured dopamine neurons". Proc. Natl. Acad. Sci. U.S.A. 106 (32): 13570–5. Bibcode:2009PNAS..10613570A. doi:10.1073/pnas.0905125106. PMC 2714762. PMID 19628689.
  27. ^ Brito, C; Simao, D; Costa, I; Malpique, R; Pereira, C; Fernandes, P; Serra, M; Schwarz, S; Schwarz, J; Kremer, E; Alves, P (2012). "Generation and genetic modification of 3D cultures of human dopaminergic neurons derived from neural progenitor cells". Methods. 56 (3): 452–60. doi:10.1016/j.ymeth.2012.03.005. PMID 22433395.
  28. ^ Stabenfeldt, S; Irons, H; LaPlace, M (2011). "Stem Cells and Bioactive Scaffolds as a Treatment for Traumatic Brain Injury". Current Stem Cell Research & Therapy. 6 (3): 208–20. doi:10.2174/157488811796575396. PMID 21476977.
  29. ^ Ratajczak, J; Zuba-Surma, E; Paczkowska, K; Kucia, M; Nowacki, P; Ratajczak, MZ (2011). "Stem cells for neural regeneration--a potential application of very small embryonic-like stem cells". J. Physiol. Pharmacol. 62 (1): 3–12. PMID 21451204.
  30. ^ a b c Reynolds, B.; Weiss, S (1992). "Generation of neurons and astrocytes from isolated cells of the adult mammalian central nervous system". Science. 255 (5052): 1707–10. Bibcode:1992Sci...255.1707R. doi:10.1126/science.1553558. PMID 1553558. S2CID 17905159.
  31. ^ Campos, L. S.; Leone, DP; Relvas, JB; Brakebusch, C; Fässler, R; Suter, U; Ffrench-Constant, C (2004). "β1 integrins activate a MAPK signalling pathway in neural stem cells that contributes to their maintenance". Development. 131 (14): 3433–44. doi:10.1242/dev.01199. PMID 15226259.
  32. ^ Lobo, M. V. T.; Alonso, F. J. M.; Redondo, C.; Lopez-Toledano, M. A.; Caso, E.; Herranz, A. S.; Paino, C. L.; Reimers, D.; Bazan, E. (2003). "Cellular Characterization of Epidermal Growth Factor-expanded Free-floating Neurospheres". Journal of Histochemistry & Cytochemistry. 51 (1): 89–103. doi:10.1177/002215540305100111. PMID 12502758.
  33. ^ Leone, D. P.; Relvas, JB; Campos, LS; Hemmi, S; Brakebusch, C; Fässler, R; Ffrench-Constant, C; Suter, U (2005). "Regulation of neural progenitor proliferation and survival by β1 integrins". Journal of Cell Science. 118 (12): 2589–99. doi:10.1242/jcs.02396. PMID 15928047.
  34. ^ Singec, Ilyas; Knoth, Rolf; Meyer, Ralf P; MacIaczyk, Jaroslaw; Volk, Benedikt; Nikkhah, Guido; Frotscher, Michael; Snyder, Evan Y (2006). "Defining the actual sensitivity and specificity of the neurosphere assay in stem cell biology". Nature Methods. 3 (10): 801–6. doi:10.1038/nmeth926. PMID 16990812. S2CID 6925259.
  35. ^ Louis, Sharon A.; Rietze, Rodney L.; Deleyrolle, Loic; Wagey, Ravenska E.; Thomas, Terry E.; Eaves, Allen C.; Reynolds, Brent A. (2008). "Enumeration of Neural Stem and Progenitor Cells in the Neural Colony-Forming Cell Assay". Stem Cells. 26 (4): 988–96. doi:10.1634/stemcells.2007-0867. PMID 18218818. S2CID 21935724.
  36. ^ Altman, Joseph; Das, Gopal D. (1965-06-01). "Autoradiographic and histological evidence of postnatal hippocampal neurogenesis in rats". The Journal of Comparative Neurology. 124 (3): 319–335. doi:10.1002/cne.901240303. ISSN 1096-9861. PMID 5861717. S2CID 14121873.
  37. ^ Temple, S (1989). "Division and differentiation of isolated CNS blast cells in microculture". Nature. 340 (6233): 471–73. Bibcode:1989Natur.340..471T. doi:10.1038/340471a0. PMID 2755510. S2CID 4364792.
  38. ^ Snyder, Evan Y.; Deitcher, David L.; Walsh, Christopher; Arnold-Aldea, Susan; Hartwieg, Erika A.; Cepko, Constance L. (1992). "Multipotent neural cell lines can engraft and participate in development of mouse cerebellum". Cell. 68 (1): 33–51. doi:10.1016/0092-8674(92)90204-P. PMID 1732063. S2CID 44695465.
  39. ^ Zigova, Tanja; Sanberg, Paul R.; Sanchez-Ramos, Juan Raymond, eds. (2002). Neural stem cells: methods and protocols. Humana Press. ISBN 978-0-89603-964-3. Retrieved 18 April 2010.[page needed]
  40. ^ Taupin, Philippe; Gage, Fred H. (2002). "Adult neurogenesis and neural stem cells of the central nervous system in mammals". Journal of Neuroscience Research. 69 (6): 745–9. doi:10.1002/jnr.10378. PMID 12205667. S2CID 39888988.
edit