FaST - Jurnal Sains dan Teknologi

According to WHO, breast cancer is one of the main causes of mortality in women. To overcome this malady, molecular biomedical research is carried out intensively. Anomalies in the lincRNA-RoR/miR-145/ARF6 expression pathway were found to play a very important role in breast cancer, especially in the type of Triple-Negative Breast Cancer (TNBC), which is the most dangerous variant of the deadly disease. Bioinformatics research has found the existence of non-coding RNA (ncRNA) in these expression pathways, whose interactions are worth studying with 3-dimensional prediction methods. The 3-D prediction method for biomolecules has been widely developed and has been successfully applied to DNA and protein. However, for the structure of RNA, it has just been developed, due to its low stability and very high dynamics on the biomolecule. Our aim is to apply the latest computational method for predicting the 3-dimensional structure of ncRNA, which can be applied as key information in biomedical application research. Extrapolation of kinetics and thermodynamic indicators of ncRNA ultimately yields the siRNA Linc-ROR 3-Dimensional structure and siRNA mRNA-ARF6, each having 13 and 8 hydrogen bonds. The existence of these hydrogen bonds is very important in maintaining the stability of the compounds and shows its efficacy as drug candidates. It is expected that preliminary information from the predicted 3-dimensional structure of ncRNA is useful for optimization of laboratory experiments in the field of crystallographic biomolecules.

Barreda, J.E., Shigenobu, Y., Ichiishi, E., and Del-Carpio, C.A. 2004. RNA 3D structure prediction: (1) assessing rna 3D structure similarity from 2D structure similarity. Genome Informatics, 15(2): 112–120. Bronowska, A.K. 2011. Thermodynamics of Ligand-Protein Interactions: Implications for Molecular Design. Thermodynamics - Interaction Studies - Solids, Liquids and Gases. Intech. Burnett, J.C. and Rossi, J.J. 2012. RNA-based therapeutics: current progress and future prospects. Chemistry & Biology, 19(1): 60–71 Caley, A. and Jones, R. 2012. The principles of cancer treatment by chemotherapy. Surgery, 30(4): 186-190 Cao, S. and Chen, S.J. 2011. Physics-based de novo prediction of RNA 3D structures. Journal of Physical Chemistry B, 115(14): 4216–4226. Dong, Z. and Chen, Y. 2013. Transcriptomics: advances and approaches. Science China Life Sciences, 56(10): 960–967. Eades, G. Wolfson, B., Zhang, Y., Li, Q., Yao, Y., and Zhou, Q. 2015. lincRNA-RoR and miR-145 regulate invasion in triple-negative breast cancer via targeting ARF6. Molecular Cancer Research, 13(2): 330–338. Graur, D. Zheng, Y., Price, N., Azevedo, R.B.R., Zufall, R.A., and Elhaik, E. 2013. On the immortality of television sets: function in the human genome according to the evolution-free gospel of ENCODE. Genome Biology and Evolution, 5(3): 578-590. Gruber, A.R. Bernhart, S.H., and Lorenz, R. 2015. The viennaRNA web services. RNA Bioinformatics, 1269: 307–326 Guex, N. and Peitsch, M.C. 1997. SWISS-MODEL and the Swiss-PdbViewer: An environment for comparative protein modeling. Electrophoresis, 18(15): 2714–2723. Guex, N. Peitsch, M.C., and Schwede, T. 2009. Automated comparative protein structure modeling with SWISS-MODEL and Swiss-PdbViewer: A historical perspective. Electrophoresis, 30(S1). Hickerson, R.P., Vlassov, A. V., Wang, Q., Leake, D., Ilves, H., Gonzalez-Gonzalez, E., Contag, C.H., Johnston, B.H., and Kaspar, R.L. 2008. Stability study of unmodified siRNA and relevance to clinical use. Oligonucleotides, 18(4): 345–354. Hillisch, A. Pineda, L.F., and Hilgenfeld, R. 2004. Utility of homology models in the drug discovery process. Drug Discovery Today, 9(15): 659–669. Kapetanovic, I.M. 2008. Computer-aided drug discovery and development (CADDD): in silico-chemico-biological approach. Chemico-Biological Interactions, 171(2): 165–176. Kemenkes-RI. 2013. Profil Kesehatan Indonesia, Jakarta, Downloaded from http://www.depkes.go.id/resources/download/pusdatin/profil-kesehatan-indonesia/profil-kesehatan-indonesia-2013.pdf on 1/12/2017 Levitt, M. 2009. Nature of the protein universe. Proceedings of the National Academy of Sciences of the United States of America,106(27):11079–11084. Li, C. Penet, M.F., Wildes, F., Takagi, T., Chen, Z., Winnard, P.T., Artemov, D., and Bhujwalla, Z.M. 2010. Nanoplex delivery of siRNA and prodrug enzyme for multimodality image-guided molecular pathway targeted cancer therapy. ACS Nano, 4(11): 6707–6716. Magnus, M. Boniecki, M.J., Dawson, W., and Bujnicki, J.M. 2016. SimRNAweb: a web server for RNA 3D structure modeling with optional restraints. Nucleic Acids Research, 44(W1): W315-W319. Mattick, J.S. 2005. The functional genomics of noncoding RNA. Science, 309(5740): 1527–1528. Mattick, J.S. 2013. Probing the phenomics of noncoding RNA eLife 2013(2). Downloaded from https://doi.org/ 10.7554/eLife.01968 on 1/12/2017. NCBI. 2013. The NCBI Handbook. National Center for Biotechnology Information (US), Downloaded from http://www.ncbi.nlm.nih.gov/books/NBK21101/ on 1/12/2017. Oh, Y.K. and Park, T.G. 2009. siRNA delivery systems for cancer treatment. Advanced Drug Delivery Reviews, 61(10): 850–862. Parikesit, A.A. dan Anurogo, D. 2016. Prediksi struktur 2-dimensi non-coding RNA dari biomarker kanker payudara triple-negative dengan Vienna RNA package. Chimica et Natura Acta, 4(1): 27. Parikesit, A.A. Anurogo, D. and Parikesit, A.A. 2016. Bioinformatics approach towards transcriptomics of filaggrin. Journal of Agromedicine and Medical Sciences, 2(3) : 8–16. Rastogi, P. 2008. Bioinformatics Methods And Applications: Genomics Proteomics And Drug Discovery 3Rd Ed. Prentice-Hall Of India Pvt. Limited, Downloaded from http://books.google.co.id/books?id =YP1rEFxFgDcC on 1/12/2017 Rinn, J.L. and Chang, H.Y. 2012. Genome regulation by long noncoding RNAs. Annual Review of Biochemistry, 81:145–166. Rother, M. Milanowska, K., Puton, T., Jeleniewicz, J., Rother, K. and Bujnicki, J.M. 2011. ModeRNA server: an online tool for modeling RNA 3D structures. Bioinformatics, 27(17): 2441–2442. Senn, H.M. and Thiel, W. 2009. QM/MM methods for biomolecular systems. Angewandte Chemie International Edition, 48(7): 1198–1229. Sotiriou, C. Wirapati, P., Loi, S., Harris, A., Fox, S., Smeds, J., Nordgren, H., Farmer, P., Praz, V., Haibe-Kains, B., Desmedt, C., Larsimont, D., Cardoso, F., Peterse, H., Nuyten, D., Buyse, M., Van de Vijver, M.J., Bergh, J., Piccart, M., and Delorenzi, M. 2006. Gene expression profiling in breast cancer: understanding the molecular basis of histologic grade to improve prognosis. Journal of the National Cancer Institute, 98(4):262–272. Sripakdeevong, P. Beauchamp, K., and Das, R. 2012. RNA 3D Structure analysis and prediction. Nucleic Acids and Molecular Biology, 27(27): 43–65. Tang, Q. Cao, B., and Cheng, G. 2014. Co-delivery of small interfering RNA using a camptothecin prodrug as the carrier. Chemical Communications, 50(11): 1323–1325. Team, T.D. 2001. DeepView – The Swiss-PdbViewer User Guide. Zurich: World Trade. Walsh, I. Martin, A.J.M., Mooney, C., Rubagotti, E., Vullo, A., and Pollastri, G. 2009. Ab initio and homology based prediction of protein domains by recursive neural networks. BMC Bioinformatics, 10(1): 195. WHO. 2016. WHO Breast Cancer Prevention and Control. WHO Fact Sheet, Downloaded from http://www.who.int/ cancer/detection/breastcancer/en/ on 1/12/2017 Zhao, L. Wang, J., Dou, X., and Cao, Z. 2009. Studying the unfolding process of protein G and protein L under physical property space. BMC Bioinformatics, 10(S1): S44.