MHC-class-II are expressed in a subpopulation of human neural stem cells in vitro in an IFNγ–independent fashion and during development

Vagaska, Barbora; New, Sophie E. P.; Alvarez-Gonzalez, Cesar; D’Acquisto, Fulvio; Gómez, Susana; Bulstrode, Neil; Madrigal, J. Alejandro; Ferretti, Patrizia

doi:10.1038/srep24251

Cited by 49 publications

(45 citation statements)

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“…Using human neural stem cells, Patrizia Ferretti (University College London, UK) reported recent progress on the development of 3D culture systems to study neural damage. She also showed that in developing human brains major histocompatibility complex class II antigens (MHC-II) are unexpectedly expressed in the germinal zone in a subset of SOX2-positive neural progenitors (Vagaska et al, 2016). This expression, which is seemingly regulated independently of inflammatory stimuli, challenges the accepted notion that microglia are the only MHC-II-expressing cells in the developing CNS.…”

Section: Regeneration Of the Cnsmentioning

confidence: 68%

Trends in tissue repair and regeneration

et al. 2017

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The 6th EMBO conference on the Molecular and Cellular Basis of Regeneration and Tissue Repair took place in Paestum (Italy) on the 17th-21st September, 2016. The 160 scientists who attended discussed the importance of cellular and tissue plasticity, biophysical aspects of regeneration, the diverse roles of injury-induced immune responses, strategies to reactivate regeneration in mammals, links between regeneration and ageing, and the impact of non-mammalian models on regenerative medicine.

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Section: Regeneration Of the Cnsmentioning

confidence: 68%

Trends in tissue repair and regeneration

et al. 2017

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“…Neuronal differentiation. A protocol previously modified from Sun et al 14,16 was used to induce neuronal differentiation of hNSCs 14,16 . After plating on Matrigel or laminin coated plates, hNSCs were maintained for 10 days in growth medium without EGF and then for further 7 days without EGF, FGF-2 and heparin to induce differentiation.…”

Section: Human Neural Stem Cells (Hnscs) Isolation Of Hnscs All Promentioning

confidence: 99%

“…Whereas the use of iPSCs (induced pluripotent stem cells) derived from patients to study neural diseases has been rapidly expanding, there is still a lack of human injury models particularly in 3D 11-13 .Here we have used human neural stem cells (hNSCs) derived from embryonic and foetal brain as a cell source for setting up 3D cultures and injury models 10,14,15 . The advantage of hNSCs over iPSCs or hESCs (human embryonic stem cells) for this purpose is that they can proliferate extensively in vitro, have the potential to differentiate towards neurons, astrocytes and oligodendrocytes and are less demanding than iPSCs to maintain in culture [14][15][16][17][18] . Furthermore, in comparison with iPSCs, hNSCs differentiation protocols are in general much shorter, as they do not require the initial phase of inducing the cells towards neural progenitors.We set out to establish and evaluate a 3D human cell culture system using hydrogel scaffolds in order to mimic in vivo CNS tissue architecture while maintaining reproducibility and minimising variation found in open Scientific RepoRtS | (2020) 10:6785 | https://doi.org/10.1038/s41598-020-62906-y www.nature.com/scientificreports www.nature.com/scientificreports/ Figure 1.…”

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confidence: 99%

“…Here we have used human neural stem cells (hNSCs) derived from embryonic and foetal brain as a cell source for setting up 3D cultures and injury models 10,14,15 . The advantage of hNSCs over iPSCs or hESCs (human embryonic stem cells) for this purpose is that they can proliferate extensively in vitro, have the potential to differentiate towards neurons, astrocytes and oligodendrocytes and are less demanding than iPSCs to maintain in culture [14][15][16][17][18] . Furthermore, in comparison with iPSCs, hNSCs differentiation protocols are in general much shorter, as they do not require the initial phase of inducing the cells towards neural progenitors.…”

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Modelling human CNS injury with human neural stem cells in 2- and 3-Dimensional cultures

Vagaska

Gillham

Ferretti

2020

Sci Rep

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The adult human central nervous system (CNS) has very limited regenerative capability, and injury at the cellular and molecular level cannot be studied in vivo. Modelling neural damage in human systems is crucial to identifying species-specific responses to injury and potentially neurotoxic compounds leading to development of more effective neuroprotective agents. Hence we developed human neural stem cell (hNSC) 3-dimensional (3D) cultures and tested their potential for modelling neural insults, including hypoxic-ischaemic and Ca 2+ -dependent injury. Standard 3D conditions for rodent cells support neuroblastoma lines used as human CNS models, but not hNSCs, but in all cases changes in culture architecture alter gene expression. Importantly, response to damage differs in 2D and 3D cultures and this is not due to reduced drug accessibility. Together, this study highlights the impact of culture cytoarchitecture on hNSC phenotype and damage response, indicating that 3D models may be better predictors of in vivo response to damage and compound toxicity.In light of the practical and ethical limitations of human research, animal models provide fundamental insight into the central nervous system (CNS) development, injury, disease, as well as the possibility of studying and screening putative therapeutic compounds. However, there is an increasing appreciation of the limitations of animal research, which often fails to reliably predict successful human clinical trials. Key examples of this are hypoxia-ischemia either in newborns (1-8 cases per 1000 births in the Western world) or adults (cerebral stroke) and traumatic injuries to the CNS 1-3 . While animal models have significantly furthered understanding of the mechanisms of injury and repair, and various neuroprotective agents have proven effective in animal injury models, this has not translated into effective treatments in humans 4-6 . Such failures to translate animal studies to successful human clinical trials are often attributed to problems with methodological and study design. However, species-specific differences in drug processing, genetic interactions and molecular mechanisms of action can be argued to be fundamental to therapeutic translation. Further studies on the cell ular mechanisms of human CNS injury and repair are therefore needed in order to develop better therapeutic strategies and bridge the gap between animal models and human clinical trials 7,8 .Three dimensional (3D) culture models have been rapidly emerging as a means to study human cells in vitro. While still in many respects rather challenging, because more complex to maintain and analyse, they reduce the strain and artificial responses which cells must undergo in order to adapt to the flat, stiff surfaces of 2D monolayer culture. A 3D architecture provides a more tissue-like environment in which cell-cell and cell-matrix interact in all dimensions and cells have more biologically relevant exposure to diffusible factors 9,10 . Whereas the use of iPSCs (induced pluripotent stem cells) derived f...

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“…Fetal VM tissue expresses MHC antigens that can elicit an immune response in the case of host mismatch (Widner et al, 1989). Expression level of MHC molecules is low in human PSCs and NSCs (Drukker et al, 2002;Vagaska et al, 2016) but can rapidly be induced in inflammatory conditions or following differentiation in vitro (Drukker and Benvenisty, 2004;Vagaska et al, 2016).…”

Section: Impact Of the Immune Status Of The Host Brainmentioning

confidence: 99%

Transplantation in the nonhuman primate MPTP model of Parkinson's disease: update and perspectives

Wianny

Vezoli

2017

Primate Biol.

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Abstract. In order to calibrate stem cell exploitation for cellular therapy in neurodegenerative diseases, fundamental and preclinical research in NHP (nonhuman primate) models is crucial. Indeed, it is consensually recognized that it is not possible to directly extrapolate results obtained in rodent models to human patients. A large diversity of neurological pathologies should benefit from cellular therapy based on neural differentiation of stem cells. In the context of this special issue of Primate Biology on NHP stem cells, we describe past and recent advances on cell replacement in the NHP model of Parkinson's disease (PD). From the different grafting procedures to the various cell types transplanted, we review here diverse approaches for cell-replacement therapy and their related therapeutic potential on behavior and function in the NHP model of PD.

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MHC-class-II are expressed in a subpopulation of human neural stem cells in vitro in an IFNγ–independent fashion and during development

Cited by 49 publications

References 45 publications

Trends in tissue repair and regeneration

Trends in tissue repair and regeneration

Modelling human CNS injury with human neural stem cells in 2- and 3-Dimensional cultures

Transplantation in the nonhuman primate MPTP model of Parkinson's disease: update and perspectives

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