Cortical stem cell growth The FOXG1 protein is widely expressed in the brain and is crucial for
cortical development (the process by which the cerebral cortex is formed in mammals). One of FOXG1's key functions is regulating the cell cycle of neural
progenitor cells by promoting proliferation and preventing premature neural differentiation. Loss of FOXG1 results in a longer
cell cycle and neural stem cells leave the cell cycle too early, leading to fewer new
brain cells being made. FOXG1 counteracts the FOXO/SMAD pathway, which normally stimulates cortical neuron differentiation. Through this counteraction, FOXG1 reduces the expression of p21, a low level of
p21 contributes to the expansion of the neural stem cell pool and prevents early cell cycle exit.
Induction of cortical laminar subtypes by FOXG1 -expressing layer 1/6 neurons and switches to producing FEZF2/CTIP2-expressing layer 5 neurons. Later, in early postmitotic neurons, FOXG1 inhibits
COUP-TFI, shifting neuronal production from
RORβ-expressing layer 4 neurons to
SATB2/
BRN2-expressing layer 2/3
neurons. FOXG1 is also involved in dorsoventral patterning (the process by which embryonic stem cells adopt different fates depending on their location) of the
telencephalon, helping to establish future compartments and specify cell types through widespread changes in
gene expression. Future compartments and specify cell types through widespread changes in gene expression. The activation of FOXG1 and the early patterning of the forebrain seems to be primarily maintained across vertebrates, where compartmentalization of the forebrain is established by cooperative interactions between
morphogens and
transcription factors. In the telencephalic territory,
SIX3 expressed in the
anterior neural plate, which competes with FOXG1 expression, whereby
FGF8 which is expressed in the anterior
neural ridge induces FOXG1 and helps to organize the telencephalic region. When the telencephalon's compartments have been established, FOXG1 regulates neuron specification.
Progenitor cells divide asymmetrically and begin producing TBR1-expressing neurons, which become layer 1 and layer 6 neurons at the surface and the deepest regions of the
cortical plate. Progenitor cells further produce layer 5 FEZF2- and
BCL11B/
CTIP2-expressing corticospinal projection cells, followed by
RORβ-expressing sensory input cells, and then layer 2/3
SATB2 and
POU3F2/
BRN2-expressing callosal projection neurons. These neurons merge into the cortical plate through an inside-out layering pattern, where more recently generated neurons migrate past those that were born earlier, settling in the surface region. Notably, while FOXG1 is expressed in many of the cortical progenitor cells and neurons, its function differs between subtypes and varies in a spatiotemporal manner (by progenitor cell proliferation and neuronal differentiation mechanism) (
spatiotemporal gene expression is the process by which genes in particular organ tissues become active at particular
stages of development) . The onset of FOXG1 expression in progenitor cells ends the production of the earliest born
neurons, in other words,
Cajal-Retzius cells, through direct suppression of a major transcriptional network. This network comprises, as shown by
transcriptome analysis and FOXG1-
ChIP sequencing,
TBR1, DMRTA1, EBF2, and EBF3. The timely negative regulation of FOXG1 by
EGR2, a target of
TGFβ, occurs in the lower intermediate zone where cells are shifting out of the cell cycle, leading to the activation of
Nr2f1/
COUP-TFI, which enables layer 4 cell competence. In contrast, the absence of EGR2 target sites raises Foxg1 expression and paves the way for the development of
SATB2/
BRN2-positive callosal projection neurons (neurons which connect both brain hemispheres via
corpus callosum). Since FOXG1
haploinsufficiency leads to
agenesis of the corpus callosum in both humans and mice due to impaired upper-layer projection neuron development, these findings suggest that having two functional copies of the Foxg1 gene is essential for regulating the production of cortical neurons and the development of
axons necessary for the formation of cortical circuits typical of FOXG1 disorders.
Role of FOXG1 in neural plasticity According to one study, FOXG1 is expressed in both the region where
neurogenesis takes place and differentiated neurons of the adult cerebral cortex, indicating its roles in cognitive skill and neural plasticity (neurogenesis is the process when new brain cells are formed). By altering the expression levels of FOXG1 in primary cultured neurons influences the development of dendrites, with increased levels of FOXG1 leading to increased dendritic length and branching of
neurites, partly by positive regulatory mechanisms of
HES1 and
CREB1 gene expression. In the adult
hippocampus, a reduction in FOXG1 gene dosage results in a gradual decline in the quantity of
dentate granule cells. Consequently, in FOXG1 syndrome, these mechanism (as mentioned above) are disrupted. == Treatment ==