Deciphering the gene regulatory network associated with anti-apoptosis in the pancreatic islets of type 2 diabetes mice using computational approaches

IF 1 Q4 ENGINEERING, BIOMEDICAL AIMS Bioengineering Pub Date : 2023-01-01 DOI:10.3934/bioeng.2023009

F. Ahmed

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Abstract

Type 2 diabetes (T2D) is a major global health problem often caused by the inability of pancreatic islets to compensate for the high insulin demand due to apoptosis. However, the complex mechanisms underlying the activation of apoptosis and its counter process, anti-apoptosis, during T2D remain unclear. In this study, we employed bioinformatics and systems biology approaches to understand the anti-apoptosis-associated gene expression and the biological network in the pancreatic islets of T2D mice. First, gene expression data from four peripheral tissues (islets, liver, muscle and adipose) were used to identify differentially expressed genes (DEGs) in T2D compared to non-T2D mouse strains. Our comparative analysis revealed that Gm2036 is upregulated across all four tissues in T2D and is functionally associated with increased cytosolic Ca2+ levels, which may alter the signal transduction pathways controlling metabolic processes. Next, our study focused on islets and performed functional enrichment analysis, which revealed that upregulated genes are significantly associated with sucrose and fructose metabolic processes, as well as negative regulation of neuron apoptosis. Using the Ingenuity Pathway Analysis (IPA) tool of QIAGEN, gene regulatory networks and their biological effects were analyzed, which revealed that glucose is associated with the underlying change in gene expression in the islets of T2D; and an activated gene regulatory network—containing upregulated CCK, ATF3, JUNB, NR4A1, GAST and downregulated DPP4—is possibly inhibiting apoptosis of islets and β-cells in T2D. Our computational-based study has identified a putative regulatory network that may facilitate the survival of pancreatic islets in T2D; however, further validation in a larger sample size is needed. Our results provide valuable insights into the underlying mechanisms of T2D and may offer potential targets for developing more efficacious treatments.

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利用计算方法破解2型糖尿病小鼠胰岛抗凋亡相关的基因调控网络

2型糖尿病(T2D)是一个主要的全球性健康问题，通常是由胰岛无法补偿细胞凋亡导致的高胰岛素需求引起的。然而，T2D期间细胞凋亡激活及其对抗过程——抗细胞凋亡的复杂机制尚不清楚。在这项研究中，我们采用生物信息学和系统生物学的方法来了解T2D小鼠胰岛中抗凋亡相关基因的表达和生物网络。首先，使用来自四个外周组织(胰岛、肝脏、肌肉和脂肪)的基因表达数据来鉴定T2D小鼠与非T2D小鼠株的差异表达基因(DEGs)。我们的比较分析显示，Gm2036在T2D的所有四个组织中都上调，并且在功能上与细胞质Ca2+水平升高相关，这可能改变控制代谢过程的信号转导途径。接下来，我们的研究重点是胰岛，并进行了功能富集分析，发现上调基因与蔗糖和果糖代谢过程显著相关，并对神经元凋亡进行负调控。利用QIAGEN独创通路分析(Ingenuity Pathway Analysis, IPA)工具，分析了T2D患者胰岛基因调控网络及其生物学效应，发现葡萄糖与T2D患者胰岛基因表达的潜在变化有关;激活的基因调控网络包含上调的CCK、ATF3、JUNB、NR4A1、GAST和下调的dpp4，可能抑制T2D中胰岛和β-细胞的凋亡。我们基于计算的研究已经确定了一个假定的调节网络，可能促进胰岛在T2D中的存活;然而，需要在更大的样本量中进一步验证。我们的结果为T2D的潜在机制提供了有价值的见解，并可能为开发更有效的治疗方法提供潜在的靶点。

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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AIMS Bioengineering ENGINEERING, BIOMEDICAL-

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4 weeks