{"title":"基于变异链球菌的特异性抗原表位设计预防糖尿病发病的预期性硅学疫苗。","authors":"Gopinath Murugan, Gugan Kothandan, Rajashree Padmanaban","doi":"10.1007/s40203-024-00260-x","DOIUrl":null,"url":null,"abstract":"<p><p>The metabolic disorder Type 2 Diabetes Mellitus (T2DM) is characterized by hyperglycaemia, causing increased mortality and healthcare burden globally. Recent studies emphasize the impact of metabolites in the gut microbiome on T2DM pathogenesis. One such microbial metabolite, imidazole propionate (Imp) derived from histidine metabolism, is shown to interfere with insulin signalling and other key metabolic processes. The key enzyme urocanate reductase (UrdA) is involved in ImP production. Hence, we propose to develop a novel therapeutic vaccine against the gut microbe producing Imp based on UrdA as a target for treating T2DM using immunoinformatics approach. Antigenic, non-allergic, non-toxic, and immunogenic B cell and T cell potential epitopes were predicted using immunoinformatics servers and tools. These epitopes were adjoined using linker sequences, and to increase immunogenicity, adjuvants were added at the N-terminal end of the final vaccine construct. Further, to confirm the vaccine's safety, antigenic and non-allergic characteristics of the developed vaccine construct were assessed. The tertiary structure of the UrdA vaccine sequence was predicted using molecular modelling tools. A molecular docking study was utilized to understand the vaccine construct interaction with immune receptors, followed by molecular dynamics simulation and binding free energy calculations to assess stability of the complex. In silico cloning techniques were employed to evaluate the expression and translation effectiveness of the developed vaccine in pET vector. 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The tertiary structure of the UrdA vaccine sequence was predicted using molecular modelling tools. A molecular docking study was utilized to understand the vaccine construct interaction with immune receptors, followed by molecular dynamics simulation and binding free energy calculations to assess stability of the complex. In silico cloning techniques were employed to evaluate the expression and translation effectiveness of the developed vaccine in pET vector. 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引用次数: 0
摘要
2 型糖尿病(T2DM)是一种以高血糖为特征的代谢性疾病,在全球范围内造成死亡率和医疗负担的增加。最近的研究强调了肠道微生物组中的代谢物对 T2DM 发病机制的影响。其中一种微生物代谢物--组氨酸代谢产生的咪唑丙酸盐(Imp)被证明会干扰胰岛素信号和其他关键代谢过程。关键酶尿囊酸还原酶(UrdA)参与了 ImP 的生成。因此,我们建议利用免疫信息学方法,以 UrdA 为治疗 T2DM 的靶点,开发一种针对肠道微生物产 Imp 的新型治疗疫苗。我们使用免疫信息学服务器和工具预测了抗原性、非过敏性、无毒性和免疫原性的 B 细胞和 T 细胞潜在表位。这些表位通过连接序列连接起来,为了增加免疫原性,在最终疫苗构建体的 N 端添加了佐剂。此外,为了确认疫苗的安全性,还对所开发疫苗构建体的抗原性和非过敏性特征进行了评估。利用分子建模工具预测了 UrdA 疫苗序列的三级结构。利用分子对接研究了解疫苗构建物与免疫受体的相互作用,然后进行分子动力学模拟和结合自由能计算,以评估复合物的稳定性。此外,还采用硅克隆技术评估了所开发疫苗在 pET 载体中的表达和翻译效果。总之,本研究开发了一种基于表位的硅学疫苗构建体,作为治疗 T2DM 的新型辅助疗法:
Anticipatory in silico vaccine designing based on specific antigenic epitopes from Streptococcus mutans against diabetic pathogenesis.
The metabolic disorder Type 2 Diabetes Mellitus (T2DM) is characterized by hyperglycaemia, causing increased mortality and healthcare burden globally. Recent studies emphasize the impact of metabolites in the gut microbiome on T2DM pathogenesis. One such microbial metabolite, imidazole propionate (Imp) derived from histidine metabolism, is shown to interfere with insulin signalling and other key metabolic processes. The key enzyme urocanate reductase (UrdA) is involved in ImP production. Hence, we propose to develop a novel therapeutic vaccine against the gut microbe producing Imp based on UrdA as a target for treating T2DM using immunoinformatics approach. Antigenic, non-allergic, non-toxic, and immunogenic B cell and T cell potential epitopes were predicted using immunoinformatics servers and tools. These epitopes were adjoined using linker sequences, and to increase immunogenicity, adjuvants were added at the N-terminal end of the final vaccine construct. Further, to confirm the vaccine's safety, antigenic and non-allergic characteristics of the developed vaccine construct were assessed. The tertiary structure of the UrdA vaccine sequence was predicted using molecular modelling tools. A molecular docking study was utilized to understand the vaccine construct interaction with immune receptors, followed by molecular dynamics simulation and binding free energy calculations to assess stability of the complex. In silico cloning techniques were employed to evaluate the expression and translation effectiveness of the developed vaccine in pET vector. In conclusion, this study developed an in silico epitope-based vaccine construct as a novel adjunct therapeutic for T2DM.