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引用次数: 0
摘要
单细胞转录组数据的细胞身份注释是构建细胞图谱、揭示发病机制和启发治疗方法的关键过程。目前,现有方法的有效性取决于特定的数据集。然而,这些数据往往来自不同的批次、测序技术、组织甚至物种。值得注意的是,基因调控关系仍然不受上述因素的影响,这凸显了生物体内广泛的基因相互作用。因此,我们提出了 scHGR,这是一种自动注释工具,旨在利用基因调控关系为单细胞转录组数据构建基因介导的细胞通讯图谱。这种策略有助于减少来自不同数据源的噪声,同时建立遥远的细胞联系,从而获得有价值的生物学见解。涉及 22 种情况的实验表明,与最先进的方法相比,scHGR 能精确、一致地注释细胞身份。最重要的是,scHGR 发现了外周血单核细胞中的新型亚型,特别是 CD4+ T 细胞和细胞毒性 T 细胞。此外,通过对 COVID-19 患者的 56 种细胞类型组成的细胞图谱进行特征描述,scHGR 确定了 IL1 和钙离子等重要因子,为有针对性的治疗干预提供了启示。
A gene regulatory network-aware graph learning method for cell identity annotation in single-cell RNA-seq data.
Cell identity annotation for single-cell transcriptome data is a crucial process for constructing cell atlases, unraveling pathogenesis, and inspiring therapeutic approaches. Currently, the efficacy of existing methodologies is contingent upon specific data sets. Nevertheless, such data are often sourced from various batches, sequencing technologies, tissues, and even species. Notably, the gene regulatory relationship remains unaffected by the aforementioned factors, highlighting the extensive gene interactions within organisms. Therefore, we propose scHGR, an automated annotation tool designed to leverage gene regulatory relationships in constructing gene-mediated cell communication graphs for single-cell transcriptome data. This strategy helps reduce noise from diverse data sources while establishing distant cellular connections, yielding valuable biological insights. Experiments involving 22 scenarios demonstrate that scHGR precisely and consistently annotates cell identities, benchmarked against state-of-the-art methods. Crucially, scHGR uncovers novel subtypes within peripheral blood mononuclear cells, specifically from CD4+ T cells and cytotoxic T cells. Furthermore, by characterizing a cell atlas comprising 56 cell types for COVID-19 patients, scHGR identifies vital factors like IL1 and calcium ions, offering insights for targeted therapeutic interventions.
期刊介绍:
Launched in 1995, Genome Research is an international, continuously published, peer-reviewed journal that focuses on research that provides novel insights into the genome biology of all organisms, including advances in genomic medicine.
Among the topics considered by the journal are genome structure and function, comparative genomics, molecular evolution, genome-scale quantitative and population genetics, proteomics, epigenomics, and systems biology. The journal also features exciting gene discoveries and reports of cutting-edge computational biology and high-throughput methodologies.
New data in these areas are published as research papers, or methods and resource reports that provide novel information on technologies or tools that will be of interest to a broad readership. Complete data sets are presented electronically on the journal''s web site where appropriate. The journal also provides Reviews, Perspectives, and Insight/Outlook articles, which present commentary on the latest advances published both here and elsewhere, placing such progress in its broader biological context.
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