Construction of a five-gene-based prognostic model for relapsed/refractory acute lymphoblastic leukemia.

IF 2 4区医学 Q3 HEMATOLOGY

Hematology Pub Date : 2024-12-01 Epub Date: 2024-10-17 DOI:10.1080/16078454.2024.2412952

Bi Zhou, BoJie Min, WenYuan Liu, Ying Li, Feng Zhu, Jin Huang, Jing Fang, Qin Chen, De Wu

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引用次数: 0

Abstract

Background: Relapsed/refractory acute lymphoblastic leukemia (R/R ALL) continues to be a major cause of mortality in children worldwide, with around 15% of ALL patients experiencing relapse and approximately 10% eventually dying from the disease. Early identification of R/R ALL in children has posed a longstanding clinical challenge.

Method: Genetic analysis of survival outcomes in pediatric patients with ALL from the TARGET-ALL dataset revealed five risk score factors identified through the intersection of differential genes (relapse/non-relapse) from the GSE17703 and GSE6092 databases. A risk score equation was formulated using these factors and validated against prognostic data from 46 ALL cases at our institution. Patients from multiple datasets were stratified into high and low-score groups based on this equation. Protein-protein interaction networks (PPI) were then constructed using the intersecting differential genes from all three datasets to identify hub nodes and predict interacting transcription factors. Additionally, genes related to cell pyroptosis with varying expression across these datasets were screened, and a multifactorial ROC curve (incorporating risk score and differential expression of pyroptosis-related genes) was generated. Furthermore, relationships among variables in the predictive model were depicted using a nomogram, and model efficacy was assessed through decision curve analysis (DCA).

Results: By analyzing the TARGET-ALL, GSE17703, and GSE6092 databases, we developed a prognostic risk assessment model for pediatric ALL incorporating BAG2, EPHA4, FBXO9, SNX10, and WNK1. Validation of this model was conducted using data from 46 pediatric ALL cases obtained from our institution. Following the identification of 27 differentially expressed genes, we constructed a PPI and identified the top 10 hub genes (PTPRC, BTK, LCK, PRKCQ, CD3D, CD27, CD3G, BLNK, RASGRP1, VPREB1). Using this network, we predicted the top 5 transcription factors (HOXB4, MYC, SOX2, E2F1, NANOG). ROC and DCA were conducted on pyroptosis-related genes exhibiting differential expression and risk scores. Subsequently, a nomogram was generated, demonstrating the effectiveness of the risk score in predicting prognosis for pediatric ALL patients.

Conclusions: We have developed a risk prediction model for pediatric R/R ALL utilizing the genes BAG2, EPHA4, FBXO9, SNX10, and WNK1. This model provides a scientific foundation for early identification of R/R ALL in children.

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构建基于五个基因的复发/难治性急性淋巴细胞白血病预后模型。

背景：复发/难治性急性淋巴细胞白血病（R/R ALL）仍然是全球儿童死亡的主要原因，约15%的ALL患者会复发，约10%最终死于该病。儿童R/R ALL的早期识别是一项长期的临床挑战：方法：通过对TARGET-ALL数据集中的儿童ALL患者生存结果进行遗传分析，发现了五个风险评分因子，这些因子是通过GSE17703和GSE6092数据库中的差异基因（复发/非复发）交叉而确定的。利用这些因素制定了风险评分方程，并根据本机构 46 例 ALL 的预后数据进行了验证。根据该方程将来自多个数据集的患者分为高分组和低分组。然后利用所有三个数据集的交叉差异基因构建了蛋白质-蛋白质相互作用网络（PPI），以确定中心节点并预测相互作用的转录因子。此外，还筛选了在这些数据集中有不同表达的细胞脓毒症相关基因，并生成了多因素 ROC 曲线（包含风险评分和脓毒症相关基因的差异表达）。此外，还利用提名图描述了预测模型中各变量之间的关系，并通过决策曲线分析（DCA）评估了模型的有效性：结果：通过分析TARGET-ALL、GSE17703和GSE6092数据库，我们建立了一个包含BAG2、EPHA4、FBXO9、SNX10和WNK1的小儿ALL预后风险评估模型。我们利用从本机构获得的 46 个小儿 ALL 病例的数据对该模型进行了验证。在确定了 27 个差异表达基因后，我们构建了一个 PPI 并确定了前 10 个中心基因（PTPRC、BTK、LCK、PRKCQ、CD3D、CD27、CD3G、BLNK、RASGRP1、VPREB1）。利用这一网络，我们预测了前 5 个转录因子（HOXB4、MYC、SOX2、E2F1、NANOG）。我们对表现出差异表达和风险评分的热核病相关基因进行了 ROC 和 DCA 分析。随后，我们生成了一个提名图，证明了风险评分在预测小儿 ALL 患者预后方面的有效性：结论：我们利用 BAG2、EPHA4、FBXO9、SNX10 和 WNK1 等基因建立了小儿 R/R ALL 风险预测模型。该模型为早期识别儿童R/R ALL提供了科学依据。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Hematology 医学-血液学

CiteScore

2.60

自引率

5.30%

发文量

140

审稿时长

3 months

期刊介绍： Hematology is an international journal publishing original and review articles in the field of general hematology, including oncology, pathology, biology, clinical research and epidemiology. Of the fixed sections, annotations are accepted on any general or scientific field: technical annotations covering current laboratory practice in general hematology, blood transfusion and clinical trials, and current clinical practice reviews the consensus driven areas of care and management.