X V I I V Í S I N D A R Á Ð S T E F N A H Í F Y L G I R I T 8 2 LÆKNAblaðið/Fylgirit 82 2015/101 55 E 152 miR200c-141 and ∆Np63 are required for breast epithelial differentiation and branching morphogenesis Bylgja Hilmarsdóttir1,2, Valgarður Sigurðsson1, Sigríður Rut Franzdóttir1, Markus Ringnér4, Ari Jón Arason1,2, Jón Þór Bergþórsson1,2, Magnús K. Magnússon1,2,3, Þórarinn Guðjónsson1,2 1Biomedical Center, Faculty of Medicine, University of Iceland, 2Department of Laboratory Hematology, Landspítali University Hospital, 3Department of Medical Pharmacology and Toxicology, Faculty of Medicine, University of Iceland, 4Division of Oncology and Pathology, Department of Clinical Sciences Lund, Lund University byh1@hi.is Introduction: The epithelial compartment of the breast contains two lineages, the luminal- and the myoepithelial cells. D492 is a breast epithelial cell line with stem cell properties that forms branching epithelial structures in 3D culture with both luminal- and myoepihelial differentiation. We have recently shown that D492 undergo epithelial to mesenchymal transition (EMT) when co-cultured with endothelial cells. This 3D co-culture model allows critical analysis of breast epithelial lineage development and EMT. Methods and data: In this study, we compared the microRNA (miR) expression profiles for D492 and its mesenchymal-derivative D492M. Results: Suppression of the miR-200 family in D492M was among the most profound changes observed. Exogenous expression of miR-200c-141 in D492M reversed the EMT phenotype resulting in gain of luminal- but not myoepithelial differentiation. In contrast, forced expression of ∆Np63 in D492M restored the myoepithelial phenotype only. Co-expression of miR-200c-141 and ∆Np63 in D492M restored the branching morphogenesis in 3D culture underlining the requirement for both luminal and myoepithelial elements for obtaining full branching morphogenesis in breast epithelium. Introduction of a miR-200c-141 construct in both D492 and D492M resulted in resistance to endothelial induced EMT. Conclusions: In conclusion, our data suggests that expression of miR-200c-141 and ∆Np63 in D492M can reverse EMT resulting in luminal- and myoepithelial differentiation, respectively, demonstrating the importance of these molecules in epithelial integrity in the human breast. E 153 Sub-cellular localization of the MITF transcription factor in melanoma cells Sigurður Rúnar Guðmundsson, Indriði Einar Reynisson, Alexander Schepsky, Margrét Helga Ögmundsdóttir, Eiríkur Steingrímsson Department of Biochemistry and Molecular Biology, Biomedical Center, Faculty of Medicine, University of Iceland srg2@hi.is Introduction: MITF (Microphthalmia-associated transcription factor) re- gulates development and differentiation of melanocytes and is a key component in formation of melanoma. Little is known about how sub- cellular localization of MITF is regulated in melanocytes and melanoma cells. In this project we characterize which domains of the MITF protein are involved in nuclear localization and which signaling pathways are involved. Methods and data: We generated MITF-EGFP fusion constructs carry- ing wild type and mutant versions of MITF and transfected into human 501mel (melanoma) and HEK293T (embryonic kidney) cells to map which domains of MITF are involved in nuclear localization. The sub- cellular location of MITF was determined using a confocal microscope. Results: We have observed that a monopartite nuclear localization signal is located between a.a. 214 and 217 and is required for the nuclear localization of MITF. Neither DNA binding nor dimerization are necess- ary for nuclear retention of MITF. We also found that a cytoplasmic mutant form of MITF colocalizes with LC3, an autophagosome marker. This might unravel an important degradation pathway affecting MITF stability. Conclusions: We have found that four basic residues of the DNA bind- ing domain are important for nuclear localization. In addition, we have shown that the carboxyl-end of MITF affects subcellular localization in unexpected ways, possibly leading to insights into protein turnover. E 154 The MITF transcription factor network in Melanoma and Melanocytes Dilixiati Remina, Erna Magnúsdóttir, Eiríkur Steingrímsson Department of Biochemistry and Molecular Biology, Biomedical Center, Faculty of Medicine, University of Iceland dir2@hi.is Introduction: The master regulator protein MITF (microphthalmia associated transcription factor) is essential for melanocyte and mel- anoma development. In melanoma MITF acts as a molecular switch that determines whether melanoma cells differentiate, proliferate or become quiescent migratory cells able to form metastasis. Recently, our labora- tory has shown that MITF interacts with different transcription factors to mediate its effects in melanocytes and melanoma. The aim of this project is to characterize this network with focus on IRF4 and TFEB in order to determine how these transcription factors mediate both normal and malignant development in the melanocyte lineage. Methods and data: We performed chromatin Immunoprecipitation (ChIP) experiments with 501mel human melanoma cells with an antibody against MITF followed by quantitative PCR (qPCR) to quanti- tatively evaluate binding site enrichment. qPCR enrichments of 5 fold or greater compared to negative control regions are considered bound by MITF. Results: We performed ChIP-qPCR on (ChIP) with antibodies that target MITF, IRF4, in the human melanoma cell line 501mel. The qPCR on the MITF ChIP reaction showed 10 to 100-fold enrichment for 8 MITF targets compared to negative two control regions whereas other 6 potential targets didn’t show good enrichment. Conclusions: Chromatin Immunoprecipitation coupled with qPCR allo- wed us to quantify and identify novel MITF binding sites in melanoma. However some potential targets didn’t show enrichment maybe due to the effect that MITF binding is depend on MITF protein level. E 155 The transcription factor MITF regulates autophagy in melanoma cells Margrét H. Ögmundsdóttir, Katrín Möller, Sólveig H. Brynjólfsdóttir, Margrét Bessadóttir, Kimberley Anderson, Eiríkur Steingrímsson Biochemistry and Molecular Biology, Biomedical Center, Faculty of Medicine, University of Iceland kam10@hi.is Introduction: Autophagy is a process that removes reactive oxygen species and other substrates that can harm the cell and it‘s DNA. The transcription factors TFEB and TFE3 control autophagy in normal cells by regulating genes required for this process. Under normal conditions these transcription factors are kept in the cytoplasm by the nutrient sen- sor mTORC1 but when cells are starved they translocate to the nucleus

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