Chemotactic factors underlying tumor infiltration by immunocompetent cells in human colorectal cancer Inauguraldissertation Zur Erlangung der Würde eines Doktors der Philosophie vorgelegt der Philosophisch-Naturwissenschaftlichen Fakultät Der Universität Basel von Cremonesi Eleonora aus Italien, Lodi Basel, 2017 Original document stored on the publication server of the University of Basel edoc.unibas.ch This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License. Genehmigt von der Philosophisch-Naturwissenschaftlichen Fakultät auf Antrag von Prof. Dr. Christoph Hess Prof. Dr. med. Giandomenica Iezzi Prof. Dr. med. Alfred Zippelius Basel, 22.03.2016 Prof. Dr. J Schibler Dekan During my PhD training I have extensively investigated the role of chemotactic factors involved in the recruitment of beneficial immune cells in human colorectal cancer (CRC). This thesis consists of an introduction highlighting the clinical relevance of immune cell infiltration in CRC, and providing an overview of CRC microenvironment determinants and their possible influence on immune cell migration. A complete description of methods used and results obtained is then included. Finally, major findings and their implications are reviewed in the discussion. The results of this study have been included in a manuscript currently under preparation. Beside my main research project, I have also been involved in additional projects of our group addressing the prognostic significance of a number of immune cells markers in human CRC, including interleukin-17A (IL-17), granulocyte macrophage colony-stimulating factor (GM- CFS), tumor necrosis factor receptor superfamily, member 4 (TNFRSF4, also known as OX40) and programmed death-ligand 1(PD-L1), and the development of innovative tridimensional systems for culturing human CRC cells in vitro. Publications resulting from these studies are included in the appendix. To my family… Summary Colorectal cancer (CRC) is a common digestive tract malignancy and a major cause of cancer mortality. Several studies have convincingly shown that CRC infiltration by immunocompetent cells and, in particular, cytotoxic CD8+ T cells (CTLs), IFN-γ-producing T-helper 1 cells (Th1), Foxp3+ regulatory T cells (Tregs), and CD16+ MPO+ neutrophils, is significantly associated with prolonged patient survival. However, the chemotactic factors driving these cell populations into the tumor site, their cellular sources and their microenvironmental triggers remain to be elucidated. During my PhD training I have investigated the chemokine/chemokine receptor network promoting CRC infiltration by immune cells associated to favorable prognosis. In particular, I addressed: 1. The expression of immune cell markers and their correlation with chemokine expression in primary CRC tissues; 2. The identification of chemokine receptors relevant for CRC infiltration by beneficial immune cells; 3. The chemokine sources in CRC; 4. The microenvironmental stimuli triggering chemokine production in CRC tissues; 5. The effects of chemokine production on immune cell recruitment into CRC. The expression of a panel of genes encoding 39 chemokines and 7 markers specific for defined immune cell populations was assessed by quantitative PCR array in 62 samples of freshly excised primary CRC and autologous healthy colonic tissue. Correlations between expression of chemokine genes and immune cell markers were then evaluated. Furthermore, chemokine receptor profiles were analysed by flow cytometry on cell suspensions obtained upon digestion of clinical specimens or on corresponding cell populations from autologous peripheral blood. Based on chemokine receptor expression on 1 tumor infiltrating cells and correlations between expression of chemokines and immune cell markers, I could identify for each immune cell subset a putative “chemokine signature”: 1) CCL3, CCL5, CCL8 CXCL9, CXCL10 and CXCL12, associated with recruitment of cytotoxic CTLs; 2) CCL5, CCL22, CXCL9, and CXCL12 correlating with infiltration by Th1; 3) CCL22 and CXCL12 potentially attracting Tregs; 4) CXCL2 and CXCL5 promoting chemotaxis of CD16+ MPO+ neutrophils. I have further investigated potential chemokine sources and stimuli leading to chemokine release within CRC tissues. I found that CRC cells purified from primary tumor specimens express many of the genes encoding identified immune cell recruiting chemokines, including CCL3, CCL5, CXCL2, CXCL5, CXCL9 and CXCL10. In vitro experiments showed that chemokine production by CRC cells is triggered upon their exposure to microbial stimuli, such as Toll-like receptor agonists, or CRC-associated bacteria, including Fusobacterium nucleatum, Bacteroides Fragilis, Bacteroides vulgatus, and Escherichia Coli, thus suggesting that components of the gut flora may critically influence chemokine production in CRC tissues. This was indeed confirmed by “in vivo” experiments showing that chemokine gene expression in xenografts, generated upon injection of human CRC cells in immunodeficient NSG mice, appeared to be related to the presence of commensal bacteria. In particular, chemokine gene expression levels in intracecal xenografts, were found to be ≥10 fold higher as compared to those of subcutaneous xenografts, and they were significantly reduced upon antibiotic treatment of tumor bearing mice. Most importantly, a correlation between extent of immune cell infiltration and bacterial load was also observed in human CRC samples. Indeed, CRC samples characterized by high expression of chemokine and immune cell markers, displayed significantly higher bacterial loads, as assessed by analysis of bacterial 16S ribosomal RNA, as compared to samples 2 showing low chemokine expression and immune cell infiltration. In addition, a significant correlation between bacterial load and expression of the Th1 marker IRF1, CCL3 and CCL5, was also detected. Our in vitro and in vivo results cumulatively suggest that bacteria-induced chemokine production by tumor cells may lead to tumor infiltration by beneficial immune cells. Consistent with this hypothesis, in preliminary “in vitro” experiments, I found that supernatants of bacteria-stimulated CRC cells promote chemotaxis of CTLs and Th1 cells to a higher extent than untreated tumor cells. Additional “in vivo” studies are clearly warranted. In particular, I plan to evaluate intratumoral recruitment of CRC-derived CTLs and Th1 cells upon adoptively transfer into intracecal xenografts-bearing mice. Bacterial species or strains mostly contributing to high chemokine expression and immune cell infiltration in human CRC samples also remain to be identified. Microbiome analysis of CRC samples characterized by high or low immune cell infiltration might be envisaged in future studies. The results of the present work together with the proposed additional studies will contribute to the understanding of the interplay occurring between gut flora and immune system in CRC, and may pave the way towards innovative treatments aimed at modifying the gut flora in order to promote CRC infiltration by beneficial immune cell subsets. 3 Table of content Summary ........................................................................................................................................ 1 I. INTRODUCTION ......................................................................................................................... 6 1.Human colorectal cancer .................................................................................................................. 7 1.1 Epidemiology and etiopathogenesis .......................................................................................... 7 1.2 Staging and prognosis................................................................................................................ 9 1.3 Current treatment guidelines ................................................................................................... 10 2.CRC immune contexture ................................................................................................................ 11 2.1 Definition of immune contexture ............................................................................................ 11 2.2 Impact of immune contexture in CRC ..................................................................................... 12 3. Immune cell trafficking in CRC .................................................................................................... 13 3.1 Chemokines and chemokine receptors .................................................................................... 13 3.2 Role of chemokines in leukocyte trafficking ........................................................................... 17 3.3 Gut homing receptors .............................................................................................................. 17 3.4 Prognostic significance of chemokine expression in colorectal cancer ................................... 18 4. Pathophysiology of CRC microenvironment ................................................................................ 18 4.1 Physiology of normal colonic mucosa .................................................................................... 18 4.2 The gut microbiota .................................................................................................................. 20 4.3 Interactions between gut flora and normal colonic epithelium ............................................... 21 4.4 Physiopathology of gut epithelium in CRC ............................................................................. 25 II. AIM OF THE STUDY ................................................................................................................ 28 III. MATERIALS AND METHODS ................................................................................................ 30 1. Clinical specimen collection and processing ............................................................................. 31 4 2. Cell lines .................................................................................................................................... 31 3. Bacteria ...................................................................................................................................... 31 4. Flow cytometry .......................................................................................................................... 32 5. Real-time reverse transcription PCR assays .............................................................................. 33 6. CRC cell stimulation with TLR agonists and bacteria .............................................................. 34 7. Migration assay ......................................................................................................................... 35 8. Generation of CRC xenografts .................................................................................................. 35 9. Statistical analysis ..................................................................................................................... 36 IV. RESULTS ..................................................................................................................................... 37 1. Expression of immune cell markers in primary CRC ................................................................ 38 2. Chemokine gene expression in primary CRC ........................................................................... 41 3. Correlations between expression of immune cell markers and chemokine genes in CRC ........ 41 4. Chemokine receptor expression on CRC infiltrating beneficial immune cells ......................... 42 5. Chemokine signatures underling immune cell recruitment in CRC .......................................... 47 6. Chemokine sources in primary CRC ......................................................................................... 47 7. Effects of microbial stimulation on chemokine production by CRC cells in vitro.................... 49 8. Effects of microbial stimulation on chemokine production in vivo .......................................... 52 9. Effects of chemokine production on immune cell recruitment into CRC tissues ...................... 54 V. DISCUSSION AND OUTLOOK ............................................................................................... 56 1. Discussion ..................................................................................................................................... 57 2. Outlook .......................................................................................................................................... 62 VI. BIBLIOGRAPHY ....................................................................................................................... 64 VII. APPENDIX .................................................................................................................................. 74 5 I. INTRODUCTION 6
Description: