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183 results on '"spatially resolved transcriptomics"'

5. Spall: accurate and robust unveiling cellular landscapes from spatially resolved transcriptomics data using a decomposition network.

Author

Jiang, Zhongning, Huang, Wei, Lam, Raymond H. W., and Zhang, Wei

Subjects
*GRAPH neural networks, *CELL preservation, *PANCREATIC duct, *TRANSCRIPTOMES, *CEREBRAL cortex
Abstract

Recent developments in spatially resolved transcriptomics (SRT) enable the characterization of spatial structures for different tissues. Many decomposition methods have been proposed to depict the cellular distribution within tissues. However, existing computational methods struggle to balance spatial continuity in cell distribution with the preservation of cell-specific characteristics. To address this, we propose Spall, a novel decomposition network that integrates scRNA-seq data with SRT data to accurately infer cell type proportions. Spall introduced the GATv2 module, featuring a flexible dynamic attention mechanism to capture relationships between spots. This improves the identification of cellular distribution patterns in spatial analysis. Additionally, Spall incorporates skip connections to address the loss of cell-specific information, thereby enhancing the prediction capability for rare cell types. Experimental results show that Spall outperforms the state-of-the-art methods in reconstructing cell distribution patterns on multiple datasets. Notably, Spall reveals tumor heterogeneity in human pancreatic ductal adenocarcinoma samples and delineates complex tissue structures, such as the laminar organization of the mouse cerebral cortex and the mouse cerebellum. These findings highlight the ability of Spall to provide reliable low-dimensional embeddings for downstream analyses, offering new opportunities for deciphering tissue structures. [ABSTRACT FROM AUTHOR]

Published
2024
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6. From Omics to Multi-Omics: A Review of Advantages and Tradeoffs.

Author

Hayes, C. Nelson, Nakahara, Hikaru, Ono, Atsushi, Tsuge, Masataka, and Oka, Shiro

Subjects
*MULTIOMICS, *TRANSCRIPTOMES, *RNA sequencing, *LIPIDOMICS, *EPIGENOMICS
Abstract

Bioinformatics is a rapidly evolving field charged with cataloging, disseminating, and analyzing biological data. Bioinformatics started with genomics, but while genomics focuses more narrowly on the genes comprising a genome, bioinformatics now encompasses a much broader range of omics technologies. Overcoming barriers of scale and effort that plagued earlier sequencing methods, bioinformatics adopted an ambitious strategy involving high-throughput and highly automated assays. However, as the list of omics technologies continues to grow, the field of bioinformatics has changed in two fundamental ways. Despite enormous success in expanding our understanding of the biological world, the failure of bulk methods to account for biologically important variability among cells of the same or different type has led to a major shift toward single-cell and spatially resolved omics methods, which attempt to disentangle the conflicting signals contained in heterogeneous samples by examining individual cells or cell clusters. The second major shift has been the attempt to integrate two or more different classes of omics data in a single multimodal analysis to identify patterns that bridge biological layers. For example, unraveling the cause of disease may reveal a metabolite deficiency caused by the failure of an enzyme to be phosphorylated because a gene is not expressed due to aberrant methylation as a result of a rare germline variant. Conclusions: There is a fine line between superficial understanding and analysis paralysis, but like a detective novel, multi-omics increasingly provides the clues we need, if only we are able to see them. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Graph domain adaptation–based framework for gene expression enhancement and cell type identification in large-scale spatially resolved transcriptomics.

Author

Shen, Rongbo, Cheng, Meiling, Wang, Wencang, Fan, Qi, Yan, Huan, Wen, Jiayue, Yuan, Zhiyuan, Yao, Jianhua, Li, Yixue, and Yuan, Jiao

Subjects
*SCIENTIFIC literature, *GENE expression, *TRANSCRIPTOMES, *GENE expression profiling, *SPATIAL resolution, *DEEP learning
Abstract

Spatially resolved transcriptomics (SRT) technologies facilitate gene expression profiling with spatial resolution in a naïve state. Nevertheless, current SRT technologies exhibit limitations, manifesting as either low transcript detection sensitivity or restricted gene throughput. These constraints result in diminished precision and coverage in gene measurement. In response, we introduce SpaGDA, a sophisticated deep learning–based graph domain adaptation framework for both scenarios of gene expression imputation and cell type identification in spatially resolved transcriptomics data by impartially transferring knowledge from reference scRNA-seq data. Systematic benchmarking analyses across several SRT datasets generated from different technologies have demonstrated SpaGDA's superior effectiveness compared to state-of-the-art methods in both scenarios. Further applied to three SRT datasets of different biological contexts, SpaGDA not only better recovers the well-established knowledge sourced from public atlases and existing scientific literature but also yields a more informative spatial expression pattern of genes. Together, these results demonstrate that SpaGDA can be used to overcome the challenges of current SRT data and provide more accurate insights into biological processes or disease development. The SpaGDA is available in https://github.com/shenrb/SpaGDA. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Deep clustering representation of spatially resolved transcriptomics data using multi-view variational graph auto-encoders with consensus clustering

Author

Jinyun Niu, Fangfang Zhu, Taosheng Xu, Shunfang Wang, and Wenwen Min

Subjects
Spatially resolved transcriptomics, Deep learning, Multi-view variational graph autoencoders, Consensus clustering, Biotechnology, TP248.13-248.65
Abstract

The rapid development of spatial transcriptomics (ST) technology has provided unprecedented opportunities to understand tissue relationships and functions within specific spatial contexts. Accurate identification of spatial domains is crucial for downstream spatial transcriptomics analysis. However, effectively combining gene expression data, histological images and spatial coordinate data to identify spatial domains remains a challenge. To this end, we propose STMVGAE, a novel spatial transcriptomics analysis tool that combines a multi-view variational graph autoencoder with a consensus clustering framework. STMVGAE begins by extracting histological images features using a pre-trained convolutional neural network (CNN) and integrates these features with gene expression data to generate augmented gene expression profiles. Subsequently, multiple graphs (views) are constructed using various similarity measures, capturing different aspects of the spatial and transcriptional relationships. These views, combined with the augmented gene expression data, are then processed through variational graph auto-encoders (VGAEs) to learn multiple low-dimensional latent embeddings. Finally, the model employs a consensus clustering method to integrate the clustering results derived from these embeddings, significantly improving clustering accuracy and stability. We applied STMVGAE to five real datasets and compared it with five state-of-the-art methods, showing that STMVGAE consistently achieves competitive results. We assessed its capabilities in spatial domain identification and evaluated its performance across various downstream tasks, including UMAP visualization, PAGA trajectory inference, spatially variable gene (SVG) identification, denoising, batch integration, and other analyses. All code and public datasets used in this paper is available at https://github.com/wenwenmin/STMVGAE and https://zenodo.org/records/13119867.

Published
2024
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9. Systematic evaluation with practical guidelines for single-cell and spatially resolved transcriptomics data simulation under multiple scenarios

Author

Hongrui Duo, Yinghong Li, Yang Lan, Jingxin Tao, Qingxia Yang, Yingxue Xiao, Jing Sun, Lei Li, Xiner Nie, Xiaoxi Zhang, Guizhao Liang, Mingwei Liu, Youjin Hao, and Bo Li

Subjects
Evaluation, Single-cell transcriptomics, Spatially resolved transcriptomics, Data simulation, Guideline, Biology (General), QH301-705.5, Genetics, QH426-470
Abstract

Abstract Background Single-cell RNA sequencing (scRNA-seq) and spatially resolved transcriptomics (SRT) have led to groundbreaking advancements in life sciences. To develop bioinformatics tools for scRNA-seq and SRT data and perform unbiased benchmarks, data simulation has been widely adopted by providing explicit ground truth and generating customized datasets. However, the performance of simulation methods under multiple scenarios has not been comprehensively assessed, making it challenging to choose suitable methods without practical guidelines. Results We systematically evaluated 49 simulation methods developed for scRNA-seq and/or SRT data in terms of accuracy, functionality, scalability, and usability using 152 reference datasets derived from 24 platforms. SRTsim, scDesign3, ZINB-WaVE, and scDesign2 have the best accuracy performance across various platforms. Unexpectedly, some methods tailored to scRNA-seq data have potential compatibility for simulating SRT data. Lun, SPARSim, and scDesign3-tree outperform other methods under corresponding simulation scenarios. Phenopath, Lun, Simple, and MFA yield high scalability scores but they cannot generate realistic simulated data. Users should consider the trade-offs between method accuracy and scalability (or functionality) when making decisions. Additionally, execution errors are mainly caused by failed parameter estimations and appearance of missing or infinite values in calculations. We provide practical guidelines for method selection, a standard pipeline Simpipe ( https://github.com/duohongrui/simpipe ; https://doi.org/10.5281/zenodo.11178409 ), and an online tool Simsite ( https://www.ciblab.net/software/simshiny/ ) for data simulation. Conclusions No method performs best on all criteria, thus a good-yet-not-the-best method is recommended if it solves problems effectively and reasonably. Our comprehensive work provides crucial insights for developers on modeling gene expression data and fosters the simulation process for users.

Published
2024
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10. iIMPACT: integrating image and molecular profiles for spatial transcriptomics analysis

Author

Xi Jiang, Shidan Wang, Lei Guo, Bencong Zhu, Zhuoyu Wen, Liwei Jia, Lin Xu, Guanghua Xiao, and Qiwei Li

Subjects
Spatially resolved transcriptomics, AI-reconstructed histology image, Markov random field, Spatial clustering, Spatially variable gene, Biology (General), QH301-705.5, Genetics, QH426-470
Abstract

Abstract Current clustering analysis of spatial transcriptomics data primarily relies on molecular information and fails to fully exploit the morphological features present in histology images, leading to compromised accuracy and interpretability. To overcome these limitations, we have developed a multi-stage statistical method called iIMPACT. It identifies and defines histology-based spatial domains based on AI-reconstructed histology images and spatial context of gene expression measurements, and detects domain-specific differentially expressed genes. Through multiple case studies, we demonstrate iIMPACT outperforms existing methods in accuracy and interpretability and provides insights into the cellular spatial organization and landscape of functional genes within spatial transcriptomics data.

Published
2024
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11. Multi-modal domain adaptation for revealing spatial functional landscape from spatially resolved transcriptomics.

Author

Wang, Lequn, Hu, Yaofeng, Xiao, Kai, Zhang, Chuanchao, Shi, Qianqian, and Chen, Luonan

Subjects
*TRANSCRIPTOMES, *GENE expression, *BIOLOGICAL systems, *MORPHOGENESIS, *DATA integration, *MOLECULAR pathology
Abstract

Spatially resolved transcriptomics (SRT) has emerged as a powerful tool for investigating gene expression in spatial contexts, providing insights into the molecular mechanisms underlying organ development and disease pathology. However, the expression sparsity poses a computational challenge to integrate other modalities (e.g. histological images and spatial locations) that are simultaneously captured in SRT datasets for spatial clustering and variation analyses. In this study, to meet such a challenge, we propose multi-modal domain adaption for spatial transcriptomics (stMDA), a novel multi-modal unsupervised domain adaptation method, which integrates gene expression and other modalities to reveal the spatial functional landscape. Specifically, stMDA first learns the modality-specific representations from spatial multi-modal data using multiple neural network architectures and then aligns the spatial distributions across modal representations to integrate these multi-modal representations, thus facilitating the integration of global and spatially local information and improving the consistency of clustering assignments. Our results demonstrate that stMDA outperforms existing methods in identifying spatial domains across diverse platforms and species. Furthermore, stMDA excels in identifying spatially variable genes with high prognostic potential in cancer tissues. In conclusion, stMDA as a new tool of multi-modal data integration provides a powerful and flexible framework for analyzing SRT datasets, thereby advancing our understanding of intricate biological systems. [ABSTRACT FROM AUTHOR]

Published
2024
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12. A multi-view graph contrastive learning framework for deciphering spatially resolved transcriptomics data.

Author

Zhang, Lei, Liang, Shu, and Wan, Lin

Subjects
*TRANSCRIPTOMES, *GENE expression profiling, *GENE expression
Abstract

Spatially resolved transcriptomics data are being used in a revolutionary way to decipher the spatial pattern of gene expression and the spatial architecture of cell types. Much work has been done to exploit the genomic spatial architectures of cells. Such work is based on the common assumption that gene expression profiles of spatially adjacent spots are more similar than those of more distant spots. However, related work might not consider the nonlocal spatial co-expression dependency, which can better characterize the tissue architectures. Therefore, we propose MuCoST, a Mu lti-view graph Co ntrastive learning framework for deciphering complex S patially resolved T ranscriptomic architectures with dual scale structural dependency. To achieve this, we employ spot dependency augmentation by fusing gene expression correlation and spatial location proximity, thereby enabling MuCoST to model both nonlocal spatial co-expression dependency and spatially adjacent dependency. We benchmark MuCoST on four datasets, and we compare it with other state-of-the-art spatial domain identification methods. We demonstrate that MuCoST achieves the highest accuracy on spatial domain identification from various datasets. In particular, MuCoST accurately deciphers subtle biological textures and elaborates the variation of spatially functional patterns. [ABSTRACT FROM AUTHOR]

Published
2024
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13. Attention-guided variational graph autoencoders reveal heterogeneity in spatial transcriptomics.

Author

Lei, Lixin, Han, Kaitai, Wang, Zijun, Shi, Chaojing, Wang, Zhenghui, Dai, Ruoyan, Zhang, Zhiwei, Wang, Mengqiu, and Guo, Qianjin

Subjects
*TRANSCRIPTOMES, *GRAPH neural networks, *PHENOMENOLOGICAL biology, *GENE expression, *HETEROGENEITY
Abstract

The latest breakthroughs in spatially resolved transcriptomics technology offer comprehensive opportunities to delve into gene expression patterns within the tissue microenvironment. However, the precise identification of spatial domains within tissues remains challenging. In this study, we introduce AttentionVGAE (AVGN), which integrates slice images, spatial information and raw gene expression while calibrating low-quality gene expression. By combining the variational graph autoencoder with multi-head attention blocks (MHA blocks), AVGN captures spatial relationships in tissue gene expression, adaptively focusing on key features and alleviating the need for prior knowledge of cluster numbers, thereby achieving superior clustering performance. Particularly, AVGN attempts to balance the model's attention focus on local and global structures by utilizing MHA blocks, an aspect that current graph neural networks have not extensively addressed. Benchmark testing demonstrates its significant efficacy in elucidating tissue anatomy and interpreting tumor heterogeneity, indicating its potential in advancing spatial transcriptomics research and understanding complex biological phenomena. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Inferring Allele-Specific Copy Number Aberrations and Tumor Phylogeography from Spatially Resolved Transcriptomics

Author

Ma, Cong, Balaban, Metin, Liu, Jingxian, Chen, Siqi, Ding, Li, Raphael, Benjamin J., Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, van Leeuwen, Jan, Series Editor, Hutchison, David, Editorial Board Member, Kanade, Takeo, Editorial Board Member, Kittler, Josef, Editorial Board Member, Kleinberg, Jon M., Editorial Board Member, Kobsa, Alfred, Series Editor, Mattern, Friedemann, Editorial Board Member, Mitchell, John C., Editorial Board Member, Naor, Moni, Editorial Board Member, Nierstrasz, Oscar, Series Editor, Pandu Rangan, C., Editorial Board Member, Sudan, Madhu, Series Editor, Terzopoulos, Demetri, Editorial Board Member, Tygar, Doug, Editorial Board Member, Weikum, Gerhard, Series Editor, Vardi, Moshe Y, Series Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, and Ma, Jian, editor

Published
2024
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15. Deep learning in spatially resolved transcriptfomics: a comprehensive technical view.

Author

Zahedi, Roxana, Ghamsari, Reza, Argha, Ahmadreza, Macphillamy, Callum, Beheshti, Amin, Alizadehsani, Roohallah, Lovell, Nigel H, Lotfollahi, Mohammad, and Alinejad-Rokny, Hamid

Subjects
*DEEP learning, *MACHINE learning, *GENE expression, *TRANSCRIPTOMES, *SCIENTIFIC community
Abstract

Spatially resolved transcriptomics (SRT) is a pioneering method for simultaneously studying morphological contexts and gene expression at single-cell precision. Data emerging from SRT are multifaceted, presenting researchers with intricate gene expression matrices, precise spatial details and comprehensive histology visuals. Such rich and intricate datasets, unfortunately, render many conventional methods like traditional machine learning and statistical models ineffective. The unique challenges posed by the specialized nature of SRT data have led the scientific community to explore more sophisticated analytical avenues. Recent trends indicate an increasing reliance on deep learning algorithms, especially in areas such as spatial clustering, identification of spatially variable genes and data alignment tasks. In this manuscript, we provide a rigorous critique of these advanced deep learning methodologies, probing into their merits, limitations and avenues for further refinement. Our in-depth analysis underscores that while the recent innovations in deep learning tailored for SRT have been promising, there remains a substantial potential for enhancement. A crucial area that demands attention is the development of models that can incorporate intricate biological nuances, such as phylogeny-aware processing or in-depth analysis of minuscule histology image segments. Furthermore, addressing challenges like the elimination of batch effects, perfecting data normalization techniques and countering the overdispersion and zero inflation patterns seen in gene expression is pivotal. To support the broader scientific community in their SRT endeavors, we have meticulously assembled a comprehensive directory of readily accessible SRT databases, hoping to serve as a foundation for future research initiatives. [ABSTRACT FROM AUTHOR]

Published
2024
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16. Spatially contrastive variational autoencoder for deciphering tissue heterogeneity from spatially resolved transcriptomics.

Author

Hu, Yaofeng, Xiao, Kai, Yang, Hengyu, Liu, Xiaoping, Zhang, Chuanchao, and Shi, Qianqian

Subjects
*TRANSCRIPTOMES, *GRAPH neural networks, *HETEROGENEITY
Abstract

Recent advances in spatially resolved transcriptomics (SRT) have brought ever-increasing opportunities to characterize expression landscape in the context of tissue spatiality. Nevertheless, there still exist multiple challenges to accurately detect spatial functional regions in tissue. Here, we present a novel contrastive learning framework, SPAtially Contrastive variational AutoEncoder (SpaCAE), which contrasts transcriptomic signals of each spot and its spatial neighbors to achieve fine-grained tissue structures detection. By employing a graph embedding variational autoencoder and incorporating a deep contrastive strategy, SpaCAE achieves a balance between spatial local information and global information of expression, enabling effective learning of representations with spatial constraints. Particularly, SpaCAE provides a graph deconvolutional decoder to address the smoothing effect of local spatial structure on expression's self-supervised learning, an aspect often overlooked by current graph neural networks. We demonstrated that SpaCAE could achieve effective performance on SRT data generated from multiple technologies for spatial domains identification and data denoising, making it a remarkable tool to obtain novel insights from SRT studies. [ABSTRACT FROM AUTHOR]

Published
2024
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17. Recent advances in differential expression analysis for single-cell RNA-seq and spatially resolved transcriptomic studies.

Author

Guo, Xiya, Ning, Jin, Chen, Yuanze, Liu, Guoliang, Zhao, Liyan, Fan, Yue, and Sun, Shiquan

Subjects
*GENE expression, *RNA sequencing, *TRANSCRIPTOMES
Abstract

Differential expression (DE) analysis is a necessary step in the analysis of single-cell RNA sequencing (scRNA-seq) and spatially resolved transcriptomics (SRT) data. Unlike traditional bulk RNA-seq, DE analysis for scRNA-seq or SRT data has unique characteristics that may contribute to the difficulty of detecting DE genes. However, the plethora of DE tools that work with various assumptions makes it difficult to choose an appropriate one. Furthermore, a comprehensive review on detecting DE genes for scRNA-seq data or SRT data from multi-condition, multi-sample experimental designs is lacking. To bridge such a gap, here, we first focus on the challenges of DE detection, then highlight potential opportunities that facilitate further progress in scRNA-seq or SRT analysis, and finally provide insights and guidance in selecting appropriate DE tools or developing new computational DE methods. [ABSTRACT FROM AUTHOR]

Published
2024
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18. Promise of spatially resolved omics for tumor research

Author

Yanhe Zhou, Xinyi Jiang, Xiangyi Wang, Jianpeng Huang, Tong Li, Hongtao Jin, and Jiuming He

Subjects
Tumor, Spatially resolved transcriptomics, Spatially resolved metabolomics, Therapeutics. Pharmacology, RM1-950
Abstract

Tumors are spatially heterogeneous tissues that comprise numerous cell types with intricate structures. By interacting with the microenvironment, tumor cells undergo dynamic changes in gene expression and metabolism, resulting in spatiotemporal variations in their capacity for proliferation and metastasis. In recent years, the rapid development of histological techniques has enabled efficient and high-throughput biomolecule analysis. By preserving location information while obtaining a large number of gene and molecular data, spatially resolved metabolomics (SRM) and spatially resolved transcriptomics (SRT) approaches can offer new ideas and reliable tools for the in-depth study of tumors. This review provides a comprehensive introduction and summary of the fundamental principles and research methods used for SRM and SRT techniques, as well as a review of their applications in cancer-related fields.

Published
2023
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19. Superresolved spatial transcriptomics transferred from a histological context.

Author

Wang, Shu, Zhou, Xiaocheng, Kong, Yan, and Lu, Hui

Subjects
DEEP learning, TRANSCRIPTOMES, CONVOLUTIONAL neural networks, GENE expression
Abstract

Spatially resolved transcriptomics (SRT) is a vital technique in biology that allows for gene expression measurement at the resolution of individual spots while preserving spatial information. However, owing to technical limitations, single-spot resolution often includes data from multiple cells, leading to suboptimal results and opportunities for improvement. In this study, we propose a deep learning-based, plug-and-play method for enhancing spot resolution to obtain higher-resolution SRT data. Our approach involves training a convolutional neural network (CNN) model and introducing a shift-predict operation to obtain superresolution spots. Using a human breast cancer SRT dataset, we demonstrate that our method achieves 9 × superresolution, outperforming traditional superresolution techniques. Crucially, our method decreased the mean squared error (MSE) to 1.379 for all genes, 2.287 for tumor-related genes at 4 × superresolution, 1.866 for all genes, and 3.371 for tumor-related genes at 9 × superresolution, reflecting substantial improvements compared to the traditional approaches, including Gaussian RBF, multiquadric RBF, linear RBF, resize-predict, bilinear, and bicubic methods. Furthermore, we verify our method's effectiveness using external and simulated datasets. Our proposed method offers a substantial advancement in SRT by enabling higher-resolution gene expression data generation. By providing a deeper understanding of gene expression patterns and their underlying biological significance, this method contributes to progress in biology and medicine. [ABSTRACT FROM AUTHOR]

Published
2023
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20. Harnessing computational spatial omics to explore the spatial biology intricacies.

Author

Yuan, Zhiyuan and Yao, Jianhua

Subjects
*BIOLOGY
Abstract

Spatially resolved transcriptomics (SRT) has unlocked new dimensions in our understanding of intricate tissue architectures. However, this rapidly expanding field produces a wealth of diverse and voluminous data, necessitating the evolution of sophisticated computational strategies to unravel inherent patterns. Two distinct methodologies, gene spatial pattern recognition (GSPR) and tissue spatial pattern recognition (TSPR), have emerged as vital tools in this process. GSPR methodologies are designed to identify and classify genes exhibiting noteworthy spatial patterns, while TSPR strategies aim to understand intercellular interactions and recognize tissue domains with molecular and spatial coherence. In this review, we provide a comprehensive exploration of SRT, highlighting crucial data modalities and resources that are instrumental for the development of methods and biological insights. We address the complexities and challenges posed by the use of heterogeneous data in developing GSPR and TSPR methodologies and propose an optimal workflow for both. We delve into the latest advancements in GSPR and TSPR, examining their interrelationships. Lastly, we peer into the future, envisaging the potential directions and perspectives in this dynamic field. [ABSTRACT FROM AUTHOR]

Published
2023
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21. Identifying spatial domains of spatially resolved transcriptomics via multi-view graph convolutional networks.

Author

Shi, Xuejing, Zhu, Juntong, Long, Yahui, and Liang, Cheng

Subjects
*GENE expression profiling, *GENE expression, *BIOLOGICAL networks
Abstract

Motivation: Recent advances in spatially resolved transcriptomics (ST) technologies enable the measurement of gene expression profiles while preserving cellular spatial context. Linking gene expression of cells with their spatial distribution is essential for better understanding of tissue microenvironment and biological progress. However, effectively combining gene expression data with spatial information to identify spatial domains remains challenging. Results: To deal with the above issue, in this paper, we propose a novel unsupervised learning framework named STMGCN for identifying spatial domains using multi-view graph convolution networks (MGCNs). Specifically, to fully exploit spatial information, we first construct multiple neighbor graphs (views) with different similarity measures based on the spatial coordinates. Then, STMGCN learns multiple view-specific embeddings by combining gene expressions with each neighbor graph through graph convolution networks. Finally, to capture the importance of different graphs, we further introduce an attention mechanism to adaptively fuse view-specific embeddings and thus derive the final spot embedding. STMGCN allows for the effective utilization of spatial context to enhance the expressive power of the latent embeddings with multiple graph convolutions. We apply STMGCN on two simulation datasets and five real spatial transcriptomics datasets with different resolutions across distinct platforms. The experimental results demonstrate that STMGCN obtains competitive results in spatial domain identification compared with five state-of-the-art methods, including spatial and non-spatial alternatives. Besides, STMGCN can detect spatially variable genes with enriched expression patterns in the identified domains. Overall, STMGCN is a powerful and efficient computational framework for identifying spatial domains in spatial transcriptomics data. [ABSTRACT FROM AUTHOR]

Published
2023
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22. Padlock Probe–Based Targeted In Situ Sequencing: Overview of Methods and Applications.

Author

Magoulopoulou, Anastasia, Salas, Sergio Marco, Tiklová, Katarína, Samuelsson, Erik Reinhold, Hilscher, Markus M., and Nilsson, Mats

Abstract

Elucidating spatiotemporal changes in gene expression has been an essential goal in studies of health, development, and disease. In the emerging field of spatially resolved transcriptomics, gene expression profiles are acquired with the tissue architecture maintained, sometimes at cellular resolution. This has allowed for the development of spatial cell atlases, studies of cell–cell interactions, and in situ cell typing. In this review, we focus on padlock probe–based in situ sequencing, which is a targeted spatially resolved transcriptomic method. We summarize recent methodological and computational tool developments and discuss key applications. We also discuss compatibility with other methods and integration with multiomic platforms for future applications. [ABSTRACT FROM AUTHOR]

Published
2023
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23. Promise of spatially resolved omics for tumor research.

Author

Zhou, Yanhe, Jiang, Xinyi, Wang, Xiangyi, Huang, Jianpeng, Li, Tong, Jin, Hongtao, and He, Jiuming

Subjects
HISTOLOGICAL techniques, TUMORS, GENE expression, METABOLOMICS
Abstract

Tumors are spatially heterogeneous tissues that comprise numerous cell types with intricate structures. By interacting with the microenvironment, tumor cells undergo dynamic changes in gene expression and metabolism, resulting in spatiotemporal variations in their capacity for proliferation and metastasis. In recent years, the rapid development of histological techniques has enabled efficient and high-throughput biomolecule analysis. By preserving location information while obtaining a large number of gene and molecular data, spatially resolved metabolomics (SRM) and spatially resolved transcriptomics (SRT) approaches can offer new ideas and reliable tools for the in-depth study of tumors. This review provides a comprehensive introduction and summary of the fundamental principles and research methods used for SRM and SRT techniques, as well as a review of their applications in cancer-related fields. [Display omitted] • The principles and characteristics of SRT and SRM techniques are summarized. • Tumors show spatiotemporal variation via microenvironment interactions. • Single-cell spatially resolved omics reveals tumor heterogeneity. [ABSTRACT FROM AUTHOR]

Published
2023
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24. Spatially resolved transcriptomics reveals genes associated with the vulnerability of middle temporal gyrus in Alzheimer’s disease

Author

Shuo Chen, Yuzhou Chang, Liangping Li, Diana Acosta, Yang Li, Qi Guo, Cankun Wang, Emir Turkes, Cody Morrison, Dominic Julian, Mark E. Hester, Douglas W. Scharre, Chintda Santiskulvong, Sarah XueYing Song, Jasmine T. Plummer, Geidy E. Serrano, Thomas G. Beach, Karen E. Duff, Qin Ma, and Hongjun Fu

Subjects
Spatially resolved transcriptomics, Alzheimer’s disease, Vulnerability, Human middle temporal gyrus, Microglia, Oligodendrocytes, Neurology. Diseases of the nervous system, RC346-429
Abstract

Abstract 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 10 × 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.

Published
2022
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26. Spatially aware self-representation learning for tissue structure characterization and spatial functional genes identification.

Author

Zhang, Chuanchao, Li, Xinxing, Huang, Wendong, Wang, Lequn, and Shi, Qianqian

Subjects
*GENES, *TISSUES, *TRANSCRIPTOMES, *DEEP learning, *HETEROGENEITY
Abstract

Spatially resolved transcriptomics (SRT) enable the comprehensive characterization of transcriptomic profiles in the context of tissue microenvironments. Unveiling spatial transcriptional heterogeneity needs to effectively incorporate spatial information accounting for the substantial spatial correlation of expression measurements. Here, we develop a computational method, SpaSRL (spatially aware self-representation learning), which flexibly enhances and decodes spatial transcriptional signals to simultaneously achieve spatial domain detection and spatial functional genes identification. This novel tunable spatially aware strategy of SpaSRL not only balances spatial and transcriptional coherence for the two tasks, but also can transfer spatial correlation constraint between them based on a unified model. In addition, this joint analysis by SpaSRL deciphers accurate and fine-grained tissue structures and ensures the effective extraction of biologically informative genes underlying spatial architecture. We verified the superiority of SpaSRL on spatial domain detection, spatial functional genes identification and data denoising using multiple SRT datasets obtained by different platforms and tissue sections. Our results illustrate SpaSRL's utility in flexible integration of spatial information and novel discovery of biological insights from spatial transcriptomic datasets. [ABSTRACT FROM AUTHOR]

Published
2023
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27. Deciphering tissue heterogeneity from spatially resolved transcriptomics by the autoencoder-assisted graph convolutional neural network.

Author

Xinxing Li, Wendong Huang, Xuan Xu, Hong-Yu Zhang, and Qianqian Shi

Subjects
CONVOLUTIONAL neural networks, ARTIFICIAL neural networks, HETEROGENEITY
Abstract

Spatially resolved transcriptomics (SRT) provides an unprecedented opportunity to investigate the complex and heterogeneous tissue organization. However, it is challenging for a single model to learn an effective representation within and across spatial contexts. To solve the issue, we develop a novel ensemble model, AE-GCN (autoencoder-assisted graph convolutional neural network), which combines the autoencoder (AE) and graph convolutional neural network (GCN), to identify accurate and fine-grained spatial domains. AE-GCN transfers the AE-specific representations to the corresponding GCN-specific layers and unifies these two types of deep neural networks for spatial clustering via the clustering-aware contrastive mechanism. In this way, AE-GCN accommodates the strengths of both AE and GCN for learning an effective representation. We validate the effectiveness of AE-GCN on spatial domain identification and data denoising using multiple SRT datasets generated from ST, 10x Visium, and SlideseqV2 platforms. Particularly, in cancer datasets, AE-GCN identifies diseaserelated spatial domains, which reveal more heterogeneity than histological annotations, and facilitates the discovery of novel differentially expressed genes of high prognostic relevance. These results demonstrate the capacity of AE-GCN to unveil complex spatial patterns from SRT data. [ABSTRACT FROM AUTHOR]

Published
2023
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29. Spatially Guided and Single Cell Tools to Map the Microenvironment in Cutaneous T-Cell Lymphoma.

Author

Kalliara, Eirini, Belfrage, Emma, Gullberg, Urban, Drott, Kristina, and Ek, Sara

Subjects
*DISEASE progression, *MEDICAL technology, *INDIVIDUALIZED medicine, *GENE expression profiling, *TUMOR markers, *CUTANEOUS T-cell lymphoma
Abstract

Simple Summary: While most patients with cutaneous T-cell lymphoma (CTCL) may be diagnosed with early-stage disease, approximately 25–30% of those patients will unexpectedly progress to the advanced stage with an unforeseeable course of progression and response to treatment. Therefore, it is of pivotal importance to decipher the exact biological events governing disease aggressiveness to identify early those patients who will progress, and to design personalized treatment strategies for them. We propose that the way forward should entail a combination of advanced spatially resolving and tissue disruptive single-cell transcriptomics tools to enable deep phenotypic and molecular profiling of the benign immune and malignant T-cell populations in the two different disease compartments and thus acquire a global view of the inter-patient and intra-tumor heterogeneity. This will promote the development of novel molecular biomarkers for improved prognostication and personalized treatment to improve the survival outcomes and quality of life of chronic cancer patients with MF and SS. Mycosis fungoides (MF) and Sézary syndrome (SS) are two closely related clinical variants of cutaneous T-cell lymphomas (CTCL). Previously demonstrated large patient-to-patient and intra-patient disease heterogeneity underpins the importance of personalized medicine in CTCL. Advanced stages of CTCL are characterized by dismal prognosis, and the early identification of patients who will progress remains a clinical unmet need. While the exact molecular events underlying disease progression are poorly resolved, the tumor microenvironment (TME) has emerged as an important driver. In particular, the Th1-to-Th2 shift in the immune response is now commonly identified across advanced-stage CTCL patients. Herein, we summarize the role of the TME in CTCL evolution and the latest studies in deciphering inter- and intra-patient heterogeneity. We introduce spatially resolved omics as a promising technology to advance immune-oncology efforts in CTCL. We propose the combined implementation of spatially guided and single-cell omics technologies in paired skin and blood samples. Such an approach will mediate in-depth profiling of phenotypic and molecular changes in reactive immune subpopulations and malignant T cells preceding the Th1-to-Th2 shift and reveal mechanisms underlying disease progression from skin-limited to systemic disease that collectively will lead to the discovery of novel biomarkers to improve patient prognostication and the design of personalized treatment strategies. [ABSTRACT FROM AUTHOR]

Published
2023
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30. Spatially resolved transcriptomics provide a new method for cancer research

Author

Bowen Zheng and Lin Fang

Subjects
Spatially resolved transcriptomics, Cancer, Research Progress, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

Abstract A major feature of cancer is the heterogeneity, both intratumoral and intertumoral. Traditional single-cell techniques have given us a comprehensive understanding of the biological characteristics of individual tumor cells, but the lack of spatial context of the transcriptome has limited the study of cell-to-cell interaction patterns and hindered further exploration of tumor heterogeneity. In recent years, the advent of spatially resolved transcriptomics (SRT) technology has made possible the multidimensional analysis of the tumor microenvironment in the context of intact tissues. Different SRT methods are applicable to different working ranges due to different working principles. In this paper, we review the advantages and disadvantages of various current SRT methods and the overall idea of applying these techniques to oncology studies, hoping to help researchers find breakthroughs. Finally, we discussed the future direction of SRT technology, and deeper investigation into the complex mechanisms of tumor development from different perspectives through multi-omics fusion, paving the way for precisely targeted tumor therapy.

Published
2022
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31. Technique integration of single-cell RNA sequencing with spatially resolved transcriptomics in the tumor microenvironment

Author

Hailan Yan, Jinghua Shi, Yi Dai, Xiaoyan Li, Yushi Wu, Jing Zhang, Zhiyue Gu, Chenyu Zhang, and Jinhua Leng

Subjects
Integration, Single-cell RNA sequencing, Spatially resolved transcriptomics, Tumor microenvironment, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282, Cytology, QH573-671
Abstract

Abstract Background The tumor microenvironment contributes to tumor initiation, growth, invasion, and metastasis. The tumor microenvironment is heterogeneous in cellular and acellular components, particularly structural features and their gene expression at the inter-and intra-tumor levels. Main text Single-cell RNA sequencing profiles single-cell transcriptomes to reveal cell proportions and trajectories while spatial information is lacking. Spatially resolved transcriptomics redeems this lack with limited coverage or depth of transcripts. Hence, the integration of single-cell RNA sequencing and spatial data makes the best use of their strengths, having insights into exploring diverse tissue architectures and interactions in a complicated network. We review applications of integrating the two methods, especially in cellular components in the tumor microenvironment, showing each role in cancer initiation and progression, which provides clinical relevance in prognosis, optimal treatment, and potential therapeutic targets. Conclusion The integration of two approaches may break the bottlenecks in the spatial resolution of neighboring cell subpopulations in cancer, and help to describe the signaling circuitry about the intercommunication and its exact mechanisms in producing different types and malignant stages of tumors.

Published
2022
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32. VistoSeg: Processing utilities for high-resolution images for spatially resolved transcriptomics data.

Author

Tippani, Madhavi, Divecha, Heena R., Catallini II, Joseph L., Kwon, Sang H., Weber, Lukas M., Spangler, Abby, Jaffe, Andrew E., Hyde, Thomas M., Kleinman, Joel E., Hicks, Stephanie C., Martinowich, Keri, Collado-Torres, Leonardo, Page, Stephanie C., and Maynard, Kristen R.

Subjects
HIGH resolution imaging, IMAGE processing, DNA sequencing, IMMUNOFLUORESCENCE, DATA integration
Abstract

Spatially resolved transcriptomics (SRT) is a growing field that links gene expression to anatomical context. SRT approaches that use next-generation sequencing (NGS) combine RNA sequencing with histological or fluorescent imaging to generate spatial maps of gene expression in intact tissue sections. These technologies directly couple gene expression measurements with high-resolution histological or immunofluorescent images that contain rich morphological information about the tissue under study. While broad access to NGS-based spatial transcriptomic technology is now commercially available through the Visium platform from the vendor 10× Genomics, computational tools for extracting image-derived metrics for integration with gene expression data remain limited. We developed VistoSeg as a MATLAB pipeline to process, analyze and interactively visualize the high-resolution images generated in the Visium platform. VistoSeg outputs can be easily integrated with accompanying transcriptomic data to facilitate downstream analyses in common programing languages including R and Python. VistoSeg provides user-friendly tools for integrating image-derived metrics from histological and immunofluorescent images with spatially resolved gene expression data. Integration of this data enhances the ability to understand the transcriptional landscape within tissue architecture. VistoSeg is freely available at http://research.libd.org/VistoSeg/. [ABSTRACT FROM AUTHOR]

Published
2023
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33. Performant web-based interactive visualization tool for spatially-resolved transcriptomics experiments.

Author

Sriworarat, Chaichontat, Nguyen, Annie, Eagles, Nicholas J., Collado-Torres, Leonardo, Martinowich, Keri, Maynard, Kristen R., and Hicks, Stephanie C.

Subjects
VISUALIZATION, TRANSCRIPTOMES, HIGH resolution imaging, BIOLOGICAL systems, WEB browsers
Abstract

High-resolution and multiplexed imaging techniques are giving us an increasingly detailed observation of a biological system. However, sharing, exploring, and customizing the visualization of large multidimensional images can be a challenge. Here, we introduce Samui, a performant and interactive image visualization tool that runs completely in the web browser. Samui is specifically designed for fast image visualization and annotation and enables users to browse through large images and their selected features within seconds of receiving a link. We demonstrate the broad utility of Samui with images generated with two platforms: Vizgen MERFISH and 10x Genomics Visium Spatial Gene Expression. Samui along with example datasets is available at https://samuibrowser.com. [ABSTRACT FROM AUTHOR]

Published
2023
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34. Spatially resolved transcriptomics reveals genes associated with the vulnerability of middle temporal gyrus in Alzheimer's disease.

Author

Chen, Shuo, Chang, Yuzhou, Li, Liangping, Acosta, Diana, Li, Yang, Guo, Qi, Wang, Cankun, Turkes, Emir, Morrison, Cody, Julian, Dominic, Hester, Mark E., Scharre, Douglas W., Santiskulvong, Chintda, Song, Sarah XueYing, Plummer, Jasmine T., Serrano, Geidy E., Beach, Thomas G., Duff, Karen E., Ma, Qin, and Fu, Hongjun

Subjects
ALZHEIMER'S disease, TEMPORAL lobe, MICROGLIA, FLUORESCENCE in situ hybridization, GENE regulatory networks, WHITE matter (Nerve tissue)
Abstract

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 10 × 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. [ABSTRACT FROM AUTHOR]

Published
2022
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35. Performant web-based interactive visualization tool for spatially-resolved transcriptomics experiments

Author

Chaichontat Sriworarat, Annie Nguyen, Nicholas J. Eagles, Leonardo Collado-Torres, Keri Martinowich, Kristen R. Maynard, and Stephanie C. Hicks

Subjects
georeferencing, interactive image viewer, multi-dimensional image, single-cell transcriptomics, spatially resolved transcriptomics, web-based browser, Biology (General), QH301-705.5, Medical technology, R855-855.5
Abstract

High-resolution and multiplexed imaging techniques are giving us an increasingly detailed observation of a biological system. However, sharing, exploring, and customizing the visualization of large multidimensional images can be a challenge. Here, we introduce Samui, a performant and interactive image visualization tool that runs completely in the web browser. Samui is specifically designed for fast image visualization and annotation and enables users to browse through large images and their selected features within seconds of receiving a link. We demonstrate the broad utility of Samui with images generated with two platforms: Vizgen MERFISH and 10x Genomics Visium Spatial Gene Expression. Samui along with example datasets is available at https://samuibrowser.com.

Published
2023
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36. VistoSeg: Processing utilities for high-resolution images for spatially resolved transcriptomics data

Author

Madhavi Tippani, Heena R. Divecha, Joseph L. Catallini, Sang H. Kwon, Lukas M. Weber, Abby Spangler, Andrew E. Jaffe, Thomas M. Hyde, Joel E. Kleinman, Stephanie C. Hicks, Keri Martinowich, Leonardo Collado-Torres, Stephanie C. Page, and Kristen R. Maynard

Subjects
hematoxylin and eosin, immunofluorescence, MATLAB, segmentation, spatially resolved transcriptomics, Visium, Visium-Spatial Proteogenomics, Biology (General), QH301-705.5, Medical technology, R855-855.5
Abstract

Spatially resolved transcriptomics (SRT) is a growing field that links gene expression to anatomical context. SRT approaches that use next-generation sequencing (NGS) combine RNA sequencing with histological or fluorescent imaging to generate spatial maps of gene expression in intact tissue sections. These technologies directly couple gene expression measurements with high-resolution histological or immunofluorescent images that contain rich morphological information about the tissue under study. While broad access to NGS-based spatial transcriptomic technology is now commercially available through the Visium platform from the vendor 10× Genomics, computational tools for extracting image-derived metrics for integration with gene expression data remain limited. We developed VistoSeg as a MATLAB pipeline to process, analyze and interactively visualize the high-resolution images generated in the Visium platform. VistoSeg outputs can be easily integrated with accompanying transcriptomic data to facilitate downstream analyses in common programing languages including R and Python. VistoSeg provides user-friendly tools for integrating image-derived metrics from histological and immunofluorescent images with spatially resolved gene expression data. Integration of this data enhances the ability to understand the transcriptional landscape within tissue architecture. VistoSeg is freely available at http://research.libd.org/VistoSeg/.

Published
2023
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37. Matisse: a MATLAB-based analysis toolbox for in situ sequencing expression maps

Author

Sergio Marco Salas, Daniel Gyllborg, Christoffer Mattsson Langseth, and Mats Nilsson

Subjects
In situ sequencing, Spatially resolved transcriptomics, Analysis toolbox, Probabilistic cell typing, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5
Abstract

Abstract Background A range of spatially resolved transcriptomic methods has recently emerged as a way to spatially characterize the molecular and cellular diversity of a tissue. As a consequence, an increasing number of computational techniques are developed to facilitate data analysis. There is also a need for versatile user friendly tools that can be used for a de novo exploration of datasets. Results Here we present MATLAB-based Analysis toolbox for in situ sequencing (ISS) expression maps (Matisse). We demonstrate Matisse by characterizing the 2-dimensional spatial expression of 119 genes profiled in a mouse coronal section, exploring different levels of complexity. Additionally, in a comprehensive analysis, we further analyzed expression maps from a second technology, osmFISH, targeting a similar mouse brain region. Conclusion Matisse proves to be a valuable tool for initial exploration of in situ sequencing datasets. The wide set of tools integrated allows for simple analysis, using the position of individual reads, up to more complex clustering and dimensional reduction approaches, taking cellular content into account. The toolbox can be used to analyze one or several samples at a time, even from different spatial technologies, and it includes different segmentation approaches that can be useful in the analysis of spatially resolved transcriptomic datasets.

Published
2021
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38. A review of recent advances in spatially resolved transcriptomics data analysis.

Author

Gao, Yue, Gao, Ying-Lian, Jing, Jing, Li, Feng, Zheng, Chun-Hou, and Liu, Jin-Xing

Subjects
*TRANSCRIPTOMES, *TECHNOLOGICAL innovations, *GENE expression, *GENETIC regulation, *DATA analysis
Abstract

The increasing significance of spatial organization and our understanding of molecular characteristics have greatly contributed to technological advancements in spatially resolved transcriptomics (SRT). Its development provides a new perspective to explore the spatial specificity of gene expression, which assists in revealing the interactions between tissues and cells, along with abnormal gene expression patterns in disease development, further enhancing our comprehension of gene regulation mechanisms in organisms. The main purpose of this review is to introduce some of the latest developments in the analysis and development of spatial transcriptomics data, and emphasize their current research approaches in spatial clustering, spatial trajectory inference, identification of spatially variable genes, cell–cell/gene–gene interaction, batch effect correction and gene expression denoising. • Provides deep insights into the latest methods in the spatial resolved transcriptomics. • Summarized the common applications of spatial resolved transcriptomics. • Analyzed advanced methods application in spatial transcriptomics scenarios. [ABSTRACT FROM AUTHOR]

Published
2024
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39. Spatially resolved transcriptomics provide a new method for cancer research.

Author

Zheng, Bowen and Fang, Lin

Subjects
CANCER research, TUMOR microenvironment, RESEARCH methodology, TRANSCRIPTOMES
Abstract

A major feature of cancer is the heterogeneity, both intratumoral and intertumoral. Traditional single-cell techniques have given us a comprehensive understanding of the biological characteristics of individual tumor cells, but the lack of spatial context of the transcriptome has limited the study of cell-to-cell interaction patterns and hindered further exploration of tumor heterogeneity. In recent years, the advent of spatially resolved transcriptomics (SRT) technology has made possible the multidimensional analysis of the tumor microenvironment in the context of intact tissues. Different SRT methods are applicable to different working ranges due to different working principles. In this paper, we review the advantages and disadvantages of various current SRT methods and the overall idea of applying these techniques to oncology studies, hoping to help researchers find breakthroughs. Finally, we discussed the future direction of SRT technology, and deeper investigation into the complex mechanisms of tumor development from different perspectives through multi-omics fusion, paving the way for precisely targeted tumor therapy. [ABSTRACT FROM AUTHOR]

Published
2022
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40. Statistical and machine learning methods for spatially resolved transcriptomics with histology

Author

Jian Hu, Amelia Schroeder, Kyle Coleman, Chixiang Chen, Benjamin J. Auerbach, and Mingyao Li

Subjects
Spatially resolved transcriptomics, Spatial clustering, Spatially variable genes, Celltype deconvolution, Cell-cell communications, Biotechnology, TP248.13-248.65
Abstract

Recent developments in spatially resolved transcriptomics (SRT) technologies have enabled scientists to get an integrated understanding of cells in their morphological context. Applications of these technologies in diverse tissues and diseases have transformed our views of transcriptional complexity. Most published studies utilized tools developed for single-cell RNA sequencing (scRNA-seq) for data analysis. However, SRT data exhibit different properties from scRNA-seq. To take full advantage of the added dimension on spatial location information in such data, new methods that are tailored for SRT are needed. Additionally, SRT data often have companion high-resolution histology information available. Incorporating histological features in gene expression analysis is an underexplored area. In this review, we will focus on the statistical and machine learning aspects for SRT data analysis and discuss how spatial location and histology information can be integrated with gene expression to advance our understanding of the transcriptional complexity. We also point out open problems and future research directions in this field.

Published
2021
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41. Accurate and fast cell marker gene identification with COSG.

Author

Dai, Min, Pei, Xiaobing, and Wang, Xiu-Jie

Subjects
*RNA sequencing, *GENES, *SEQUENCE analysis
Abstract

Accurate cell classification is the groundwork for downstream analysis of single-cell sequencing data, yet how to identify true marker genes for different cell types still remains a big challenge. Here, we report COSine similarity-based marker Gene identification (COSG) as a cosine similarity-based method for more accurate and scalable marker gene identification. COSG is applicable to single-cell RNA sequencing data, single-cell ATAC sequencing data and spatially resolved transcriptome data. COSG is fast and scalable for ultra-large datasets of million-scale cells. Application on both simulated and real experimental datasets showed that the marker genes or genomic regions identified by COSG have greater cell-type specificity, demonstrating the superior performance of COSG in terms of both accuracy and efficiency as compared with other available methods. [ABSTRACT FROM AUTHOR]

Published
2022
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42. SSAM-lite: A Light-Weight Web App for Rapid Analysis of Spatially Resolved Transcriptomics Data.

Author

Tiesmeyer, Sebastian, Sahay, Shashwat, Müller-Bötticher, Niklas, Eils, Roland, Mackowiak, Sebastian D., and Ishaque, Naveed

Subjects
WEB-based user interfaces, SOMATOSENSORY cortex, CELL nuclei, PROGRAMMING languages, WEB browsers
Abstract

The combination of a cell's transcriptional profile and location defines its function in a spatial context. Spatially resolved transcriptomics (SRT) has emerged as the assay of choice for characterizing cells in situ. SRT methods can resolve gene expression up to single-molecule resolution. A particular computational problem with single-molecule SRT methods is the correct aggregation of mRNA molecules into cells. Traditionally, aggregating mRNA molecules into cell-based features begins with the identification of cells via segmentation of the nucleus or the cell membrane. However, recently a number of cell-segmentation-free approaches have emerged. While these methods have been demonstrated to be more performant than segmentation-based approaches, they are still not easily accessible since they require specialized knowledge of programming languages and access to large computational resources. Here we present SSAM-lite, a tool that provides an easy-to-use graphical interface to perform rapid and segmentation-free cell-typing of SRT data in a web browser. SSAM-lite runs locally and does not require computational experts or specialized hardware. Analysis of a tissue slice of the mouse somatosensory cortex took less than a minute on a laptop with modest hardware. Parameters can interactively be optimized on small portions of the data before the entire tissue image is analyzed. A server version of SSAM-lite can be run completely offline using local infrastructure. Overall, SSAM-lite is portable, lightweight, and easy to use, thus enabling a broad audience to investigate and analyze single-molecule SRT data. [ABSTRACT FROM AUTHOR]

Published
2022
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43. SSAM-lite: A Light-Weight Web App for Rapid Analysis of Spatially Resolved Transcriptomics Data

Author

Sebastian Tiesmeyer, Shashwat Sahay, Niklas Müller-Bötticher, Roland Eils, Sebastian D. Mackowiak, and Naveed Ishaque

Subjects
spatial transcriptomics, web application, cell typing, in situ sequencing, in situ hybridization, spatially resolved transcriptomics, Genetics, QH426-470
Abstract

The combination of a cell’s transcriptional profile and location defines its function in a spatial context. Spatially resolved transcriptomics (SRT) has emerged as the assay of choice for characterizing cells in situ. SRT methods can resolve gene expression up to single-molecule resolution. A particular computational problem with single-molecule SRT methods is the correct aggregation of mRNA molecules into cells. Traditionally, aggregating mRNA molecules into cell-based features begins with the identification of cells via segmentation of the nucleus or the cell membrane. However, recently a number of cell-segmentation-free approaches have emerged. While these methods have been demonstrated to be more performant than segmentation-based approaches, they are still not easily accessible since they require specialized knowledge of programming languages and access to large computational resources. Here we present SSAM-lite, a tool that provides an easy-to-use graphical interface to perform rapid and segmentation-free cell-typing of SRT data in a web browser. SSAM-lite runs locally and does not require computational experts or specialized hardware. Analysis of a tissue slice of the mouse somatosensory cortex took less than a minute on a laptop with modest hardware. Parameters can interactively be optimized on small portions of the data before the entire tissue image is analyzed. A server version of SSAM-lite can be run completely offline using local infrastructure. Overall, SSAM-lite is portable, lightweight, and easy to use, thus enabling a broad audience to investigate and analyze single-molecule SRT data.

Published
2022
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44. Exploring Cellular Heterogeneity: Single-Cell and Spatial Transcriptomics of Alzheimer Disease Brains and iPSC-Derived Microglia.

Author

Garg A, Vo S, Brase L, Aladyeva E, Albanus RD, Nallapu A, Fu H, and Harari O

Abstract

Background: Substantial evidence has established the critical role of microglia, the brain's resident immune cells, in the pathogenesis of Alzheimer's disease (AD). Microglia exhibit diverse transcriptional states in response to neuroinflammatory stimuli, and understanding these states is crucial for elucidating the underlying mechanisms of AD., Methods: In this work, we integrated single-cell and spatially resolved transcriptomics data from multiple cohorts and brain regions, including microglia from experimental and human brains., Results: This comprehensive atlas revealed a great heterogeneity of microglial states, with a significant enrichment of specific states, including activated microglia, in AD brains compared to controls. Further integration of spatial transcriptomics and immunohistochemistry showed that activated microglia are predominantly located in the external cortical layers near amyloid plaques, while homeostatic microglia are more prevalent in the internal cortical layers and further away from the plaques. These spatial patterns were further validated using P2RY12 immunostaining, which confirmed the reliability of the transcriptomic data., Conclusion: By integrating single-cell and spatial transcriptomics, we have provided a detailed atlas of microglial diversity, revealing the regional and pathological specificity of microglial states., Competing Interests: Declarations Competing Interests The authors have no conflicts of interest to disclose.

Published
2024
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45. Exploit Spatially Resolved Transcriptomic Data to Infer Cellular Features from Pathology Imaging Data.

Author

Sui Z, Li Z, and Sun W

Abstract

Digital pathology is a rapidly advancing field where deep learning methods can be employed to extract meaningful imaging features. However, the efficacy of training deep learning models is often hindered by the scarcity of annotated pathology images, particularly images with detailed annotations for small image patches or tiles. To overcome this challenge, we propose an innovative approach that leverages paired spatially resolved transcriptomic data to annotate pathology images. We demonstrate the feasibility of this approach and introduce a novel transfer-learning neural network model, STpath (Spatial Transcriptomics and pathology images), designed to predict cell type proportions or classify tumor microenvironments. Our findings reveal that the features from pre-trained deep learning models are associated with cell type identities in pathology image patches. Evaluating STpath using three distinct breast cancer datasets, we observe its promising performance despite the limited training data. STpath excels in samples with variable cell type proportions and high-resolution pathology images. As the influx of spatially resolved transcriptomic data continues, we anticipate ongoing updates to STpath, evolving it into an invaluable AI tool for assisting pathologists in various diagnostic tasks., Competing Interests: Competing interests No competing interest is declared.

Published
2024
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46. Matisse: a MATLAB-based analysis toolbox for in situ sequencing expression maps.

Author

Marco Salas, Sergio, Gyllborg, Daniel, Mattsson Langseth, Christoffer, and Nilsson, Mats

Subjects
GENE expression profiling, TRANSCRIPTOMES
Abstract

Background: A range of spatially resolved transcriptomic methods has recently emerged as a way to spatially characterize the molecular and cellular diversity of a tissue. As a consequence, an increasing number of computational techniques are developed to facilitate data analysis. There is also a need for versatile user friendly tools that can be used for a de novo exploration of datasets. Results: Here we present MATLAB-based Analysis toolbox for in situ sequencing (ISS) expression maps (Matisse). We demonstrate Matisse by characterizing the 2-dimensional spatial expression of 119 genes profiled in a mouse coronal section, exploring different levels of complexity. Additionally, in a comprehensive analysis, we further analyzed expression maps from a second technology, osmFISH, targeting a similar mouse brain region. Conclusion: Matisse proves to be a valuable tool for initial exploration of in situ sequencing datasets. The wide set of tools integrated allows for simple analysis, using the position of individual reads, up to more complex clustering and dimensional reduction approaches, taking cellular content into account. The toolbox can be used to analyze one or several samples at a time, even from different spatial technologies, and it includes different segmentation approaches that can be useful in the analysis of spatially resolved transcriptomic datasets. [ABSTRACT FROM AUTHOR]

Published
2021
Full Text
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47. Spatiotemporal mapping of RNA editing in the developing mouse brain using in situ sequencing reveals regional and cell-type-specific regulation

Author

Elin Lundin, Chenglin Wu, Albin Widmark, Mikaela Behm, Jens Hjerling-Leffler, Chammiran Daniel, Marie Öhman, and Mats Nilsson

Subjects
Single-cell resolution, RNA editing, Spatially resolved transcriptomics, Brain development, Biology (General), QH301-705.5
Abstract

Abstract Background Adenosine-to-inosine (A-to-I) RNA editing is a process that contributes to the diversification of proteins that has been shown to be essential for neurotransmission and other neuronal functions. However, the spatiotemporal and diversification properties of RNA editing in the brain are largely unknown. Here, we applied in situ sequencing to distinguish between edited and unedited transcripts in distinct regions of the mouse brain at four developmental stages, and investigate the diversity of the RNA landscape. Results We analyzed RNA editing at codon-altering sites using in situ sequencing at single-cell resolution, in combination with the detection of individual ADAR enzymes and specific cell type marker transcripts. This approach revealed cell-type-specific regulation of RNA editing of a set of transcripts, and developmental and regional variation in editing levels for many of the targeted sites. We found increasing editing diversity throughout development, which arises through regional- and cell type-specific regulation of ADAR enzymes and target transcripts. Conclusions Our single-cell in situ sequencing method has proved useful to study the complex landscape of RNA editing and our results indicate that this complexity arises due to distinct mechanisms of regulating individual RNA editing sites, acting both regionally and in specific cell types.

Published
2020
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48. Complete spatially resolved gene expression is not necessary for identifying spatial domains.

Author

Lin S, Cui Y, Zhao F, Yang Z, Song J, Yao J, Zhao Y, Qian BZ, Zhao Y, and Yuan Z

Subjects
Humans, Transcriptome genetics, Algorithms, Gene Expression Profiling methods
Abstract

Spatially resolved transcriptomics (SRT) technologies have revolutionized the study of tissue organization. We introduce a graph convolutional network with an attention and positive emphasis mechanism, termed BINARY, relying exclusively on binarized SRT data to accurately delineate spatial domains. BINARY outperforms existing methods across various SRT data types while using significantly less input information. Our study suggests that precise gene expression quantification may not always be essential, inspiring further exploration of the broader applications of spatially resolved binarized gene expression data., Competing Interests: Declaration of interests The author declare no competing interests., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2024
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49. Spatially Resolved Transcriptomes—Next Generation Tools for Tissue Exploration.

Author

Asp, Michaela, Bergenstråhle, Joseph, and Lundeberg, Joakim

Subjects
*TRANSCRIPTOMES, *BIOLOGICAL systems, *GENE expression, *TISSUES, *TECHNOLOGICAL innovations
Abstract

Recent advances in spatially resolved transcriptomics have greatly expanded the knowledge of complex multicellular biological systems. The field has quickly expanded in recent years, and several new technologies have been developed that all aim to combine gene expression data with spatial information. The vast array of methodologies displays fundamental differences in their approach to obtain this information, and thus, demonstrate method‐specific advantages and shortcomings. While the field is moving forward at a rapid pace, there are still multiple challenges presented to be addressed, including sensitivity, labor extensiveness, tissue‐type dependence, and limited capacity to obtain detailed single‐cell information. No single method can currently address all these key parameters. In this review, available spatial transcriptomics methods are described and their applications as well as their strengths and weaknesses are discussed. Future developments are explored and where the field is heading to is deliberated upon. [ABSTRACT FROM AUTHOR]

Published
2020
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50. Mapping Transcriptomes in Tissues

Author

Larsson, Ludvig and Larsson, Ludvig

Abstract

Over the past few decades, the advent of pioneering biotechnological methods has allowed scientists to analyze the molecular components of multicellular organisms with remarkable precision. The field of transcriptomics has witnessed a rapid development of technologies for gene expression profiling of biological samples. These gene expression profiles offer crucial insights into biological processes that underlie organism development, homeostasis, and disease-causing dysregulation. Modern transcriptomics technologies can profile samples at various degrees of precision and resolution, and when combined, they contribute to a comprehensive understanding of the complex molecular mechanisms that shape entire organisms. Some of these molecular mechanisms occur at the microscopic scale, controlled by communication between nearby cells. Other mechanisms depend on coordinated efforts between large networks of cells organized into tissues and organs. Cells, tissues and organs represent hierarchical levels of structural organization, and each level plays a vital role in the proper functioning of the organism. Gene expression profiling technologies yield comprehensive data that can be harnessed to explore and characterize biological phenomena within and across these structural levels. The central theme of this thesis revolves around the use of experimental technologies and computational methods in the field of transcriptomics to enhance our understanding of multicellular life. Particular attention is directed at a technology known as Visium, which has held an important position in the field in recent years. The research articles included in this thesis demonstrate the applications of Visium and related technologies in biological research. In article I, we present a computational toolbox for processing, analyzing, and visualizing Visium data, assembled into an open-source package written in the R programming language. The package facilitates the characterization of gene expressio, Under de senaste decennierna har tillkomsten av banbrytande bioteknologiska metoder gjort det möjligt för forskare att analysera de molekylära komponenterna i flercelliga organismer med anmärkningsvärd precision. Forskningsfältet transkriptomik har bevittnat en snabb utveckling av teknologier som har utökat möjligheterna att erhålla omfattande genuttrycksprofiler från biologiska prover. Dessa genuttrycksprofiler ger avgörande insikter i biologiska processer som ligger till grund för organismers utveckling, homeostas och sjukdomsframkallande dysreglering. Moderna teknologier kan användas för att utforska prover i olika grader av precision och upplösning, och när de kombineras bidrar de till en holistisk bild av de invecklade molekylära mekanismerna som formar flercelliga organismer. Vissa av dessa molekylära mekanismer förekommer i mikroskopisk skala och styrs genom kommunikation mellan närliggande celler. Andra mekanismer är beroende av samordnade processer inom stora nätverk av celler organiserade i vävnader och organ. Celler, vävnader och organ bildar en hierarki av strukturella nivåer, och varje nivå spelar en viktig roll för att organismen ska fungera korrekt. Experimentella teknologier inom fältet transkriptomik ger omfattande data som kan användas för att utforska och karaktärisera biologiska fenomen inom och mellan dessa strukturella nivåer. Det centrala temat för denna avhandling kretsar kring användningen av experimentella teknologier och beräkningsmetoder inom biologisk forskning. Här undersöks hur dessa verktyg kan användas för att förbättra vår förståelse av flercelligt liv. Särskild uppmärksamhet riktas mot en teknologi känd som Visium, vilken haft en viktig position inom fältet de senaste åren. Forskningsartiklarna som ingår i denna avhandling visar tillämpningarna av Visium-teknologin och relaterade teknologier inom biologisk forskning. I artikel I beskriver vi beräkningsverktyg för bearbetning, analys och visualisering av Visium-data, sammansatt til, QC 2023-04-25

Published
2023

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