Absence of the transcription factor <i>Nfib</i> delays the formation of the basilar pontine and other mossy fiber nuclei

Kumbasar, Asli; Plachez, Céline; Gronostajski, Richard M.; Richards, Linda J.; Litwack, E. David

doi:10.1002/cne.21943

Cited by 24 publications

(16 citation statements)

References 61 publications

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“…One genetic candidate in neural progenitor cell maintenance is NFIB, a member of the Nuclear Factor One (NFI) family of transcription factors that is essential for normal brain development. Mice with an NfiB gene mutation ( NfiB −/− ) have enlarged lateral ventricles, agenesis of the corpus callosum, defects in the formation of the hippocampus, basilar pons and midline structures and die at birth due to lung defects (Plachez et al, 2008; Kumbasar et al, 2009; Piper et al, 2009). NFIB regulates the migration and axonal projection of cerebellar granule neurons (Wang et al, 2007; Mason et al, 2009; Heng et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Nuclear factor one B regulates neural stem cell differentiation and axonal projection of corticofugal neurons

Betancourt

Katzman

Chen

2013

J of Comparative Neurology

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During development of the cerebral cortex, neural stem cells divide to expand the progenitor pool and generate basal progenitors, outer radial glia and cortical neurons. As these newly born neurons differentiate, they must properly migrate toward their final destination in the cortical plate, project axons to appropriate targets, and develop dendrites. However, a complete understanding of the precise genetic mechanisms regulating these steps is lacking. Here we show that a member of the nuclear factor one (NFI) family of transcription factors, NFIB, is essential for many of these processes in mice. We performed a detailed analysis of NFIB expression during cortical development, and investigated defects in cortical neurogenesis, neuronal migration and differentiation in NfiB−/− brains. We found that NFIB is strongly expressed in radial glia and corticofugal neurons throughout cortical development. However, in NfiB−/− cortices, radial glia failed to generate outer radial glia, subsequently resulting in a loss of late basal progenitors. In addition, corticofugal neurons showed a severe loss of axonal projections, while late-born cortical neurons displayed defects in migration and ectopically expressed the early-born neuronal marker, CTIP2. Furthermore, gene expression analysis, by RNA-sequencing, revealed a misexpression of genes that regulate the cell cycle, neuronal differentiation and migration in NfiB−/− brains. Together these results demonstrate the critical functions of NFIB in regulating cortical development.

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Section: Introductionmentioning

confidence: 99%

Nuclear factor one B regulates neural stem cell differentiation and axonal projection of corticofugal neurons

Betancourt

Katzman

Chen

2013

J of Comparative Neurology

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“…For instance, mice lacking this transcription factor display enlarged lateral ventricles, dysgenesis of the corpus callosum and failure of glial maturation at the telencephalic midline [26], while also exhibiting cerebellar and hippocampal defects [28,34]. Development of the pons within Nfib mutants is also abnormal, with development of neurons within the pontine nuclei occurring substantially later than in control mice [35]. …”

Section: Nfi Genes: Key Regulators Of Nervous System Developmentmentioning

confidence: 99%

Nuclear Factor I Genes Regulate Neuronal Migration

et al. 2012

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Neuronal migration plays a central role in the formation of the brain, and deficits in this process can lead to aberrant brain function and subsequent disease. Neuronal migration is a complex process that involves the interaction of the neuron with the surrounding environmental milieu, and as such involves both cell-intrinsic and cell-extrinsic mechanisms. Studies performed in rodent models to investigate the formation of brain structures have provided key insights into how neuronal migration is coordinated during development. Within the cerebral cortex, glutamatergic neurons derived from the cortical ventricular zone migrate radially into the cortical plate, whereas interneurons derived within the ventrally located ganglionic eminences migrate tangentially into the cortex. Within the embryonic cerebellum, cerebellar granule neuron progenitors migrate from the rhombic lip over the surface of the cerebellar anlage, before differentiating and migrating radially into the internal granule layer of the cerebellum perinatally. In this review, we focus on one family of proteins, the nuclear factor I transcription factors, and review our understanding of how these molecules contribute to the formation of the hippocampus and the cerebellum via the regulation of neuronal migration.

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“…The

c_{5} - c_{6}

branch is inferred from transition genes including PAX3, CRX, SOX11, EBF2, FOXP4, ASCL1, FOXO3 , and SIX3 which have strong expression in developing dopaminergic and gabaergic neurons of the midbrain (Agoston et al, 2012; Erickson et al, 2010; Pino et al, 2014; Yang et al, 2015; Yin et al, 2009; Zhang et al, 2002). Transition genes in the

c_{5} - c_{7}

branch include ARGFX, DUXA, HES1, NFIB, PPARA, SOX2, SOX7 , and SOX9 , which are known to be associated with the medulla oblongata region of the hindbrain (Fawcett and Klymkowsky, 2004; Kameda et al, 2011; Kumbasar et al, 2009; Madissoon et al, 2016; Matsui et al, 2000; Stolt et al, 2003). …”

Section: Resultsmentioning

confidence: 99%

Discovering sparse transcription factor codes for cell states and state transitions during development

Furchtgott

Melton

Menon

et al. 2017

eLife

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Computational analysis of gene expression to determine both the sequence of lineage choices made by multipotent cells and to identify the genes influencing these decisions is challenging. Here we discover a pattern in the expression levels of a sparse subset of genes among cell types in B- and T-cell developmental lineages that correlates with developmental topologies. We develop a statistical framework using this pattern to simultaneously infer lineage transitions and the genes that determine these relationships. We use this technique to reconstruct the early hematopoietic and intestinal developmental trees. We extend this framework to analyze single-cell RNA-seq data from early human cortical development, inferring a neocortical-hindbrain split in early progenitor cells and the key genes that could control this lineage decision. Our work allows us to simultaneously infer both the identity and lineage of cell types as well as a small set of key genes whose expression patterns reflect these relationships.DOI: http://dx.doi.org/10.7554/eLife.20488.001

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Absence of the transcription factor Nfib delays the formation of the basilar pontine and other mossy fiber nuclei

Cited by 24 publications

References 61 publications

Nuclear factor one B regulates neural stem cell differentiation and axonal projection of corticofugal neurons

Nuclear factor one B regulates neural stem cell differentiation and axonal projection of corticofugal neurons

Nuclear Factor I Genes Regulate Neuronal Migration

Discovering sparse transcription factor codes for cell states and state transitions during development

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