Browsing by Subject "MicroRNAs"
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Item Open Access The effect of Maras powder and smoking on the microRNA deregulation of oral mucosa(Faculdade De Odontologia De Bauru - USP, 2020) Taş, B.; Güre, Ali OsmayObjective: This study aimed to investigate the effects of Maras powder (a type of smokeless tobacco obtained from Nicotiana rustica Linn and mixed with the ashes of wood, especially from oak, walnut or grapevine) on the microRNA (miRNA) deregulation of oral mucosa, and it compares these effects with those of smoking. Methodology: Oral mucosal samples were collected from 74 patients, consisting of 16 nonusers, 26 smokers, and 32 Maras powder users. Genes associated with oral cancer were selected and 90 microRNAs targeting these genes were identified. MicroRNA were isolated and purified using the microRNA isolation kit. MicroRNA were expressed using Fluidigm RT-PCR. Results: A positive correlation between the duration of Maras powder use with miR-31 expression levels, and a negative correlation between the Maras powder chewing time and miR-372 expression levels was found. In addition, there is a negative correlation between the amount of Maras powder consumed and expression levels of miR-375, miR-378a, miR-145, and miR-10b; moreover, another negative correlation is observed between the number of cigarettes consumed and the expression levels of miR-23a, miR-23b, miR-203a, miR-200b, and miR-375. However, miR-200b and miR-92a levels were downregulated significantly more in Maras powder users when compared with smokers and nonusers (p<0.05). Conclusion: The results show both chewing Maras powder and smoking have an effect on deregulation of miR-200b and miR-92a expressions. This leads to the belief that assessing the expression of these two miRNAs is a promising noninvasive method of analysis, especially in mutagen exposures. Finally, large-scale and high-throughput studies may help to identify an extensive miRNA expression profile associated with tobacco use and improve the understanding of oral malignancies.Item Open Access Effects of Cholinergic Receptor Nicotinic Alpha 5 (CHRNA5) RNAi on apoptosis, DNA damage response, drug sensitivity, and HSA-MIR-495-3P overexpression in breast cancer(2018-12) Köker, Şahika CıngırCholinergic Receptor Nicotinic Alpha 5 (CHRNA5) is associated with nicotine addiction and it has an important role in the prognosis of lung cancer. Despite its important cellular functions, its role in breast cancer remains to be elucidated. In this thesis, I aimed to identify the alterations in the important cancer signaling pathways occurring upon CHRNA5 depletion. Drug resistance is one of the major obstacles in breast cancer therapy. Heterogeneous nature of breast cancer necessitates identification of more biomarkers which aid in precise diagnosis and hence development of proper treatment options. In this study, by using more than one cell line which is representative of different subtypes of breast cancer, I showed the alterations occurred in cancer signaling pathways such as cell cycle and apoptosis upon CHRNA5 depletion, which could serve as a novel biomarker in breast cancer subtyping. Depending on mutation status of TP53, which is the gatekeeper protein during G1/S checkpoint, CHRNA5 depletion mostly exerted its effects over decreasing the levels of total CHEK1 and pCHEK1 (S345) which significantly altered the response of MCF7 cells to topoisomerase inhibitors in terms of enhanced drug sensitivity. Increases in apoptotic markers, such as BAX/BCL2 ratio along with increased FAS levels, further confirmed that this sensitization of MCF7 cells upon CHRNA5 depletion might have ended with apoptosis. So far in the literature, there is no study examining the regulation of CHRNA5 by small endogenous molecules such as miRNAs. Due to the predictive binding sites in 3’UTR of CHRNA5 and the importance of participating in tamoxifen resistance in breast cancer; I also examined the interplay between miR-15a family and CHRNA5 in MCF7 cells. I showed significant decrease in CHRNA5 levels upon using miR-15a mimic while demonstrating similar activity of miR-15a family mimics with CHRNA5 depletion using RT-qPCR. Another important implication of CHRNA5 depletion in MCF7 cells was the global change in miRNA expression prolife which was verified with independent microRNA arrays. Based on these in silico results, hsa-miR-495-3p appeared as the most downregulated miRNA which is known as a tumor suppressor miRNA. As stated in the literature, the role of miR-495 differs depending on the tumor type. Therefore, I tried to restore its expression by mimicking along with CHRNA5 depletion. The transcriptomic changes observed with CHRNA5 depletion was boosted with the restoration of miR-495 levels.Item Open Access Identifying and targeting coding/non-coding molecular switches regulating drug resistance and metastasis in breast cancer(2017-09) Raza, UmarBreast cancer is the second most common cancer and the leading cause of cancer associated deaths in women worldwide. Despite the availability of large number and various types of therapy agents which are effective in limiting tumor burden at initial stages, cancer cells still manage to resist to therapy treatment and exhibit re-growth of existing tumor or metastasize to distant organs. Therefore, there is a dire need to identify underlying molecular mechanisms to enhance therapy response and to block metastasis. In addition to coding genome, non-coding RNAs have also play active role in controlling proliferation, apoptosis, invasion and drug resistance in cancer. Therefore, I aimed to identify novel coding/non-coding molecular switches regulating drug resistance and metastasis in breast cancer. In the first part of this dissertation, I identified miR-644a as a novel tumor suppressor inhibiting both cell survival and epithelial mesenchymal transition (EMT) whereby acting as pleiotropic therapy-sensitizer in breast cancer. Both miR-644a expression and its gene signature are associated with tumor progression and distant metastasis-free survival. Mechanistically, miR-644a directly targets the transcriptional co-repressor C-terminal binding protein 1 (CTBP1) whose knock-outs by the CRISPR-Cas9 system inhibit tumor growth, metastasis, and drug resistance, mimicking the phenotypes induced by miR-644a. Furthermore, miR-644a/CTBP1-mediated upregulation of wild type- or mutant-p53 acts as a ‘molecular switch’ between G1-arrest and apoptosis by inducing p21 or Noxa, respectively. Interestingly, an increase in mutant-p53 by either overexpression of miR- 644a or downregulation of CTBP1 was enough to shift the balance between cell cycle arrest and apoptosis in favor of apoptosis through the upregulation of Noxa. Notably, p53-mutant patients, but not p53-wild type ones, with high CTBP1 level have a shorter survival suggesting that CTBP1 could be a potential prognostic factor for breast cancer patients with p53 mutations. Overall, modulation of the miR-644a/CTBP1/p53 axis may represent a new strategy for overcoming both therapy resistance and metastasis. In the second part of this dissertation, I performed whole transcriptome sequencing with downstream pathway analysis in the chemoresistant triple negative breast cancer (TNBC) tumors we developed in vivo. This suggested a potential role of integrins and hypoxia in chemoresistance. Mechanistically, we showed that our candidate gene is hypoxia-induced and is overexpressed in resistant tumors, and activates integrin subunit alpha 5 (ITGA5). In the meantime, hypoxia-mediated downregulation of a miRNA targeting our candidate gene, leads to further activation of the ITGA5. This culminates in the activation of FAK/Src signaling thereby mediating resistance. Importantly, higher expression of our candidate gene, or lower expression of miRNA was associated with poorer relapse-free survival only in chemotherapy-treated TNBC patients. Finally, inhibition of candidate gene increased the efficacy of chemotherapy in highly aggressive TNBC models in vivo providing pre-clinical evidence for testing inhibitors against our candidate gene to overcome chemoresistance in TNBC patients.Item Open Access mESAdb: microRNA expression and sequence analysis database(Oxford University Press, 2011) Kaya, Koray D.; Karakülah, G.; Yakıcıer, Cengiz M.; Acar, Aybar C.; Konu, ÖzlenMicroRNA expression and sequence analysis database (http://konulab.fen. bilkent.edu.tr/mirna/) (mESAdb) is a regularly updated database for the multivariate analysis of sequences and expression of microRNAs from multiple taxa. mESAdb is modular and has a user interface implemented in PHP and JavaScript and coupled with statistical analysis and visualization packages written for the R language. The database primarily comprises mature microRNA sequences and their target data, along with selected human, mouse and zebrafish expression data sets. mESAdb analysis modules allow (i) mining of microRNA expression data sets for subsets of microRNAs selected manually or by motif; (ii) pair-wise multivariate analysis of expression data sets within and between taxa; and (iii) association of microRNA subsets with annotation databases, HUGE Navigator, KEGG and GO. The use of existing and customized R packages facilitates future addition of data sets and analysis tools. Furthermore, the ability to upload and analyze user-specified data sets makes mESAdb an interactive and expandable analysis tool for microRNA sequence and expression data.Item Open Access MicroRNA-519a is a novel oncomir conferring tamoxifen resistance by targeting a network of tumour-suppressor genes in ER+ breast cancer(John Wiley and Sons Ltd, 2014) Ward, A.; Shukla, K.; Balwierz, A.; Soons, Z.; König, R.; Sahin, O.; Wiemann, S.Tamoxifen is an endocrine therapy which is administered to up to 70% of all breast cancer patients with oestrogen receptor alpha (ERα) expression. Despite the initial response, most patients eventually acquire resistance to the drug. MicroRNAs (miRNAs) are a class of small non-coding RNAs which have the ability to post-transcriptionally regulate genes. Although the role of a few miRNAs has been described in tamoxifen resistance at the single gene/target level, little is known about how concerted actions of miRNAs targeting biological networks contribute to resistance. Here we identified the miRNA cluster, C19MC, which harbours around 50 mature miRNAs, to be up-regulated in resistant cells, with miRNA-519a being the most highly up-regulated. We could demonstrate that miRNA-519a regulates tamoxifen resistance using gain- and loss-of-function testing. By combining functional enrichment analysis and prediction algorithms, we identified three central tumour-suppressor genes (TSGs) in PI3K signalling and the cell cycle network as direct target genes of miR-519a. Combined expression of these target genes correlated with disease-specific survival in a cohort of tamoxifen-treated patients. We identified miRNA-519a as a novel oncomir in ER+ breast cancer cells as it increased cell viability and cell cycle progression as well as resistance to tamoxifen-induced apoptosis. Finally, we could show that elevated miRNA-519a levels were inversely correlated with the target genes' expression and that higher expression of this miRNA correlated with poorer survival in ER+ breast cancer patients. Hence we have identified miRNA-519a as a novel oncomir, co-regulating a network of TSGs in breast cancer and conferring resistance to tamoxifen. Using inhibitors of such miRNAs may serve as a novel therapeutic approach to combat resistance to therapy as well as proliferation and evasion of apoptosis in breast cancer.Item Open Access miR-200c: a versatile watchdog in cancer progression, EMT, and drug resistance(Springer Verlag, 2016-06) Mutlu, M.; Raza, U.; Saatci, Ö.; Eyüpoğlu, E.; Yurdusev, E.; Şahin, Ö.MicroRNAs (miRNAs) are 20–22-nucleotide small endogenous non-coding RNAs which regulate gene expression at post-transcriptional level. In the last two decades, identification of almost 2600 miRNAs in human and their potential to be modulated opened a new avenue to target almost all hallmarks of cancer. miRNAs have been classified as tumor suppressors or oncogenes depending on the phenotype they induce, the targets they modulate, and the tissue where they function. miR-200c, an illustrious tumor suppressor, is one of the highly studied miRNAs in terms of development, stemness, proliferation, epithelial-mesenchymal transition (EMT), therapy resistance, and metastasis. In this review, we first focus on the regulation of miR-200c expression and its role in regulating EMT in a ZEB1/E-cadherin axis-dependent and ZEB1/E-cadherin axis-independent manner. We then describe the role of miR-200c in therapy resistance in terms of multidrug resistance, chemoresistance, targeted therapy resistance, and radiotherapy resistance in various cancer types. We highlight the importance of miR-200c at the intersection of EMT and chemoresistance. Furthermore, we show how miR-200c coordinates several important signaling cascades such as TGF-β signaling, PI3K/Akt signaling, Notch signaling, VEGF signaling, and NF-κB signaling. Finally, we discuss miR-200c as a potential prognostic/diagnostic biomarker in several diseases, but mainly focusing on cancer and its potential application in future therapeutics.Item Open Access The miR-644a/CTBP1/p53 axis suppresses drug resistance by simultaneous inhibition of cell survival and epithelialmesenchymal transition in breast cancer(Impact Journals LLC, 2016) Raza, U.; Saatci, O.; Uhlmann, S.; Ansari, S. A.; Eyüpoglu, E.; Yurdusev, E.; Mutlu, M.; Ersan, P. G.; Altundağ, M. K.; Zhang, J. D.; Dogan, H. T.; Güler, G.; Şahin, Ö.Tumor cells develop drug resistance which leads to recurrence and distant metastasis. MicroRNAs are key regulators of tumor pathogenesis; however, little is known whether they can sensitize cells and block metastasis simultaneously. Here, we report miR-644a as a novel inhibitor of both cell survival and EMT whereby acting as pleiotropic therapy-sensitizer in breast cancer. We showed that both miR-644a expression and its gene signature are associated with tumor progression and distant metastasis-free survival. Mechanistically, miR-644a directly targets the transcriptional co-repressor C-Terminal Binding Protein 1 (CTBP1) whose knock-outs by the CRISPRCas9 system inhibit tumor growth, metastasis, and drug resistance, mimicking the phenotypes induced by miR-644a. Furthermore, downregulation of CTBP1 by miR-644a upregulates wild type- or mutant-p53 which acts as a 'molecular switch' between G1-arrest and apoptosis by inducing cyclin-dependent kinase inhibitor 1 (p21, CDKN1A, CIP1) or pro-apoptotic phorbol-12-myristate-13-acetate-induced protein 1 (Noxa, PMAIP1), respectively. Interestingly, an increase in mutant-p53 by either overexpression of miR-644a or downregulation of CTBP1 was enough to shift this balance in favor of apoptosis through upregulation of Noxa. Notably, p53- mutant patients, but not p53-wild type ones, with high CTBP1 have a shorter survival suggesting that CTBP1 could be a potential prognostic factor for breast cancer patients with p53 mutations. Overall, re-activation of the miR-644a/CTBP1/p53 axis may represent a new strategy for overcoming both therapy resistance and metastasis.Item Open Access Targeting mirna-protein regulatory networks to enhance chemotherapy response in BRCA1-mutated TNBCs(2016-09) Eyüpoğlu, ErolBreast cancer is the second most common cancer and the leading cause of cancer associated deaths in women worldwide. Triple-negative breast cancer (TNBC) is the most aggressive subtype of breast cancer. BRCA1-mutated TNBC patients generally respond well to DNA cross-linking agents like Cisplatin. However, most of the patients acquire resistance and eventually die. Therefore, there is a dire need of developing promising approaches to enhance chemo-response, hence, extending the survival of TNBC patients. MicroRNAs (miRNAs) play active role in controlling proliferation, apoptosis, invasion and drug resistance in cancer. However, the role of miRNA-protein interactions as a regulatory network in determining chemotherapy response of TNBCs has not been elucidated yet. Thus, we aimed to delineate miRNAs and miRNA-protein regulatory networks controlling chemotherapy resistance/response in BRCA1–mutated TNBCs. We firstly confirmed that BRCA1-mutated breast cancer cells are more sensitive to Cisplatin as compared to BRCA1-competent cells. Afterwards, developing acquired chemotherapy resistant cell line model and using next generation sequencing technology (both miR-Seq and RNA-Seq), we have unravelled that p53 signalling is the upstream regulator of Cisplatin resistance. Moreover, with the use of Ingenuity Pathway Anlaysis (IPA) which uses omics data from a variety of experimental platforms, we analyzed, combined and modelled miRNA-mRNA interactions regulating Cisplatin resistance for the first time in a network manner. Interestingly, we identifed several network motifs e.g. coherent and incoherent feedforward loops centered around p53 protein which need further experimental validations. Again for the first time, this study has reported the re-sensitization effect of miR-455 family on Cisplatin resistance in breast cancer. Overall, findings of this study might be used as an alternative strategy for treatment of BRCA1-mutated TNBCs by modulating miRNAs and their targets to re-sensitize Cisplatin resistant tumors.