Identification of new genes that control neurogenesis in the cerebral cortex

Van Den Ameele, Jelle

20 May 2014

The cerebral cortex is one of the most complex and divergent of all biological structures and is composed of hundreds of different types of highly interconnected neurons. This complexity underlies its ability to perform exceedingly complex neural processes. One of the most important questions in developmental neurobiology is how such a vast degree of diversity and specificity is achieved during embryogenesis. Furthermore, understanding the cellular and genetic basis of cortical development may yield insights into the mechanisms underlying human disorders such as mental retardation, autism, epilepsies and brain tumors. <p>During this Phd-project, we set out to identify novel transcription factors involved in cortical neurogenesis. Therefore, we initially took advantage of a model of in vitro embryonic stem cell (ESC)-derived corticogenesis that was previously established in the lab (Gaspard et al. 2008) and from several previously generated ESC lines that allow overexpression of specific transcription factors potentially involved in corticogenesis (van den Ameele et al. 2012). <p>Among the genes tested, Bcl6, a B-cell lymphoma oncogene known to be expressed during cortical development but without well-characterized function in this context, displayed a strong proneurogenic activity and thus became the main focus of this thesis. <p><p>During neurogenesis, neural stem/progenitor cells (NPCs) undergo an irreversible fate transition to become neurons. The Notch pathway is well known to be important for this process, and repression of Notch-dependent Hes genes is essential for triggering differentiation. However, Notch signalling often remains active throughout neuronal differentiation, implying a change in the transcriptional responsiveness to Notch during the neurogenic transition.<p>We showed that Bcl6 starts to be expressed specifically during the transition from progenitors to postmitotic neurons and is required for proper neurogenesis of the mouse cerebral cortex. Bcl6 promotes this neurogenic conversion by switching the composition of Notch-dependent transcriptional complexes at the Hes5 promoter. Bcl6 triggers exclusion of the co-activator Mastermind-like 1 and recruitment of the NAD+-dependent deacetylase Sirt1, which we showed to be required for Bcl6-dependent neurogenesis in vitro. The resulting epigenetic silencing of Hes5 leads to neuronal differentiation despite active Notch signalling. These findings thus suggest a role for Bcl6 as a novel proneurogenic factor and uncover Notch-Bcl6-Sirt1 interactions that may affect other aspects of physiology and disease (Tiberi et al. 2012a). <p><p>A subsequent yet unpublished part of this Phd-project focused on unraveling roles for Bcl6 in regionalization of the cerebral cortex. In all mammals, the three major areas of the neocortex are the motor, somatosensory and visual areas, each subdivided in secondary domains and complemented with species-specific additional areas. All these domains comprise of neurons with different functionality, molecular profiles, electrical activity and connectivity. Spatial patterning of the cortex is mainly under the control of diffusible molecules produced by organizing centers, but is also regulated by intrinsic, cell-autonomous programs (Tiberi et al. 2012b). <p>Since Bcl6 expression is confined to frontal and parietal regions of the developing cerebral cortex and remains high in postmitotic neurons, also after completion of neurogenesis, we hypothesized it would be involved in acquisition of motor and somatosensory identity. As expected from the neurogenesis defect in these regions, we observed a trend towards a reduced size of the frontal areas in the Bcl6 mutant cortex. Preliminary data from cDNA microarray profiling after gain- and loss-of-function of Bcl6 and from in situ hybridization on mouse cortex however do not show dramatic changes in molecular markers of different cortical areas. Similarly, the coarse-grained pattern of thalamocortical and efferent projections of motor and somatosensory neurons appears to be spared. These preliminary findings thus suggest that Bcl6 is not strictly required for proper acquisition of motor and somatosensory areal identity. / Doctorat en Sciences médicales / info:eu-repo/semantics/nonPublished

Médecine pathologie humaine

Cerebral cortex -- Growth

Developmental neurobiology

Cortex cérébral -- Croissance

Neurologie du développement

Neurogenesis

Hes5

Notch

Sirt1

Bcl6

cerebral cortex

Areal patterning

Eomes

Mesp1

cardiac differentiation

embryonic stem cell

Expression of histone deacetylase enzymes in murine and chick optic nerve

Tiwari, Sarika

January 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Epigenetic alterations have been shown to control cell type specification and differentiation leading to the changes in chromatin structure and organization of many genes. HDACs have been well documented to play an important role in both neurogenesis and gliogenesis in ganglionic eminence and cortex-derived cultures. However, the role of HDACs in glial cell type specification and differentiation in the optic nerve has not been well described. As a first step towards understanding their role in glial cell type specification, we have examined histone acetylation and methylation levels as well as the expression levels and patterns of the classical HDACs in both murine and chick optic nerve. Analysis of mRNA and protein levels in the developing optic nerve indicated that all 11 members of the classical HDAC family were expressed, with a majority declining in expression as development proceeded. Based on the localization pattern in both chick and murine optic nerve glial cells, we were able to group the classical HDACs: predominantly nuclear, nuclear and cytoplasmic, predominantly cytoplasmic. Nuclear expression of HDACs during different stages of development studied in this project in both murine and chick optic nerve glial cells suggests that HDACs play a role in stage-dependent changes in gene expression that accompany differentiation of astrocytes and oligodendrocytes. Examination of localization pattern of the HDACs is the first step towards identifying the specific HDACs involved directly in specification and differentiation of glia in optic nerve.

Epigenetics

Epigenetics -- Research -- Analysis

Enzymes -- Analysis

Optic nerve -- Research -- Development

Neuroglia -- Research -- Analysis

Chicks -- Research -- Analysis

Chromatin

Gene expression -- Research

Cerebral cortex -- Growth

Nervous system -- Regeneration

Acetylation -- Research

Methylation -- Research

Astrocytes

Messenger RNA

Genetic markers

Developmental neurobiology