Multiomics blueprint of PANoptosis in deciphering immune characteristics and prognosis stratification of glioma patients

IF 3.2 4区医学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Journal of Gene Medicine Pub Date : 2023-11-23 DOI:10.1002/jgm.3621

Maohua Chen, Min Huang, Xiaoxiang Chen, Xiaoyu Lin, Xianglin Chen

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Abstract

Background

As the most prevalent primary brain tumor in adults, glioma accounts for the majority of all central nervous system malignant tumors. The concept of PANoptosis is a relatively new, underlining the interconnection and synergy among three distinct pathways: pyroptosis, apoptosis and necroptosis.

Methods

We performed single-cell annotations of glioma cells and determined crucial signaling pathways through cell chat analysis. Using least absolute shrinkage and selection operator (LASSO) and Cox analyses, we identified a gene set with prognostic values. Our model was validated using independent external cohort. In addition, we employed single-sample gene set enrichment analysis and xCell analyses to describe the detailed profile of infiltrated immune cells and depicted the gene mutation landscape in the two groups.

Results

We identified seven distinct cell clusters in glioma samples, including oligodendrocyte precursor cells (OPCs), myeloid cells, tumor cells, oligodendrocytes, astrocytes, vascular cells and neuronal cells. We found that myeloid cells showed the highest PANoptosis activity. An intense mutual cell communication pattern between the tumor cells and OPCs and oligodendrocytes was observed. Differentially expressed genes between the high-PANoptosis and low-PANoptosis cell groups were obtained, which were enriched to actin cytoskeleton, cell adhesion molecules and gamma R-mediated phagocytosis pathways. We determined a set of five genes of prognostic significance: SAA1, SLPI, DCX, S100A8 and TNR. The prognostic differences between the two groups in the internal and external sets were found to be statistically significant. We found a marked correlation between S100A8 and activated dendritic cell, macrophage, mast cell, myeloid derived suppressor cell and Treg infiltration. Moreover, we have observed a significant increase of PTEN mutation in the high risk (HR) group of glioma patients.

Conclusions

In the present study, we have constructed a prognostic model that is based on the PANoptosis, and we have demonstrated its significant efficacy in stratifying patients with glioma. This innovative prognostic model offers novel insights into precision immune treatments that could be used to combat this disease and improve patient outcomes, thereby providing a new avenue for personalized treatment options.

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PANoptosis的多组学蓝图在胶质瘤患者免疫特征和预后分层中的解读。

背景:神经胶质瘤是成人最常见的原发性脑肿瘤，在所有中枢神经系统恶性肿瘤中占绝大多数。PANoptosis是一个相对较新的概念，强调了焦亡、凋亡和坏死三种不同途径之间的相互联系和协同作用。方法:我们对胶质瘤细胞进行了单细胞注释，并通过细胞聊天分析确定了关键的信号通路。使用最小绝对收缩和选择算子(LASSO)和Cox分析，我们确定了一组具有预后价值的基因。我们的模型通过独立的外部队列验证。此外，我们采用单样本基因集富集分析和xCell分析来描述浸润免疫细胞的详细情况，并描绘了两组的基因突变景观。结果:我们在胶质瘤样本中鉴定出七种不同的细胞簇，包括少突胶质细胞前体细胞(OPCs)、髓细胞、肿瘤细胞、少突胶质细胞、星形胶质细胞、血管细胞和神经元细胞。我们发现骨髓细胞表现出最高的PANoptosis活性。观察到肿瘤细胞与OPCs和少突胶质细胞之间存在强烈的相互细胞通讯模式。在高panoptosis细胞组和低panoptosis细胞组之间获得了差异表达基因，这些基因富集于肌动蛋白细胞骨架、细胞粘附分子和γ r介导的吞噬途径。我们确定了一组具有预后意义的五个基因:SAA1, SLPI, DCX, S100A8和TNR。两组内、外组预后差异有统计学意义。我们发现S100A8与活化的树突状细胞、巨噬细胞、肥大细胞、髓源性抑制细胞和Treg浸润有显著的相关性。此外，我们观察到PTEN突变在胶质瘤患者的高风险(HR)组中显著增加。结论:在本研究中，我们构建了一个基于PANoptosis的预后模型，并证明了其对胶质瘤患者分层的显著疗效。这种创新的预后模型为精确免疫治疗提供了新的见解，可用于对抗这种疾病并改善患者的预后，从而为个性化治疗选择提供了新的途径。

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来源期刊

Journal of Gene Medicine 医学-生物工程与应用微生物

CiteScore

6.40

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： The aims and scope of The Journal of Gene Medicine include cutting-edge science of gene transfer and its applications in gene and cell therapy, genome editing with precision nucleases, epigenetic modifications of host genome by small molecules, siRNA, microRNA and other noncoding RNAs as therapeutic gene-modulating agents or targets, biomarkers for precision medicine, and gene-based prognostic/diagnostic studies. Key areas of interest are the design of novel synthetic and viral vectors, novel therapeutic nucleic acids such as mRNA, modified microRNAs and siRNAs, antagomirs, aptamers, antisense and exon-skipping agents, refined genome editing tools using nucleic acid /protein combinations, physically or biologically targeted delivery and gene modulation, ex vivo or in vivo pharmacological studies including animal models, and human clinical trials. Papers presenting research into the mechanisms underlying transfer and action of gene medicines, the application of the new technologies for stem cell modification or nucleic acid based vaccines, the identification of new genetic or epigenetic variations as biomarkers to direct precision medicine, and the preclinical/clinical development of gene/expression signatures indicative of diagnosis or predictive of prognosis are also encouraged.