A major cause of the cerebral cortex expansion that occurred during evolution is the increase in subventricular zone (SVZ) progenitors. We found that progenitors in the outer SVZ (OSVZ) of developing human neocortex retain features of radial glia, in contrast to rodent SVZ progenitors, which have limited proliferation potential. Although delaminating from apical adherens junctions, OSVZ progenitors maintained a basal process contacting the basal lamina, a canonical epithelial property. OSVZ progenitor divisions resulted in asymmetric inheritance of their basal process. Notably, OSVZ progenitors are also found in the ferret, a gyrencephalic nonprimate. Functional disruption of integrins, expressed on the basal process of ferret OSVZ progenitors, markedly decreased the OSVZ progenitor population size, but not that of other, process-lacking SVZ progenitors, in slice cultures of ferret neocortex. Our findings suggest that maintenance of this epithelial property allows integrin-mediated, repeated asymmetric divisions of OSVZ progenitors, providing a basis for neocortical expansion.
The expansion of the neocortex during mammalian brain evolution results primarily from an increase in neural progenitor cell divisions in its two principal germinal zones during development, the ventricular zone (VZ) and the subventricular zone (SVZ). Using mRNA sequencing, we analyzed the transcriptomes of fetal human and embryonic mouse VZ, SVZ, and cortical plate. In mouse, the transcriptome of the SVZ was more similar to that of the cortical plate than that of the VZ, whereas in human the opposite was the case, with the inner and outer SVZ being highly related to each other despite their cytoarchitectonic differences. We describe sets of genes that are up-or down-regulated in each germinal zone. These data suggest that cell adhesion and cell-extracellular matrix interactions promote the proliferation and self-renewal of neural progenitors in the developing human neocortex. Notably, relevant extracellular matrix-associated genes include distinct sets of collagens, laminins, proteoglycans, and integrins, along with specific sets of growth factors and morphogens. Our data establish a basis for identifying novel cell-type markers and open up avenues to unravel the molecular basis of neocortex expansion during evolution.cerebral cortex | neural stem cells | neurogenesis N eocortex expansion is a hallmark of mammalian brain evolution. With regard to neuron number, a major cause of this expansion is the increase in the population size of neural stem and progenitor cells (NSPCs) and the number of divisions that each of the various NSPC types undergoes during cortical development (1-4). Two principal classes of these cells can be distinguished based on the location of their mitosis: (i) apical progenitors (APs), which undergo mitosis at the luminal surface of the ventricular zone (VZ); and (ii) basal progenitors (BPs), which undergo mitosis at an abventricular location, typically in the subventricular zone (SVZ) (2, 5, 6). Neurons born from AP and BP cell divisions migrate radially and settle at the basal (pial) side of the developing cortical wall to form the cortical plate (CP).Both APs and BPs comprise several types of NSPCs that differ in key cell biological features (e.g., cell polarity, cell processes, cell-to-cell junctions, nuclear migration) and in the principal modes of cell division (symmetric proliferative vs. asymmetric self-renewing vs. symmetric or asymmetric consumptive) (2, 5-10). APs comprise neuroepithelial cells, which transform into apical radial glial cells (aRGCs) at the onset of neurogenesis (11), and short neural precursors (12). BPs include basal (or outer) radial glial cells (bRGCs), transit amplifying progenitors (TAPs), and intermediate progenitor cells (IPCs) (2, 3, 13).The evolutionary expansion of the neocortex is associated with an increase in the thickness of the SVZ, which develops into two cytoarchitecturally distinct zones, an inner SVZ (ISVZ) and an outer SVZ (OSVZ) (1-4, 14, 15). The evolutionary increase in the SVZ is accompanied by a change in the proportion of BP subtypes. Fo...
RNA interference (RNAi)-based strategies that mediate the specific knockdown of target genes by administration of small interfering RNAs (siRNAs) could be applied for treatment of presently incurable neurodegenerative diseases such as Parkinson’s disease. However, inefficient delivery of siRNA into neurons hampers in vivo application of RNAi. We have previously established the 4–12 kDa branched polyethylenimine (PEI) F25-LMW with superior transfection efficacy for delivery of siRNA in vivo. Here, we present that siRNA complexed with this PEI extensively distributes across the CNS down to the lumbar spinal cord after a single intracerebroventricular infusion. siRNA against α-synuclein (SNCA), a pre-synaptic protein that aggregates in Parkinson’s disease, was complexed with PEI F25-LMW and injected into the lateral ventricle of mice overexpressing human wild-type SNCA (Thy1-aSyn mice). Five days after the single injection of 0.75 μg PEI/siRNA, SNCA mRNA expression in the striatum was reduced by 65%, accompanied by reduction of SNCA protein by ∼50%. Mice did not show signs of toxicity or adverse effects. Moreover, ependymocytes and brain parenchyma were completely preserved and free of immune cell invasion, astrogliosis, or microglial activation. Our results support the efficacy and safety of PEI nanoparticle-mediated delivery of siRNA to the brain for therapeutic intervention.
A hallmark of mammalian brain evolution is the emergence of the neocortex, which has expanded in all mammalian infraclasses (Eutheria, Marsupialia, Monotremata). In eutherians, neocortical neurons derive from distinct neural stem and progenitor cells (NPCs). However, precise data on the presence and abundance of the NPCs, especially of basal radial glia (bRG), in the neocortex of marsupials are lacking. This study characterized and quantified the NPCs in the developing neocortex of a marsupial, the tammar wallaby (Macropus eugenii). Our data demonstrate that its neocortex is characterized by high NPC diversity. Importantly, we show that bRG exist at high relative abundance in the tammar indicating that this cell type is not specific to the eutherian neocortex and that similar mechanisms may underlie the formation of an expanded neocortex in eutherian and marsupial mammals. We also show that bRG are likely to have been present in the therian ancestor, so did not emerge independently in the eutherian and marsupial lineages. Moreover, our data support the concept that changes in multiple parameters contribute to neocortex expansion and demonstrate the importance of bRG and other NPCs for the development and expansion of the mammalian neocortex.
The neocortex plays a key role in cognition, volitional motor control and sensory perception and has undergone tremendous expansion during evolution. The mature neocortex consists of radially aligned neurons that are arranged in six layers. Layers II-VI are often split into two groups: deep and upper layers, both building up the so-called cortical plate during embryonic and foetal development. So far cortical neurogenesis, including the generation of deep and upper layers, has mostly been studied in laboratory rodents and primates. However, precise data for most companion animals are lacking. This study determined the main period of neurogenesis, specifically the timing of deep and upper layer generation, in the developing domestic cat, pig and sheep neocortex using immunohistochemistry for specific neuronal markers, that is Tbr1 and Brn2. We found that the general sequence of neural events is preserved among cat, pig, sheep and other mammalian species. However, we observed differences in the timing of the overall cortical neurogenic period and occurrence of distinct neural events when these three species were compared. Moreover, our data provide further evidence that the cortical neurogenic period and gestation length might be tightly related. Together, these data expand our current understanding of neocortex development and are important for future studies investigating neocortex development and expansion especially in companion animals.
The neocortex is the most complex part of the mammalian brain and as such it has undergone tremendous expansion during evolution, especially in primates. The majority of neocortical neurons originate from distinct neural stem and progenitor cells (NPCs) located in the ventricular and subventricular zone (SVZ). Previous studies revealed that the SVZ thickness as well as the abundance and distribution of NPCs, especially that of basal radial glia (bRG), differ markedly between the lissencephalic rodent and gyrencephalic primate neocortex. The northern tree shrew (Tupaia belangeri) is a rat-sized mammal with a high brain to body mass ratio, which stands phylogenetically mid-way between rodents and primates. Our study provides – for the first time – detailed data on the presence, abundance and distribution of bRG and other distinct NPCs in the developing neocortex of the northern tree shrew (Tupaia belangeri). We show that the developing tree shrew neocortex is characterized by an expanded SVZ, a high abundance of Pax6+ NPCs in the SVZ, and a relatively high percentage of bRG at peak of upper-layer neurogenesis. We further demonstrate that key features of tree shrew neocortex development, e.g., the presence, abundance and distribution of distinct NPCs, are closer related to those of gyrencephalic primates than to those of ferret and lissencephalic rodents. Together, our study provides novel insight into the evolution of bRG and other distinct NPCs in the neocortex development of Euarchontoglires and introduces the tree shrew as a potential novel model organism in the area of human brain development and developmental disorders.
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