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1. Domain-swapped T cell receptors improve the safety of TCR gene therapy.

Author

Bethune, Michael T, Gee, Marvin H, Bunse, Mario, Lee, Mark S, Gschweng, Eric H, Pagadala, Meghana S, Zhou, Jing, Cheng, Donghui, Heath, James R, Kohn, Donald B, Kuhns, Michael S, Uckert, Wolfgang, and Baltimore, David

Subjects
Animals, Mice, Graft vs Host Disease, Disease Models, Animal, Receptors, Antigen, T-Cell, Recombinant Proteins, Recombination, Genetic, Genes, T-Cell Receptor, Genetic Therapy, Protein Domains, T cell, T cell receptor, autoimmunity, cancer immunotherapy, human biology, immunology, medicine, mouse, protein engineering, receptor biogenesis, Disease Models, Animal, Receptors, Antigen, T-Cell, Recombination, Genetic, Genes, T-Cell Receptor, Biochemistry and Cell Biology
Abstract

T cells engineered to express a tumor-specific αβ T cell receptor (TCR) mediate anti-tumor immunity. However, mispairing of the therapeutic αβ chains with endogenous αβ chains reduces therapeutic TCR surface expression and generates self-reactive TCRs. We report a general strategy to prevent TCR mispairing: swapping constant domains between the α and β chains of a therapeutic TCR. When paired, domain-swapped (ds)TCRs assemble with CD3, express on the cell surface, and mediate antigen-specific T cell responses. By contrast, dsTCR chains mispaired with endogenous chains cannot properly assemble with CD3 or signal, preventing autoimmunity. We validate this approach in cell-based assays and in a mouse model of TCR gene transfer-induced graft-versus-host disease. We also validate a related approach whereby replacement of αβ TCR domains with corresponding γδ TCR domains yields a functional TCR that does not mispair. This work enables the design of safer TCR gene therapies for cancer immunotherapy.

Published
2016

5. Data from ERK1 as a Therapeutic Target for Dendritic Cell Vaccination against High-Grade Gliomas

Author

Ku, Min-Chi, primary, Edes, Inan, primary, Bendix, Ivo, primary, Pohlmann, Andreas, primary, Waiczies, Helmar, primary, Prozorovski, Tim, primary, Günther, Martin, primary, Martin, Conrad, primary, Pagès, Gilles, primary, Wolf, Susanne A., primary, Kettenmann, Helmut, primary, Uckert, Wolfgang, primary, Niendorf, Thoralf, primary, and Waiczies, Sonia, primary

Published
2023
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6. Ku et al_supplemental_methods from ERK1 as a Therapeutic Target for Dendritic Cell Vaccination against High-Grade Gliomas

Author

Ku, Min-Chi, primary, Edes, Inan, primary, Bendix, Ivo, primary, Pohlmann, Andreas, primary, Waiczies, Helmar, primary, Prozorovski, Tim, primary, Günther, Martin, primary, Martin, Conrad, primary, Pagès, Gilles, primary, Wolf, Susanne A., primary, Kettenmann, Helmut, primary, Uckert, Wolfgang, primary, Niendorf, Thoralf, primary, and Waiczies, Sonia, primary

Published
2023
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7. methods from Chimeric PD-1:28 Receptor Upgrades Low-Avidity T cells and Restores Effector Function of Tumor-Infiltrating Lymphocytes for Adoptive Cell Therapy

Author

Schlenker, Ramona, primary, Olguín-Contreras, Luis Felipe, primary, Leisegang, Matthias, primary, Schnappinger, Julia, primary, Disovic, Anja, primary, Rühland, Svenja, primary, Nelson, Peter J., primary, Leonhardt, Heinrich, primary, Harz, Hartmann, primary, Wilde, Susanne, primary, Schendel, Dolores J., primary, Uckert, Wolfgang, primary, Willimsky, Gerald, primary, and Noessner, Elfriede, primary

Published
2023
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8. Data from Chimeric PD-1:28 Receptor Upgrades Low-Avidity T cells and Restores Effector Function of Tumor-Infiltrating Lymphocytes for Adoptive Cell Therapy

Author

Schlenker, Ramona, primary, Olguín-Contreras, Luis Felipe, primary, Leisegang, Matthias, primary, Schnappinger, Julia, primary, Disovic, Anja, primary, Rühland, Svenja, primary, Nelson, Peter J., primary, Leonhardt, Heinrich, primary, Harz, Hartmann, primary, Wilde, Susanne, primary, Schendel, Dolores J., primary, Uckert, Wolfgang, primary, Willimsky, Gerald, primary, and Noessner, Elfriede, primary

Published
2023
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11. Supplementary Data from Eradication of Large Solid Tumors by Gene Therapy with a T-Cell Receptor Targeting a Single Cancer-Specific Point Mutation

Author

Leisegang, Matthias, primary, Engels, Boris, primary, Schreiber, Karin, primary, Yew, Poh Yin, primary, Kiyotani, Kazuma, primary, Idel, Christian, primary, Arina, Ainhoa, primary, Duraiswamy, Jaikumar, primary, Weichselbaum, Ralph R., primary, Uckert, Wolfgang, primary, Nakamura, Yusuke, primary, and Schreiber, Hans, primary

Published
2023
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12. Efficient non-viral T cell engineering for TCR gene therapy by Sleeping Beauty minicircles

Author

Uckert, Wolfgang, Matuschewski, Kai, Pezzutto, Antonio, Clauß, Julian, Uckert, Wolfgang, Matuschewski, Kai, Pezzutto, Antonio, and Clauß, Julian

Abstract

Sleeping Beauty (SB) Transposon-basierte Vektoren werden als Alternative zu viralen Vektoren für T-Zell-Gentherapie erforscht und ermöglichen eine schnelle und kostengünstige Genmanipulation von T-Zellen. Die Verwendung von Transposon-Vektoren erfordert jedoch die DNA-Elektroporation von T-Zellen, die sich schädlich auf T-Zellen auswirkt. DNA-elektroporierte T-Zellen weisen eine verringerte Lebensfähigkeit und eine verzögerte Aktivierung nach Stimulation des T-Zell-Rezeptors (TCR) auf. Um die Nachteile der Transposon-basierten T-Zell-Genmanipulation zu überwinden, haben wir neuartige SB-Vektoren entwickelt. Durch die Kombination von SB Transposon-basierten Minicircle-Vektoren mit SB100X Transposase-mRNA konnten T-Zellen effizient genmodifiziert werden. Unser Ansatz reduzierte die T-Zell-Mortalität und steigerte gleichzeitig die Transfektionseffizienz. Mit diesen neuartigen Vektoren wurde die stabile Expression verschiedener TCRs und CARs in über 50% der eingesetzten T-Zellen erreicht. Gentechnisch manipulierte T-Zellen konnten Antigen-spezifisch stimuliert werden und zeigten effiziente Zytokin-Sekretion und Tumorzell-Lyse. Weiterhin haben wir miRNAs entwickelt, die die Expression der endogenen TCR-Ketten unterdrücken. Der Einbau dieser miRNAs in die TCR-Expressionskassette erhöhte die Oberflächenexpression des therapeutischen TCRs, verringerte die Fehlpaarung mit endogenen TCR-Ketten und erhöhte die T-Zell-Funktionalität. Ein direkter Vergleich von SB- und Virus-modifizierten T-Zellen zeigte sowohl in vitro als auch in vivo eine vergleichbare Wirksamkeit der modifizierten T-Zellen hinsichtlich Zytokin-Sekretion, Tumorzell-Lyse und Tumorkontrolle. In dieser Arbeit konnte gezeigt werden, dass SB Minicircle-Vektoren die Herstellung von genetisch modifizierten T-Zellen ermöglichen und diese Tumor-spezifische Wirksamkeit aufweisen. Dieser Ansatz könnte die Herstellung therapeutischer T-Zellen für die personalisierte T-Zell-Gentherapie vereinfachen und beschleunigen., Sleeping Beauty (SB) transposon-based vectors have entered clinical trials as an alternative to viral vectors for T cell gene therapy, offering time- and cost-efficient engineering of therapeutic T cells. However, transposon vectors require DNA electroporation into T cells, which we found to cause adverse effects. T cell viability was decreased, and DNA-transfected T cells showed delayed activation upon T cell receptor (TCR) stimulation regarding blast formation and proliferation. To overcome the limitations of transposon-based T cell engineering, we investigated the effect of DNA electroporation on T cells and developed novel SB vectors. T cells could efficiently be engineered with Sleeping Beauty vectors by combining SB transposon minicircles and SB100X transposase mRNA. Our approach reduced T cell mortality and substantially enhanced transfection efficiency. We achieved stable expression of several TCRs and CARs in more than 50% of the transfected T cells compared to 15% when conventional plasmids were used. T cells engineered to express a tumor-specific TCR mediated effective tumor cell lysis and cytokine secretion upon antigen-specific stimulation. Furthermore, we developed miRNAs to silence the expression of the endogenous TCR chains. Incorporation of these miRNAs into the TCR expression cassette increased surface expression of the therapeutic TCR, diminished mispairing with endogenous TCR chains, and enhanced T cell functionality. Importantly, a direct comparison of SB minicircle- and RV-engineered T cells in vitro as well as in vivo demonstrated equal T cell efficacy with regards to cytokine release, tumor cell lysis and tumor control. We demonstrated that SB minicircles enable the generation of gene-modified T cells with tumor-specific reactivity. Our approach facilitates the manufacturing of therapeutic T cells with superior biosafety and accelerates the generation of patient-specific T cell products for personalized T cell gene therapy.

Published
2023

14. Targeting human melanoma neoantigens by T cell receptor gene therapy

Author

Leisegang, Matthias, Kammertoens, Thomas, Uckert, Wolfgang, and Blankenstein, Thomas

Subjects
T cells -- Research -- Genetic aspects, Gene therapy -- Usage, Melanoma -- Analysis -- Health aspects -- Care and treatment, Health care industry
Abstract

In successful cancer immunotherapy, T cell responses appear to be directed toward neoantigens created by somatic mutations; however, direct evidence that neoantigen-specific T cells cause regression of established cancer is lacking. Here, we generated T cells expressing a mutation-specific transgenic T cell receptor (TCR) to target different immunogenic mutations in cyclin-dependent kinase 4 (CDK4) that naturally occur in human melanoma. Two mutant CDK4 isoforms (R24C, R24L) similarly stimulated T cell responses in vitro and were analyzed as therapeutic targets for TCR gene therapy. In a syngeneic HLA-A2-transgenic mouse model of large established tumors, we found that both mutations differed dramatically as targets for TCR-modified T cells in vivo. While T cells expanded efficiently and produced IFN- γ in response to R24L, R24C failed to induce an effective antitumor response. Such differences in neoantigen quality might explain why cancer immunotherapy induces tumor regression in some individuals, while others do not respond, despite similar mutational load. We confirmed the validity of the in vivo model by showing that the melan-A- specific (MART-1-specific) TCR DMF5 induces rejection of tumors expressing analog, but not native, MART-1 epitopes. The described model allows identification of those neoantigens in human cancer that serve as suitable T cell targets and may help to predict clinical efficacy., Introduction Melanoma regression, either through adoptive T cell therapy (ATT) or T cell checkpoint inhibitors blocking CTLA4 or PD-1/PD-1 ligand, correlated with increased frequencies of neoantigen-specific T cells, as deduced [...]

Published
2016
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15. Generation of Epstein-Barr Virus-specific T Cell Receptorengineered T Cells for Cancer Treatment

Author

Matuschewski, Kai, Meyer, Thomas F., Uckert, Wolfgang, Dudaniec, Krystyna, Matuschewski, Kai, Meyer, Thomas F., Uckert, Wolfgang, and Dudaniec, Krystyna

Abstract

Die adoptive T-Zell-Therapie (ATT) ist eine sich schnell entwickelnde Immuntherapie, die bei Patienten, die an verschiedenen Krebsarten leiden, eine positive klinische Reaktion anzeigt. Eine Variante der ATT ist eine T-Zellen-Rezeptor (TCR)-Gentherapie, bei der Patienten-T-Zellen mit krebsspezifischen TCRs ausgestattet werden. Die Herstellung der TCR-erzeugten T-Zellen ist schnell und robust und erfordert eine geringe Anfangsmenge an Patienten-T-Zellen. Der Mangel an verfügbaren krebsspezifischen TCRs, die auf verschiedene Moleküle des menschlichen Leukozytenantigens (HLA) der Klasse I beschränkt sind, schließt jedoch viele Patienten von der Krebsbehandlung aus. Die Generierung einer krebsspezifischen TCR-Bibliothek, die aus gut definierten TCRs besteht, könnte die Zahl der Patienten, die an klinischen Studien teilnehmen, erhöhen. Das Ziel dieser Doktorarbeit war es, Epstein-Barr-Virus (EBV)-spezifische TCRs zu identifizieren und zu isolieren, um eine EBV-spezifische TCR-Bibliothek als ein nützliches Werkzeug der TCR-Gentherapie bei der Behandlung von EBV-bedingten Krebserkrankungen zu generieren. Insgesamt wurden neun EBV-spezifische TCRs von EBV-positiven Spendern isoliert und charakterisiert, die verschiedene pHLA-Komplexe von EBV-Latentmembranproteinen (LMP1, LMP2A) und Kernprotein (EBNA3C) erkannten. Zusätzlich wurde ein neuartiges immunogenes LMP1-Epitop (QQNWWTLLV) entdeckt, das auf HLA-C*15:02 beschränkt ist. Definierte EBV-spezifische TCRs können als Grundlage für die EBV-spezifische TCR-Bibliothek verwendet werden, die eine wertvolle Quelle von TCRs für die schnelle Generierung von EBV-spezifischen T-Zellen zur Behandlung von Krebspatienten mit verschiedenen HLA-Typen darstellt., Adoptive T cell therapy (ATT) is a fast developing immunotherapy indicating positive clinical response in patients suffering from different type of cancers. One type of the ATT is a T cell receptor (TCR) gene therapy, which involves endowing patient T cells with cancer-specific TCRs. Manufacturing of the TCR-engineered T cells is fast and robust, requiring small initial amount of patient T cells. However, lack of available cancer-specific TCRs restricted to various human leukocyte antigen (HLA) class I molecules eliminates many patients from cancer treatment. Generation of a cancer-specific TCR library consisting of well-defined TCRs could increase the number of patients enrolled in clinical trials. The aim of this PhD thesis was to identify and isolate Epstein-Barr virus (EBV)-specific TCRs in order to generate the EBV-specific TCR library as a useful tool of the TCR gene therapy for treatment of EBV-related malignancies. In total, nine EBV-specific TCRs of EBV-positive donors that recognized various pHLA complexes of EBV latent membrane proteins (LMP1, LMP2A) and nuclear protein (EBNA3C) were isolated and characterized. Additionally, a novel immunogenic LMP1 epitope (QQNWWTLLV) restricted to a HLA-C*15:02 was discovered. Defined EBV-specific TCRs can be used as a basis for the EBV-specific TCR library, which provides a valuable source of TCRs for rapid generation of EBV-specific T cells to treat cancer patients with different HLA types.

Published
2022

19. Antigen receptor‐engineered Tregs inhibit CNS autoimmunity in cell therapy using nonredundant immune mechanisms in mice

Author

Pohar, Jelka, primary, O'Connor, Richard, additional, Manfroi, Benoît, additional, El‐Behi, Mohamed, additional, Jouneau, Luc, additional, Boudinot, Pierre, additional, Bunse, Mario, additional, Uckert, Wolfgang, additional, Luka, Marine, additional, Ménager, Mickael, additional, Liblau, Roland, additional, Anderton, Stephen M., additional, and Fillatreau, Simon, additional

Published
2022
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24. Characterization and modulation of anti-αβTCR antibodies and their respective binding sites at the βTCR chain to enrich engineered T cells

Author

Kierkels, Guido J.J., primary, van Diest, Eline, additional, Hernández-López, Patricia, additional, Scheper, Wouter, additional, de Bruin, Anja C.M., additional, Frijlink, Elselien, additional, Aarts-Riemens, Tineke, additional, van Dooremalen, Sanne F.J., additional, Beringer, Dennis X., additional, Oostvogels, Rimke, additional, Kramer, Lovro, additional, Straetemans, Trudy, additional, Uckert, Wolfgang, additional, Sebestyén, Zsolt, additional, and Kuball, Jürgen, additional

Published
2021
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26. Characterization and modulation of anti-alpha beta TCR antibodies and their respective binding sites at the beta TCR chain to enrich engineered T cells

Author

CTI Kuball, Infection & Immunity, Cancer, ZL Neuro-Oncologie Medisch, CTI Beringer, CTI Straetemans, MS Hematologie, Regenerative Medicine and Stem Cells, Kierkels, Guido J J, van Diest, Eline, Hernández-López, Patricia, Scheper, Wouter, de Bruin, Anja C M, Frijlink, Elselien, Aarts-Riemens, Tineke, van Dooremalen, Sanne F J, Beringer, Dennis X, Oostvogels, Rimke, Kramer, Lovro, Straetemans, Trudy, Uckert, Wolfgang, Sebestyén, Zsolt, Kuball, Jürgen, CTI Kuball, Infection & Immunity, Cancer, ZL Neuro-Oncologie Medisch, CTI Beringer, CTI Straetemans, MS Hematologie, Regenerative Medicine and Stem Cells, Kierkels, Guido J J, van Diest, Eline, Hernández-López, Patricia, Scheper, Wouter, de Bruin, Anja C M, Frijlink, Elselien, Aarts-Riemens, Tineke, van Dooremalen, Sanne F J, Beringer, Dennis X, Oostvogels, Rimke, Kramer, Lovro, Straetemans, Trudy, Uckert, Wolfgang, Sebestyén, Zsolt, and Kuball, Jürgen

Published
2021

28. MHC-restricted fratricide of human lymphocytes expressing survivin-specific transgenic T cell receptors

Author

Leisegang, Matthias, Wilde, Susanne, Spranger, Stefani, Milosevic, Slavoljub, Frankenberger, Bernhard, Uckert, Wolfgang, and Schendel, Dolores J.

Subjects
T cells -- Receptors, Antigen receptors, T cell -- Physiological aspects -- Genetic aspects -- Research, Major histocompatibility complex -- Physiological aspects -- Genetic aspects -- Research, Immunotherapy -- Health aspects, Cancer -- Genetic aspects -- Care and treatment -- Research, Health care industry
Abstract

The apoptosis inhibitor protein survivin is overexpressed in many tumors, making it a candidate target molecule for various forms of immunotherapy. To explore survivin as a target antigen for adoptive T cell therapy using lymphocytes expressing survivin-specific transgenic T cell receptors (Tg-TCRs), we isolated HLA-A2--allorestricted survivin-specific T cells with high functional avidity. Lymphocytes expressing Tg-TCRs were derived from these T cells and specifically recognized HLA-A[2.sup.-] [survivin.sup.+] tumor cells. Surprisingly, HLA-A[2.sup.-] but not HLA-A[2.sup.-] lymphocytes expressing Tg-TCRs underwent extensive apoptosis over time. This demise was caused by HLA-A2--restricted fratricide that occurred due to survivin expression in lymphocytes, which created ligands for Tg-TCR recognition. Therefore, survivin-specific TCR gene therapy would be limited to application in HLA-A2-mismatched stem cell transplantation. We also noted that lymphocytes that expressed survivin-specific Tg-TCRs killed T cell clones of various specificities derived from HLA-[A2.sup.+] but not HLA-A[2.sup.-] donors. These results raise a general question regarding the development of cancer vaccines that target proteins that are also expressed in activated lymphocytes, since induction of high-avidity T cells that expand in lymph nodes following vaccination or later accumulate at tumor sites might limit themselves by self-MHC--restricted fratricide while at the same time inadvertently eliminating neighboring T cells of other specificities., Introduction Several recent developments have converged to improve adoptive T cell therapy of cancer. First, expression of TCRs as transgenic proteins in peripheral blood lymphocytes (PBLs) enables T cells with [...]

Published
2010
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29. Lethal graft-versus-host disease in mouse models of T cell receptor gene therapy

Author

Bendle, Gavin M., Linnemann, Carsten, Hooijkaas, Anna I., Bies, Laura, de Witte, Moniek A., Jorritsma, Annelies, Kaiser, Andrew D.M., Pouw, Nadine, Debets, Reno, Kieback, Elisa, Uckert, Wolfgang, Song, Ji-Ying, Haanen, John B.A.G., and Schumacher, Ton N.M.

Subjects
T cells -- Receptors, Antigen receptors, T cell -- Health aspects, Autoimmunity -- Research, Gene therapy -- Complications and side effects, Biological sciences, Health
Abstract

The transfer of T cell receptor (TCR) genes can be used to induce immune reactivity toward defined antigens to which endogenous T cells are insufficiently reactive. This approach, which is called TCR gene therapy, is being developed to target tumors and pathogens, and its clinical testing has commenced in patients with cancer. In this study we show that lethal cytokine-driven autoimmune pathology can occur in mouse models of TCR gene therapy under conditions that closely mimic the clinical setting. We show that the pairing of introduced and endogenous TCR chains in TCR gene-modified T cells leads to the formation of self-reactive TCRs that are responsible for the observed autoimmunity. Furthermore, we demonstrate that adjustments in the design of gene therapy vectors and target T cell populations can be used to reduce the risk of TCR gene therapy-induced autoimmune pathology., Most human tumor-associated antigens that are shared between individuals consist of nonmutated self antigens (1). Consequently, the endogenous T cell repertoire that reacts to these antigens will generally be small [...]

Published
2010
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32. The tumor-associated antigen EBAG9 negatively regulates the cytolytic capacity of mouse [CD8.sup.+] T cells

Author

Ruder, Constantin, Hopken, Uta E., Wolf, Jana, Mittrucker, Hans-Willi, Engels, Boris, Erdmann, Bettina, Wollenzin, Susanne, Uckert, Wolfgang, Dorken, Bernd, and Rehm, Armin

Subjects
Exocytosis -- Research, Mice -- Usage, Mice -- Models, Immune response -- Health aspects, Immune response -- Research, T cells -- Health aspects, T cells -- Research
Abstract

CTLs eliminate virus-infected and tumorigenic cells through exocytosis of cytotoxic agents from lytic granules. While insights into the intracellular mechanisms facilitating lytic granule release have been obtained through analysis of loss-of-function mutations in humans and mice, there is a paucity of information on negative regulators of secretory lysosome release at the molecular level. By generating and analyzing estrogen receptor--binding fragment-associated antigen 9-KO (Ebag9 KO) mice, we show here that loss of EBAG9 confers CTLs with enhanced cytolytic capacity in vitro and in vivo. Although loss of EBAG9 did not affect lymphocyte development, it led to an increase in CTL secretion of granzyme A, a marker of lytic granules. This resulted in increased cytotoxicity in vitro and an enhanced cytolytic primary and memory T cell response in vivo. We further found that EBAG9 interacts with the adaptor molecule [gamma]2-adaptin, suggesting EBAG9 is involved in endosomal-lysosomal biogenesis and membrane fusion. Indeed, granzyme B was sorted to secretory lysosomes more efficiently in EBAG9-deficient CTLs than it was in WT CTLs, a finding consistent with the observed enhanced kinetics of cathepsin D proteolytic processing. While EBAG9 deficiency did not disrupt the formation of the immunological synapse, lytic granules in Ebag9-/- CTLs were smaller than in WT CTLs. These data suggest that EBAG9 is a tunable inhibitor of CTL-mediated adaptive immune response functions., Introduction CTLs and NK cells employ regulated exocytosis of perforin and granzymes, cytotoxic agents from specialized secretory lysosomes (also referred to as lytic granules) to eliminate virus-infected and tumorigenic transformed [...]

Published
2009

34. Tumour ischaemia by interferon- resembles physiological blood vessel regression

Author

Kammertoens, Thomas, Friese, Christian, Arina, Ainhoa, Idel, Christian, Briesemeister, Dana, Rothe, Michael, Ivanov, Andranik, Szymborska, Anna, Patone, Giannino, Kunz, Severine, Sommermeyer, Daniel, Engels, Boris, Leisegang, Matthias, Textor, Ana, Joerg Fehling, Hans, Fruttiger, Marcus, Lohoff, Michael, Herrmann, Andreas, Yu, Hua, Weichselbaum, Ralph, Uckert, Wolfgang, Hbner, Norbert, Gerhardt, Holger, Beule, Dieter, Schreiber, Hans, and Blankenstein, Thomas

Subjects
Tumors -- Physiological aspects, Interferon -- Physiological aspects, Ischemia -- Physiological aspects, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Author(s): Thomas Kammertoens [1, 2]; Christian Friese [1, 2]; Ainhoa Arina [3]; Christian Idel [4]; Dana Briesemeister [1, 2]; Michael Rothe [1, 2]; Andranik Ivanov [5, 6]; Anna Szymborska [2]; [...]

Published
2017
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43. Herpes simplex virus thymidine kinase/ganciclovir-induced apoptosis involves ligand-independent death receptor aggregation and activation of caspases

Author

Beltinger, Christian, Fulda, Simone, Kammertoens, Thomas, Meyer, Eric, Uckert, Wolfgang, and Debatin, Klaus-Michael

Subjects
Herpes simplex virus -- Research, Gene therapy -- Research, Cancer cells -- Research, Cancer -- Research, Tumor suppressor genes -- Research, Science and technology
Abstract

Suicide gene therapy systems such as the herpes simplex thymidine kinase/ganciclovir system (TK/GCV) may kill cancer cells by apoptosis through as yet undefined mechanisms. Here we show that TK/GCV treatment induces p53 accumulation and increases cell surface expression of CD95 and tumor necrosis factor receptor, which is likely to involve p53-mediated translocation of CD95 to the cell surface. TK/GCV-induced apoptosis involves CD95-L-independent CD95 aggregation leading to the formation of a Fas-associated death domain protein (FADD) and caspase-8-containing, death-inducing signaling complex. Dominant negative FADD, the caspase-8 inhibitor zIETD-fmk [Z-Ile-Glu(OMe)-Thr-Asp(OMe)-fluoromethylketone], and zVAD-fmk (Z-Val-Ala-Asp-fluoromethylketone) partially abrogate TK/GCV-induced apoptosis. In addition to apoptosis induction, TK/GCV treatment strongly sensitizes for CD95-L-, TNF-, and TNF-related, apoptosis-inducing, ligand (TRAIL)induced cell death in constitutively resistant cells. These findings may be used to increase the efficacy of TK/GCV and other suicide gene therapy systems for the treatment of cancer.

Published
1999

47. ER‐aminopeptidase 1 determines the processing and presentation of an immunotherapy‐relevant melanoma epitope

Author

Textoris‐Taube, Kathrin, primary, Cammann, Clemens, additional, Henklein, Petra, additional, Topfstedt, Eylin, additional, Ebstein, Frédéric, additional, Henze, Sarah, additional, Liepe, Juliane, additional, Zhao, Fang, additional, Schadendorf, Dirk, additional, Dahlmann, Burkhardt, additional, Uckert, Wolfgang, additional, Paschen, Annette, additional, Mishto, Michele, additional, and Seifert, Ulrike, additional

Published
2019
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48. CAR T Cells with Enhanced Sensitivity to B Cell Maturation Antigen for the Targeting of B Cell Non-Hodgkin's Lymphoma and Multiple Myeloma

Author

Bluhm, Julia, Kieback, Elisa, Marino, Stephen F., Oden, Felix, Westermann, Joerg, Chmielewski, Markus, Abken, Hinrich, Uckert, Wolfgang, Hoepken, Uta E., Rehm, Armin, Bluhm, Julia, Kieback, Elisa, Marino, Stephen F., Oden, Felix, Westermann, Joerg, Chmielewski, Markus, Abken, Hinrich, Uckert, Wolfgang, Hoepken, Uta E., and Rehm, Armin

Abstract

Autologous T cells genetically modified with a chimeric antigen receptor (CAR) redirected at CD19 have potent activity in the treatment of B cell leukemia and B cell non-Hodgkin's lymphoma (B-NHL). Immunotherapies to treat multiple myeloma (MM) targeted the B cell maturation antigen (BCMA), which is expressed in most cases of MM. We developed a humanized CAR with specificity for BCMA based on our previously generated anti-BCMA monoclonal antibody. The targeting single chain variable fragment (scFv) domain exhibited a binding affinity in the low nanomolar range, conferring T cells with high functional avidity. Redirecting T cells by this CAR allowed us to explore BCMA as an alternative target for mature B-NHLs. We validated BCMA expression in diffuse large B cell lymphoma, follicular lymphoma, mantle cell lymphoma, and chronic lymphocytic leukemia. BCMA CAR T cells triggered target cell lysis with an activation threshold in the range of 100 BCMA molecules, which allowed for an efficient eradication of B-NHL cells in vitro and in vivo. Our data corroborate BCMA is a suitable target in B cell tumors beyond MM, providing a novel therapeutic option for patients where BCMA is expressed at low abundance or where anti-CD19 immunotherapies have failed due to antigen loss.

Published
2018

49. Manufacture of Gene-Modified Human T-Cells with a Memory Stem/Central Memory Phenotype

Author

Gomez-Eerland, Raquel, Nuijen, Bastiaan, Heemskerk, Bianca, van Rooij, Nienke, van den Berg, Joost H, Beijnen, Jos H, Uckert, Wolfgang, Kvistborg, Pia, Schumacher, Ton N, Haanen, John B A G, Jorritsma, Annelies, Sub Clinical Pharmacology, Pharmacoepidemiology and Clinical Pharmacology, Sub Clinical Pharmacology, and Pharmacoepidemiology and Clinical Pharmacology

Subjects
Cytotoxicity, Immunologic, Interleukin 2, Skin Neoplasms, Cellular differentiation, Genetic Vectors, Receptors, Antigen, T-Cell, Gene Expression, Biology, Applied Microbiology and Biotechnology, Interferon-gamma, MART-1 Antigen, Antigen, Antigens, CD, Transduction, Genetic, Genetics, medicine, Humans, Cell Engineering, Melanoma, Research Articles, Genetics (clinical), Cell Proliferation, Interleukin-15, Pharmacology, Clinical Trials as Topic, Tumor Necrosis Factor-alpha, Interleukin-7, T-cell receptor, CD28, Cell biology, Phenotype, Retroviridae, Interleukin 15, Immunology, Cancer cell, Interleukin-2, Molecular Medicine, Immunologic Memory, T-Lymphocytes, Cytotoxic, medicine.drug
Abstract

Advances in genetic engineering have made it possible to generate human T-cell products that carry desired functionalities, such as the ability to recognize cancer cells. The currently used strategies for the generation of gene-modified T-cell products lead to highly differentiated cells within the infusion product, and on the basis of data obtained in preclinical models, this is likely to impact the efficacy of these products. We set out to develop a good manufacturing practice (GMP) protocol that yields T-cell receptor (TCR) gene-modified T-cells with more favorable properties for clinical application. Here, we show the robust clinical-scale production of human peripheral blood T-cells with an early memory phenotype that express a MART-1-specific TCR. By combining selection and stimulation using anti-CD3/CD28 beads for retroviral transduction, followed by expansion in the presence of IL-7 and IL-15, production of a well-defined clinical-scale TCR gene-modified T-cell product could be achieved. A major fraction of the T-cells generated in this fashion were shown to coexpress CD62L and CD45RA, and express CD27 and CD28, indicating a central memory or memory stemlike phenotype. Furthermore, these cells produced IFNγ, TNFα, and IL-2 and displayed cytolytic activity against target cells expressing the relevant antigen. The T-cell products manufactured by this robust and validated GMP production process are now undergoing testing in a phase I/IIa clinical trial in HLA-A*02:01 MART-1-positive advanced stage melanoma patients. To our knowledge, this is the first clinical trial protocol in which the combination of IL-7 and IL-15 has been applied for the generation of gene-modified T-cell products.

Published
2014

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