Project description:TRIM9 and TRIM67 are neuronally-enriched E3 ubiquitin ligases essential for neuronal morphogenesis and responses to the axon guidance cue netrin-1. Deletion of either gene in the mouse results in subtle neuroanatomical anomalies yet overt deficits in spatial learning and memory. The identify of few TRIM9 or TRIM67 substrates are known. Here we performed ubiquitin remnant profiling approach (Xu et al., 2010)in cultured cortical neurons from murine wildtype, Trim9-/-, Trim67-/-, and Trim9-/-:Trim67-/- embryos cultured with or without netrin-1 supplementation to attempt to identify proteins with altered ubiquitination. Although batch variability hindered our ability to identify differential protein ubiquitination, the results delineate the neuronal ubiquitionome during neurite outgrowth, axon specification, and axon branching.

Project description:Cell type diversity during neuro-ectodermal (NE) differentiation is achieved through selective activation and silencing of neurodevelopmental genes. Here, we show a key role for the histone deacetylase complex MiDAC during neuronal differentiation of mouse embryonic stem cells (mESCs) into NE. We demonstrate that MiDAC functions as a modulator of a neurodevelopmental gene expression program and binds to important regulators of neurite outgrowth. MiDAC mediates the removal of H4K20ac on the promoters and enhancers of pro-neural genes such as the axon guidance ligands Slit3 and Ntn1 while in parallel reducing H3K27ac on promoter-proximal and -distal elements of negative regulators of neurogenesis thereby upregulating and inhibiting gene expression, respectively. Furthermore, neurite outgrowth defects in MiDAC KO neurons can be rescued by restoring Slit3/Robo3-Ntn1/Unc5b signaling. Taken together, our work suggests a crucial role for MiDAC in regulating the secretome of the Slit3/Robo3-Ntn1/Unc5b signaling axes to ensure the proper integrity of neurite development.

Project description:Cell type diversity during neuro-ectodermal (NE) differentiation is achieved through selective activation and silencing of neurodevelopmental genes. Here, we show a key role for the histone deacetylase complex MiDAC during neuronal differentiation of mouse embryonic stem cells (mESCs) into NE. We demonstrate that MiDAC functions as a modulator of a neurodevelopmental gene expression program and binds to important regulators of neurite outgrowth. MiDAC mediates the removal of H4K20ac on the promoters and enhancers of pro-neural genes such as the axon guidance ligands Slit3 and Ntn1 while in parallel reducing H3K27ac on promoter-proximal and -distal elements of negative regulators of neurogenesis thereby upregulating and inhibiting gene expression, respectively. Furthermore, neurite outgrowth defects in MiDAC KO neurons can be rescued by restoring Slit3/Robo3-Ntn1/Unc5b signaling. Taken together, our work suggests a crucial role for MiDAC in regulating the secretome of the Slit3/Robo3-Ntn1/Unc5b signaling axes to ensure the proper integrity of neurite development.

Project description:Developmental alteration in brain wiring that would make it more susceptible to later pathological processes has been suggested as a basis for the occurrence of neurodegenerative diseases, but mechanisms have remained elusive. A recent series of magnetic resonance imaging studies have demonstrated that, in Wolfram syndrome, neurodegenerative processes appear during childhood and adolescence on top of a clinically silent global defect in brain development. Here, differentiation of induced pluripotent stem cell lines derived from Wolfram syndrome patients’ cells along the neural lineage has revealed phenotypic and molecular correlates of that global brain defect. A proportion of neural cells displayed aberrant neurite outgrowth associated with alterations in the expression of genes involved in axonal guidance. In contrast, an activation of endoplasmic reticulum stress response genes was absent while it is present in late Wolfram syndrome degenerative processes. These results concur to the broader hypothesis that axon guidance genes may play a role in the susceptibility to neurodegenerative diseases.

Project description:After injury to the central nervous system (CNS), both neuron-intrinsic limitations on regenerative responses and inhibitory factors in the injured CNS environment restrict regenerative axon growth. Instances of successful axon regrowth offer opportunities to identify features that differentiate these situations from that of the normal adult CNS. One such opportunity is provided by the kinase inhibitor RO48, which dramatically enhances neurite outgrowth of neurons in vitro and substantially increased contralateral sprouting of corticospinal tract neurons when infused intraventricularly following unilateral pyramidotomy. The authors present here a transcriptomic deconvolution of RO48-associated axon growth, with the goal of identifying transcriptional regulators associated with axon growth in the CNS. Through the use of RNA sequencing (RNA-seq) and transcription factor binding site enrichment analysis, the authors identified a list of transcription factors putatively driving differential gene expression during RO48-induced neurite outgrowth of rat hippocampal neurons in vitro. The 82 transcription factor motifs identified in this way included some with known association to axon growth regulation, such as Jun, Klf4, Myc, Atf4, Stat3, and Nfatc2, and many with no known association to axon growth. A phenotypic loss-of-function screen was carried out to evaluate these transcription factors for their roles in neurite outgrowth; this screen identified several potential outgrowth regulators. Subsequent validation suggests that the Forkhead box (Fox) family transcription factor Foxp2 restricts neurite outgrowth, while FoxO subfamily members Foxo1 and Foxo3a promote neurite outgrowth. The authors’ combined transcriptomic-phenotypic screening strategy therefore allowed identification of novel transcriptional regulators of neurite outgrowth downstream of a multitarget kinase inhibitor.

Project description:Recent reports have emphasized the pitfalls of iPSC technology including the potential for immunogenicity of transplanted cells. It is serious safety-related concern for iPSC-based cell therapy. However, preclinical data supporting the safety and efficacy of iPSCs are also accumulating. To address the concern of immunogenicity of ESCs/iPSCs or ESCs/iPSCs-derived neurospheres, global gene expression profiles were compared between undifferentiated mouse ESCs (EB3 line), mouse iPSCs (38C2 line), and ESC/iPSC-derived neurosphere and mouse primary culture of neurosphere obtained from fetal mouse ganglionic eminence. Mouse adult sklin fibroblast was used as a control. We used affymetrix microarrays to compare the global gene expression of neurospheres prepared several origins. Keywords: Expression profiling by array RNA extracted from neurospheres was hybridized to Affymetrix microarrays.

Project description:Zika virus (ZIKV) has been associated with microcephaly and other brain abnormalities; however, the molecular consequences of ZIKV to human brain development are still not fully understood. Here we describe alterations in human neurospheres derived from induced pluripotent stem (iPS) cells infected with the strain of Zika virus that is circulating in Brazil. Combining proteomics and mRNA transcriptional profiling, over 500 proteins and genes associated with the Brazilian ZIKV infection were found to be differentially expressed. These genes and proteins provide an interactome map, which indicates that ZIKV controls the expression of RNA processing bodies, miRNA biogenesis and splicing factors required for self-replication. It also suggests that impairments in the molecular pathways underpinning cell cycle and neuronal differentiation are caused by ZIKV. These results point to biological mechanisms implicated in brain malformations, which are important to further the understanding of ZIKV infection and can be exploited as therapeutic potential targets to mitigate it.

Project description:Zika virus (ZIKV) has been associated with microcephaly and other brain abnormalities; however, the molecular consequences of ZIKV to human brain development are still not fully understood. Here we describe alterations in human neurospheres derived from induced pluripotent stem (iPS) cells infected with the strain of Zika virus that is circulating in Brazil. Combining proteomics and mRNA transcriptional profiling, over 500 proteins and genes associated with the Brazilian ZIKV infection were found to be differentially expressed. These genes and proteins provide an interactome map, which indicates that ZIKV controls the expression of RNA processing bodies, miRNA biogenesis and splicing factors required for self-replication. It also suggests that impairments in the molecular pathways underpinning cell cycle and neuronal differentiation are caused by ZIKV. These results point to biological mechanisms implicated in brain malformations, which are important to further the understanding of ZIKV infection and can be exploited as therapeutic potential targets to mitigate it.

Project description:During central nervous system (CNS) development, proper and timely induction of axon elongation is critical for generating functional, mature neurons and neuronal networks. Despite the wealth of information on the action of extracellular cues, little is known about the intrinsic gene regulatory factors that control this developmental decision. Here we report the identification of Prox1, a homeobox transcription factor, as a key player in inhibiting axon elongation. Although Prox1 promotes acquisition of early neuronal identity and is expressed in nascent post-mitotic neurons, it is heavily down-regulated in the majority of terminally differentiated neurons, indicating a regulatory role in delaying axon outgrowth in newly formed neurons. Consistently, we show that Prox1 is sufficient to inhibit neurite extension in neuroblastoma cell lines. Furthermore, shRNA-mediated knock-down of Prox1 in Neuro2A cells induces the extension of neurites. More importantly, Prox1 overexpression suppresses axon elongation in primary neuronal cultures as well as in the developing mouse brain, while Prox1 knock-down promotes axon outgrowth. Mechanistically, RNA-Seq analysis reveals that Prox1 affects critical pathways for neuronal maturation and neurite extension. Interestingly, Prox1 strongly inhibits many components of Ca2+ signaling pathway, an important mediator of axon extension and neuronal maturation. In accordance, Prox1 represses Ca2+ entry upon KCl-mediated depolarization and reduce CREB phosphorylation. These observations suggest that Prox1 acts as a potent suppressor of axon elongation by inhibiting Ca2+ signaling pathway. This action may provide the appropriate time window for nascent neurons to find the correct position in the CNS prior to initiation of axon elongation.

Project description:Cadherins play an important role in tissue homeostasis, as they are responsible for cell-cell adhesion during embryogenesis, tissue morphogenesis, and differentiation. In this study, we identified Cadherin-12 (CDH12), which encodes a type II classical cadherin, as a gene to promote neurite outgrowth in a vitro model consist of neurons with differentiated intrinsic growth ability. First, the effects of CDH12 on neurons were evaluated by RNA interference, and the result indicated that the knock down of CDH12 expression restrained the axon extension of E18 neurons. The transcriptome profile of the neurons with or without siCDH12 treatment revealed a set of pathways positively correlated with the effect of CDH12 on neurite outgrowth. We further revealed that CDH12 affected Rac1/Cdc42 phosphorylation in PKA dependent manner by testing with H-89 and 8-Bromo-cAMP sodium salt. Moreover, we investigated the expression of CDH12 in brain, spinal cord, and dorsal root ganglion during development by using immunofluorescence staining. Thereafter, we explored the effects of CDH12 on neurite outgrowth in vivo. A zebrafish model of CDH12 knockdown was established by using NgAgo-gDNA system and registered the vital role of CDH12 in peripheral neurogenesis. In summary, our study is the first to report the effect of CDH12 on axonal extension in vitro and in vivo and we provided a preliminary explanation for the mechanism.