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Background: Prostate cancer (PC) is a fatally aggressive urogenital cancer killing millions of men, globally. Thus, this study aims to identify key miRNAs, target genes, and drug targets associated with prostate cancer metastasis. Methods: The miRNA and mRNA expression datasets of 148 prostate tissue biopsies (39 tumours and 109 normal tissues), were analysed by differential gene expression analysis, protein interactome mapping, biological pathway analysis, miRNA-mRNA networking, drug target analysis, and survival curve analysis. Results: The dysregulated expression of 53 miRNAs and their 250 target genes involved in Hedgehog, ErbB, and cAMP signalling pathways connected to cell growth, migration, and proliferation of prostate cancer cells was detected. The subsequent miRNA-mRNA network and expression status analysis have helped us in narrowing down their number to 3 hub miRNAs (hsa-miR-455-3p, hsa-miR-548c-3p, and hsa-miR-582-5p) and 9 hub genes (NFIB, DICER1, GSK3B, DCAF7, FGFR1OP, ABHD2, NACC2, NR3C1, and FGF2). Further investigations with different systems biology methods have prioritized NR3C1, ABHD2, and GSK3B as potential genes involved in prostate cancer metastasis owing to their high mutation load and expression status. Interestingly, down regulation of NR3C1 seems to improve the prostate cancer patient survival rate beyond 150 months. The NR3C1, ABHD2, and GSK3B genes are predicted to be targeted by hsa-miR-582-5p, besides some antibodies, PROTACs and inhibitory molecules. Conclusion: This study identified key miRNAs (miR-548c-3p and miR-582-5p) and target genes (NR3C1, ABHD2, and GSK3B) as potential biomarkers for metastatic prostate cancers from large-scale gene expression data using systems biology approaches.
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Inflammatory bowel disease (IBD) is a gastrointestinal disease with an underlying contribution of genetic, microbial, environment, immunity factors. The coding region risk markers identified by IBD genome wide association studies have not been well characterized at protein phenotype level. Therefore, this study is conducted to characterize the role of NOD2 (Arg675Trp and Gly908Arg) and IL23R (Gly149Arg and Arg381Gln) missense variants on the structural and functional features of corresponding proteins. Thus, we used different variant pathogenicity assays, molecular modelling, secondary structure, stability, molecular dynamics, and molecular docking analysis methods. Our findings suggest that SIFT, Polyphen, GREP++, PhyloP, SiPhy and REVEL methods are very sensitive in determining pathogenicity of NOD2 and IL23R missense variants. We have also noticed that all the tested missense variants could potentially alter secondary (α-helices, ß-strands, and coils) and tertiary (residue level deviations) structural features. Moreover, our molecular dynamics (MD) simulation findings have simulated that NOD2 (Arg675Trp and Gly908Arg) and IL23R (Gly149Arg and Arg381Gln) variants creates rigid local structures comprising the protein flexibility and conformations. These predictions are corroborated by molecular docking results, where we noticed that NOD2 and IL23R missense variants induce molecular interaction deformities with RIPK2 and JAK2 ligand molecules, respectively. These functional alterations could potentially alter the signal transduction pathway cascade involved in inflammation and autoimmunity. Drug library searches and findings from docking studies have identified the inhibitory effects of Tacrolimus and Celecoxib drugs on NOD2 and IL23R variant forms, underlining their potential to contribute to personalized medicine for IBD. The present study supports the utilization of computational methods as primary filters (pre-in vitro and in vivo) in studying the disease potential mutations in the context of genptype-protein phenotype characteristics.
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Lamellar ichthyosis (LI) is a rare inherited disease where affected infants present a extensive skin scaling characterized by hyperkeratosis. Inherited mutations in the Transglutaminase 1 (TGM1) protein is one of the known causative genetic factor for the LI. The main objective of this study is to explore the impact of LI causative missense mutations on the structural and stability aspects of TGM1 protein using structural modeling, molecular docking and molecular dynamics approaches. By testing all LI causative TMG1 mutations against multiple stability prediction methods, we found that L362R and L388P mutations positioned in the Transglut_core domain were most destabilizing to the stability of TGM1 protein. These 2 mutations were 3D protein modeled and further analyzed by molecular docking and dynamic simulation methods. Molecular docking of these TGM1 mutant structures with chitosan, a natural polyphenolic compound and known inducer for transglutaminase enzyme, has shown stable molecular interactions between the native TGM1-chitosan and TGM1(L388P)-chitosan complex, when compared to the TGM1(L362R)-chitosan complex. Interestingly, molecular dynamics analysis have also yielded similar findings, where L388P-chitosan complex is shown to develop B-sheets and attain better stability, whereas TGM1-L362R complex possessed coils over the simulation period, pointing its highly destabilizing behavior on the protein structure. This study concludes that missense mutations in Transglut_core domain of the TGM1 are deleterious to the stability and structural changes of TGM1 protein and also suggest that chitosan molecule could act as a natural activator against few pathogenic TGM1 mutations. Communicated by Ramaswamy H. Sarma.