scholarly journals Identification of Claudin 6-specific HLA class I- and HLA class II-restricted T cell receptors for cellular immunotherapy in ovarian cancer

2022 ◽  
Vol 11 (1) ◽  
Author(s):  
Junko Matsuzaki ◽  
Shashikant Lele ◽  
Kunle Odunsi ◽  
Takemasa Tsuji
Keyword(s):  
Ovarian Cancer ◽  
T Cell ◽  
T Cell Receptors ◽  
Hla Class I ◽  
Class Ii ◽  
Hla Class Ii ◽  
Class I ◽  
Cellular Immunotherapy ◽  
Cell Receptors

HLAs, TCRs, and KIRs, a Triumvirate of Human Cell-Mediated Immunity

2020 ◽  
Vol 89 (1) ◽  
pp. 717-739 ◽  
Author(s):  
Zakia Djaoud ◽  
Peter Parham
Keyword(s):  
T Cells ◽  
T Cell ◽  
Nk Cells ◽  
T Cell Receptors ◽  
Hla Class I ◽  
Class Ii ◽  
Class I ◽  
Antigenic Specificity ◽  
Class I Mhc ◽  
Cell Receptors

In all human cells, human leukocyte antigen (HLA) class I glycoproteins assemble with a peptide and take it to the cell surface for surveillance by lymphocytes. These include natural killer (NK) cells and γδ T cells of innate immunity and αβ T cells of adaptive immunity. In healthy cells, the presented peptides derive from human proteins, to which lymphocytes are tolerant. In pathogen-infected cells, HLA class I expression is perturbed. Reduced HLA class I expression is detected by KIR and CD94:NKG2A receptors of NK cells. Almost any change in peptide presentation can be detected by αβ CD8+ T cells. In responding to extracellular pathogens, HLA class II glycoproteins, expressed by specialized antigen-presenting cells, present peptides to αβ CD4+ T cells. In comparison to the families of major histocompatibility complex (MHC) class I, MHC class II and αβ T cell receptors, the antigenic specificity of the γδ T cell receptors is incompletely understood.

scholarly journals Peptide–MHC Binding Reveals Conserved Allosteric Sites in MHC Class I- and Class II-Restricted T Cell Receptors (TCRs)

2020 ◽  
Vol 432 (24) ◽  
pp. 166697 ◽  
Author(s):  
Yanan He ◽  
Pragati Agnihotri ◽  
Sneha Rangarajan ◽  
Yihong Chen ◽  
Melissa C. Kerzic ◽  
...  
Keyword(s):  
T Cell ◽  
Mhc Class I ◽  
T Cell Receptors ◽  
Class Ii ◽  
Class I ◽  
Cell Receptors ◽  
Allosteric Sites

Characterization Of The HLA Class II Ligandome In Acute Myeloid Leukemia (AML) Reveals Novel Candidates For Peptide-Based Immunotherapy

Blood ◽  
2013 ◽  
Vol 122 (21) ◽  
pp. 5012-5012 ◽  
Author(s):  
Juliane S. Stickel ◽  
Claudia Berlin ◽  
Daniel J. Kowalewski ◽  
Lothar Kanz ◽  
Helmut R. Salih ◽  
...  
Keyword(s):  
T Cell ◽  
Cell Response ◽  
Hla Class I ◽  
Class Ii ◽  
Hla Class Ii ◽  
T Cell Response ◽  
Cd4 T Cell ◽  
Class I ◽  
Tumor Associated Antigens ◽  
Healthy Donors

Abstract CD4+ T cells are crucial for the induction and maintenance of cytotoxic T cell responses, but can also mediate direct tumor rejection. The therapeutic efficacy of peptide-based cancer vaccines may thus be improved by including HLA class II epitopes to stimulate T helper cells. In contrast to HLA class I ligands, only a small number of class II ligands of TAA has been described so far. We recently reported on the overexpression of HLA class II in AML cells as compared to autologous monocytes and granulocytes as well as on the first HLA class I leukemia associated antigens identified directly on the cell surface of primary AML cells (Stickel et. al. abstract in Blood 2012). In this study we characterized the HLA class II ligandome in AML to identify additional ligands for a peptide-based immunotherapy approach. HLA class II ligands from primary AML cells as well as bone marrow and peripheral blood mononuclear cell (BMNCs/PBMCs) of healthy donors were analyzed using the approach of direct isolation and identification of naturally presented HLA peptides by affinity chromatography and mass spectrometry (LC-MS/MS). LC-MS/MS peptide analysis provided qualitative and semi-quantitative information regarding the composition of the respective ligandomes. Comparative analysis of malignant and benign samples served to identify ligandome-derived tumor associated antigens (LiTAAs) and to select peptide vaccine candidates. Most abundantly detected peptides were functionally characterized with regard to their ability to induce a specific CD4+ T-cell response in healthy donors and in tumor patients using ELISpot. Samples from 10 AML patients (5 FLT3-ITD mutated) and 18 healthy donors were analyzed. We identified more than 2,100 AML-derived HLA class II ligands representing >1,000 different source proteins, of which 315 were exclusively represented in AML, but not in healthy PBMC/BMNC. Data mining for broadly represented LiTAAs pinpointed 26 HLA class II ligands from 8 source proteins that were presented exclusively on more than 40% of all analyzed AML samples as most promising targets. Amongst them were already described TAAs (e.g., RAB5A) as well as several so far understated proteins (e.g. calsyntenin 1, glycophorin A, mannose-binding lectin 2). Subset analysis revealed 58 LiTAAs presented exclusively on FLT3-ITD mutated AML cells. Additional screening for HLA class II ligands from described leukemia associated antigens showed positive results for NPM1 (1 peptide sequence) and MPO (13 peptide sequences). Peptides from calsyntenin 1 and RAB5A were able to elicit CD4+-T-cell response in 25% of tested AML patients (n=16). Thus, our study identified, for the first time, HLA class II tumor associated antigens directly obtained from the HLA ligandomes of AML patients and thereby represents a further step to our goal of developing a multipeptide vaccine for immunotherapy of AML. Disclosures: No relevant conflicts of interest to declare.

scholarly journals Identification of Naturally Presented HLA Ligands of Enriched Leukemic Progenitor Cells for Peptide-Based Immunotherapy in Acute Myeloid Leukemia (AML)

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 4046-4046 ◽  
Author(s):  
Annika Nelde ◽  
Heiko Schuster ◽  
Daniel J. Kowalewski ◽  
Lothar Kanz ◽  
Helmut R. Salih ◽  
...  
Keyword(s):  
Stem Cell ◽  
T Cell ◽  
Progenitor Cells ◽  
Hla Class I ◽  
Class Ii ◽  
Hla Class Ii ◽  
Class I ◽  
Isolation And Identification ◽  
Hla Ligands ◽  
Hla Ligandome

Abstract Several studies demonstrated that peptide-based cancer immunotherapy can induce specific immune responses and affect clinical outcome in a variety of different cancer entities. We recently conducted a study, which directly characterized the antigenic landscape of acute myeloid leukemia (AML) by mass spectrometric analysis of naturally presented HLA ligands and identified a panel of AML-specific CD4+ as well as CD8+ T-cell epitopes as suitable targets for T-cell based immunotherapy (Berlin et al. Leukemia 2015). One main reason for the high relapse rates in AML patients after standard polychemotherapy and allogeneic stem cell transplantation is the presence of minimal residual disease (MRD), which is associated with the persistence of leukemic stem cells (LSCs) in the bone marrow of patients. For clinically effective immunotherapy it is therefore indispensable to target the highly chemotherapy resistant LSCs. Here we present a mass spectrometry-based study, which for the first time analyzes the naturally presented HLA ligandome of stem cell enriched (LSCenr) fractions of primary AML samples to identify novel LSC-associated antigens using the approach of direct peptide isolation and identification. The enrichment of LSCs was performed using fluorescence-activated cell sorting of the originally described phenotype of lineage-negative CD34+CD38- cells of PBMCs from eight AML patients. The original stem cell containing population of 1-3% within the PBMCs of most patients was enriched to >90% purity with cell counts of 20-200x106 for the LSCenr fraction per sample. Consistent with our own previous results, all samples showed comparable expression levels of HLA class I molecules on primary leukemia blasts as well as for the LSCenr fractions, with HLA class I molecule counts ranging from 145,000 to 175,000 molecules/cell for the LSCenr fractions. To specifically identify leukemia-associated antigens on LSCenr cells, the HLA ligandome results obtained from the sorted LSCenrfractions were combined with data acquired from AML blasts of 20 AML patients (HLA class I n=19, HLA class II n=20) in previous studies as well as our normal tissue database that comprises 153 HLA class I and 82 HLA class II ligandomes of various healthy tissues (e.g. blood, bone marrow, spleen, kidney, liver, brain, skin, ovary, bowl). We identified more than 14,600 different naturally presented HLA class I ligands representing ̴6,500 source proteins on LSCenr fractions of primary AML samples (n=8) and their autologous blast cells by mass spectrometry. Overlap analysis of the HLA class I ligandomes of LSCenr fractions and autologous AML blasts with the benign peptidome revealed 45.4% (3,132/6,896) and 40.2% (4,922/12,244) of the LSCenr fraction and the autologous AML blast ligandomes to be represented in the benign-associated HLA ligandome, respectively. 79.1% (5,458/6,896) of the mapped LSCenr fraction ligandome was also presented on autologous AML blasts. 1,029 (14.9%) of these identified HLA class I ligands were presented exclusively on LSCenr fractions and not found on autologous AML blasts, previously analyzed AML blasts or any benign tissue. Furthermore, we were able to identify more than 8,000 different naturally presented HLA class II ligands representing ̴1,700 source proteins. Overlap of the HLA class II ligandomes revealed 45.0% (2,800/4,624) and 39.9% (2,706/6,790) of the LSCenr fraction and autologous AML blast ligandomes to be represented in the benign-associated HLA ligands, respectively. The HLA ligandomes of the LSCenr fraction and the autologous AML blasts showed an overlap of 69.7% (3,224/4,624). 941 (11.5%) HLA class II ligands showed exclusive representation in the LSCenr fraction ligandomes and were never identified on AML blast or benign tissue. These LSC-associated peptides represent highly interesting targets for immunotherapeutic approaches in AML patients and will be further evaluated for their potential to elicit a specific T-cell response. Taken together these preliminary results prove the feasibility of our approach to enrich leukemic progenitor cells of primary AML samples for the successful isolation and identification of HLA presented peptides associated with enriched leukemic progenitor cells. Disclosures Schuster: Immatics Biotechnologies GmbH: Employment. Kowalewski:Immatics Biotechnologies GmbH: Employment.

Identification of Four New HLA Class II Restricted Minor Histocompatibility Antigens Contributing to Graft Versus Leukemia Reactivity.

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 3247-3247
Author(s):  
Anita N. Stumpf ◽  
Edith D. van der Meijden ◽  
Cornelis A.M. van Bergen ◽  
Roelof Willemze ◽  
J.H. Frederik Falkenburg ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cd4 T Cells ◽  
Hla Class I ◽  
Class Ii ◽  
Hla Class Ii ◽  
Cd4 T Cell ◽  
Class I ◽  
T Cell Clones ◽  
Cell Clones

Abstract Patients with relapsed hematological malignancies after HLA-matched hematopoietic stem cell transplantation (HSCT) can be effectively treated with donor lymphocyte infusion (DLI). Donor-derived T cells mediate beneficial graft-versus-leukemia (GvL) effect but may also induce detrimental graft-versus-host disease (GvHD). These T cell responses are directed against polymorphic peptides which differ between patient and donor due to single nucleotide polymorphisms (SNPs). These so called minor histocompatibility antigens (mHag) are presented by HLA class I or II, thereby activating CD8+ and CD4+ T cells, respectively. Although a broad range of different HLA class I restricted mHags have been identified, we only recently characterized the first autosomal HLA class II restricted mHag phosphatidylinositol 4-kinase type 2 beta (LB-PI4K2B-1S; PNAS, 2008, 105 (10), p.3837). As HLA class II is predominantly expressed on hematopoietic cells, CD4+ T cells may selectively confer GvL effect without GvHD. Here, we present the molecular identification of four new autosomal HLA class II restricted mHags recognized by CD4+ T cells induced in a patient with relapsed chronic myeloid leukemia (CML) after HLAmatched HSCT who experienced long-term complete remission after DLI with only mild GvHD of the skin. By sorting activated CD4+ T cells from bone marrow mononuclear cells obtained 5 weeks after DLI, 17 highly reactive mHag specific CD4+ T cell clones were isolated. Nine of these T cell clones recognized the previously described HLADQ restricted mHag LB-PI4K2B-1S. The eight remaining T cell clones were shown to exhibit five different new specificities. To determine the recognized T cell epitopes, we used our recently described recombinant bacteria cDNA library. This method proved to be extremely efficient, since four out of five different specificities could be identified as new HLA-class II restricted autosomal mHags. The newly identified mHags were restricted by different HLA-DR molecules of the patient. Two mHags were restricted by HLA-DRB1 and were found to be encoded by the methylene-tetrahydrofolate dehydrogenase 1 (LBMTHFD1- 1Q; DRB1*0301) and lymphocyte antigen 75 (LB-LY75-1K; DRB1*1301) genes. An HLA-DRB3*0101 restricted mHag was identified as LB-PTK2B-1T, which is encoded by the protein tyrosine kinase 2 beta gene. The fourth mHag LB-MR1-1R was restricted by HLA-DRB3*0202 and encoded by the major histocompatibility complex, class I related gene. All newly identified HLA class II restricted mHags exhibit high population frequencies of 25% (LB-MR1-1R), 33% (LB-LY75-1K), 68% (LB-MTHFD1- 1Q), and 70% (LB-PTK2B-1T) and the genes encoding these mHags show selective (LY- 75) or predominant (MR1, MTHFD1, PTK2B) expression in cells of hematopoietic origin as determined by public microarray databases. All T cell clones directed against the newly identified mHags recognized high HLA class II-expressing B-cells, mature dendritic cells (DC) and in vitro cultured leukemic cells with antigen-presenting phenotype. The clone recognizing LB-MTHFD1-1Q also showed direct recognition of CD34+ CML precursor cells from the patient. In conclusion, we molecularly characterized the specificity of the CD4+ T cell response in a patient with CML after HLA-matched HSCT who went into long-term complete remission after DLI. By screening a recombinant bacteria cDNA library, four new different CD4+ T cell specificities were characterized. Our screening method and results open the possibility to identify the role of CD4+ T cells in human GvL and GvHD, and to explore the use of hematopoiesis- and HLA class II-restricted mHag specific T cells in the treatment of hematological malignancies.

HLA Ligandome Analysis of Different Hematological Malignancies Identifies a Small Panel of "Pan-Leukemia"-Associated Antigens

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 2169-2169
Author(s):  
Linus Backert ◽  
Daniel J. Kowalewski ◽  
Simon D. Walz ◽  
Heiko Schuster ◽  
Claudia Berlin ◽  
...  
Keyword(s):  
T Cell ◽  
Myeloid Leukemia ◽  
Research Funding ◽  
Hematological Malignancies ◽  
Hla Class I ◽  
Class Ii ◽  
Hla Class Ii ◽  
Class I ◽  
Hla Ligands ◽  
Hla Ligandome

Abstract Effective antigen-specific T-cell-based cancer immunotherapy requires exact knowledge of tumor-associated epitopes that can act as rejection antigens. While the current paradigm views mutation-derived neoantigens as the most promising targets, we have recently demonstrated that tumor-specific T-cell responses target panels of non-mutated tumor-associated self antigens in patients with hematological malignancies. Using the approach of direct HLA ligandome analysis by mass spectrometry, we were able to identify and characterize multiple immunogenic and naturally presented tumor-associated antigens for chronic lymphocytic leukemia (CLL, Kowalewski et. al., PNAS 2015), acute myeloid leukemia (AML, Berlin/Kowalewski et. al., Leukemia 2014), multiple myeloma (MM, Walz/Stickel et. al., Blood 2015) and chronic myeloid leukemia (CML, unpublished data). In this project we performed a comprehensive meta-analysis of our HLA ligandome data from different hematological malignancies (HM) to screen for the existence of "pan-leukemia" antigens for the broad application in T-cell based immunotherapy approaches in hematological malignancies. In a first step we performed unsupervised cluster analyses to identify similarities and differences in the HLA ligandome landscape of HM. To avoid skewed clustering due to HLA types of the samples, these analyses were performed specifically for the most common HLA allotypes in our datasets (A*02 (n=46 HM), A*03 (n=28 HM)). Distinct clustering was shown for the different entities (CLL, MM, CML, AML) as well as for the lymphoid versus myeloid malignancies on the HLA ligandome level. To identify leukemia-exclusive HLA ligands we compared the HLA ligandomes of CLL (HLA class I, n=35; HLA class II, n=30), AML (HLA class I, n=19; HLA class II, n=20), MM (HLA class I, n=15; HLA class II n=12) and CML (HLA class I, n=16; HLA class II n=15) with our normal tissue database including 153 HLA class I and 82 HLA class II ligandomes of various normal tissues (including normal blood, bone marrow and spleen). Cluster analysis of the leukemia-exclusive antigens showed identical clustering of the different entities and lymphoid/myeloid malignancies as shown before for the whole HLA ligandome and the respective source proteins. Overlap analysis revealed only 0.6% (16/2,716) and 0.3% (10/3,141) of the identified leukemia-exclusive HLA class I and class II antigens, respectively, to be represented across all analyzed hematological malignancies. These "pan-leukemia" antigens (n=26) include candidate antigens associated with T-cell activation (HSH2D), lymphoid development (IL2RF) and oncogenesis (LYN protooncogene, RAB5A). However, none of these "pan-leukemia" antigens shows frequent representation (>20%) across all 4 entities (CLL, AML, MM, CML). Furthermore, none of the "pan-leukemia" source proteins yielded corresponding peptides represented in all entities. To identify "pan-leukemia" HLA ligands, overlap analyses were performed in an allotype-specific fashion for the most frequent HLA allotypes (HLA-A*01, -A*02, -A*03, -A*24, -B*07, -B*08, -B*18) in our cohort. 0% (0/92) of HLA-A*01-, 1.6% (12/744) of HLA-A*02-, 1.4% (8/561) of HLA-A*03-, 0% (0/331) of HLA-A*24-, 0.1% (1/830) of HLA-B*07-, 0% (0/472) of HLA-B*08- and 0.8% (5/600) of the HLA-B*18-restricted peptides showed representation in all four entities. Out of these 26 "pan-leukemia" HLA ligands, only two (1 HLA-A*02-, 1 HLA-A*03-restricted peptide) showed frequent representation (>20%) in all entities. These peptides represent "pan-leukemia" targets that might be used for immunotherapeutic approaches in patients expressing the respective HLA allotype. Taken together, our approach of direct HLA ligandome analysis of hematological malignancies identified a small panel of "pan-leukemia"- proteins and peptides that show cancer-exclusive representation across all 4 included hematological malignancies. However, due to the low presentation frequencies of the candidate targets within the different entities, target discovery and compound development for the immunotherapy of HM may be more effectively achieved in an entity-specific or even patient-individualized manner. Disclosures Kowalewski: Immatics Biotechnologies GmbH: Employment. Schuster:Immatics Biotechnologies GmbH: Employment. Brümmendorf:Pfizer: Consultancy, Honoraria; Ariad: Consultancy, Honoraria; Bristol-Myers Squibb: Consultancy, Honoraria; Novartis: Consultancy, Honoraria, Research Funding; Patent on the use of imatinib and hypusination inhibitors: Patents & Royalties. Niederwieser:Novartis Oncology Europe: Research Funding, Speakers Bureau; Amgen: Speakers Bureau. Weisel:Celgene: Consultancy, Honoraria, Research Funding; Janssen: Consultancy, Honoraria, Research Funding; Amgen: Consultancy, Honoraria; Onyx: Consultancy; BMS: Consultancy, Honoraria; Takeda: Consultancy, Honoraria; Novartis: Honoraria.

Specificity, degeneracy, and molecular mimicry in antigen recognition by HLA-Class II restricted T cell receptors: implications for clinical medicine

2003 ◽  
Vol 13 (3) ◽  
pp. 205-214
Author(s):  
Yasushi Uemura ◽  
Satoru Senju ◽  
Shinji Fujii ◽  
Leo Kei Iwai ◽  
Katsumi Maenaka ◽  
...  
Keyword(s):  
T Cell ◽  
T Cell Receptors ◽  
Clinical Medicine ◽  
Molecular Mimicry ◽  
Class Ii ◽  
Hla Class Ii ◽  
Antigen Recognition ◽  
Cell Receptors

scholarly journals Mapping the HLA Ligandome Landscape of Chronic Myeloid Leukemia Identifies Novel CD8+ and CD4+ T Cell-Epitopes for Immunotherapeutic Approaches

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 4232-4232
Author(s):  
Tatjana Bilich ◽  
Annika Nelde ◽  
Daniel J. Kowalewski ◽  
Janet Peper ◽  
Mirle Schemionek ◽  
...  
Keyword(s):  
T Cell ◽  
Immune Responses ◽  
Hla Class I ◽  
Class Ii ◽  
Hla Class Ii ◽  
Class I ◽  
Hla Ligands ◽  
Tki Treatment ◽  
Positive Controls

Abstract While the discovery of BCR-ABL and the respective tyrosine kinase inhibitors (TKI) resulted in a significant prolongation of patient survival rates, there still is no curative treatment for chronic myeloid leukemia (CML) except for allogeneic stem cell transplantation. The concept of T cell-based immunotherapy is a promising opportunity to eliminate residual leukemic cells, which might promote disease relapse after TKI discontinuation. As effective antigen-specific immunotherapy requires exact knowledge of tumor-associated epitopes that can act as rejection antigens, we have developed a mass spectrometry-based approach, which allows for the direct identification of naturally presented tumor-associated HLA ligands in hematological malignancies. In this study we used this approach to identify HLA class I and II CML-associated peptides as targets for T cell-based immunotherapy. Analysis of HLA class I ligandomes of primary CML cells (n=16) identified 8,291 HLA ligands representing 4,337 source proteins. Comparative ligandome profiling using a benign HLA class I database, which includes various healthy tissues (n=188, 65,949 HLA ligands, 14,030 source proteins) originating from peripheral blood, bone marrow, kidney, lung, liver, colon, spleen and others, revealed 38 CML-exclusive HLA class I ligands with frequencies ≥ 25% of CML patients. Because of the important indirect and direct roles of CD4+ T cells in anti-cancer immune responses, an optimal immunotherapy approach requires the inclusion of HLA class II epitopes. Hence we also analyzed the HLA class II ligandomes of primary CML cells (n=15, 2,822 HLA ligands, 794 source proteins). Comparative ligandome analysis (benign tissue, n=114, 54,149 HLA ligands, 8,584 source proteins) identified 44 CML-associated HLA class II ligands showing CML-exclusive representation in > 25% of the analyzed CML samples. To validate the immunogenicity of our HLA class I and II CML-associated peptides, we performed IFNγ- ELISPOT assays after 12-days of in vitro peptide stimulation. For HLA class II antigens, a panel of 4 peptides was implemented for stimulation of PBMCs obtained from CML patients and healthy volunteers (HV). The ELISPOT assay revealed peptide-specific immune recognition of 4/4 (100%) CML-exclusive peptides in CML patients. The frequencies of the detected immune responses ranged from 17% (4/23 patients) to 4% (1/23 patients) within the tested CML samples. These immune responses were mediated by functional CML patient-derived CD4+ T cells and strictly CML-directed, as no immune response against CML-associated peptides could be detected in HV (0/8). For HLA class I antigens, ELISPOT assays were performed using a panel of 8 peptides. Immune responses were only detected for 1/8 (13%) peptides with a low frequency of 6% (1/18 patients) of tested CML patient samples. A possible explanation for the observed weak immune response to our HLA class I CML-associated peptides compared to the immune responses shown for HLA class II peptides and for HLA class I peptides in other hematological malignancies (e.g. CLL (Kowalewski et. al. PNAS 2015)) might be an inhibition of CD8+ T cell-responses, that reportedly occurs upon TKI treatment of CML patients. To prove this hypothesis in our CML patient cohort (all patients included were under TKI treatment at the time of sample collection), we compared the ELISPOT positive controls (stimulated with a set of 5 Epstein-Barr viral peptides) of all analyzed CML samples with positive controls derived from HV and CLL samples. We could show a highly significant mean spot count reduction (per 100,000 cells) in CML samples (mean 74±16 spots, n=19) compared to HV (mean 241±24 spots, n=42, p<0.001, two-tailed t-test) or CLL (mean 218±16 spots, n=125, p=0.008) samples, confirming the general debilitated CD8+ T cell-response in CML patients under TKI treatment. To prove the immunogenicity of our HLA class I CML-associated peptides, we performed in vitro artificial antigen-presenting cell (aAPC)-based priming experiments of HV CD8+ cells. For one HLA-A*03-restricted peptide we observed tetramer-positive CD8+ populations with frequencies ranging from 0.12% to 1.41% of viable cells in 2/2 HVs so far. Taken together, these results are a first step towards a successful validation of these newly defined HLA class I and II CML-associated antigens as prime targets for further T cell-based immunotherapy approaches in CML patients. Disclosures Kowalewski: Immatics Biotechnologies GmbH: Employment. Brümmendorf:Ariad: Consultancy, Honoraria; Bristol-Myers Squibb: Consultancy, Honoraria; Pfizer: Consultancy, Honoraria; Novartis: Consultancy, Honoraria, Research Funding; Patent on the use of imatinib and hypusination inhibitors: Patents & Royalties. Niederwieser:Amgen: Speakers Bureau; Novartis Oncology Europe: Research Funding, Speakers Bureau.

scholarly journals Characterization of cells emerging at the time of graft failure after bone marrow transplantation from an unrelated marrow donor

Blood ◽  
1993 ◽  
Vol 82 (3) ◽  
pp. 1023-1029 ◽  
Author(s):  
J Donohue ◽  
M Homge ◽  
NA Kernan
Keyword(s):  
T Cell ◽  
Mononuclear Cells ◽  
Hla Class I ◽  
Class Ii ◽  
Hla Class Ii ◽  
Class I ◽  
Unrelated Donor ◽  
Peripheral Blood Mononuclear ◽  
Hla Dr

Abstract To help elucidate the mechanism responsible for graft failure (GF) following a T-cell depleted bone marrow transplant (BMT) from an unrelated donor, five patients (2 chronic myelogenous leukemia, 1 acute undifferentiated leukemia, 2 myelodysplastic syndrome) who experienced this complication were studied. All patients were HLA class I identical with their donors as determined by serology and one-dimensional isoelectric focusing (IEF); two were serologically matched with their donors for HLA class II antigens, whereas three donor-recipient pairs were serologically mismatched for one HLA-DR antigen. All patients received total body irradiation (fractionated, 1,500 rads), VP-16 (750 mg/m2), and cyclophosphamide (120 mg/kg) pre-BMT and antithymocyte globulin (15 mg/kg every other day) and methylprednisolone (2 mg/kg) post-BMT. Three patients experienced primary nonengraftment and two experienced secondary GF. Peripheral blood mononuclear cells obtained from the patients at the time of GF were studied to examine their functional and phenotypic characteristics. Emerging cells were of host origin and were found to be specifically cytotoxic to donor target cells and suppressive to the in vitro growth of donor BM, especially in the cases of primary nonengraftment. Peripheral blood mononuclear cells from these patients were expanded to form T-cell lines (TcLs). The cytotoxic activities of TcLs were tested in the presence of blocking MoAbs directed against various HLA determinants in an attempt to determine if HLA antigens expressed on donor cells were the target for cytotoxicity. The observed cytotoxic activity was blocked by antibodies to HLA-B, -C (1 patient), HLA-DR (1 patient), and HLA-DQ (1 patient). In two cases, antidonor cytotoxicity could not be blocked by MoAb directed against HLA-A, -B, -C, or -DR. Phenotypic characterization of four successfully maintained TcLs showed 100% CD3+ cells with 100% CD4+ (3 patients) or 50% CD4+/50% CD8+ (1 patient). In two of the three patients with 100% CD4+ cells, antidonor cytotoxicity was blocked by an anti-HLA class II MoAb. In contrast to our previous findings in cases of GF following T-cell-depleted HLA nonidentical family member BMT in which host T cells were CD8+ and cytotoxicity was directed against HLA class I antigens, our present study indicates host T cells emerging at the time of GF following BMT from an HLA class I IEF-identical unrelated donor can be of the CD4+ subset and seem to be capable of recognizing antigenic disparities in the HLA class II region.

scholarly journals The HLA Ligandome Landscape of Chronic Myeloid Leukemia Delineates Novel T-Cell Epitopes for Immunotherapy

Blood ◽  
2018 ◽  
Vol 132 (Supplement 1) ◽  
pp. 4243-4243
Author(s):  
Tatjana Bilich ◽  
Annika Nelde ◽  
Leon Bichmann ◽  
Helmut R. Salih ◽  
Daniel Johannes Kowalewski ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Myeloid Leukemia ◽  
Research Funding ◽  
Hla Class I ◽  
Class Ii ◽  
Hla Class Ii ◽  
Class I ◽  
Cell Responses ◽  
Tki Treatment

Abstract Chronic myeloid leukemia (CML) is characterized by the translocation t(9;22), which leads to the formation of the BCR-ABL fusion transcript. Several approved tyrosine kinase inhibitors (TKIs) target the resulting fusion protein, leading to an improved prognosis of CML patients. Currently, the main treatment goal is the achievement of a deep molecular response (MR), in which TKI therapy can be terminated. Several studies provide evidence that immunological control plays a major role for the course of CML and contributes to the achievement of deep MR in CML patients under TKI treatment (CMLTKI). This implies that reinforcing these immune responses might sustain long-term TKI-free survival or even cure for CML patients. Besides unspecific immunotherapy, such as interferon or immune checkpoint blocking antibodies, a more specific and minor side effect targeting of CML cells might be achieved by antigen-specific immunotherapy approaches. The prerequisite for such strategies is the identification of T-cell targets represented by tumor-associated human leukocyte antigen (HLA)-presented peptides on malignant cells. In this study, we used a mass spectrometry-based approach to identify naturally presented, CML-associated peptides in primary CML samples (HLA class I, n=21, 11,945 peptides, 5,478 source proteins; class II, n=20, 5,991 peptides, 1,302 proteins). Comparative HLA peptidome profiling using a comprehensive dataset of various benign tissues (e.g. blood, bone marrow, spleen, and lung) revealed frequently presented and strictly CML-associated antigens. In detail, the benign tissue dataset comprises hematological benign samples (class I, n=108, 51,233 peptides, 11,437 proteins; class II, n=88, 42,753 peptides, 4,877 proteins) and non-hematological benign tissues (28 tissues, n=166; class I, 128,590 peptides, 16,405 proteins; class II, 143,652 peptides, 13,410 proteins). We identified 50 CML-associated, HLA class I-restricted peptides with HLA allotype adjusted representation frequencies of ≥38% presented on HLA-A*02, -A*03, -A*11, and -B*07. HLA class II comparative profiling delineated 36 peptides exclusively and frequently presented in the HLA peptidome of ≥20% analyzed CML patients. For immunological characterization, we selected 8 HLA class I- and 6 class II-restricted highly CML-associated antigens. These peptides were analyzed in IFNγ ELISPOT assays using PBMCs from CMLTKI patients and healthy volunteers (HVs). Peptide-specific immune recognition was detected for 1/8 (13%) HLA class I peptides in 2/17 (12%) of CMLTKI patients. We hypothesized that this weak immune response might be due to an impaired CD8+ T cell function that reportedly is caused by TKI treatment. Thus, we compared T-cell responses against viral epitopes in IFNγ ELISPOT assays of CMLTKI patients with that of HVs and chronic lymphocytic leukemia (CLL) patients: in line with our hypothesis, we observed significantly reduced IFNγ release of T cells from CMLTKI patients compared to HVs and CLL patients (p<0.001), whereas CD8+ T-cell counts were not reduced. In contrast, no reduced IFNγ production was observed for HLA class II-restricted viral epitopes. These results were confirmed by memory T-cell responses detected for 6/6 (100%) HLA class II CML-associated peptides with frequencies up to 24% (4/17) of analyzed CMLTKI patients. To assess the immunogenicity of all HLA class I peptides, we performed in vitro artificial antigen presenting cell-based priming experiments using CD8+ T cells of HVs and CML patients. Effective priming of T cells was observed for 8/8 CML-associated peptides in ≥70% of analyzed HVs with frequencies of 0.1-33.9% (mean 2.2%) of CD8+ peptide-specific T cells. Notably, peptide-specific CD8+ T cells with frequencies of 0.1-2.2% (mean 0.4%) could also be induced in samples of CMLTKI patients that had not displayed preexisting immune responses. For 6/8 peptides, we observed multifunctionality of peptide-specific T cells by IFNγ and TNF production as well as upregulation of the degranulation marker CD107a. Cytotoxicity assays with polyclonal peptide-specific effector T cells confirmed the capacity to induce antigen-specific lysis for 3/4 analyzed peptides. Taken together, we here identified novel, naturally presented, CML-associated antigens and validated them as promising targets for tailored T cell-based immunotherapeutic approaches for CML patients. Disclosures Salih: Several patent applications: Patents & Royalties: e.g. EP3064507A1. Kowalewski:Immatics Biotechnologies GmbH: Employment. Schuster:Immatics Biotechnologies GmbH: Employment. Brümmendorf:Pfizer: Consultancy, Research Funding; Novartis: Consultancy, Research Funding; Janssen: Consultancy; Merck: Consultancy; Takeda: Consultancy. Niederwieser:Miltenyi: Speakers Bureau; Novartis: Research Funding.

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