Brain regionalization by Polycomb-group proteins and chromatin accessibility.

During brain development, neural precursor cells (NPCs) in different brain regions produce different types of neurons, and each of these regions plays a different role in the adult brain. Therefore, precise regionalization is essential in the early stages of brain development, and irregular regionalization has been proposed as the cause of neurodevelopmental disorders. The mechanisms underlying brain regionalization have been well studied in terms of morphogen-induced expression of critical transcription factors for regionalization. NPC potential in different brain regions is defined by chromatin structures that regulate the plasticity of gene expression. Herein, we present recent findings on the importance of chromatin structure in brain regionalization, particularly with respect to its regulation by Polycomb-group proteins and chromatin accessibility.

Radial glia fibers translate Fgf8 morphogenetic signals to generate a thalamic nuclear complex protomap in the mantle layer.

Thalamic neurons are distributed between different nuclear groups of the thalamic multinuclear complex; they develop topologically ordered specific projections that convey information on voluntary motor programs and sensory modalities to functional areas in the cerebral cortex. Since thalamic neurons present a homogeneous morphology, their functional specificity is derived from their afferent and efferent connectivity. Adequate development of thalamic afferent and efferent connections depends on guide signals that bind receptors in nuclear neuropils and axonal growth cones, respectively. These are finally regulated by regionalization processes in the thalamic neurons, codifying topological information. In this work, we studied the role of Fgf8 morphogenetic signaling in establishing the molecular thalamic protomap, which was revealed by Igsf21, Pde10a and Btbd3 gene expression in the thalamic mantle layer. Fgf8 signaling activity was evidenced by pERK expression in radial glia cells and fibers, which may represent a scaffold that translates neuroepithelial positional information to the mantle layer. In this work, we describe the fact that Fgf8-hypomorphic mice did not express pERK in radial glia cells and fibers and presented disorganized thalamic regionalization, increasing neuronal death in the ventro-lateral thalamus and strong disruption of thalamocortical projections. In conclusion, Fgf8 encodes the positional information required for thalamic nuclear regionalization and the development of thalamocortical projections.

Comprehensive analysis of target genes in zebrafish embryos reveals gbx2 involvement in neurogenesis.

It is well established that the gbx2 homeobox gene contributes to the positioning of the midbrain-hindbrain boundary (MHB) governing the development of adjacent brain regions in vertebrate embryos, but the specific aspects of the gene regulatory network regulated by gbx2 during brain development remain unclear. In the present study, we sought to comprehensively identify gbx2 target genes in zebrafish embryos by microarray analysis around the end of gastrulation, when the MHB is established, using transgenic embryos harboring heat-inducible gbx2. This analysis revealed that a large number of genes were either upregulated or downregulated following gbx2 induction, and the time course of induction differed depending on the genes. The differences in response to gbx2 were found by functional annotation analysis to be related to the functions and structures of the target genes. Among the significantly downregulated genes was her5, whose expression in the midbrain was precisely complementary to gbx2 expression around the MHB, suggesting that gbx2 expression in the anterior hindbrain restricts her5 expression to the midbrain. Because her5 represses neurogenesis, gbx2 may positively regulate neural development in its expression domain. Indeed, we showed further that gbx2 induction upregulated neural marker expression in the midbrain. Quantitative PCR analysis revealed that gbx2 upregulated the expression of the zebrafish proneural gene ebf2, whereas it repressed notch1a, which generally represses neurogenesis. Taken together, these results demonstrate that gbx2 not only functions to position the MHB but also regulates neurogenesis in the anterior hindbrain.

Mathematical Model of Evolution of Brain Parcellation.

We study the distribution of brain and cortical area sizes [parcellation units (PUs)] obtained for three species: mouse, macaque, and human. We find that the distribution of PU sizes is close to lognormal. We propose the mathematical model of evolution of brain parcellation based on iterative fragmentation and specialization. In this model, each existing PU has a probability to be split that depends on PU size only. This model suggests that the same evolutionary process may have led to brain parcellation in these three species. Within our model, region-to-region (macro) connectivity is given by the outer product form. We show that most experimental data on non-zero macaque cortex macroscopic-level connections can be explained by the outer product power-law form suggested by our model (62% for area V1). We propose a multiplicative Hebbian learning rule for the macroconnectome that could yield the correct scaling of connection strengths between areas. We thus propose an evolutionary model that may have contributed to both brain parcellation and mesoscopic level connectivity in mammals.