Li Yaling, Jiang Bin, Chen Bancheng, Zou Yanfen, Wang Yan, Liu Qian, Song Bing, Yu Bo
Department of Dermatology, Institute of Dermatology, Peking University Shenzhen Hospital, Shenzhen Peking University-The Hong Kong University of Science and Technology Medical Center, Shenzhen, 518036, China.
Institute of Biomedical and Health Engineering, Shen Zhen Institutes of Advanced Technology, Chinese Academy of Science, Shenzhen, 518055, Guangdong, China.
Heliyon. 2024 Mar 15;10(6):e28244. doi: 10.1016/j.heliyon.2024.e28244. eCollection 2024 Mar 30.
The immune microenvironment and oxidative stress of melanoma show significant heterogeneity, which affects tumor growth, invasion and treatment response. Single-cell and bulk RNA-seq data were used to explore the heterogeneity of the immune microenvironment and oxidative stress of melanoma.
The R package Seurat facilitated the analysis of the single-cell dataset, while Harmony, another R package, was employed for batch effect correction. Cell types were classified using Uniform Manifold Approximation and Projection (UMAP). The Secreted Signaling algorithm from CellChatDB.human was applied to elucidate cell-to-cell communication patterns within the single-cell data. Consensus clustering analysis for the skin cutaneous melanoma (SKCM) samples was executed with the R package ConsensusClusterPlus. To quantify immune infiltrating cells, we utilized CIBERSORT, ESTIMATE, and TIMERxCell algorithms provided by the R package Immuno-Oncology Biological Research (IOBR). Single nucleotide variant (SNV) analysis was conducted using Maftools, an R package specifically designed for this purpose. Subsequently, the expression levels of and genes were assessed in melanoma tissues compared to adjacent normal tissues. Furthermore, in vitro experiments were conducted to evaluate the proliferation and reactive oxygen species expression in melanoma cells following transfection with siRNA targeting and .
Malignant tumor cell populations were reclassified based on a comprehensive single-cell dataset analysis, which yielded six distinct tumor subsets. The specific marker genes identified for these subgroups were then used to interrogate the Cancer Genome Atlas Skin Cutaneous Melanoma (TCGA-SKCM) cohort, derived from bulk RNA sequencing data, resulting in the delineation of two immune molecular subtypes. Notably, patients within the cluster2 (C2) subtype exhibited a significantly more favorable prognosis compared to those in the cluster1 (C1) subtype. An alignment of immune characteristics was observed between the C2 subtype and unique immune functional tumor cell subsets. Genes differentially expressed across these subtypes were subsequently leveraged to construct a predictive risk model. In vitro investigations further revealed elevated expression levels of and in melanoma tissue samples. Functional assays indicated that modulation of and expression could influence the production of reactive oxygen species (ROS) and the proliferative capacity of melanoma cells.
The constructed six-gene signature can be used as an immune response and an oxidative stress marker to guide the clinical diagnosis and treatment of melanoma.
黑色素瘤的免疫微环境和氧化应激表现出显著的异质性,这会影响肿瘤的生长、侵袭及治疗反应。利用单细胞和批量RNA测序数据来探究黑色素瘤免疫微环境和氧化应激的异质性。
R包Seurat用于单细胞数据集的分析,而另一个R包Harmony则用于批次效应校正。使用均匀流形近似和投影(UMAP)对细胞类型进行分类。应用来自CellChatDB.human的分泌信号算法来阐明单细胞数据内的细胞间通讯模式。使用R包ConsensusClusterPlus对皮肤黑色素瘤(SKCM)样本进行一致性聚类分析。为了量化免疫浸润细胞,我们利用了R包免疫肿瘤生物学研究(IOBR)提供的CIBERSORT、ESTIMATE和TIMERxCell算法。使用专门为此目的设计的R包Maftools进行单核苷酸变异(SNV)分析。随后,评估黑色素瘤组织与相邻正常组织中相关基因的表达水平。此外,进行体外实验以评估用靶向相关基因的siRNA转染后黑色素瘤细胞中的增殖和活性氧表达。
基于全面的单细胞数据集分析对恶性肿瘤细胞群体进行了重新分类,产生了六个不同的肿瘤亚群。然后使用为这些亚群鉴定的特异性标记基因来分析源自批量RNA测序数据的癌症基因组图谱皮肤黑色素瘤(TCGA-SKCM)队列,从而划分出两种免疫分子亚型。值得注意的是,与cluster1(C1)亚型的患者相比,cluster2(C2)亚型的患者预后明显更好。在C2亚型与独特的免疫功能肿瘤细胞亚群之间观察到免疫特征的一致性。随后利用这些亚型中差异表达的基因构建预测风险模型。体外研究进一步揭示了黑色素瘤组织样本中相关基因的表达水平升高。功能测定表明,相关基因表达的调节可影响活性氧(ROS)的产生和黑色素瘤细胞的增殖能力。
构建的六基因特征可作为免疫反应和氧化应激标志物,以指导黑色素瘤的临床诊断和治疗。
