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The SLC22A18 transporter, a potential biomarker for chemotherapeutic treatmentFrederickx, Nancy 02 October 2015 (has links)
SUMMARYThe diversity of cancer molecular origins associated with the genetic variability of patients has encouraged the development of chemotherapeutic treatments adapted not only to the target tumor, but also to a specific patient. This personalized strategy is based on cancer biomarkers allowing a better identification and characterization of each tumor where predictive biomarkers provide the distinction between various factors indicative of the response to the treatment. In this context, several studies highlighted the role of the solute carrier transporter family 22 (solute carriers 22 or SLC22) in the uptake of platinum anticancer drugs. This mechanism being not well understood, our work intends to establish the potential role of SLC22 member A18 (SLC22A18) as predictive biomarker in the aim to help to a better targeted chemotherapeutic strategy for each patient. We optimized a system overexpressing SLC22A18 stably or transiently in HeLa cancer cell line. SLC22A18 expression was confirmed by qRT-PCR, western blotting, microscopy and flow cytometry. The cell lines were treated with taxane, anthracyclin, vinca alkaloid and nitrosoureas anticancer drug families. We showed that doxorubicin, camptothecin, chloroquine, tetracycline and carmustin had no effect on the cell viability assays suggesting that they are not substrates of SLC22A18. Interestingly, the cell line was sensitized in the presence of antimitotic drug with a sensitivity factor of 2.7 in the presence of paclitaxel, 1.4 with docetaxel, 1.8 with vinblastin and 2.2 in the presence of vincristine. To confirm these results, we elaborated a SLC22A18 knockdown cell line in HS683 cells using siRNA technology. The downexpression of SLC22A18 was correlated to a tendency to resist to the accumulation of paclitaxel thereby confirming the previous results. Simultaneously, a knockout cell line was established using the transcription activator-like effectors nuclease (TALEN) technology in U373 cell line. Our studies constitute a robust base of knowledge for further investigation on SLC22A18 transporter as a predictive biomarker promoting antimitotic treatment in tumors where this transporter is detected. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished
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Atypical Solute Carriers : Identification, evolutionary conservation, structure and histology of novel membrane-bound transportersPerland, Emelie January 2017 (has links)
Solute carriers (SLCs) constitute the largest family of membrane-bound transporter proteins in humans, and they convey transport of nutrients, ions, drugs and waste over cellular membranes via facilitative diffusion, co-transport or exchange. Several SLCs are associated with diseases and their location in membranes and specific substrate transport makes them excellent as drug targets. However, as 30 % of the 430 identified SLCs are still orphans, there are yet numerous opportunities to explain diseases and discover potential drug targets. Among the novel proteins are 29 atypical SLCs of major facilitator superfamily (MFS) type. These share evolutionary history with the remaining SLCs, but are orphans regarding expression, structure and/or function. They are not classified into any of the existing 52 SLC families. The overall aim in this thesis was to study the atypical SLCs with a focus on their phylogenetic clustering, evolutionary conservation, structure, protein expression in mouse brains and if and how their gene expressions were affected upon changed food intake. In Papers I-III, the focus was on specific proteins, MFSD5 and MFSD11 (Paper I), MFSD1 and MFSD3 (Paper II), and MFSD4A and MFSD9 (Paper III). They all shared neuronal expression, and their transcription levels were altered in several brain areas after subjecting mice to food deprivation or a high-fat diet. In Paper IV, the 29 atypical SLCs of MFS type were examined. They were divided into 15 families, based on phylogenetic analyses and sequence identities, to facilitate functional studies. Their sequence relationships with other SLCs were also established. Some of the proteins were found to be well conserved with orthologues down to nematodes and insects, whereas others emerged at first in vertebrates. The atypical SLCs of MFS type were predicted to have the common MFS structure, composed of 12 transmembrane segments. With single-cell RNA sequencing and in situ proximity ligation assay, co-expression of atypical SLCs was analysed to get a comprehensive understanding of how membrane-bound transporters interact. In conclusion, the atypical SLCs of MFS type are suggested to be novel SLC transporters, involved in maintaining nutrient homeostasis through substrate transport.
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Molecular basis of secondary multidrug transportMasureel, Matthieu 14 June 2013 (has links)
The Major Facilitator Superfamily groups a vast number of secondary transporters that import or export distinct substrates. Among these, multidrug antiporters constitute a peculiar class of transporters, both because of their multispecificity, recognizing structurally very diverse substrates, and because of their transport mechanism, that relies on bilayer-mediated extrusion of cytotoxic compounds. An accurate and detailed description of the conformational changes that underlie the transport cycle is still lacking and the structural basis for energetic coupling in these transporters has not been elucidated, with so far only limited crystallographic evidence available. We investigate the molecular basis of secondary multidrug transport with biochemical and biophysical studies on LmrP, a Major Facilitator Superfamily multidrug transporter from Lactococcus lactis. We used extensive continuous-wave electron paramagnetic resonance and double electron-electron resonance measurements on a library of spin-labeled LmrP mutants to uncover the conformational states involved in transport and to investigate how protons and ligands shift the equilibrium between conformers to enable transport. We find that the transporter switches between outward-open and outward-closed conformations depending on the protonation states of specific acidic residues forming a transmembrane protonation relay. We observe that substrate binding restricts the conformational freedom of LmrP and induces localized conformational changes. Our data allows to build a model of secondary multidrug transport wherein substrate binding initiates the transport cycle by opening the extracellular side to protons. Subsequent protonation of membrane-embedded acidic residues induces substrate release to the extracellular side and triggers a cascade of conformational changes that culminates in a proton release to the intracellular side. Parallel to this, we have optimized our purification and expression protocol in order to set up crystallization trials on LmrP. Through extensive screening and optimization of the lipidation state of LmrP, using ad hoc methods for sample preparation, we were able to obtain low-resolution diffracting crystals. By improving our lipidation technique and modifying the lipid composition we further improved crystal quality. Other factors such as ligand addition, the presence of secondary detergent and additives for controlling phase separation and nucleation were tested, paving the way to high resolution structure determination of LmrP. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished
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