Project description:Ongoing, lifelong neurogenesis maintains the neuronal population of the olfactory epithelium in the face of piecemeal neuronal turnover and restores it following wholesale loss. The molecular phenotypes corresponding to different stages along the progression from multipotent globose basal cell (GBC) progenitor to differentiated olfactory sensory neuron are poorly characterized. We used the transgenic expression of GFP and cell surface markers to FACS-isolate Sox2-GFP(+) GBCs, Neurog1-GFP(+) GBCs and immature neurons, and OMP-GFP(+) mature neurons from normal adult mice. In addition, the latter two populations were also collected 3 weeks after olfactory bulb ablation, a lesion that results in persistently elevated neurogenesis. Global profiling of mRNA from the populations indicates that all stages of neurogenesis share a cohort of >2100 genes that are upregulated compared to sustentacular cells. A further cohort of >1200 genes are specifically upregulated in GBCs as compared to sustentacular cells and differentiated neurons. The increased rate of neurogenesis caused by olfactory bulbectomy had little effect on the transcriptional profile of the Neurog1-GFP(+) population. In contrast, the abbreviated lifespan of OMP-GFP(+) neurons born in the absence of the bulb correlated with substantial differences in gene expression as compared to the mature neurons of the normal epithelium. Detailed examination of the specific genes upregulated in the different progenitor populations revealed that the chromatin modifying complex proteins LSD1 and coREST were expressed sequentially in upstream Sox2-GFP(+) GBCs and Neurog1-GFP(+) GBCs/immature neurons. The expression patterns of these proteins are dynamically regulated after activation of the epithelium by methyl bromide lesion. Total RNA was isolated from dissected, dissociated and FACS-purified olfactory mucosal cells from normal adult mice or mice 3 weeks after unilateral bulbectomy. Cells were purified with FACS using endogenous GFP fluorescence from various transgenic lines and cell surface labeling. Two to seven adult mice were used per replicate and three replicates per condition were performed using Illumina bead arrays. 21 samples from olfactory mucosa were analyzed in this series and 3 samples were from a commercially available reference RNA sample. Universal mouse reference RNA from Stratagene was used as a general control and Normal olfactory mucosa was used as a tissue specific control.

Project description:We performed the first integrative single-cell and spatial transcriptomic analysis on HPV-negative oral squamous cell carcinoma (OSCC) to comprehensively characterize tumor core (TC) and leading edge (LE) transcriptional architectures. We show that the TC and LE are characterized by unique transcriptional profiles, cellular compositions, and ligand-receptor interactions. We demonstrate that LE regions are conserved across multiple cancers while TC states are more tissue specific, highlighting the existence of common mechanisms underlying tumor progression and invasion. Additionally, we found our LE gene signature is associated with worse clinical outcomes while the TC gene signature is associated with improved prognosis across multiple cancer types. Finally, using an in silico modeling approach, we describe spatially-regulated patterns of cell development in OSCC that are predictably associated with drug response. Our work provides pan-cancer insights into TC and LE biology and a platform for data exploration (http://www.pboselab.ca/spatial_OSCC/) that can be foundational for developing novel targeted therapies.

Project description:Ongoing, lifelong neurogenesis maintains the neuronal population of the olfactory epithelium in the face of piecemeal neuronal turnover and restores it following wholesale loss. The molecular phenotypes corresponding to different stages along the progression from multipotent globose basal cell (GBC) progenitor to differentiated olfactory sensory neuron are poorly characterized. We used the transgenic expression of GFP and cell surface markers to FACS-isolate Sox2-GFP(+) GBCs, Neurog1-GFP(+) GBCs and immature neurons, and OMP-GFP(+) mature neurons from normal adult mice. In addition, the latter two populations were also collected 3 weeks after olfactory bulb ablation, a lesion that results in persistently elevated neurogenesis. Global profiling of mRNA from the populations indicates that all stages of neurogenesis share a cohort of >2100 genes that are upregulated compared to sustentacular cells. A further cohort of >1200 genes are specifically upregulated in GBCs as compared to sustentacular cells and differentiated neurons. The increased rate of neurogenesis caused by olfactory bulbectomy had little effect on the transcriptional profile of the Neurog1-GFP(+) population. In contrast, the abbreviated lifespan of OMP-GFP(+) neurons born in the absence of the bulb correlated with substantial differences in gene expression as compared to the mature neurons of the normal epithelium. Detailed examination of the specific genes upregulated in the different progenitor populations revealed that the chromatin modifying complex proteins LSD1 and coREST were expressed sequentially in upstream Sox2-GFP(+) GBCs and Neurog1-GFP(+) GBCs/immature neurons. The expression patterns of these proteins are dynamically regulated after activation of the epithelium by methyl bromide lesion.

Project description:The mammalian neocortex is a layered sheet of neural tissue that mediates complex cognitive processes including perception and cognition. Despite its importance, we still lack detailed knowledge of the cellular components of the neocortex. Integrating morphological, electrophysiological and molecular classification schemes into a common framework for defining cell types is challenging due to the limited scope of most single-cell analyses. Here, we developed a protocol for high-throughput electrophysiological and transcriptomic analysis of single neurons that combines whole-cell recordings and single-cell RNA-sequencing, which we call Patch-seq. Using this approach, we fully characterized the electrophysiological and molecular profiles of ~50 neocortical neurons, and show that gene expression patterns can be used to infer the morphological and physiological properties of individual neurons and their corresponding cell type. Our results shed light on the molecular underpinnings of neuronal diversity and demonstrate a path forward for comprehensive cell type characterization in the nervous system.

Project description:Metabolic gene expression analysis of Glioblastoma cells from patient tumors edge vs core and the GBM cells from the edge and core of the 3d invasion model was carried out using Nanostring N counter platform

Project description:This dataset supports a study introducing a framework for patch-clamp single-cell proteomics (patch-SCP) in acute rat brain slices. Patch-SCP combines whole-cell electrophysiology with mass spectrometry to directly link neuronal excitability with molecular composition. We systematically analyzed neurons from layer 2/3 of the medial prefrontal cortex (mPFC) using a shotgun retrieval strategy in which all patched cells were collected, regardless of electrophysiological outcome. Retrieval outcomes included neurons with preserved gigaseals, neurons that lost the gigaseal during soma withdrawal, neurons without gigaseals (collected without electrophysiological recordings), and torn/aspirated neurons. Electrophysiological parameters such as capacitance, resistance, and spiking were recorded where possible. Each retrieved soma was processed using a single-cell surfactant-based workflow (DDM lysis, one-pot digestion in low-bind plates) and analyzed by nanoLC coupled to an Orbitrap Astral mass spectrometer operating in DIA mode. The dataset contains raw DIA files, DIA-NN search outputs, and annotated metadata linking each cell to its retrieval outcome and electrophysiological properties. Together, these data provide a resource for evaluating how neuron size, retrieval quality, and physiological characterization influence single-cell proteomic recovery in acute brain slices.

Project description:Clinical outcomes for patients with glioblastoma (GBM) are extremely poor due to inevitable tumor recurrence even after extensive treatments. These recurrences are thought to manifest from cells located within the tumor edge. Despite this, the precise molecular mechanism governing GBM spatial phenotypic heterogeneity (e.g. edge vs. core) and subsequent tumor recurrence remains poorly elucidated. Here, using patient-derived GBM core and edge tissues, we analyzed transcriptional and metabolic signatures in an effort to determine how GBM facilitates the edge phenotype and its associated recurrence-initiating cells (RICs). In so doing, we unexpectedly identified CD38 as an essential protein in the formation of the edge phenotype and found a CD38-driven interaction between edge GBM cells and neighboring astrocytes that communally develops a GBM edge that is unresectable by surgery and retains RICs.

Project description:Morphological, electrophysiological and transcriptomic profiling of single neurons using Patch-seq

Project description:Calyx of Held giant presynaptic terminals in the medial nucleus of the trapezoid body of the auditory brainstem form axosomatic synapses that have advanced to one of the best-studied synaptic system of the mammalian brain. As the auditory system matures and adjusts to high fidelity synaptic transmission, the calyx undergoes extensive structural and functional changes: it is formed around postnatal day 3 (P3), achieves immature function until hearing onset around P10 and can be considered mature from P21 onwards. This setting provides the unique opportunity to examine the repertoire of genes driving synaptic structure and function. We performed cell type-specific gene expression profiling of globular bushy cells (GBCs), the neurons giving rise to the calyx of Held, at different maturational stages (P3, P8 and P21). We identified GBCs by stereotaxic injection of fluorescently labelled retrograde tracer Cholera toxin B into the contralateral MNTB of anesthetized rats. Animals were sacrificed 24h after injection, the brain was taken out and flash frozen. 12um thick brainstem cryosections were prepared and 200 fluorescently labelled GBCs per animal were excised from the VCN using laser microdissection. Cells were collected from 6 animals at P3 (synapse formation), 9 animals at P8 (juvenile synapse) and 5 animals at P21 (mature synapse). RNA was isolated from the collected cells and linearly amplified in order to perform cell-type specific expression profiling.

Project description:Prior studies have described the complex interplay that exists between glioma cells and neurons, however, the electrophysiological properties endogenous to tumor cells remain obscure. To address this, we employed Patch-sequencing on human glioma specimens and found that one third of patched cells in IDH mutant (IDHmut) tumors demonstrate properties of both neurons and glia by firing single, short action potentials. To define these hybrid cells (HCs) and discern if they are tumor in origin, we developed a computational tool, Single Cell Rule Association Mining (SCRAM), to annotate each cell individually. SCRAM revealed that HCs represent tumor and non-tumor cells that have select features of GABAergic neurons and oligodendrocyte precursor cells. These studies are the first to characterize the combined electrophysiological and molecular properties of human glioma cells and describe a new cell type in human glioma with unique electrophysiological and transcriptomic properties that may also exist in the non-tumor brain.