了解槟榔mirna对人体健康的分子机制。

Toral Manvar, Naman Mangukia, Saumya K. Patel, Rakesh M. Rawal
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引用次数: 0

摘要

背景自古以来,“槟榔叶”因其宗教、文化和药用特性而备受推崇。胡椒中的植物化学物质对多种疾病都有效,包括癌症。然而,到目前为止,还没有发现任何基因组研究或证据来阐明支撑其治疗特性的调节机制。这是第一项预测胡椒豆miRNA的同类研究,也是第一个胡椒豆的基因组学来源代表。根据之前的研究,我们食用的植物中的miRNA可以调节基因表达。与此相一致,我们的计算机研究表明,胡椒和人类的跨王国控制发生了。方法本研究证明了来自NGS衍生转录序列的Piper betle miRNA的预测和计算机验证。研究了跨王国调节,也可以理解为物种间RNA调节,以确定由Piper betle miRNA控制的人类mRNA靶点。对人类靶点进行功能注释和基因-疾病关联,以了解Piper betle miRNA在人类健康和疾病中的作用。进一步进行了靶点的蛋白质-蛋白质相互作用和表达研究,以阐明它们在癌症发展中的作用。结果鉴定了6个属于miR156、miR164、miR172和miR535家族的Piper betle miRNA,它们靶向198个参与各种代谢和疾病过程的人类mRNA。血管生成和细胞表面信号通路是与靶点相关的最丰富的基因本体,两者在疾病机制中都发挥着关键作用,尤其是在癌症的情况下。在对基因与疾病相互作用的分析中,发现40个基因与癌症有关。根据蛋白质-蛋白质相互作用,CDK6基因被认为是细胞周期进展的中心调节因子,被发现是一种中枢蛋白,影响CBFB、SAMD9、MDM4、AXIN2和NOTCH2癌基因的作用。进一步的研究表明,pbe-miRNA164a可作为调节因子,在急性髓细胞白血病中降低疾病的严重程度,与正常细胞相比,CDK6的表达最高。结论本研究预测的pbe-miRNA164a可能是一种很有前途的CDK6基因参与肿瘤血管生成的抑制剂。pbe-miRNA164a模拟物的体内验证可能为抗击癌症的新机会铺平道路,并利用Piper betle在医疗保健领域的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Understanding the Molecular Mechanisms of Betel miRNAs on Human Health.
BACKGROUND Since ancient times, "betel leaf" (Piper betle) has been revered for its religious, cultural, and medicinal properties. Phytochemicals from the Piper betle are effective in a variety of conditions, including cancer. To date, however, no genomic study or evidence has been found to elucidate the regulatory mechanism that underpins its therapeutic properties. This is the first study of its kind to predict Piper betle miRNAs and also the first genomics source representation of Piper betle. According to previous research, miRNAs from the plants we eat can regulate gene expression. In line with this, our in-silico study revealed that Piper betle and human cross-kingdom control occurs. METHOD This study demonstrates the prediction and in-silico validation of Piper betle miRNAs from NGS-derived transcript sequences. The cross-kingdom regulation which can also be understood as inter-species RNA regulation was studied to identify human mRNA targets being controlled by Piper betle miRNAs. Functional annotation and gene-disease association of human targets were performed to understand the role of Piper betle miRNAs in human health and disease. The protein-protein interaction and expression study of targets was further carried out to decipher their role in cancer development. RESULTS Identified six Piper betle miRNAs belonging to miR156, miR164, miR172, and miR535 families were discovered to target 198 human mRNAs involved in various metabolic and disease processes. Angiogenesis and the cell surface signaling pathway were the most enriched gene ontology correlated with targets, both of which play a critical role in disease mechanisms, especially in the case of carcinoma. In an analysis of gene-disease interactions, 40 genes were found to be related to cancer. According to a protein-protein interaction, the CDK6 gene, which is thought to be a central regulator of cell cycle progression, was found as a hub protein, affecting the roles of CBFB, SAMD9, MDM4, AXIN2, and NOTCH2 onco genes. Further investigation revealed that pbe-miRNA164a can be used as a regulator to minimise disease severity in Acute Myeloid Leukemia, where CDK6 expression is highest compared to normal cells. CONCLUSION The predicted pbe-miRNA164a in this study can be a promising suppressor of CDK6 gene involved in tumour angiogenesis. In vivo validation of the pbe-miRNA164a mimic could pave the way for new opportunities to fight cancer and leverage the potential of Piper betle in the healthcare sector.
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