Abstract
Because folding of the cerebral cortex in the mammalian brain is believed to be crucial for higher brain functions, the mechanisms underlying its formation during development and evolution are of great interest. Although it has been proposed that increased neural progenitors in the subventricular zone (SVZ) are responsible for making cortical folds, their roles in cortical folding are still largely unclear, mainly because genetic methods for gyrencephalic mammals had been poorly available. Here, by taking an advantage of our newly developed in utero electroporation technique for the gyrencephalic brain of ferrets, we investigated the role of SVZ progenitors in cortical folding. We found regional differences in the abundance of SVZ progenitors in the developing ferret brain even before cortical folds began to be formed. When Tbr2 transcription factor was inhibited, intermediate progenitor cells were markedly reduced in the ferret cerebral cortex. Interestingly, outer radial glial cells were also reduced by inhibiting Tbr2. We uncovered that reduced numbers of SVZ progenitors resulted in impaired cortical folding. When Tbr2 was inhibited, upper cortical layers were preferentially reduced in gyri compared to those in sulci. Our findings indicate the biological importance of SVZ progenitors in cortical folding in the gyrencephalic brain.
Highlights
Folding of the cerebral cortex is a distinctive feature of the mammalian brain
Using our in utero electroporation (IUE) technique, we recently demonstrated that ectopic expression of FGF8 in the ferret cerebral cortex led to an increase in subventricular zone (SVZ) progenitors and polymicrogyria, suggesting that increased SVZ progenitors may underlie the formation of additional gyri[24]
Our findings indicate that SVZ progenitors are crucial for cortical folding in gyrencephalic mammals
Summary
Folding of the cerebral cortex is a distinctive feature of the mammalian brain. It has been believed that cortical folding underlies the acquisition of higher brain functions during development and evolution. Recent reports showed that despite lissencephalic cortical morphology, SVZ progenitors were observed with similar abundance in developing marmosets to those in the developing humans and ferrets[20,21], raising another hypothesis that the increase of SVZ progenitors is dispensable for cortical folding. These two hypotheses have not been addressed, mainly because in vivo genetic manipulations that can be applied to the cerebral cortex of gyrencephalic mammals had not been established. Our results indicate the biological importance of SVZ progenitors in cortical folding
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