单细胞多组学图谱揭示多发性硬化病变中特定细胞类型的机制驱动因素。
Single-Cell Multi-Omics Map of Cell Type-Specific Mechanistic Drivers of Multiple Sclerosis Lesions.
机构信息
From the Department of Neurology (M.L.E., A.W., Z.I.), Odense University Hospital; BRIDGE (M.L.E., A.W., M.T., Z.I.), Department of Clinical Research; Department of Molecular Medicine (M.L.E., A.W., L.V., Z.I.), University of Southern Denmark, Odense, Denmark; Biomedical Network Science Lab (A.H.), Department Artificial Intelligence in Biomedical Engineering, Friedrich-Alexander-Universität Erlangen-Nürnberg, Germany; Department of Mathematics and Computer Science (A.H., Richard Rottger, J.B.), University of Southern Denmark, Odense, Denmark; Institute for Computational Systems Biology (M.O., J.B.), University of Hamburg, Germany; Department of Brain Sciences (Richard Reynolds), Imperial College, London, United Kingdom; and Clinical Genome Center (M.T.), Research Unit of Human Genetics, Department of Clinical Research, University of Southern Denmark, Odense, Denmark.
出版信息
Neurol Neuroimmunol Neuroinflamm. 2024 May;11(3):e200213. doi: 10.1212/NXI.0000000000200213. Epub 2024 Apr 2.
BACKGROUND AND OBJECTIVES
In progressive multiple sclerosis (MS), compartmentalized inflammation plays a pivotal role in the complex pathology of tissue damage. The interplay between epigenetic regulation, transcriptional modifications, and location-specific alterations within white matter (WM) lesions at the single-cell level remains underexplored.
METHODS
We examined intracellular and intercellular pathways in the MS brain WM using a novel dataset obtained by integrated single-cell multi-omics techniques from 3 active lesions, 3 chronic active lesions, 3 remyelinating lesions, and 3 control WM of 6 patients with progressive MS and 3 non-neurologic controls. Single-nucleus RNA-seq and ATAC-seq were combined and additionally enriched with newly conducted spatial transcriptomics from 1 chronic active lesion. Functional gene modules were then validated in our previously published bulk tissue transcriptome data obtained from 73 WM lesions of patients with progressive MS and 25 WM of non-neurologic disease controls.
RESULTS
Our analysis uncovered an MS-specific oligodendrocyte genetic signature influenced by the KLF/SP gene family. This modulation has potential associations with the autocrine iron uptake signaling observed in transcripts of transferrin and its receptor . In addition, an inflammatory profile emerged within these oligodendrocytes. We observed unique cellular endophenotypes both at the periphery and within the chronic active lesion. These include a distinct metabolic astrocyte phenotype, the importance of FGF signaling among astrocytes and neurons, and a notable enrichment of mitochondrial genes at the lesion edge populated predominantly by astrocytes. Our study also identified B-cell coexpression networks indicating different functional B-cell subsets with differential location and specific tendencies toward certain lesion types.
DISCUSSION
The use of single-cell multi-omics has offered a detailed perspective into the cellular dynamics and interactions in MS. These nuanced findings might pave the way for deeper insights into lesion pathogenesis in progressive MS.
背景与目的
在进展性多发性硬化症(MS)中,分隔式炎症在组织损伤的复杂病理中起着关键作用。在单细胞水平上,白色物质(WM)病变中表观遗传调控、转录修饰和位置特异性改变之间的相互作用仍未得到充分探索。
方法
我们使用从 6 名进展性 MS 患者的 3 个活动病变、3 个慢性活动病变、3 个髓鞘再生病变和 3 个对照 WM 中获得的集成单细胞多组学技术的新数据集,研究了 MS 大脑 WM 中的细胞内和细胞间途径。单细胞 RNA-seq 和 ATAC-seq 相结合,并从 1 个慢性活动病变中补充了新进行的空间转录组学。然后在我们之前发表的来自 73 个进展性 MS 患者 WM 病变和 25 个非神经疾病对照 WM 的批量组织转录组数据中验证了功能基因模块。
结果
我们的分析揭示了一种受 KLF/SP 基因家族影响的 MS 特异性少突胶质细胞遗传特征。这种调节可能与转铁蛋白及其受体的转录本中观察到的自分泌铁摄取信号有关。此外,在这些少突胶质细胞中出现了一种炎症特征。我们在病变外围和慢性活动病变内观察到独特的细胞内表型。这些包括独特的代谢星形胶质细胞表型、星形胶质细胞和神经元之间 FGF 信号的重要性,以及病变边缘富含主要由星形胶质细胞组成的线粒体基因。我们的研究还鉴定了 B 细胞共表达网络,表明具有不同位置和特定倾向于某些病变类型的不同功能 B 细胞亚群。
讨论
单细胞多组学的使用提供了对 MS 中细胞动力学和相互作用的详细视角。这些细微的发现可能为深入了解进展性 MS 中的病变发病机制铺平道路。
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