Generation of a ciliary margin-like stem cell niche from self-organizing human retinal tissue

Kuwahara, Atsushi; Ozone, Chikafumi; Nakano, Tokushige; Saito, Koichi; Eiraku, Mototsugu; Sasai, Yoshiki

doi:10.1038/ncomms7286

Cited by 278 publications

(349 citation statements)

References 66 publications

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“…Furthermore, the timing of neural differentiation seems to be species-specific, as seen in vivo, as illustrated by the slower neural maturation of hESCs compared with primate ESCs (Otani et al, 2016) and by the faster in vitro differentiation of mouse cells into neurons compared with human cells (Wichterle et al, 2002). In the case of the optic cup discussed earlier, it took much longer to form organoids from human cells than from mouse cells (Kuwahara et al, 2015), again reflecting the relative developmental timing of these species. One is tempted to speculate that timing is independent from one tissue to another, supported by the observation that developmental compensation time in the mouse is not the same for each organ, as discussed above (Kojima et al, 2014).…”

Section: Size Control and Scalingmentioning

confidence: 90%

“…Importantly, this organoid formed without external scaffolding or mechanics, further demonstrating the innate ability of cells to self-generate functional multicellular structures. This approach was later adapted for making retinal tissue from human ESCs (hESCs) (Kuwahara et al, 2015). More recently, it was shown that human optic cup organoids engrafted onto injured eyes in primates continue to differentiate into a variety of retinal cell types, even creating synaptic contacts with the host (Shirai et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Embryoids, organoids and gastruloids: new approaches to understanding embryogenesis

2017

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Cells have an intrinsic ability to self-assemble and self-organize into complex and functional tissues and organs. By taking advantage of this ability, embryoids, organoids and gastruloids have recently been generated in vitro, providing a unique opportunity to explore complex embryological events in a detailed and highly quantitative manner. Here, we examine how such approaches are being used to answer fundamental questions in embryology, such as how cells selforganize and assemble, how the embryo breaks symmetry, and what controls timing and size in development. We also highlight how further improvements to these exciting technologies, based on the development of quantitative platforms to precisely follow and measure subcellular and molecular events, are paving the way for a more complete understanding of the complex events that help build the human embryo.

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Section: Size Control and Scalingmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Embryoids, organoids and gastruloids: new approaches to understanding embryogenesis

2017

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“…4B). Another aspect of the selforganizing property of retinal development from human PSCs was demonstrated more recently (Kuwahara et al, 2015), in which a specific stem cell niche called the retinal ciliary margin (RCM) (Agathocleous and Harris, 2009),which is located at the boundary of the NR and RPE, could be generated in vitro and displayed the potential to produce retinal progenitors, which in turn generate various retinal subtypes including photoreceptors (Fig. 4C).…”

Section: The Retinamentioning

confidence: 99%

“…4B) (Ader and Tanaka, 2014;Eiraku et al, 2011;Kuwahara et al, 2015;Nakano et al, 2012;Sasai et al, 2012). Initial retinal regional specification is achieved using culture with morphogen inhibitors such as Nodal for mouse PSCs and Wnt inhibitor for human PSCs, in the presence of basement membrane matrix components (Matrigel) (Nakano et al, 2012).…”

Section: The Retinamentioning

confidence: 99%

Is this a brain which I see before me? Modeling human neural development with pluripotent stem cells

Suzuki

Vanderhaeghen

2015

Development

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The human brain is arguably the most complex structure among living organisms. However, the specific mechanisms leading to this complexity remain incompletely understood, primarily because of the poor experimental accessibility of the human embryonic brain. Over recent years, technologies based on pluripotent stem cells (PSCs) have been developed to generate neural cells of various types. While the translational potential of PSC technologies for disease modeling and/or cell replacement therapies is usually put forward as a rationale for their utility, they are also opening novel windows for direct observation and experimentation of the basic mechanisms of human brain development. PSC-based studies have revealed that a number of cardinal features of neural ontogenesis are remarkably conserved in human models, which can be studied in a reductionist fashion. They have also revealed species-specific features, which constitute attractive lines of investigation to elucidate the mechanisms underlying the development of the human brain, and its link with evolution.

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“…114,124 Formation of a ciliary margin stem cell niche in 3D optic vesicles was recently shown to expand the generation of the retinal progenitor cell population in vitro. 125 Further definition of conditions that expand progenitor populations committed to produce rod or cone photoreceptors would be very useful. A recent study demonstrated enrichment of ESC-derived cone photoreceptors using a new protocol inhibiting bone morphogenetic protein (BMP), transforming growth factor beta (TGFb), and Wnt signaling.…”

Section: Yield and Puritymentioning

confidence: 99%

Induced Pluripotent Stem Cell Therapies for Degenerative Disease of the Outer Retina: Disease Modeling and Cell Replacement

Foggia

Makwana

Ali³

et al. 2016

Journal of Ocular Pharmacology and Therapeutics

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Stem cell therapies are being explored as potential treatments for retinal disease. How to replace neurons in a degenerated retina presents a continued challenge for the regenerative medicine field that, if achieved, could restore sight. The major issues are: (i) the source and availability of donor cells for transplantation; (ii) the differentiation of stem cells into the required retinal cells; and (iii) the delivery, integration, functionality, and survival of new cells in the host neural network. This review considers the use of induced pluripotent stem cells (iPSC), currently under intense investigation, as a platform for cell transplantation therapy. Moreover, patientspecific iPSC are being developed for autologous cell transplantation and as a tool for modeling specific retinal diseases, testing gene therapies, and drug screening.

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Generation of a ciliary margin-like stem cell niche from self-organizing human retinal tissue

Cited by 278 publications

References 66 publications

Embryoids, organoids and gastruloids: new approaches to understanding embryogenesis

Embryoids, organoids and gastruloids: new approaches to understanding embryogenesis

Is this a brain which I see before me? Modeling human neural development with pluripotent stem cells

Induced Pluripotent Stem Cell Therapies for Degenerative Disease of the Outer Retina: Disease Modeling and Cell Replacement

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