Cocultures of human colorectal tumor spheroids with immune cells reveal the therapeutic potential of MICA/B and NKG2A targeting for cancer treatment
BackgroundImmunotherapies still fail to benefit colorectal cancer (CRC) patients. Relevant functional assays aimed at studying these failures and the efficacy of cancer immunotherapy in human are scarce. 3D tumor cultures, called tumor organoids or spheroids, represent interesting models to study cancer treatments and could help to challenge these issues.MethodsWe analyzed heterotypic cocultures of human colon tumor-derived spheroids with immune cells to assess the infiltration, activation and function of T and NK cells toward human colorectal tumors in vitro.ResultsWe showed that allogeneic T and NK cells rapidly infiltrated cell line-derived spheroids, inducing immune-mediated tumor cell apoptosis and spheroid destruction. NKG2D, a key activator of cytotoxic responses, was engaged on infiltrating cells. We thus assessed the therapeutic potential of an antibody targeting the specific ligands of NKG2D, MICA and MICB, in this system. Anti-MICA/B enhanced immune-dependent destruction of tumor spheroid by driving an increased NK cells infiltration and activation. Interestingly, tumor cells reacted to immune infiltration by upregulating HLA-E, ligand of the inhibitory receptor NKG2A expressed by CD8 and NK cells. NKG2A was increased after anti-MICA/B treatment and, accordingly, combination of anti-MICA/B and anti-NKG2A was synergistic. These observations were ultimately confirmed in a clinical relevant model of coculture between CRC patients-derived spheroids and autologous tumor-infiltrating lymphocytes.ConclusionsAltogether, we show that tumor spheroids represent a relevant tool to study tumor-lymphocyte interactions on human tissues and revealed the antitumor potential of immunomodulatory antibodies targeting MICA/B and NKG2A.Electronic supplementary materialThe online version of this article (10.1186/s40425-019-0553-9) contains supplementary material, which is available to authorized users.
Intestinal tissue-resident memory CD8 T cells (Trm) are non-recirculating effector cells ideally positioned to detect and react to microbial infections in the gut mucosa. There is an emerging understanding of Trm cell differentiation and functions, but their implication in inflammatory bowel diseases, such as Crohn's disease (CD), is still unknown. Here, we describe CD8 cells in the human intestine expressing KLRG1 or CD103, two receptors of E-cadherin. While CD103 CD8 T cells are present in high numbers in the mucosa of CD patients and controls, KLRG1 CD8 T cells are increased in inflammatory conditions. Mucosal CD103 CD8 T cells are more responsive to TCR restimulation, but KLRG1 CD8 T cells show increased cytotoxic and proliferative potential. CD103 CD8 T cells originate mostly from KLRG1 negative cells after TCR triggering and TGFβ stimulation. Interestingly, mucosal CD103 CD8 T cells from CD patients display major changes in their transcriptomic landscape compared to controls. They express Th17 related genes including CCL20, IL22, and IL26, which could contribute to the pathogenesis of CD. Overall, these findings suggest that CD103 CD8 T cells in CD induce a tissue-wide alert increasing innate immune responses and recruitment of effector cells such as KLRG1 CD8 T cells.
Autologous organoid co-culture model reveals T cell-driven epithelial cell death in Crohn’s Disease
Lympho-epithelial interactions between intestinal T resident memory cells (Trm) and the epithelium have been associated with inflammatory bowel disease (IBD) activity. We developed ex vivo autologous organoid-mucosal T cell cocultures to functionally assess lymphoepithelial interactions in Crohn’s Disease (CD) patients compared to controls. We demonstrate the direct epithelial cell death induced by autologous mucosal T cells in CD patients but not in controls. These findings were positively correlated with T cell infiltration of the organoids. This potential was inhibited by limiting lympho-epithelial interactions through CD103 and NKG2D blocking antibodies. These data directly demonstrate for the first time the direct deleterious effect of mucosal T cells on the epithelium of CD patients. Such ex-vivo models are promising techniques to unravel the pathophysiology of these diseases and the potential mode of action of current and future therapies.
ObjectiveT cells are major effectors of the antitumoural immune response. Their activation by tumour-associated antigens can unleash their proliferation and cytotoxic functions, leading to tumour cell elimination. However, tumour-related immunosuppressive mechanisms including the overexpression of immune checkpoints like programmed cell death protein-1 (PD-1), are also engaged, promoting immune escape. Current immunotherapies targeting these pathways have demonstrated weak efficacy in colorectal cancer (CRC). It is thus crucial to find new targets for immunotherapy in this cancer type.DesignIn a prospective cohort of patients with CRC, we investigated the phenotype of tumour-related and non-tumour related intestinal T cells (n=44), particularly the adenosinergic pathway, correlating with clinical phenotype. An autologous coculture model was developed between patient-derived primary tumour spheroids and their autologous tumour-associated lymphocytes. We used this relevant model to assess the effects of CD39 blockade on the antitumour T cell response.ResultsWe show the increased expression of CD39, and its co-expression with PD-1, on tumour infiltrating T cells compared with mucosal lymphocytes. CD39 expression was higher in the right colon and early-stage tumours, thus defining a subset of patients potentially responsive to CD39 blockade. Finally, we demonstrate in autologous conditions that CD39 blockade triggers T cell infiltration and tumour spheroid destruction in cocultures.ConclusionIn CRC, CD39 is strongly expressed on tumour infiltrating lymphocytes and its inhibition represents a promising therapeutic strategy for treating patients.
Background T resident memory (Trm) cells in the intestinal mucosa and in particular subpopulations expressing phenotypic markers such as alphaE-beta7 or NKG2D have been associated with chronic inflammatory bowel disease (IBD) activity. We hypothesize that these populations may have a direct deleterious impact on the intestinal epithelium in IBD. Methods The phenotypic study of mucosal lymphocytes was performed in two prospective cohorts: ELYP including patients with active IBD before initiation of biotherapy and REMIND including patients with ileal Crohn’s disease (CD) requiring ileocaecal resection. These analyses were performed before initiation of treatment and one year after continuous therapy in the ELYP cohort and on the resection specimen in the REMIND cohort. An innovative ex vivo autologous organoid-mucosal T cell coculture model was developed using the REMIND cohort specimens for patients and healthy ileum from individuals without IBD for controls (Figure 1). T cell infiltration within the organoid and epithelial cell death were assessed by confocal microscopy. A panel of 30 cytokines was quantified in the supernatants of cocultures. Figure 1 Results In the ELYP cohort, before the start of treatment, IBD patients had lower expression of alphaE-beta7 and NKG2D on mucosal CD8 T cells. While alphaE-beta7 and NKG2D expression on mucosal CD8 T cells had returned to normal in endoscopic responders, it remained decreased in non-responders. Similarly, the inflammatory mucosa of the REMIND surgical specimens had lower levels of CD4 and CD8 T cells expressing alphaE-beta7 and NKG2D compared with controls and non-inflamed regions. We developed a coculture model between mucosal lymphocytes and organoids generated under autologous conditions. We showed an increase in apoptotic cell death in epithelial cells from CD patients which was not found in control cocultures. There was a significant correlation between the degree of epithelial cell death and T cell infiltration (Figure 2). Various proinflammatory cytokines such as IFNgamma, TNFalpha, IL-6 and IL- 17a were also increased in the supernatants. The use of antibodies blocking the alphaE-beta7 and NKG2D pathways of interest inhibited this effect by different mechanisms (Figure 3) While anti-beta7 and anti-NKG2D had comparable effects in terms of cell death inhibition, only anti-beta7 reduced T cell infiltration. Anti-NKG2D had no effect on cell infiltration but a reduction of perforin was observed in the supernatants. Figure 2 Figure 3 CC= Coculture Conclusion These data demonstrate for the first time the direct cytotoxic deleterious effect of mucosal T cells on the epithelium of CD patients using a novel coculture model. AlphaE-beta7 and NKG2D pathways appear to be relevant in this process.
Oil and Gas operators are more and more interested in developing and improving native CO2 recovery technologies as capturing native CO2 can drastically reduce the greenhouse gases emission and at the same time can be valorized for enhanced oil recovery. While considering CO2 emission from a gas plant, native CO2 significantly contributes to the total amount. Usually when natural gas contains both CO2 and H2S, they are removed together and sent to an air fueled Sulfur Recovery Unit (SRU) resulting in a tail gas containing mainly nitrogen and CO2. The native CO2 can then be separated by the use of a chemical solvent such as Monoethanolamine (MEA) for example. TOTAL and Air Liquide Engineering & Construction have developed and patented an innovative process scheme for recovering the native CO2 and reducing the overall operating and investment costs of such process. This patented innovative process scheme consists in a Claus unit, fed with pure oxygen or enriched air instead of air, which leads to a tail gas stream containing mainly CO2 and H2 but no or only little nitrogen. A CO2 purification unit allows a CO2 rich stream to be recovered with a purity level reaching even 99.9%, while producing valuable by-products such as pure nitrogen and a hydrogen-rich stream, both of which can be used as utilities in other process units depending upon selected technology. This also reduces continuous emissions from the gas plant by eliminating the continuous operation of an incineration system. The CO2 purification unit can be either membrane, cryogenic or adsorption technologies. This paper also discusses the integration of the technologies of Air Liquide Engineering & Construction: OxyClausTM, Tail Gas Treatment Unit (TGTU) and CryoCapTM, a very efficient CO2 purification technology. The scheme has been studied in detail for specific application to optimize the overall integration. It has been also compared to conventional CO2 capture schemes.
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