Regulation of cerebral cortex size and folding by expansion of basal progenitors

Nonaka-Kinoshita, Miki; Reillo, Isabel; Artegiani, Benedetta; Martínez-Martínez, Maria Ángeles; Nelson, Mark L.; Borrell, Vı́ctor; Calegari, Federico

doi:10.1038/emboj.2013.96

Cited by 194 publications

(228 citation statements)

References 45 publications

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“…Nevertheless, the possibility 2821 RESEARCH REPORT Brain viral gene transfer of obtaining high and widespread infectivity and stable integration provides a practical and fast alternative to the generation of transgenic mice to investigate gene function during mammalian development. In fact, our laboratory has manipulated the same genes in neural stem cells by all three overexpression systems discussed in this study, with electroporation allowing the fast assessment of cellular effects in a small brain area, generation of transgenic mice extending this effect to the whole organ, and viral injection leading to qualitatively identical cellular effects with, in our conditions, phenotypes of even a greater magnitude than transgenic mice (Lange et al, 2009;Nonaka-Kinoshita et al, 2013).…”

Section: Lentiviruses Provide An Additional Powerful Resource To Manimentioning

confidence: 99%

Lentiviruses allow widespread and conditional manipulation of gene expression in the developing mouse brain

Artegiani

Calegari

2013

Development

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Generation of transgenic mice, in utero electroporation and viral injection are common approaches to manipulate gene expression during embryonic development of the mammalian brain. While very powerful in many contexts, these approaches are each characterized by their own limitations: namely, that generation of transgenic mice is time-consuming and electroporation only allows the targeting of a small area of the brain. Similarly, viral injection has been predominantly characterized by using retroviruses or adenoviruses that are limited by a relatively low infectivity or lack of integration, respectively. Here we report the use of integrating lentiviral vectors as a system to achieve widespread and efficient infection of the whole brain after in utero injection in the telencephalic ventricle of mouse embryos. In addition, we explored the use of Cre-mediated recombination of loxP-containing lentiviral vectors to achieve spatial and temporal control of gene expression of virtually any transgene without the need for generation of additional mouse lines. Our work provides a system to overcome the limitations of retroviruses and adenoviruses by achieving widespread and high efficiency of transduction. The combination of lentiviral injection and site-specific recombination offers a fast and efficient alternative to complement and diversify the current methodologies to acutely manipulate gene expression in developing mammalian embryos.

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Section: Lentiviruses Provide An Additional Powerful Resource To Manimentioning

confidence: 99%

Lentiviruses allow widespread and conditional manipulation of gene expression in the developing mouse brain

Artegiani

Calegari

2013

Development

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“…Elevated neurogenesis for enlargement of the CP is dependent on the absolute number of progenitors involved. The SVZ/OSVZ is the main regulator for neocortical expansion since this is the only region that expands over the course of neurogenesis in gyrencephalic species, and particularly extensively in primates (Nonaka-Kinoshita et al, 2013;Smart et al, 2002;Stahl et al, 2013). During cortical development, early-born neurons are generated by progenitors in the VZ at E11.5-13.5 and form deeper layers, including SP, layer VI and V (Haubensak et al, 2004;Price et al, 1997).…”

Section: Fetal Brain Oxygenation Is Essential For the Generation Of Cmentioning

confidence: 99%

“…This cell type undergoes self-renewing divisions to generate new OSVZ progenitor cells and is able to produce IPs. Interestingly, it is known that the development of this recently identified proliferative zone is responsible for the differences in brain size among mammalian species (Kriegstein et al, 2006;Nonaka-Kinoshita et al, 2013;Stahl et al, 2013). The abundance of this progenitor population is expanded in gyrencephalic species (such as primates and ferrets) and correlates with higher complexity of cortical architecture (Fietz et al, 2010;Reillo et al, 2011;Smart et al, 2002).…”

Section: Introductionmentioning

confidence: 99%

Brain oxygen tension controls the expansion of outer subventricular zone-like basal progenitors in the developing mouse brain

et al. 2015

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The mammalian neocortex shows a conserved six-layered structure that differs between species in the total number of cortical neurons produced owing to differences in the relative abundance of distinct progenitor populations. Recent studies have identified a new class of proliferative neurogenic cells in the outer subventricular zone (OSVZ) in gyrencephalic species such as primates and ferrets. Lissencephalic brains of mice possess fewer OSVZ-like progenitor cells and these do not constitute a distinct layer. Most in vitro and in vivo studies have shown that oxygen regulates the maintenance, proliferation and differentiation of neural progenitor cells. Here we dissect the effects of fetal brain oxygen tension on neural progenitor cell activity using a novel mouse model that allows oxygen tension to be controlled within the hypoxic microenvironment in the neurogenic niche of the fetal brain in vivo. Indeed, maternal oxygen treatment of 10%, 21% and 75% atmospheric oxygen tension for 48 h translates into robust changes in fetal brain oxygenation. Increased oxygen tension in fetal mouse forebrain in vivo leads to a marked expansion of a distinct proliferative cell population, basal to the SVZ. These cells constitute a novel neurogenic cell layer, similar to the OSVZ, and contribute to corticogenesis by heading for deeper cortical layers as a part of the cortical plate.

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“…Recent studies indicate that cells with one radial process projecting to the pial surface play a key role in producing folds. In the neocortex of gyrencephalic mammals, basal radial glial cells seem to be responsible for the formation of the folds, or gyri and sulci (Nonaka-Kinoshita et al, 2013;Stahl et al, 2013). In the cerebellar cortex of mice, the base of each fissure that separates two folds (folia) has a distinct cellular organization of Bergmann glial radial fibers and associated granule cell progenitors (gcps), referred to as anchoring centers (see Fig.…”

Section: Introductionmentioning

confidence: 99%

Clonal analysis reveals granule cell behaviors and compartmentalization that determine the folded morphology of the cerebellum

2015

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The mammalian cerebellum consists of folds of different sizes and shapes that house distinct neural circuits. A crucial factor underlying foliation is the generation of granule cells (gcs), the most numerous neuron type in the brain. We used clonal analysis to uncover global as well as folium size-specific cellular behaviors that underlie cerebellar morphogenesis. Unlike most neural precursors, gc precursors divide symmetrically, accounting for their massive expansion. We found that oriented cell divisions underlie an overall anteroposteriorly polarized growth of the cerebellum and gc clone geometry. Clone geometry is further refined by mediolateral oriented migration and passive dispersion of differentiating gcs. Most strikingly, the base of each fissure acts as a boundary for gc precursor dispersion, which we propose allows each folium to be regulated as a developmental unit. Indeed, the geometry and size of clones in long and short folia are distinct. Moreover, in engrailed 1/2 mutants with shorter folia, clone cell number and geometry are most similar to clones in short folia of wild-type mice. Thus, the cerebellum has a modular mode of development that allows the plane of cell division and number of divisions to be differentially regulated to ensure that the appropriate number of cells are partitioned into each folium.

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Regulation of cerebral cortex size and folding by expansion of basal progenitors

Cited by 194 publications

References 45 publications

Lentiviruses allow widespread and conditional manipulation of gene expression in the developing mouse brain

Lentiviruses allow widespread and conditional manipulation of gene expression in the developing mouse brain

Brain oxygen tension controls the expansion of outer subventricular zone-like basal progenitors in the developing mouse brain

Clonal analysis reveals granule cell behaviors and compartmentalization that determine the folded morphology of the cerebellum

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