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:Excitatory neurons arising from a common progenitor establish radially-oriented clonal units in the neocortex which have been proposed to serve as elementary information processing modules. To characterize the cell types and circuit diagram within these clonal units, we performed single-cell RNA-sequencing and multi-cell patch clamp recordings of neurons derived from Nestin-positive progenitors. We found that radial clones do not appear to be fate-restricted, but instead individual clones are composed of a random sampling of the transcriptomic cell types present in a particular cortical area. The effect of lineage on synaptic connectivity depends on the type of connection tested: pairs of clonally related neurons were more likely to be connected vertically, across cortical layers, but not laterally within the same layer, compared to unrelated pairs. We propose that integration of vertical input from related neurons with lateral input from unrelated neurons may represent a developmentally programmed motif for assembling neocortical circuits.

Project description:Neural progenitors derived from human pluripotent stem cells (hPSCs) develop into electrophysiologically active neurons at heterogeneous rates, which can confound disease-relevant discoveries in neurology and psychiatry. The goal of this study was to resolve the diversity of functional states of hPSC-derived neurons in vitro by combining patch clamping with morphological and RNA-sequencing analysis of single neurons (Patch-seq).

Project description:<p>During development of the human brain, multiple cell types with diverse regional identities are generated. Here we report a system to generate early human brain forebrain and mid/hindbrain cell types from human embryonic stem cells (hESCs), and infer and experimentally confirm a lineage tree for the generation of these types based on single-cell RNA-Seq analysis. We engineered <i>SOX2^Cit/+</i> and <i>DCX^Cit/Y</i> hESC lines to target progenitors and neurons throughout neural differentiation for single-cell transcriptomic profiling, then identified discrete cell types consisting of both rostral (cortical) and caudal (mid/hindbrain) identities. Direct comparison of the cell types were made to primary tissues using gene expression atlases and fetal human brain single-cell gene expression data, and this established that the cell types resembled early human brain cell types, including preplate cells. From the single-cell transcriptomic data a Bayesian algorithm generated a unified lineage tree, and predicted novel regulatory transcription factors. The lineage tree highlighted a prominent bifurcation between cortical and mid/hindbrain cell types, confirmed by clonal analysis experiments. We demonstrated that cell types from either branch could preferentially be generated by manipulation of the canonical Wnt/beta-catenin pathway. In summary, we present an experimentally validated lineage tree that encompasses multiple brain regions, and our work sheds light on the molecular regulation of region-specific neural lineages during human brain development.</p>

Project description:We characterize the transcriptomic, morphological and functional features of 472 high-quality RGCs using Patch-seq, providing functional and morphological annotation of many transcriptomic defined cell types of previously established RGC atlas.

Project description:Development and plasticity in the nervous system are regulated by specific patterns of neural impulse activity. Patterned activity orchestrates spatial and temporal changes in the expression of networks of genes. These gene regulatory networks underlie the long-term changes in cell specification, growth of synaptic connections, and frequency adaptation that occur throughout neonatal and postnatal life. We show that the temporal nature of action potentials and downstream signaling differentially regulate the expression of hundreds of diverse neuronal genes through distinct gene regulatory networks. Analysis of upstream regulatory regions showed enrichment in transcription factor binding sites for NF-Kappa that was action potential firing pattern specific. Our new findings demonstrate spike-frequency decoding by action potentials at the transcriptional level by pattern-specific activation of transcription factors and associated gene-regulatory networks that operate to adjust the modalities of sensory neurons. We analyzed the transcriptomic changes in primary cultures of embronic dorsal root ganglia (DRG) neurons subjected to four electric stimulation patterns with respect to their non-stimulated counterparts. We have adopted the multiple yellow strategy in which differently fluorescent labeled biological replicas are co-hybridized with each array and then similarly labeled samples from cells subjected to different conditions are compared and results averaged over the two labels.

Project description:We obtained full transcriptome data from single cortical neurons after whole-cell patch-clamp recording (termed “Patch-seq”). By applying “Patch-seq” to cortical neurons, we reveal a close link between biophysical membrane properties and genes coding for neurotransmitter receptors and channels, including well-established and hitherto undescribed subtypes.

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

Project description:Despite the rapid progress in dissecting neural circuits for social behaviors, it remains unknown whether specific neural cell types are selectively vulnerable in social dysfunction cases often associated with neurodevelopmental disorders. Here, employing a single-cell transcriptome analysis in mice, we show that an embryonic disturbance known to induce social dysfunction preferentially impairs gene expressions crucial for neural functions in parvocellular oxytocin (OT) neurons—a subtype linked to social rewards—while neighboring cell types experience a lesser impact. Chemogenetic stimulation of OT neurons at the neonatal stage ameliorated social deficits, concomitant with a cell-type-specific sustained recovery of the pivotal gene expressions. Our data illuminates the transcriptomic selective vulnerability within the hypothalamic social behavioral center, offering a potential therapeutic target through specific neonatal neurostimulation.

Project description:Neurons undergo substantial morphological and functional changes during development to form precise synaptic connections and acquire specific physiological features. What are the underlying transcriptomic bases? Here, we obtained the single-cell transcriptomes of Drosophila olfactory projection neurons (PNs) at four developmental stages. We decoded the identity of 21 transcriptomic clusters corresponding to 20 PN types and developed methods to match transcriptomic clusters representing the same PN type across development. We discovered that PN transcriptomes reflect unique biological processes unfolding at each stage—neurite growth and pruning during metamorphosis at an early pupal stage; peaked transcriptomic diversity during olfactory circuit assembly at mid-pupal stages; and neuronal signaling in adults. At early developmental stages, PN types with adjacent birth order share similar transcriptomes. Together, our work reveals principles of cellular diversity during brain development and provides a resource for future studies of neural development in PNs and other neuronal types.