Bridget E. LaMonica scite author profile

A hallmark of mammalian brain evolution is cortical expansion, which reflects an increase in the number of cortical neurons established by the progenitor cell subtypes present and the number of their neurogenic divisions. Recent studies have revealed a new class of radial glia-like (oRG) progenitor cells in the human brain, which reside in the outer subventricular zone. Expansion of the subventricular zone and appearance of oRG cells may have been essential evolutionary steps leading from lissencephalic to gyrencephalic neocortex. Here we show that oRG-like progenitor cells are present in the mouse embryonic neocortex. They arise from asymmetric divisions of radial glia and undergo self-renewing asymmetric divisions to generate neurons. Moreover, mouse oRG cells undergo mitotic somal translocation whereby centrosome movement into the basal process during interphase preceeds nuclear translocation. Our finding of oRG cells in the developing rodent brain fills a gap in our understanding of neocortical expansion.

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Mitotic spindle orientation predicts outer radial glial cell generation in human neocortex

LaMonica

et al. 2013

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The human neocortex is increased in size and complexity as compared to most other species. Neocortical expansion has recently been attributed to protracted neurogenesis by outer radial glial (oRG) cells in the outer subventricular zone (oSVZ), a region present in humans but not in rodents. The mechanisms of human oRG cell generation are unknown, but are proposed to involve division of ventricular radial glial (vRG) cells; neural stem cells present in all developing mammals. Here we show that human vRG cells produce oRG cells and seed formation of the oSVZ via horizontal divisions, which occur more frequently in humans than in rodents. We further find that oRG cell mitotic behavior is cell intrinsic, and that the basal fiber, inherited by oRG cells after vRG division, determines cleavage angle. Our results suggest that altered regulation of mitotic spindle orientation increased oRG cell numbers, and ultimately neuronal numbers, during human brain evolution.

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Diverse Behaviors of Outer Radial Glia in Developing Ferret and Human Cortex

et al. 2014

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The dramatic increase in neocortical size and folding during mammalian brain evolution has been attributed to the elaboration of the subventricular zone (SVZ) and the associated increase in neural progenitors. However, recent studies have shown that SVZ size and the abundance of resident progenitors do not directly predict cortical topography, suggesting that complex behaviors of the progenitors themselves may contribute to the overall size and shape of the adult cortex. Using time-lapse imaging, we examined the dynamic behaviors of SVZ progenitors in the ferret, a gyrencephalic carnivore, focusing our analysis on outer radial glial cells (oRGs). We identified a substantial population of oRGs by marker expression and their unique mode of division, termed mitotic somal translocation (MST). Ferret oRGs exhibited diverse behaviors in terms of division location, cleavage angle, and MST distance, as well as fiber orientation and dynamics. We then examined the human fetal cortex and found that a subset of human oRGs displayed similar characteristics, suggesting that diversity in oRG behavior may be a general feature. Similar to the human, ferret oRGs underwent multiple rounds of self-renewing divisions but were more likely to undergo symmetric divisions that expanded the oRG population, as opposed to producing intermediate progenitor cells (IPCs). Differences in oRG behaviors, including proliferative potential and daughter cell fates, may contribute to variations in cortical structure between mammalian species.

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