Project description:Molecular mechanisms underlying dorsolateral prefrontal cortex (dlPFC) dysfunction in schizophrenia (SCZ) are poorly understood. dlPFC cell types are spatially organized across the six layers into functional microcircuits, which regulate cognitive and emotional processes that are implicated in SCZ. While regional specificity across cortical layers and cell types has been demonstrated for some SCZ-linked genes, spatially-resolved transcriptomics (SRT) can more definitively map molecular associations of disease. We investigated spatial gene expression changes in the human dlPFC from neurotypical control (n=31) and SCZ (n=32) brain donors using the Visium platform with incorporation of immunostaining to label perineuronal nets, neurons and vasculature. SCZ-associated DEGs were then mapped across these labeled cellular microenvironments and cortical layers. Major transcriptional alterations were identified in synaptic and neuroimmune pathways, which we localized to neuropil and glia-enriched domains. Integrative analysis with bulk and single-cell RNA studies highlighted distinct roles for spatially-localized glial cell populations, and identified enrichment of novel DEGs in endothelial cells and microglia. These findings were supported by enrichment of SCZ genetic risk across similar domains, and association of laminae-specific transcription factors to SCZ risk variants. Cellular resolution SRT using Xenium extended laminar disease associations to spatially-organized cell types. The findings highlight unique advantages of SRT to identify novel SCZ-related biology, particularly for cellular populations and compartments that may be missed with alternative technologies. We provide data resources to enable sample-level visualization of the spatial transcriptomics data (Samui) and to explore SCZ-associated DEGs across spatial domains (iSEE-layer adjusted) and cellular microenvironments (iSEE-Neuropil, iSEE-Neuron, iSEE-vasculature, iSEE-PNNs). The primary goal of the Xenium experiments was to cross-validate layer-adjusted schizophrenia-associated differentially expressed genes previously identified by Visium spatial transcriptomics at enhanced cellular resolution, along with a select set of previously reported SCZ-associated genes and risk factors.

Project description:Spatially resolved transcriptomics (SRT) produces complex, multi-dimensional gene expression data sets at up to subcellular spatial resolution. While SRT provides powerful datasets to probe biological processes, well-designed computational tools provide the key to extracting value from SRT technology. Currently, no single piece of software facilitates the combined automated analysis, visualisation, and subsequent interaction of single or multi-section SRT data as a desktop application or in an immersive environment. Here we present VR-Omics, a freely available, SRT platform agnostic, stand-alone programme that incorporates an in-built, automated workflow to pre-process and spatially mine SRT data within a user-friendly graphical interface. Benchmarking demonstrates VR-Omics has superior capabilities for seamless end-to-end analyses of SRT data, hence making SRT data processing and mining accessible to users regardless of computational and data handling skills. Importantly, VR-Omics supports comparison between datasets generated using different spatial technologies alongside processing and analysis of multiple 2D or 3D SRT datasets provides a unique environment for biological discovery. Finally, we utilise VR-Omics to uncover the molecular mechanisms that drive the growth of rare paediatric cardiac rhabdomyomas.

Project description:The hippocampus contains many unique cell types, which serve the structure’s specialized functions, including learning, memory and cognition. These cells have distinct spatial topography, morphology, physiology, and connectivity, highlighting the need for transcriptome-wide profiling strategies that retain cytoarchitectural organization. Here, we generated spatially-resolved transcriptomics (SRT) and single-nucleus RNA-sequencing (snRNA-seq) data from adjacent tissue sections of the anterior human hippocampus across ten adult neurotypical donors. We defined molecular profiles for hippocampal cell types and spatial domains. Using non-negative matrix factorization and transfer learning, we integrated these data to define gene expression patterns within the snRNA-seq data and probe their expression in the SRT data. Using this approach, we leveraged existing rodent datasets that feature information on circuit connectivity and neural activity induction to make predictions about axonal projection targets and likelihood of ensemble recruitment in spatially-defined cellular populations of the human hippocampus. Finally, we integrated genome-wide association studies with transcriptomic data to identify enrichment of genetic components for neurodevelopmental, neuropsychiatric, and neurodegenerative disorders across cell types, spatial domains, and gene expression patterns of the human hippocampus. To make this comprehensive molecular atlas accessible to the scientific community, both raw and processed data are freely available, including through interactive web applications.

Project description:The hippocampus contains many unique cell types, which serve the structure’s specialized functions, including learning, memory and cognition. These cells have distinct spatial topography, morphology, physiology, and connectivity, highlighting the need for transcriptome-wide profiling strategies that retain cytoarchitectural organization. Here, we generated spatially-resolved transcriptomics (SRT) and single-nucleus RNA-sequencing (snRNA-seq) data from adjacent tissue sections of the anterior human hippocampus across ten adult neurotypical donors. We defined molecular profiles for hippocampal cell types and spatial domains. Using non-negative matrix factorization and transfer learning, we integrated these data to define gene expression patterns within the snRNA-seq data and probe their expression in the SRT data. Using this approach, we leveraged existing rodent datasets that feature information on circuit connectivity and neural activity induction to make predictions about axonal projection targets and likelihood of ensemble recruitment in spatially-defined cellular populations of the human hippocampus. Finally, we integrated genome-wide association studies with transcriptomic data to identify enrichment of genetic components for neurodevelopmental, neuropsychiatric, and neurodegenerative disorders across cell types, spatial domains, and gene expression patterns of the human hippocampus. To make this comprehensive molecular atlas accessible to the scientific community, both raw and processed data are freely available, including through interactive web applications.

Project description:Patients with treatment-refractory pancreatic cancer often succumb to widespread systemic metastases; however, the transcriptomic heterogeneity that underlies recalcitrance to therapy remains understudied, particularly in the spatial context. We constructed high-resolution spatial maps of transcriptional heterogeneity, clonal architecture and lineage plasticity using spatially resolved transcriptomics (SRT) from 13 primary cancers and 36 corresponding liver, lung, and peritoneal metastases, collected via a rapid (“warm”) autopsy program. To validate findings from our SRT dataset at single-cell resolution, we performed CosMX SMI profiling (Nanostring) on 7 samples from 3 patients, including primary and/or liver metastasis.

Project description:The medulla is the largest neuropil of the Drosophila optic lobe. It contains about 100 neuronal types that have been comprehensively characterized morphologically and molecularly. These neuronal types are specified from a larval neuroepithelium called the Outer Proliferation Center (OPC) via the integration of temporal, spatial, and Notch-driven mechanisms. Although we recently characterized the temporal windows of origin of all medulla neurons, as well as their Notch status, their spatial origins remained unknown. Here, we isolated cells from different OPC spatial domains and performed single-cell mRNA-sequencing to identify the neuronal types produced in these domains. This allowed us to characterize in a high-throughput manner the spatial origins of all medulla neurons.

Project description:Spatially resolved transcriptomics has enabled precise genome-wide mRNA expression profiling within tissue sections. The performance of unbiased SRT methods targeting the polyA tail of mRNA, relies on the availability of specimens with high RNA quality. Moreover, the high cost of currently available SRT assays requires a careful sample screening process to increase the chance of obtaining high-quality data. Indeed, the upfront analysis of RNA quality can show considerable variability due to sample handling, storage, and/or intrinsic factors. We present RNA-Rescue Spatial Transcriptomics (RRST), an SRT workflow designed to improve mRNA recovery from fresh frozen specimens with moderate to low RNA quality. First, we provide a benchmark of RRST against the standard Visium spatial gene expression protocol on high RNA quality samples represented by mouse brain and prostate cancer samples. Then, we demonstrate the RRST protocol on tissue sections collected from five challenging tissue types, including: human lung, colon, small intestine, pediatric brain tumor, and mouse bone/cartilage. In total, we analyzed 52 tissue sections and our results demonstrate that RRST is a versatile, powerful, and reproducible protocol for FF specimens of different qualities and origins.

Project description:Human middle temporal gyrus (MTG) is a vulnerable brain region in early Alzheimer’s disease (AD), but little is known about the molecular mechanisms underlying this regional vulnerability. Here we utilize the 10x Visium platform to define the spatial transcriptomic profile in both AD and control (CT) MTG. We identify unique marker genes for cortical layers and the white matter, and layer-specific differentially expressed genes (DEGs) in human AD compared to CT. Deconvolution of the Visium spots showcases the significant difference in particular cell types among cortical layers and the white matter. Gene co-expression analyses reveal eight gene modules, four of which have significantly altered co-expression patterns in the presence of AD pathology. The co-expression patterns of hub genes and enriched pathways in the presence of AD pathology indicate an important role of cell-cell-communications among microglia, oligodendrocytes, astrocytes, and neurons, which may contribute to the cellular and regional vulnerability in early AD. Using single-molecule fluorescent in situ hybridization, we validated the cell-type-specific expression of three novel DEGs (e.g., KIF5A, PAQR6, and SLC1A3) and eleven previously reported DEGs associated with AD pathology (i.e., amyloid beta plaques and intraneuronal neurofibrillary tangles or neuropil threads) at the single cell level. Our results may contribute to the understanding of the complex architecture and neuronal and glial response to AD pathology of this vulnerable brain region.

Project description:Multiple distinct cell types of the human lung and airways have been defined by single cell RNA sequencing (scRNAseq). Here we present a multi-omics spatial lung atlas to define novel cell types which we map back into the macro- and micro-anatomical tissue context to define functional tissue microenvironments. Firstly, we have generated single cell and nuclei RNA sequencing, VDJ-sequencing and Visium Spatial Transcriptomics data sets from 5 different locations of the human lung and airways. Secondly, we define additional cell types/states, as well as spatially map novel and known human airway cell types, such as adult lung chondrocytes, submucosal gland (SMG) duct cells, distinct pericyte and smooth muscle subtypes, immune-recruiting fibroblasts, peribronchial and perichondrial fibroblasts, peripheral nerve associated fibroblasts and Schwann cells. Finally, we define a survival niche for IgA-secreting plasma cells at the SMG, comprising the newly defined epithelial SMG-Duct cells, and B and T lineage immune cells. Using our transcriptomic data for cell-cell interaction analysis, we propose a signalling circuit that establishes and supports this niche. Overall, we provide a transcriptional and spatial lung atlas with multiple novel cell types that allows for the study of specific tissue microenvironments such as the newly defined gland-associated lymphoid niche (GALN).

Project description:Tissue development, function, and disease are largely driven by the spatial organization of individual cells and their interactions within a complex and heterogeneous cellular microenvironment. Engineered tissue models provide a controllable platform to dissect these spatially driven processes. However, strategies to fabricate tissues that replicate near-exact spatial organization and cellular composition of native microenvironments, necessary to faithfully recapitulate in vivo spatial relationships, have remained elusive to date. Here we present a precision bioprinting approach capable of generating high-fidelity replicas of patient biopsies that preserve complex cellular organization and heterogeneity with subcellular resolution. We demonstrate spatial placement of individual cells with down to ~3 µm spatial precision and up to eight cell types per bioprint. Using this approach, we demonstrate for the first time that altering the microscale spatial organization of tumor microenvironments of similar cellular composition can significantly alter transcriptomic programs of cell response. The ability to engineer and manipulate native cellular microenvironments with single-cell resolution marks a significant advancement toward understanding the critical influence of spatial biology on complex biological systems, such as the tumor microenvironment and organogenesis.