Project description:Layer 5 extratelencephalic (ET) neurons are a main class of neocortical projection neurons that predominate in the motor cortex and send their axon to multiple proximal and distal targets including the thalamus, pons, medulla and spinal cord1-6. Precise connectivity of ET neurons is critical for fine motor control; they are central to loss of function upon spinal cord injury and specifically degenerate in amyotrophic lateral sclerosis7-10. ET neurons consist of several subtypes of cells with distinct laminar and areal locations, molecular identities, connectivities, and functions11,12. Two cardinal subtypes of ET neurons have been identified: neurons that express Nprs1 or Hpgd and project proximally to the pons and thalamus (ETprox), and neurons that express Slco2a1 and project more distally to the pons, medulla and spinal cord (ETdist)11. Despite their critical function, how these neuronal subtypes emerge during development and acquire their area-specific distributions remains unaddressed. Here, using combinations of anatomical labeling, MAPseq mapping13, and single- nucleus transcriptomics across developing cortical areas, we reveal that these two subtypes of ET neurons are present at birth along opposite antero-posterior cortical gradients. We first characterize area-specific developmental axonal dynamics of ETprox and ETdist neurons and find that the former can emerge by pruning of subsets of ETdist neurons. We next identify area- and ET neuron subtype-specific developmental transcriptional programs to identify key target genes in vivo and predict their gene regulatory networks. Finally, we reprogram ET neuron subtype- specific connectivity from motor to visual-like, by generating more proximal connections through postnatal in vivo knockdown of three subtype-specific transcription factors. Together, these findings delineate the functional transcriptional programs controlling ET neuron diversity across cortical areas and provide a molecular blueprint to investigate and direct the developmental emergence of corticospinal motor function.

Project description:Layer 5 extratelencephalic (ET) neurons are a main class of neocortical projection neurons that predominate in the motor cortex and send their axon to multiple proximal and distal targets including the thalamus, pons, medulla and spinal cord1-6. Precise connectivity of ET neurons is critical for fine motor control; they are central to loss of function upon spinal cord injury and specifically degenerate in amyotrophic lateral sclerosis7-10. ET neurons consist of several subtypes of cells with distinct laminar and areal locations, molecular identities, connectivities, and functions11,12. Two cardinal subtypes of ET neurons have been identified: neurons that express Nprs1 or Hpgd and project proximally to the pons and thalamus (ETprox), and neurons that express Slco2a1 and project more distally to the pons, medulla and spinal cord (ETdist)11. Despite their critical function, how these neuronal subtypes emerge during development and acquire their area-specific distributions remains unaddressed. Here, using combinations of anatomical labeling, MAPseq mapping13, and single- nucleus transcriptomics across developing cortical areas, we reveal that these two subtypes of ET neurons are present at birth along opposite antero-posterior cortical gradients. We first characterize area-specific developmental axonal dynamics of ETprox and ETdist neurons and find that the former can emerge by pruning of subsets of ETdist neurons. We next identify area- and ET neuron subtype-specific developmental transcriptional programs to identify key target genes in vivo and predict their gene regulatory networks. Finally, we reprogram ET neuron subtype- specific connectivity from motor to visual-like, by generating more proximal connections through postnatal in vivo knockdown of three subtype-specific transcription factors. Together, these findings delineate the functional transcriptional programs controlling ET neuron diversity across cortical areas and provide a molecular blueprint to investigate and direct the developmental emergence of corticospinal motor function.

Project description:Background: The goal of this study was to determine the transcriptional consequences of norepinephrine transporter (NET) gene deletion in noradrenergic neuron differentiation. The norepinephrine transporter (NET) is the target of powerful mind-altering substances, such as tricyclic antidepressants and the drug of abuse, cocaine. NET function in adult noradrenergic neurons of the peripheral and central nervous systems is that of a scavenger that internalizes norepinephrine from the synaptic cleft. By contrast, norepinephrine (NE) transport has a different role in embryogenesis. It promotes differentiation of neural crest cells and locus ceruleus progenitors into noradrenergic neurons, whereas NET inhibitors, such as the tricyclic antidepressant desipramine and the drug of abuse, cocaine, inhibit noradrenergic differentiation. While NET structure und regulation of NET function is well described, little is known about downstream targets of NE transport. Results: We have determined by long serial analysis of gene expression (LongSAGE) the gene expression profiles of in vitro differentiating wild type and norepinephrine transporter-deficient (NETKO) neural crest derivatives. Comparison analyses with the wild type library (GSM 105765) have identified a number of important differentially expressed genes, including genes relevant to noradrenergic neuron differentiation and to the phenotype of NETKO mice. Furthermore we have identified novel differentially expressed genes. Conclusions: Loss of NET function during embryonic development deregulates signaling pathways that are critically involved in neural crest formation and noradrenergic neuron differentiation. The library was constructed from total RNA of 60 neural crest culture at culture day 7. The neural tubes were dissected from E9.5 embryos that lack the norepinephrine transporter gene.

Project description:We previously identified that the RNA binding protein Nucleolin is localized to axons of DRG sensory neurons by interaction with the molecular motor Kinesin-1 (Kif5A) and subsequently localizes importin beta1 mRNA there (Perry et al., 2016). To further identify additional RNAs that are localized to axons in a similar mechanism, we immunopercipitated Kif5A from dorsal roots (centrally projecting axons) or Sciatic nerves (peripherally projecting axons), isolated the bound RNA and sequnced it.

Project description:Transcriptomic analysis of enriched of neuron population collected from in-vivo mouse brains has been a challenge in the neuroscience field due to its fragility in withstanding harsh condition during isolation and collection process. We established a fluorescent reporter mouse Ddc-hKO1 to facilitate the identification and collection of Ddc-expressing neurons (dopaminergic, serotonergic, cholinergic and adrenergic neurons) by the detection of red fluorescence signals using a FACs. We utilized an improved isolation protocol that ensure high yield and quality of viable neurons during collection that is suitable for RNA-sequencing. This is the first report of transcriptomic profiling of Ddc expressing (hKO1(+)) neurons. Successful collection of Ddc-expressing neurons were verified by gene markers of dopaminergic, serotonergic, cholinergic neurons in hKO1(+) populations while other neuron types in hKO1(-) population. Furthermore, GSEA analysis were performed on both hKO1(+) and hKO1(-) to further support the neuron types collected in respective population.

Project description:Amyotrophic lateral sclerosis (ALS) and frontotemporal lobar degeneration (FTLD) are two incurable and fatal neurodegenerative conditions. While distinct, they share many clinical, genetic, and pathological characteristics, and both show highly vulnerable layer 5 extratelencephalic-projecting cortical populations, including Betz cells in ALS2 and von Economo neurons (VENs) in FTLD. Here, we report the first single-cell atlas of the human primary motor cortex and its changes in ALS and FTLD across ~380,000 nuclei from 64 control, sporadic and C9orf72-associated ALS and FTLD individuals. We identify 46 transcriptionally distinct cellular subtypes including two Betz-cell subtypes, and observe a previously-unappreciated molecular similarity between Betz cells and VENs of the frontal insula. Most dysregulated genes and pathways were shared, including stress response, ribosome function, oxidative phosphorylation, synaptic vesicle cycle, endoplasmic reticulum protein processing, and autophagy. Betz cells and SCN4B+ long-range projecting L3/L5 cells are the most transcriptionally affected in both ALS and FTLD. Lastly, the VEN/Betz-cell-enriched dysregulated gene POU3F1 co-localizes with TDP-43 aggregates in Betz cells.

Project description:The 5HT system is organized into rostral and caudal populations with discrete anatomical locations and opposite axonal trajectories in the developing hindbrain. 5HT neuron cell bodies in the rostral subdivision migrate to the midbrain and pons and extend ascending projections throughout the forebrain. 5HT cell bodies in the caudal subdivision migrate to the ventral medulla and caudal half of the pons and provide descending projections to the brainstem and spinal cord. Experiment Overall Design: We used microarrays to determine genes expressed by both rostral and caudal 5HT neurons as well as genes that are differentially expressed between rostral and caudal 5HT neurons at E12.5 when axon pathfinding and cell migration are underway. E12.5 neural tubes were isolated from ePet-EYFP embryos and dissected into a rostral domain (mesecephalic flexure to pontine flexure) and a caudal domain (pontine flexure to spinal cord). After cell dissociation (details under growth protocol), cells were subjected to fluorescent activated cell sorting (FACS) to obtain 4 cell populations. R+ = rostral ePetEYFP positive 5HT neurons; R- = YFP negative non-serotonergic cells in the rostral neural tube; C+ = caudal ePetEYFP positive 5HT neurons; C- = YFP negative non-serotonergic cells in the caudal neural tube. 200,000 cells for each of the 4 cell types (R+, R-, C+, C-) were collected for RNA extraction and hybridization to Affymetrix Mouse 430 2.0 arrays.

Project description:Human serotonergic neurons

Project description:This article presents a study that examines the proteomic alterations associated with opioid use disorder (OUD) in the human brain. The study investigates the interplay between pro-inflammatory signaling, extracellular matrix (ECM) remodeling, and synaptic plasticity in the corticostriatal circuitry associated with OUD. The findings reveal differential alterations in the synaptic proteomes across the nucleus accumbens (NAc) and dorsolateral prefrontal cortex (DLPFC), indicating that changes in certain synaptic subtypes are unique to each brain region. The proteomic alterations associated with OUD in DLPFC are mainly in glutamatergic, serotonergic, dopaminergic, and oxytocin signaling, while altered adrenergic signaling is enriched in NAc. The study also identifies alterations in proteins involved in circadian entrainment specifically in synaptic enrichments in both DLPFC and NAc of OUD subjects. These findings provide new evidence linking disrupted molecular rhythms in the regulation of distinct synaptic subtypes altered by opioids.

Project description:Sensorimotor reflex circuits engage distinct neuronal subtypes, defined by precise connectivity, to transform sensation into compensatory behavior. Whether and how motor partner populations shape the subtype fate and connectivity of their pre-motor counterparts remains controversial. Here, we discovered that motor partners are dispensable for proper connectivity across an entire vestibular reflex circuit that stabilizes gaze. We first measured activity following vestibular sensation in pre-motor projection neurons after constitutive loss of their extraocular motor neuron partners.We observed normal responses and topography consistent with unchanged functional connectivity between sensory neurons and projection neurons. Next, we show that projection neurons remain anatomically and molecularly poised to connect appropriately with their motor partners. Lastly, we show that the transcriptional signatures of projection neuron subtypes develop independently of motor partners. Our findings comprehensively overturn a long-standing model: that connectivity in the circuit for gaze stabilization is retrogradely determined by motor partner-derived signals. By defining the contribution of motor neurons to canonical sensorimotor circuit assembly, our work speaks to comparable processes in spinal circuits and advances our understanding of general principles of neural development.