ABSTRACT
The isocortex and hippocampal formation (HPF) in the mammalian brain play critical roles in perception, cognition, emotion, and learning. We profiled Ć¢ĀĀ¼1.3 million cells covering the entire adult mouse isocortex and HPF and derived a transcriptomic cell-type taxonomy revealing a comprehensive repertoire of glutamatergic and GABAergic neuron types. Contrary to the traditional view of HPF as having a simpler cellular organization, we discover a complete set of glutamatergic types in HPF homologous to all major subclasses found in the six-layered isocortex, suggesting that HPF and the isocortex share a common circuit organization. We also identify large-scale continuous and graded variations of cell types along isocortical depth, across the isocortical sheet, and in multiple dimensions in hippocampus and subiculum. Overall, our study establishes a molecular architecture of the mammalian isocortex and hippocampal formation and begins to shed light on its underlying relationship with the development, evolution, connectivity, and function of these two brain structures.
Subject(s)
Hippocampus/cytology , Neocortex/cytology , Transcriptome/genetics , Animals , GABAergic Neurons/cytology , GABAergic Neurons/metabolism , Glutamic Acid/metabolism , Mice, Inbred C57BL , Mice, TransgenicABSTRACT
Modern genetic approaches are powerful in providing access to diverse cell types in the brain and facilitating the study of their function. Here, we report a large set of driver and reporter transgenic mouse lines, including 23 new driver lines targeting a variety of cortical and subcortical cell populations and 26 new reporter lines expressing an array of molecular tools. In particular, we describe the TIGRE2.0 transgenic platform and introduce Cre-dependent reporter lines that enable optical physiology, optogenetics, and sparse labeling of genetically defined cell populations. TIGRE2.0 reporters broke the barrier in transgene expression level of single-copy targeted-insertion transgenesis in a wide range of neuronal types, along with additional advantage of a simplified breeding strategy compared to our first-generation TIGRE lines. These novel transgenic lines greatly expand the repertoire of high-precision genetic tools available to effectively identify, monitor, and manipulate distinct cell types in the mouse brain.
Subject(s)
Brain/metabolism , Gene Knockout Techniques/methods , Genes, Reporter , Animals , Brain/cytology , Calcium/metabolism , Cell Line , In Situ Hybridization, Fluorescence , Light , Mice , Mice, Transgenic , Microscopy, Fluorescence , Neurons/metabolism , Optogenetics , RNA, Untranslated/genetics , Transgenes/geneticsABSTRACT
Elucidating the cellular architecture of the human cerebral cortex is central to understanding our cognitive abilities and susceptibility to disease. Here we used single-nucleus RNA-sequencing analysis to perform a comprehensive study of cell types in the middle temporal gyrus of human cortex. We identified a highly diverse set of excitatory and inhibitory neuron types that are mostly sparse, with excitatory types being less layer-restricted than expected. Comparison to similar mouse cortex single-cell RNA-sequencing datasets revealed a surprisingly well-conserved cellular architecture that enables matching of homologous types and predictions of properties of human cell types. Despite this general conservation, we also found extensive differences between homologous human and mouse cell types, including marked alterations in proportions, laminar distributions, gene expression and morphology. These species-specific features emphasize the importance of directly studying human brain.
Subject(s)
Astrocytes/classification , Biological Evolution , Cerebral Cortex/cytology , Cerebral Cortex/metabolism , Neurons/classification , Adolescent , Adult , Aged , Animals , Astrocytes/cytology , Female , Humans , Male , Mice , Middle Aged , Neural Inhibition , Neurons/cytology , Principal Component Analysis , RNA-Seq , Single-Cell Analysis , Species Specificity , Transcriptome/genetics , Young AdultABSTRACT
The neocortex contains a multitude of cell types that are segregated into layers and functionally distinct areas. To investigate the diversity of cell types across the mouse neocortex, here we analysed 23,822 cells from two areas at distant poles of the mouse neocortex: the primary visual cortex and the anterior lateral motor cortex. We define 133 transcriptomic cell types by deep, single-cell RNA sequencing. Nearly all types of GABA (ĆĀ³-aminobutyric acid)-containing neurons are shared across both areas, whereas most types of glutamatergic neurons were found in one of the two areas. By combining single-cell RNA sequencing and retrograde labelling, we match transcriptomic types of glutamatergic neurons to their long-range projection specificity. Our study establishes a combined transcriptomic and projectional taxonomy of cortical cell types from functionally distinct areas of the adult mouse cortex.
Subject(s)
Gene Expression Profiling , Neocortex/cytology , Neocortex/metabolism , Animals , Biomarkers/analysis , Female , GABAergic Neurons/metabolism , Glutamic Acid/metabolism , Male , Mice , Motor Cortex/anatomy & histology , Motor Cortex/cytology , Motor Cortex/metabolism , Neocortex/anatomy & histology , Organ Specificity , Sequence Analysis, RNA , Single-Cell Analysis , Visual Cortex/anatomy & histology , Visual Cortex/cytology , Visual Cortex/metabolismABSTRACT
Drosophila melanogaster shows exquisite light sensitivity for modulation of circadian functions in vivo, yet the activities of the Drosophila circadian photopigment cryptochrome (CRY) have only been observed at high light levels. We studied intensity/duration parameters for light pulse induced circadian phase shifts under dim light conditions in vivo. Flies show far greater light sensitivity than previously appreciated, and show a surprising sensitivity increase with pulse duration, implying a process of photic integration active up to at least 6 hours. The CRY target timeless (TIM) shows dim light dependent degradation in circadian pacemaker neurons that parallels phase shift amplitude, indicating that integration occurs at this step, with the strongest effect in a single identified pacemaker neuron. Our findings indicate that CRY compensates for limited light sensitivity in vivo by photon integration over extraordinarily long times, and point to select circadian pacemaker neurons as having important roles.
Subject(s)
Circadian Rhythm/genetics , Cryptochromes/genetics , Drosophila Proteins/genetics , Drosophila melanogaster/genetics , Eye Proteins/genetics , Photophobia/genetics , Animals , Circadian Clocks/genetics , Circadian Rhythm/physiology , Drosophila melanogaster/physiology , Mutation , Neurons/metabolism , Photons , Photoperiod , Photoreceptor Cells, Invertebrate/physiologyABSTRACT
We describe a method for light-inducible and tissue-selective cell ablation using a genetically encoded photosensitizer, miniSOG (mini singlet oxygen generator). miniSOG is a newly engineered fluorescent protein of 106 amino acids that generates singlet oxygen in quantum yield upon blue-light illumination. We transgenically expressed mitochondrially targeted miniSOG (mito-miniSOG) in Caenorhabditis elegans neurons. Upon blue-light illumination, mito-miniSOG causes rapid and effective death of neurons in a cell-autonomous manner without detectable damages to surrounding tissues. Neuronal death induced by mito-miniSOG appears to be independent of the caspase CED-3, but the clearance of the damaged cells partially depends on the phagocytic receptor CED-1, a homolog of human CD91. We show that neurons can be killed at different developmental stages. We further use this method to investigate the role of the premotor interneurons in regulating the convulsive behavior caused by a gain-of-function mutation in the neuronal acetylcholine receptor acr-2. Our findings support an instructive role for the interneuron AVB in controlling motor neuron activity and reveal an inhibitory effect of the backward premotor interneurons on the forward interneurons. In summary, the simple inducible cell ablation method reported here allows temporal and spatial control and will prove to be a useful tool in studying the function of specific cells within complex cellular contexts.
Subject(s)
Caenorhabditis elegans Proteins/metabolism , Caenorhabditis elegans/metabolism , Flavoproteins/metabolism , Luminescent Proteins/metabolism , Neurons/metabolism , Animals , Animals, Genetically Modified , Caenorhabditis elegans/cytology , Caenorhabditis elegans/genetics , Caenorhabditis elegans Proteins/genetics , Caspases/genetics , Caspases/metabolism , Cell Death/radiation effects , Cell Survival/radiation effects , Dose-Response Relationship, Radiation , Flavoproteins/genetics , Interneurons/cytology , Interneurons/metabolism , Interneurons/radiation effects , Light , Luminescent Proteins/genetics , Membrane Proteins/genetics , Membrane Proteins/metabolism , Microscopy, Confocal , Microscopy, Fluorescence , Mitochondria/metabolism , Motor Neurons/cytology , Motor Neurons/metabolism , Motor Neurons/radiation effects , Neurons/cytology , Neurons/radiation effects , Receptors, Nicotinic/genetics , Receptors, Nicotinic/metabolism , Singlet Oxygen/metabolism , Time FactorsABSTRACT
Multiplexed fluorescence in situ hybridization techniques have enabled cell-type identification, linking transcriptional heterogeneity with spatial heterogeneity of cells. However, inaccurate cell segmentation reduces the efficacy of cell-type identification and tissue characterization. Here, we present a method called Spot-based Spatial cell-type Analysis by Multidimensional mRNA density estimation (SSAM), a robust cell segmentation-free computational framework for identifying cell-types and tissue domains in 2D and 3D. SSAM is applicable to a variety of in situ transcriptomics techniques and capable of integrating prior knowledge of cell types. We apply SSAM to three mouse brain tissue images: the somatosensory cortex imaged by osmFISH, the hypothalamic preoptic region by MERFISH, and the visual cortex by multiplexed smFISH. Here, we show that SSAM detects regions occupied by known cell types that were previously missed and discovers new cell types.
Subject(s)
Brain/cytology , Computational Biology/methods , Gene Expression Profiling/methods , Image Processing, Computer-Assisted/methods , Imaging, Three-Dimensional/methods , In Situ Hybridization, Fluorescence/methods , Single-Cell Analysis/methods , Algorithms , Animals , Brain/diagnostic imaging , Computer Simulation , Mice , Neurons/cytology , Neurons/metabolism , Preoptic Area/cytology , Preoptic Area/diagnostic imaging , Somatosensory Cortex/cytology , Somatosensory Cortex/diagnostic imaging , Transcriptome/genetics , Visual Cortex/cytology , Visual Cortex/diagnostic imagingABSTRACT
Abundant evidence supports the presence of at least three distinct types of thalamocortical (TC) neurons in the primate dorsal lateral geniculate nucleus (dLGN) of the thalamus, the brain region that conveys visual information from the retina to the primary visual cortex (V1). Different types of TC neurons in mice, humans, and macaques have distinct morphologies, distinct connectivity patterns, and convey different aspects of visual information to the cortex. To investigate the molecular underpinnings of these cell types, and how these relate to differences in dLGN between human, macaque, and mice, we profiled gene expression in single nuclei and cells using RNA-sequencing. These efforts identified four distinct types of TC neurons in the primate dLGN: magnocellular (M) neurons, parvocellular (P) neurons, and two types of koniocellular (K) neurons. Despite extensively documented morphological and physiological differences between M and P neurons, we identified few genes with significant differential expression between transcriptomic cell types corresponding to these two neuronal populations. Likewise, the dominant feature of TC neurons of the adult mouse dLGN is high transcriptomic similarity, with an axis of heterogeneity that aligns with core vs. shell portions of mouse dLGN. Together, these data show that transcriptomic differences between principal cell types in the mature mammalian dLGN are subtle relative to the observed differences in morphology and cortical projection targets. Finally, alignment of transcriptome profiles across species highlights expanded diversity of GABAergic neurons in primate versus mouse dLGN and homologous types of TC neurons in primates that are distinct from TC neurons in mouse.
Subject(s)
Cell Nucleus/genetics , Geniculate Bodies/metabolism , Neurons/metabolism , Visual Cortex/metabolism , Animals , Gene Expression Profiling , Humans , Macaca , Mice , RNA-Seq , Single-Cell Analysis , Thalamus/metabolism , Visual Pathways/metabolismABSTRACT
The evolutionarily conserved default mode network (DMN) is a distributed set of brain regions coactivated during resting states that is vulnerable to brain disorders. How disease affects the DMN is unknown, but detailed anatomical descriptions could provide clues. Mice offer an opportunity to investigate structural connectivity of the DMN across spatial scales with cell-type resolution. We co-registered maps from functional magnetic resonance imaging and axonal tracing experiments into the 3D Allen mouse brain reference atlas. We find that the mouse DMN consists of preferentially interconnected cortical regions. As a population, DMN layer 2/3 (L2/3) neurons project almost exclusively to other DMN regions, whereas L5 neurons project in and out of the DMN. In the retrosplenial cortex, a core DMN region, we identify two L5 projection types differentiated by in- or out-DMN targets, laminar position, and gene expression. These results provide a multi-scale description of the anatomical correlates of the mouse DMN.
Subject(s)
Brain/diagnostic imaging , Default Mode Network/diagnostic imaging , Nerve Net/diagnostic imaging , Neurons/physiology , Animals , Brain/cytology , Connectome , Default Mode Network/cytology , Magnetic Resonance Imaging , Mice , Nerve Net/cytology , Neurons/cytologyABSTRACT
Rapid cell type identification by new genomic single-cell analysis methods has not been met with efficient experimental access to these cell types. To facilitate access to specific neural populations in mouse cortex, we collected chromatin accessibility data from individual cells and identified enhancers specific for cell subclasses and types. When cloned into recombinant adeno-associated viruses (AAVs) and delivered to the brain, these enhancers drive transgene expression in specific cortical cell subclasses. We extensively characterized several enhancer AAVs to show that they label different projection neuron subclasses as well as a homologous neuron subclass in human cortical slices. We also show how coupling enhancer viruses expressing recombinases to a newly generated transgenic mouse, Ai213, enables strong labeling of three different neuronal classes/subclasses in the brain of a single transgenic animal. This approach combines unprecedented flexibility with specificity for investigation of cell types in the mouse brain and beyond.
Subject(s)
Brain/cytology , Neurons/classification , Neurons/cytology , Single-Cell Analysis/methods , Animals , Datasets as Topic , Dependovirus , Humans , Mice , Mice, TransgenicABSTRACT
Understanding the diversity of cell types in the brain has been an enduring challenge and requires detailed characterization of individual neurons in multiple dimensions. To systematically profile morpho-electric properties of mammalian neurons, we established a single-cell characterization pipeline using standardized patch-clamp recordings in brain slices and biocytin-based neuronal reconstructions. We built a publicly accessible online database, the Allen Cell Types Database, to display these datasets. Intrinsic physiological properties were measured from 1,938 neurons from the adult laboratory mouse visual cortex, morphological properties were measured from 461 reconstructed neurons, and 452 neurons had both measurements available. Quantitative features were used to classify neurons into distinct types using unsupervised methods. We established a taxonomy of morphologically and electrophysiologically defined cell types for this region of the cortex, with 17 electrophysiological types, 38 morphological types and 46 morpho-electric types. There was good correspondence with previously defined transcriptomic cell types and subclasses using the same transgenic mouse lines.
Subject(s)
Datasets as Topic , Neurons/classification , Visual Cortex/cytology , Action Potentials , Animals , Cell Shape , Databases, Factual , Genes, Reporter , Mice , Mice, Transgenic , Patch-Clamp Techniques , Transcriptome , Visual Cortex/physiologyABSTRACT
Transcriptomic profiling of complex tissues by single-nucleus RNA-sequencing (snRNA-seq) affords some advantages over single-cell RNA-sequencing (scRNA-seq). snRNA-seq provides less biased cellular coverage, does not appear to suffer cell isolation-based transcriptional artifacts, and can be applied to archived frozen specimens. We used well-matched snRNA-seq and scRNA-seq datasets from mouse visual cortex to compare cell type detection. Although more transcripts are detected in individual whole cells (~11,000 genes) than nuclei (~7,000 genes), we demonstrate that closely related neuronal cell types can be similarly discriminated with both methods if intronic sequences are included in snRNA-seq analysis. We estimate that the nuclear proportion of total cellular mRNA varies from 20% to over 50% for large and small pyramidal neurons, respectively. Together, these results illustrate the high information content of nuclear RNA for characterization of cellular diversity in brain tissues.
Subject(s)
Cell Nucleus/genetics , Single-Cell Analysis , Transcriptome/genetics , Visual Cortex/metabolism , Animals , Cell Lineage/genetics , Cell Lineage/physiology , Gene Expression Profiling/methods , Mice , Neurons/metabolism , Sequence Analysis, RNA/methods , Visual Cortex/physiologyABSTRACT
Single-cell characterization and perturbation of neurons provides knowledge critical to addressing fundamental neuroscience questions including the structure-function relationship and neuronal cell-type classification. Here we report a robot for efficiently performing in vivo single-cell experiments in deep brain tissues optically difficult to access. This robot automates blind (non-visually guided) single-cell electroporation (SCE) and extracellular electrophysiology, and can be used to characterize neuronal morphological and physiological properties of, and/or manipulate genetic/chemical contents via delivering extraneous materials (for example, genes) into single neurons in vivo. Tested in the mouse brain, our robot successfully reveals the full morphology of single-infragranular neurons recorded in multiple neocortical regions, as well as deep brain structures such as hippocampal CA3, with high efficiency. Our robot thus can greatly facilitate the study of in vivo full morphology and electrophysiology of single neurons in the brain.