Project description:Genome-wide transcriptional profiling allows characterization of the molecular underpinnings of neocortical organization, including cortical areal specialization, laminar cell type diversity and functional anatomy. Microarray analysis of individual cortical layers across sensorimotor and association cortices in rhesus macaque demonstrated robust and specific laminar and areal molecular signatures driven by differential expression of genes associated with specialized neuronal function. Gene expression corresponding with laminar architecture was generally similar across cortical areas, although genes with robust areal patterning were often highly laminar as well, and these patterns were more highly conserved between macaque and human as compared to mouse. Layer 4 of primate primary visual cortex displayed a distinct molecular signature compared to other cortical regions, a specialization not observed in mouse. Overall, transcriptome-based relationships were strongest between proximal layers in a cortical area, and between neighboring areas along the rostrocaudal axis, reflecting in vivo cortical spatial topography and therefore a developmental imprint. Tissue from male and female monkeys (n = 2-3 animals/gender) was collected from anterior cingulate gyrus (ACG), layers 2, 3, 5, 6; orbitofrontal cortex (OFC), layers 2, 3, 5, 6; dorsolateral prefrontal cortex (DLPFC), layers 2-6; primary motor cortex (M1), layers 2, 3, 5, 6; primary somatosensory cortex (S1), layers 2-6; primary auditory cortex (A1), layers 2-6; primary visual cortex (V1), layers 2-6 including 4A, 4B, 4Calpha (4Ca), 4Cbeta (4Cb); secondary visual cortex (V2), layers 2-6; middle temporal area (MT), layers 2-6; temporal area (TE), layers 2-6; hippocampus, CA1, CA2, CA3, dentate gyrus (DG); and dorsal lateral geniculate nucleus (LGN), magnocellular, parvocellular and koniocellular divisions. Due to the limited number of samples that could be amplified concurrently, amplifications were performed in 3 batches (batches A-C, containing 102, 119 and 10 experimental samples, respectively). To control for batch effects, common RNA pool control samples were amplified and hybridized in each batch. These included LCM extracted hippocampus CA3 samples from the current study and a whole rhesus brain RNA pool (Biochain). These control samples were hybridized in 6 replicates in batch A and B and in 3 replicates in batch C (3 replicates per 96 well plate).

Project description:Genome-wide transcriptional profiling allows characterization of the molecular underpinnings of neocortical organization, including cortical areal specialization, laminar cell type diversity and functional anatomy. Microarray analysis of individual cortical layers across sensorimotor and association cortices in rhesus macaque demonstrated robust and specific laminar and areal molecular signatures driven by differential expression of genes associated with specialized neuronal function. Gene expression corresponding with laminar architecture was generally similar across cortical areas, although genes with robust areal patterning were often highly laminar as well, and these patterns were more highly conserved between macaque and human as compared to mouse. Layer 4 of primate primary visual cortex displayed a distinct molecular signature compared to other cortical regions, a specialization not observed in mouse. Overall, transcriptome-based relationships were strongest between proximal layers in a cortical area, and between neighboring areas along the rostrocaudal axis, reflecting in vivo cortical spatial topography and therefore a developmental imprint.

Project description:In the mammalian cerebral cortex, the developmental events governing the allocation of different classes of inhibitory neurons into distinct cortical layers are poorly understood. Here we report that the guidance receptor PlexinA4 is upregulated in serotonin receptor 3a-expressing (HTR3A) cortical interneurons (hINs) as they invade the cortical plate and that it regulates their laminar allocation to superficial cortical layers. We find that the PlexinA4 ligand Semaphorin3A acts as a chemorepulsive factor on hINs migrating into the nascent cortex and demonstrate that Semaphorin3A specifically controls their laminar positioning through PlexinA4. We identify that deep layer interneurons constitute a major source of Semaphorin3A in the developing cortex and demonstrate that cell-type specific genetic deletion of Semaphorin3A in these interneurons specifically affects the laminar allocation of hINs. These data demonstrate that in the neocortex, deep layer interneurons control the laminar allocation of hINs into superficial layers.

Project description:Genome organization is driven by forces affecting transcriptional state, but the relationship between transcription and genome architecture remains unclear. Here, we identified the Drosophila transcription factor Motif 1 Binding Protein (M1BP) in physical association with the gypsy chromatin insulator core complex, including the universal insulator protein CP190. M1BP is required for enhancer-blocking and barrier activities of the gypsy insulator as well as its proper nuclear localization. Genome-wide, M1BP specifically colocalizes with CP190 at Motif 1-containing promoters, which are enriched at topologically associating domain (TAD) borders. M1BP facilitates CP190 chromatin binding at many shared sites and vice versa. Both factors promote Motif 1-dependent gene expression and transcription near TAD borders genome-wide. Finally, loss of M1BP reduces chromatin accessibility and increases both inter- and intra-TAD local genome compaction. Our results reveal physical and functional interaction between CP190 and M1BP to activate transcription at TAD borders and mediate chromatin insulator-dependent genome organization.

Project description:We optimized Voltage-Seq which combines, all-optical physiology, spatial mapping, on-site classification, and RNA-transcriptomics to robustly increase the throughput of synaptic connectivity testing and targeted molecular classification of postsynaptic neurons. Single-cell RNA-sequencing was performed on spatial- and voltage-recorded neurons in the mouse PAG. Uniform Manifold Approximation and Projection (UMAP) clustered cells as excitatory or inhibitory, and further differential expression analyses highlighted putative marker genes of GABAergic neurons. These sequencing results were in agreement with in-situ hybridization (ISH) and neuronal activity recordings.

Project description:Laminar gene expression of rat extraocular orbital and global layers

Project description:While the cerebral cortex is organized into six excitatory neuronal layers, it is unclear whether glial cells show distinct layering. Here, we developed a high-content pipeline, the Large-area Spatial Transcriptomic (LaST) map, which can quantify single-cell gene expression in situ. Screening 46 candidate genes for astrocyte diversity across the mouse cortex, we identified superficial, mid, and deep astrocyte identities in gradient layer patterns that were distinct from those of neurons. Astrocyte layer features, established in early postnatal cortex, mostly persisted in adult mouse and human cortex. Single cell RNA sequencing and spatial reconstruction analysis further confirmed the presence of astrocyte layers in the adult cortex. Satb2 and Reeler mutations that shifted neuronal post-mitotic development were sufficient to alter glial layering, indicating an instructive role for neuronal cues. Finally, astrocyte layer patterns diverged between mouse cortical regions. These findings indicate that excitatory neurons and astrocytes are organized into distinct lineage-associated laminae.  

Project description:The discovery that genomes are partitioned into self-interacting modules or topologically associated domains (TADs) has revolutionized our understanding of the multiscale organization of chromatin. TADs are often considered as stable structures over time, however this view contrasts with the structural dynamics needed for DNA to cope rapidly and accurately with cell-specific and developmental programs regulation. Here, we combine super-resolution microscopy with state-of-the-art DNA labeling methods to reveal the variability in the multiscale organization of chromosomes in Drosophila . We find that TAD borders display very low contact frequency independently o f TAD size, epigenetic state, or cell type. Moreover, long range interactions and assemble of epigenetic domains into active/repressed compartments display different degrees of stochasticity that globally depended on cell-type. Overall, our results show that stochasticity is specifically modulated by sequence and epigenetic state at all levels of chromatin organization, revealing a novel mechanism for the spatial organization and regulation of genomes.

Project description:Distinct subtypes of intracortically-projecting neurons (ICPN) are present in all layers, allowing propagation of information within and across cortical columns. How the molecular identities of ICPN relate to their defining anatomical and functional properties is unknown. Here we show that the transcriptional identities of ICPN primarily reflect their broad axonal projections rather than their date of birth or laminar position. Thus, conserved circuit-related transcriptional programs are at play across cortical layers, which may preserve canonical circuit features across development.

Project description:Viral infections involve packaging of the viral genome and proteins into virions. Knowing virion composition and structure is critical to understand viral pathogenesis. However, an integrated picture of virion proteome organization of large viruses, such as Herpesviruses, is lacking. Here we use cross-linking mass spectrometry to derive a spatially resolved structural interactome of intact human cytomegalovirus virions. We capture interactions of 82 host and 33 viral proteins, allowing us to de novo allocate them into distinct virion-layers and identify several host proteins as constitutive virion components recruited via specific protein interactions. The abundant viral protein pp150 forms domain-specific interactions with all virion layers and scaffolds numerous viral and host proteins such as PP1 phosphatase and 14-3-3 proteins, which are incorporated via nearby short linear motifs in pp150’s C-terminus. PP1 recruitment antagonizes 14-3-3 proteins and is pivotal during early and late viral replication steps. Collectively, this study gives a spatial and quantitative inventory of the system-wide organization and functional relevance of protein interactions inside native herpesvirus particles.