Optimierte biologische Aktivität allo- und tumorreaktiver CD8-+-T-Lymphozyten im humanisierten Mausmodell durch IL-15-Superagonisten

Interleukin 15 (IL-15) gilt als eines der vielversprechendsten zukünftigen Medikamente für die Krebstherapie. Es fördert die Proliferation, Persistenz und Funktion von CD8+ T-Zellen und vermittelt zahlreiche Effekte, die es als überlegene Alternative für das derzeit in der Klinik verwendete IL-2 erscheinen lassen. Für den Einsatz von IL-15 in der vorliegenden Arbeit wurde zunächst ein Protokoll zur Herstellung von rekombinantem IL-15 in E. coli etabliert. Das hergestellte Protein hatte eine zu kommerziellen Produkten vergleichbare Bioaktivität und begünstigte die Persistenz und Aktivität antigenspezifischer, humaner CD8+ T Zellen nach adoptivem Transfer in NSG-Mäuse, wobei unter anderem ein verstärkter Effekt auf T Zellen mit TSCM-Phänotyp beobachtet wurde. Um die Bioaktivität von IL-15 zu steigern, wurden super-agonistische IL-15-Fusions¬proteine entworfen und im Expi293-System hergestellt. Dabei wurde IL 15 kovalent mit der Sushi-Domäne, der IL-15Rα-Kette und einer IgG1-Fc-Domäne verbunden, was zu einer gesteigerten Affinität der IL 15-Superagonisten zum physiologischen, niederaffinen IL 15Rβγ und zu einer stark erhöhten Halbwertszeit in Mausserum führte. Die gesteigerte Affinität der IL-15-Super¬agonisten wurde durch die IL 15Rα-Sushi-Domäne vermittelt. Eine um 13 Amino¬säuren verlängerte Sushi-Domäne zeigte im Vergleich zur normalen Form eine nochmals ge¬steigerte Affinität. Die längere Halbwertszeit wurde von der Sushi- und der IgG1-Fc-Domäne vermittelt. Die IgG1-Fc-Domäne verstärkte die Wirkung der Fusionsproteine zusätzlich über einen Mechanismus, der wahrscheinlich mit der Transpräsentation durch Fc Re¬ze¬ptoren zusammen–hängt. Die gesteigerte Bioaktivität der IL-15-Superagonisten wurde im Tiermodell mit humanen und murinen T-Zellen bestätigt und ILR13+-Fc wurde als das Fusionsprotein mit der höchsten Bioaktivität identifiziert. Im Vergleich zu anderen IL-15-Superagonisten vereint es alle derzeit bekannten Eigenschaften zur Bioaktivitätssteigerung in einem einzigen Protein. In therapeutischen Versuchen mit adoptivem Transfer tumorreaktiver T-Zellen konnte der Antitumoreffekt durch ILR13+-Fc maßgeblich verstärkt werden. Als Modellsysteme wurden NSG-Mäuse, die mit humanen AML-Blasten oder einem soliden Ovarialkarzinom engraftet wurden, verwendet. Dabei wurden sowohl antigenspezifische als auch unspezifische Effekte beobachtet. Die unspezifischen Effekte wurden wahrscheinlich durch eine ILR13+-Fc-vermittelte Überexpression von NKG2D, einem Rezeptor der angeborenen Immunantwort, auf den adoptiv transferierten T Zellen vermittelt. Die Ergebnisse dieser Arbeit zeigen, dass IL-15 und die IL-15-Superagonisten die Proliferation und Reaktivität von CD8+ T-Zellen im Rahmen der Immuntherapie fördern können. Aufgrund der hohen Bioaktivität und potenzierten Wirksamkeit, könnten vor allem die IL 15-Superagonisten in Zukunft bei der Entwicklung effizienter Therapiemethoden eingesetzt werden und dadurch einen wichtigen Beitrag zu Behandlung von Krebs leisten. rnrn

In vitro generation and characterization of acute myeloid leukemia-reactive CD8 + cytotoxic T-lymphocyte clones from healthy donors

Donor-derived CD8+ cytotoxic T lymphocytes (CTLs) eliminating host leukemic cells mediate curative graft-versus-leukemia (GVL) reactions after allogeneic hematopoietic stem cell transplantation (HSCT). The leukemia-reactive CTLs recognize hematopoiesis-restricted or broadly expressed minor histocompatibility and leukemia-associated peptide antigens that are presented by human leukocyte antigen (HLA) class I molecules on recipient cells. The development of allogeneic CTL therapy in acute myeloid leukemia (AML) is hampered by the poor efficiency of current techniques for generating leukemia-reactive CTLs from unprimed healthy donors in vitro. In this work, a novel allogeneic mini-mixed lymphocyte/leukemia culture (mini-MLLC) approach was established by stimulating CD8+ T cells isolated from peripheral blood of healthy donors at comparably low numbers (i.e. 10e4/well) with HLA class I-matched primary AML blasts in 96-well microtiter plates. Before culture, CD8+ T cells were immunomagnetically separated into CD62L(high)+ and CD62L(low)+/neg subsets enriched for naive/central memory and effector memory cells, respectively. The application of 96-well microtiter plates aimed at creating multiple different responder-stimulator cell compositions in order to provide for the growth of leukemia-reactive CTLs optimized culture conditions by chance. The culture medium was supplemented with interleukin (IL)-7, IL-12, and IL-15. On day 14, IL-12 was replaced by IL-2. In eight different related and unrelated donor/AML pairs with complete HLA class I match, numerous CTL populations were isolated that specifically lysed myeloid leukemias in association with various HLA-A, -B, or -C alleles. These CTLs recognized neither lymphoblastoid B cell lines of donor and patient origin nor primary B cell leukemias expressing the corresponding HLA restriction element. CTLs expressed T cell receptors of single V-beta chain families, indicating their clonality. The vast majority of CTL clones were obtained from mini-MLLCs initiated with CD8+ CD62L(high)+ cells. Using antigen-specific stimulation, multiple CTL populations were amplified to 10e8-10e10 cells within six to eight weeks. The capability of mini-MLLC derived AML-reactive CTL clones to inhibit the engraftment of human primary AML blasts was investigated in the immunodeficient nonobese diabetic/severe combined immune deficient IL-2 receptor common γ-chain deficient (NOD/SCID IL2Rγnull) mouse model. The leukemic engraftment in NOD/SCID IL2Rγnull was specifically prevented if inoculated AML blasts had been pre-incubated in vitro with AML-reactive CTLs, but not with anti-melanoma control CTLs. These results demonstrate that myeloid leukemia-specific CTL clones capable of preventing AML engraftment in mice can be rapidly isolated from CD8+ CD62L(high)+ T cells of healthy donors in vitro. The efficient generation and expansion of these CTLs by the newly established mini-MLLC approach opens the door for several potential applications. First, CTLs can be used within T cell-driven antigen identification strategies to extend the panel of molecularly defined AML antigens that are recognizable by T cells of healthy donors. Second, because these CTLs can be isolated from the stem cell donor by mini-MLLC prior to transplantation, they could be infused into AML patients as a part of the stem cell allograft, or early after transplantation when the leukemia burden is low. The capability of these T cells to expand and function in vivo might require the simultaneous administration of AML-reactive CD4+ T cells generated by a similar in vitro strategy or, less complex, the co-transfer of CD8-depleted donor lymphocytes. To prepare clinical testing, the mini-MLLC approach should now be translated into a protocol that is compatible with good manufacturing practice guidelines.

Detrimental effects of exuberant and restrained immune responses against the central nervous system in the context of multiple sclerosis and glioblastoma multiforme

Glioblastoma multiforme (GBM) is the most common and most aggressive astrocytic tumor of the central nervous system (CNS) in adults. The standard treatment consisting of surgery, followed by a combinatorial radio- and chemotherapy, is only palliative and prolongs patient median survival to 12 to 15 months. The tumor subpopulation of stem cell-like glioma-initiating cells (GICs) shows resistance against radiation as well as chemotherapy, and has been suggested to be responsible for relapses of more aggressive tumors after therapy. The efficacy of immunotherapies, which exploit the immune system to specifically recognize and eliminate malignant cells, is limited due to strong immunosuppressive activities of the GICs and the generation of a specialized protective microenvironment. The molecular mechanisms underlying the therapy resistance of GICs are largely unknown. rnThe first aim of this study was to identify immune evasion mechanisms in GICs triggered by radiation. A model was used in which patient-derived GICs were treated in vitro with fractionated ionizing radiation (2.5 Gy in 7 consecutive passages) to select for a more radio-resistant phenotype. In the model cell line 1080, this selection process resulted in increased proliferative but diminished migratory capacities in comparison to untreated control GICs. Furthermore, radio-selected GICs downregulated various proteins involved in antigen processing and presentation, resulting in decreased expression of MHC class I molecules on the cellular surface and diminished recognition potential by cytotoxic CD8+ T cells. Thus, sub-lethal fractionated radiation can promote immune evasion and hamper the success of adjuvant immunotherapy. Among several immune-associated proteins, interferon-induced transmembrane protein 3 (IFITM3) was found to be upregulated in radio-selected GICs. While high expression of IFITM3 was associated with a worse overall survival of GBM patients (TCGA database) and increased proliferation and migration of differentiated glioma cell lines, a strong contribution of IFITM3 to proliferation in vitro as well as tumor growth and invasiveness in a xenograft model could not be observed. rnMultiple sclerosis (MS) is the most common autoimmune disease of the CNS in young adults of the Western World, which leads to progressive disability in genetically susceptible individuals, possibly triggered by environmental factors. It is assumed that self-reactive, myelin-specific T helper cell 1 (Th1) and Th17 cells, which have escaped the control mechanisms of the immune system, are critical in the pathogenesis of the human disease and its animal model experimental autoimmune encephalomyelitis (EAE). It was observed that in vitro differentiated interleukin 17 (IL-17) producing Th17 cells co-expressed the Th1-phenotypic cytokine Interferon-gamma (IFN-γ) in combination with the two respective lineage-associated transcription factors RORγt and T-bet after re-isolation from the CNS of diseased mice. Pathogenic molecular mechanisms that render a CD4+ T cell encephalitogenic have scarcely been investigated up to date. rnIn the second part of the thesis, whole transcriptional changes occurring in in vitro differentiated Th17 cells in the course of EAE were analyzed. Evaluation of signaling networks revealed an overrepresentation of genes involved in communication between the innate and adaptive immune system and metabolic alterations including cholesterol biosynthesis. The transcription factors Cebpa, Fos, Klf4, Nfatc1 and Spi1, associated with thymocyte development and naïve T cells were upregulated in encephalitogenic CNS-isolated CD4+ T cells, proposing a contribution to T cell plasticity. Correlation of the murine T-cell gene expression dataset to putative MS risk genes, which were selected based on their proximity (± 500 kb; ensembl database, release 75) to the MS risk single nucleotide polymorphisms (SNPs) proposed by the most recent multiple sclerosis GWAS in 2011, revealed that 67.3% of the MS risk genes were differentially expressed in EAE. Expression patterns of Bach2, Il2ra, Irf8, Mertk, Odf3b, Plek, Rgs1, Slc30a7, and Thada were confirmed in independent experiments, suggesting a contribution to T cell pathogenicity. Functional analysis of Nfatc1 revealed that Nfatc1-deficient CD4+ T cells were restrained in their ability to induce clinical signs of EAE. Nfatc1-deficiency allowed proper T cell activation, but diminished their potential to fully differentiate into Th17 cells and to express high amounts of lineage cytokines. As the inducible Nfatc1/αA transcript is distinct from the other family members, it could represent an interesting target for therapeutic intervention in MS.rn