Probabilistic cell typing enables fine mapping of closely related cell types in situ

Qian, Xiaoyan; Harris, Kenneth D.; Hauling, Thomas; Nicoloutsopoulos, Dimitris; Muñoz-Manchado, Ana B.; Skene, Nathan G.; Hjerling-Leffler, Jens; Nilsson, Mats

doi:10.1038/s41592-019-0631-4

Cited by 219 publications

(368 citation statements)

References 32 publications

(39 reference statements)

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“…This has not been possible in previous ISS methods in that every PLP would be detected every round and problematic genes such as high expressers would have to be run separately. Decoding is performed through sequential combinatorial decoding scheme similar to previous ISS methods, where each barcode has a hamming distance of at least two, allowing for correction and probabilistic assignment of barcodes with better accuracy (Figure 1c) 20,21 . Moreover, with bridgeprobes, this now also allows the possibility for further error correction by including 'zeroes' in the decoding scheme where bridge-probes are simply excluded for a subset of genes in different rounds of probing.…”

Section: Resultsmentioning

confidence: 99%

“…The simplicity and flexibility of HybISS makes it a versatile image-based spatial transcriptomic method that can be easily implemented and adapted for a wide variety of scientific questions. Customizing gene lists will be vital as it is a targeted approach and curating custom gene panels from scRNA-seq data, such as probabilistic cell typing by in situ sequencing (pciSeq) 21 , to create cell-type atlases will provide a useful tool in the HybISS method.…”

Section: Discussionmentioning

confidence: 99%

“…We see the great potential of implementing HybISS in spatial cell atlas projects. SBL ISS has been demonstrated to assign cell types in mouse hippocampus 21 and neural crest development 18 . ISS has also been applied and analyzed together with scRNA-seq data and data from untargeted transcriptome-wide Spatial Transcriptomics 31 to develop a spatiotemporal atlas of the developing human heart 32 .…”

Section: Discussionmentioning

confidence: 99%

“…Multiplexed in situ hybridization offers the possibility to explore cellular diversity at subcellular resolution in a upscaled approach. As an example, our lab has developed in situ sequencing (ISS) to be used to detect RNA isoforms 19 , transcriptomic distribution 20 , and cell typing across tissue sections 21 . The established ISS method based on barcoded padlock probes (PLPs) and amplification through rolling circle amplification (RCA) has shown robust detection of RNA for various applications, however further improvements are needed to meet the upscaling demands to explore cellular diversity of scRNAseq data across large tissue areas of various origins.…”

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confidence: 99%

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Hybridization-based In Situ Sequencing (HybISS): spatial transcriptomic detection in human and mouse brain tissue

Gyllborg

Langseth

Qian

et al. 2020

Preprint

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Visualization of the transcriptome in situ has proven to be a valuable tool in exploring single-cell RNAsequencing data, providing an additional dimension to investigate spatial cell typing and cell atlases, disease architecture or even data driven discoveries. The field of spatially resolved transcriptomic technologies is emerging as a vital tool to profile gene-expression, continuously pushing current methods to accommodate larger gene panels and larger areas without compromising throughput efficiency. Here, we describe a new version of the in situ sequencing (ISS) method based on padlock probes and rolling circle amplification. Modifications in probe design allows for a new barcoding system via sequence-by-hybridization chemistry for improved spatial detection of RNA transcripts. Due to the amplification of probes, amplicons can be visualized with standard epifluorescence microscopes with high-throughput efficiency and the new sequencing chemistry removes limitations bound by sequence-by-ligation chemistry of ISS. Here we present hybridization-based in situ sequencing (HybISS) that allows for increased flexibility and multiplexing, increased signal-to-noise, all without compromising throughput efficiency of imaging large fields of view. Moreover, the current protocol is demonstrated to work on human brain tissue samples, a source that has proven to be difficult to work with image-based spatial analysis techniques. Overall, HybISS technology works as a target amplification detection method for improved spatial transcriptomic visualization, and importantly, with an ease of implementation.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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Hybridization-based In Situ Sequencing (HybISS): spatial transcriptomic detection in human and mouse brain tissue

Gyllborg

Langseth

Qian

et al. 2020

Preprint

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“…Other techniques based on probe hybridisation or local sequencing provide expression information in situ, recovering the position of the cells interrogated (reviewed in (Lein et al, 2017)). Such spatial transcriptomics techniques can be correlated and complemented with single-cell transcriptomics Phillips et al, 2019;Qian et al, 2020), and recent developments using viral barcoding have also enabled the integration of long-range projection information in a brain-wide manner (Chen et al, 2019). However, these approaches only retrieve multimodal information for small subsets of cells and/or their scalability is not straight-forward beyond a set of tissue slices (Ortiz et al, 2019), though this could suffice for small organisms (Ebbing et al, 2018).…”

Section: Seeking Multimodalitymentioning

confidence: 99%

Whole-body integration of gene expression and single-cell morphology

Vergara

Pape

Meechan

et al. 2020

Preprint

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Animal bodies are composed of hundreds of cell types that differ in location, morphology, cytoarchitecture, and physiology. This is reflected by cell type-specific transcription factors and downstream effector genes implementing functional specialisation. Here, we establish and explore the link between cell type-specific gene expression and subcellular morphology for the entire body of the marine annelid Platynereis dumerilii. For this, we registered a whole-body cellular expression atlas to a high-resolution electron microscopy dataset, automatically segmented all cell somata and nuclei, and clustered the cells according to gene expression or morphological parameters. We show that collective gene expression most efficiently identifies spatially coherent groups of cells that match anatomical boundaries, which indicates that combinations of regionally expressed transcription factors specify tissue identity. We provide an integrated browser as a Fiji plugin to readily explore, analyse and visualise multimodal datasets with remote ondemand access to all available datasets. Figure 1: Ultrastructure of a whole Platynereis by serial block-face scanning electron microscopy.A: The 3D SBEM dataset can be observed in multiple orientations, either along the acquisition plane (transversal plane, top row) or as orthogonal projections (horizontal plane, bottom row; scale bar: 50 µm). B-E: fine ultrastructure is revealed when exploring the datasets at native resolution (10 nm pixel-size x/y; scale bars: 2 µm). B: epithelial cell, interfacing the cuticle and the underlying muscle. Bundles of cytoskeletal filaments (arrowhead) form part of the attachment complex (inset). C: the adult eye forms a pigment cup composed of pigment cells (PiC) and rhabdomeric photoreceptors (rPRC). The photoreceptors extend a distal segment made by microvillar projections (mi) for light detection. In the centre of the pigment cup is the vitreous body (vb). D: longitudinal muscle fibres are cut transversally displaying cross-sections of the sarcomere as well as of the sarcoplasmic reticulum that contacts the plasma membrane (inset). E: cross section of the distal part of the nephridia, highlighting the autocell junction (arrow) which forms a lumen. The lumen houses a bundle of motile cilia (identified by the 9+2 microtubule arrangement, inset), which are contributed by each cell of the nephridium, noted by the presence of basal bodies. Panels B to E are snapshots selected from the full volume and can be retrieved directly from the PlatyBrowser "Bookmark" function. Supplementary Figure 2A). Figure 2 gives a few examples of the achieved segmentation quality for epidermal cells (B), muscles (C) and nephridia (D). We measured nuclei sizes to range from 33.6 to 147.5 cubic microns, and cell sizes from 59.8 to 1224.6 cubic microns. Note that neurites in the neuropil have not been segmented, as they are not sufficiently preserved in the EM volume for automated segmentation. Figure 2: Segmentation of nuclei, cells, tissues and body parts.A. Cells and nuclei ar...

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Spatial Transcriptomics: Technical Aspects of Recent Developments and Their Applications in Neuroscience and Cancer Research

Park

Lee

et al. 2023

Advanced Science

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Spatial transcriptomics is a newly emerging field that enables high‐throughput investigation of the spatial localization of transcripts and related analyses in various applications for biological systems. By transitioning from conventional biological studies to “in situ” biology, spatial transcriptomics can provide transcriptome‐scale spatial information. Currently, the ability to simultaneously characterize gene expression profiles of cells and relevant cellular environment is a paradigm shift for biological studies. In this review, recent progress in spatial transcriptomics and its applications in neuroscience and cancer studies are highlighted. Technical aspects of existing technologies and future directions of new developments (as of March 2023), computational analysis of spatial transcriptome data, application notes in neuroscience and cancer studies, and discussions regarding future directions of spatial multi‐omics and their expanding roles in biomedical applications are emphasized.

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Probabilistic cell typing enables fine mapping of closely related cell types in situ

Cited by 219 publications

References 32 publications

Hybridization-based In Situ Sequencing (HybISS): spatial transcriptomic detection in human and mouse brain tissue

Hybridization-based In Situ Sequencing (HybISS): spatial transcriptomic detection in human and mouse brain tissue

Whole-body integration of gene expression and single-cell morphology

Spatial Transcriptomics: Technical Aspects of Recent Developments and Their Applications in Neuroscience and Cancer Research

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