In Situ Dividing and Phagocytosing Retinal Microglia Express Nestin, Vimentin, and NG2 In Vivo

Wohl, Stefanie G.; Schmeer, Christian; Friese, Thomas; Witte, Otto W.; Isenmann, Stefan

doi:10.1371/journal.pone.0022408

Cited by 55 publications

(48 citation statements)

References 93 publications

(154 reference statements)

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“…The morphological phase-contrast pattern observed in these cells (nuclear and cytoplasmic changes) indicates differentiation, which is supported by the specific immunofluorescent staining of specific cell lineage markers that match the different morphological changes [13,14]. A similar result was previously described by us for the differentiation of adult bone marrow-derived MSCs into neuroblasts.…”

Section: Discussionsupporting

confidence: 76%

In vitro Differentiation of Adult Adipose Mesenchymal Stem Cells into Retinal Progenitor Cells

Moviglia¹,

Blasetti²,

Zárate

et al. 2012

Ophthalmic Res

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Introduction: It has been previously shown that adult mesenchymal stem cells (MSCs) differentiate into neural progenitor cells (NPCs) and that the differentiation process was completed in 24–48 h. In this previous study, MSCs from a bone marrow or fat source were co-incubated with homologous autoaggressive cells (ECs) against nerve tissue, and these NPCs were successfully used in human regenerative therapeutic approaches. The present study was conducted to investigate whether a similar differentiation method could be used to obtain autologous retinal progenitor cells (RPCs). Methods: Human Th1 cells against retinal tissue were obtained by challenging human blood mononuclear cells with an eye lysate of bovine origin; negative selection was performed using a specific immunomagnetic bead cocktail. Fat MSCs were obtained from a human donor through mechanical and enzymatic dissociation of a surgical sample. The ECs and MSCs were co-cultured in a serum-free medium without the addition of cytokines for 0, 24, 48 and 72 h. The plastic adherent cells were morphologically examined using inverted-phase microscopy and characterized by immunofluorescent staining using antibodies against Pax 6, TUBB3, GFAP, Bestrophin 2, RPE 65, OPN1 SW, and rhodopsin antigens. Results: The early signs of MSC differentiation into RPCs were observed at 24 h of co-culture, and the early differentiated retinal linage cells appeared at 72 h (neurons, rods, Müller cells, retinal ganglion cells and retinal pigmented epithelial cells). These changes increased during further culture. Conclusion: The results reported here support the development of a method to obtain a large number of autologous adult RPCs, which could be used to treat different retinopathies.

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Section: Discussionsupporting

confidence: 76%

In vitro Differentiation of Adult Adipose Mesenchymal Stem Cells into Retinal Progenitor Cells

Moviglia¹,

Blasetti²,

Zárate

et al. 2012

Ophthalmic Res

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“…Interestingly, nestin-expressing microglia have been demonstrated to exist even in the naive brain, in variable cell numbers in the various regions analyzed (Takamori et al 2009). More recently, we have demonstrated that a subpopulation of retinal microglia expressing neural markers nestin, NG2 and vimentin also exists in the naive adult rat retina (Wohl et al 2011), displaying a similar subcellular distribution of nestin filaments as that recently reported for the brain (Takamori et al 2009). Following ON transection, the microglial fraction expressing nestin proliferates in situ and we therefore conclude that microglial nestin expression probably plays a role in the physiological self-renewal of this endogenous cell population (Wohl et al 2010;Wohl et al 2011).…”

Section: Retinal Microgliasupporting

confidence: 77%

“…More recently, we have demonstrated that a subpopulation of retinal microglia expressing neural markers nestin, NG2 and vimentin also exists in the naive adult rat retina (Wohl et al 2011), displaying a similar subcellular distribution of nestin filaments as that recently reported for the brain (Takamori et al 2009). Following ON transection, the microglial fraction expressing nestin proliferates in situ and we therefore conclude that microglial nestin expression probably plays a role in the physiological self-renewal of this endogenous cell population (Wohl et al 2010;Wohl et al 2011). Since increasing evidence suggests that CNS injury can induce neural progenitor characteristics in activated microglia of non-neurogenic regions in vivo (Wu et al 2005;Yokoyama et al 2006), we propose that this specific retinal microglial subpopulation acts as an endogenous neural progenitor-like cell after injury.…”

Section: Retinal Microgliasupporting

confidence: 77%

Cell-replacement therapy and neural repair in the retina

2012

Self Cite

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Visual impairment severely affects the quality of life of patients and their families and is also associated with a deep economic impact. The most common pathologies responsible for visual impairment and legally defined blindness in developed countries include age-related macular degeneration, glaucoma and diabetic retinopathy. These conditions share common pathophysiological features: dysfunction and loss of retinal neurons. To date, two main approaches are being taken to develop putative therapeutic strategies: neuroprotection and cell replacement. Cell replacement is a novel therapeutic approach to restore visual capabilities to the degenerated adult neural retina and represents an emerging field of regenerative neurotherapy. The discovery of a population of proliferative cells in the mammalian retina has raised the possibility of harnessing endogenous retinal stem cells to elicit retinal repair. Furthermore, the development of suitable protocols for the reprogramming of differentiated somatic cells to a pluripotent state further increases the therapeutic potential of stem-cell-based technologies for the treatment of major retinal diseases. Stem-cell transplantation in animal models has been most effectively used for the replacement of photoreceptors, although this therapeutic approach is also being used for inner retinal pathologies. In this review, we discuss recent advances in the development of cell-replacement approaches for the treatment of currently incurable degenerative retinal diseases.

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“…Additionally, the BM-derived microglia that repopulate the brain after irradiation and depletion also express the nestin protein. Nestin expression in microglia could be shown, for example, in early stages of optic nerve injury [70] and traumatic brain injury [71], which indicates that nestin may be required for proliferation rather than serving as a stem cell marker. Importantly, as the study by Bruttger et al (2013) used the promoter of CX 3 CR1 as a cell fate-mapping system, they show that all repopulating cells are derived from CX 3 CR1 expressing progenitor cells.…”

Section: Conditional Genetic Deletion Modelsmentioning

confidence: 99%

Homeostasis of Microglia in the Adult Brain: Review of Novel Microglia Depletion Systems

Waisman¹,

Ginhoux²,

Greter³

et al. 2015

Trends in Immunology

166

147

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In Situ Dividing and Phagocytosing Retinal Microglia Express Nestin, Vimentin, and NG2 In Vivo

Cited by 55 publications

References 93 publications

In vitro Differentiation of Adult Adipose Mesenchymal Stem Cells into Retinal Progenitor Cells

In vitro Differentiation of Adult Adipose Mesenchymal Stem Cells into Retinal Progenitor Cells

Cell-replacement therapy and neural repair in the retina

Homeostasis of Microglia in the Adult Brain: Review of Novel Microglia Depletion Systems

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