Molecular screening of cancer-derived exosomes by surface plasmon resonance spectroscopy

We report on a generic method to detect and iden- tify the molecular profile of exosomes either derived from cultured cell lines or isolated from biofluids. Exosomes are nanovesicles shed by cells into their microenvironment and carry the molecular identity of their mother cells. These vesi- cles are actively involved in intercellular communication un- der physiological conditions and ultimately in the spread of various diseases such as cancer. As they are accessible in most biofluids (e.g., blood, urine, or saliva), these biological entities are promising tools for cancer diagnostics, offering a non- invasive and remote access to the molecular state of the dis- ease. The composition of exosomes derived from cancer cells depends on the sort and state of the tumor, requiring a screen- ing of multiple antigens to fully characterize the disease. Here, we exploited the capacity of surface plasmon resonance bio- sensing to detect simultaneously multiple exosomal and can- cer biomarkers on exosomes derived from breast cancer cells. We developed an immunosensor surface which provides efficient and specific capture of exosomes, together with their identification through their distinct molecular profiles. The successful analysis of blood samples demonstrated the suit- ability of our bioanalytical procedure for clinical use

Assessing the role of Hes1 and identification of target genes in human and murine T-ALL

Silvia Wirth

The Notch signalling pathway is an ancient cell signalling mechanism that enables short-range communications between cells and controls a broad spectrum of cell fates and developmental processes. In the haematopoietic system Notch signalling has been linked to physiological, but also to pathological phenotypes of T cell development. Identification of numerous activating mutations within the NOTCH1 receptor in human T cell acute lymphoblastic leukaemia (T-ALL) patient samples demonstrated that aberrant activation of this signalling pathway is a frequent event in T-ALL. Active Notch signalling leads to the expression of a plethora of genes that might be drivers or passengers in tumorigenesis including Hes1, which encodes a transcriptional repressor. We have therefore studied Hes1 in the context of T-ALL in mouse models that mimic human disease and in human T-ALL cell lines with the aim to evaluate whether Hes1 affects disease development and disease maintenance and to characterize its function on a molecular level. The first part of this study is dedicated to the functional characterisation of Hes1 in vivo in T-ALL mouse models and in vitro in human T-ALL cell lines. Using a retroviral bone marrow transplant model of T-ALL in which progenitor cells are transduced with a retrovirus expressing constitutive active Notch1 intracellular domain (NICD) we could show that Hes1 is not required in established, late stage T-ALL cells, but that it promotes tumour progression in the early stages of the disease. We have also investigated the function of HES1 in human T-ALL and can show that the overexpression of dominant negative versions of Hes1 in two patient derived cell lines (T-ALL1, CUTLL-1) does not affect proliferation or apoptosis, emphasising that HES1 does not affect cell viability once cells are fully transformed to the leukemic state. In the second part of the study we set out to systematically delineate the gene regulatory networks down-stream of Hes1 by combining RNA-seq and ChIP-seq analysis. Comparing the gene expression of murine premalignant, early stage NICD induced CD4+CD8+ DP cells in the presence and absence of Hes1 by RNA-seq, we unexpectedly found a predominant upregulation of genes in cells expressing Hes1 indicating that Hes1 might rather act as a positive regulator of transcription than as a transcriptional repressor of distinct target genes. Hes1 might influence transcription through secondary or indirect effects as combinatorial analysis of RNA-seq and ChIP-seq led to the identification of only a small number of potential direct target genes that are transcriptionally regulated by Hes1. In summary, the role of Hes1 in promoting the early stages of the disease appears to be highly complex and is likely to involve both direct and indirect control of gene regulatory networks.

EPFL2014

Transient gene expression for rapid protein production

Natalie Muller

Recombinant proteins are important for biomedical research and for the treatment of human disease. Therefore it is necessary to develop reproducible bioprocesses to rapidly produce proteins of adequate quality and quantity. Expression in mammalian cells is preferred if the proteins are to be properly folded and post-translationally modified. For the rapid production of milligram to gram quantities of a protein in mammalian cells, large-scale transient gene expression is an attractive option. The two most important components of this technology are the cell cultivation system and the gene delivery method. For this reason the goal of this thesis was to develop novel cost-efficient cell cultivation systems and gene delivery methods for the large-scale transfection of mammalian cells in chemically defined media free of any animal-derived components including serum. Cultivation of mammalian cells in suspension is essential for large-scale transient gene expression. A superior system for the cultivation of mammalian cells based on the agitation of cells in "square-shaped" glass bottles (square bottles) was developed. It is an inexpensive but efficient means to grow cells to a high density without instrumentation. The growth and viability of cultures of both human embryo kidney (HEK) 293E and Chinese hamster ovary (CHO) DG44 cells in agitated one-liter square bottles exceeded that in spinner flasks, reaching cell densities 1.5 times higher on average. Furthermore, an efficient and reproducible method to transfect cells in agitated square bottles was developed for both HEK 293E and CHO DG44 cells. A novel gene delivery method termed calfection that relies on the addition of DNA and CaCl2 directly to a suspension culture was developed. Calfection has a number of advantages over existing gene delivery methods such as calcium phosphate-DNA coprecipitation in that there are no time-dependent steps. The DNA/CaCl2 solution can be stored for long periods and is filterable. It is suitable for both large-scale transfections in bioreactors and for high-throughput transfections in microtiter plates. One drawback, however, is its dependence on the presence of serum in the culture medium. A second gene delivery method, serum-free transfection with polyethylenimine (polyfection), proved to be highly efficient for the transfection of both HEK 293E and CHO DG44 cells. A reproducible method for polyfection in microtiter plates, 50 ml centrifuge tubes, agitated square and round bottles, spinner flasks, and bioreactors was optimized for these two cell lines. Polyfection proved to be a simple and successful gene transfer method in both instrumented and non-instrumented cultivation systems. Importantly, it could be performed in serum-free chemically defined media. With HEK 293E cells, 80 mg/l of antibody was produced in agitated square bottles and with CHO DG44 cells, more than 2 g of antibody were produced in one week in a 150-liter bioreactor.

EPFL2005

Development and Characterization of a Microfluidic Chip to Capture Circulating Prostate Cancer Cells

Colette Bichsel

The analysis of circulating tumor cells (CTCs) from the blood of cancer patients promises a better understanding of metastasis formation and tumor phenotypes. CTCs are rare (there is 1 CTC in 1 billion of circulating blood cells) and therefore challenging to isolate. Recently developed highly sensitive microfluidic platforms made a leap forward in trapping these cells efficiently. This work focused on the development of a microfluidic platform that specifically captures prostate cancer cells from a whole blood sample. The versatility of the system was exploited by tethering different capturing antibodies on the microchip surface. Circulating prostate tumor cells were successfully recognized with the microfluidic chip. Furthermore, the platform was enhanced to carry out proliferation assays of captured cells directly on the chip, using hydrogel as a three-dimensional cell culture matrix. Although further improvements regarding the on-chip proliferation assay need to be done, the potential benefit of a functional readout promises new insights in cancer progression that can be translated to advanced cancer staging or prognostic tools.