Genoarchitectonic Compartmentalization of the Embryonic Telencephalon: Insights From the Domestic Cat

The telencephalon develops from the alar plate of the secondary prosencephalon and is subdivided into two distinct divisions, the pallium, which derives solely from prosomere hp1, and the subpallium which derives from both hp1 and hp2 prosomeres. In this first systematic analysis of the feline telencephalon genoarchitecture, we apply the prosomeric model to compare the expression of a battery of genes, including Tbr1, Tbr2, Pax6, Mash1, Dlx2, Nkx2-1, Lhx6, Lhx7, Lhx2, and Emx1, the orthologs of which alone or in combination, demarcate molecularly distinct territories in other species. We characterize, within the pallium and the subpallium, domains and subdomains topologically equivalent to those previously described in other vertebrate species and we show that the overall genoarchitectural map of the E26/27 feline brain is highly similar to that of the E13.5/E14 mouse. In addition, using the same approach at the earlier (E22/23 and E24/25) or later (E28/29 and E34/35) stages we further analyze neurogenesis, define the timing and duration of several developmental events, and compare our data with those from similar mouse studies; our results point to a complex pattern of heterochronies and show that, compared with the mouse, developmental events in the feline telencephalon span over extended periods suggesting that cats may provide a useful animal model to study brain patterning in ontogenesis and evolution.

Multiple Functions of the Dmrt Genes in the Development of the Central Nervous System

The Dmrt genes encode the transcription factor containing the DM (doublesex and mab-3) domain, an intertwined zinc finger-like DNA binding module. While Dmrt genes are mainly involved in the sexual development of various species, recent studies have revealed that Dmrt genes, which belong to the DmrtA subfamily, are differentially expressed in the embryonic brain and spinal cord and are essential for the development of the central nervous system. Herein, we summarize recent studies that reveal the multiple functions of the Dmrt genes in various aspects of vertebrate neural development, including brain patterning, neurogenesis, and the specification of neurons.

The Amyloid Precursor Protein regulates human cortical neurogenesis

The human neocortex has undergone significant expansion during evolution partially underlying increased human cognitive capacities. The 16 billion neurons of the human neocortex are derived from a limited number of cortical neural progenitor cells (NPCs). Human cortical NPCs initially generate neurons at a slow rate while preserving their progenitor state for a prolonged period, partly contributing to increased human cortical size. How the balance between the progenitor state and neurogenic state is regulated, and whether it contributes to species-specific brain patterning, is poorly understood. We find that the human Amyloid Precursor Protein (APP), whose mutations cause Alzheimer’s disease, specifically regulates this fine balance. Mechanistically, APP regulates these two aspects via two pathways: the AP1 transcription factor and the canonical Wnt pathway. We propose that APP is a homeostatic regulator of the neurogenic potential of cortical NPCs thus potentially contributing to human-specific patterns of neurogenesis.

Normative Brain Size Variation and the Remodeling of Brain Shape in Humans

Evolutionary and developmental increases in primate brain size have been accompanied by systematic shifts in the proportionality of different primate brain systems. However, it remains unknown if and how brain patterning varies across the more than 2-fold inter-individual variation in brain size that occurs amongst typically-developing humans. Using in vivo neuroimaging data from 2 independent cohorts totaling nearly 3000 individuals, we find that larger-brained humans show preferential areal expansion within specific fronto-parietal cortical networks (default mode, dorsal attentional) and related subcortical regions, at the expense of primary sensory/motor systems. This targeted areal expansion recapitulates cortical remodeling across evolution, manifests by early childhood and is linked to molecular signatures of heightened metabolic cost. Our results define a new organizing principle in human brain patterning which governs the highly-coordinated remodeling of human brain shape as a function of naturally-occurring variations in brain size.One Sentence SummaryA hodologically and metabolically expensive brain network is preferentially expanded in larger-brained humans.

foxQ2 evolved a key role in anterior head and central brain patterning in protostomes

Anterior patterning of animals is based on a set of highly conserved transcription factors but the interactions within the protostome anterior gene regulatory network (aGRN) remain enigmatic. Here, we identify the foxQ2 ortholog of the red flour beetle Tribolium castaneum as novel upstream component of the insect aGRN. It is required for the development of the labrum and higher order brain structures, namely the central complex and the mushroom bodies. We reveal Tc-foxQ2 interactions by RNAi and heat shock-mediated misexpression. Surprisingly, Tc-foxQ2 and Tc-six3 mutually activate each other forming a novel regulatory module at the top of the insect aGRN. Comparisons of our results with those of sea urchins and cnidarians suggest that foxQ2 has acquired functions in head and brain patterning during protostome evolution. Our findings expand the knowledge on foxQ2 gene function to include essential roles in epidermal development and central brain patterning.Author summaryThe development of the anterior most part of any animal embryo – for instance the brain of vertebrates and the head of insects – depends on a very similar set of genes present in all animals. This is true for the two major lineages of bilaterian animals, the deuterostomes (including sea urchin and humans) and protostomes (including annelids and insects) and the cnidarians (e.g. the sea anemone), which are representatives of more ancient animals. However, the interaction of these genes has been studied in deuterostomes and cnidarians but not in protostomes. Here, we present the first study the function of the gene foxQ2 in protostomes. We found that the gene acts at the top level of the genetic network and when its function is knocked down, the labrum (a part of the head) and higher order brain centers do not develop. This is in contrast to the other animal groups where foxQ2 appears to play a less central role. We conclude that foxQ2 has acquired additional functions in the course of evolution of protostomes.