Project description:The immune response against tuberculosis relies, at least in part, on CD4+ T cells. Protective vaccines require the induction of antigen-specific CD4+ T cells via mycobacterial peptides presented by MHC class-II in infected macrophages. We have purified MHC class-I and MHC-II peptides and analysed them by mass spectrometry. We have successfully identified 97 mycobacterial peptides presented by MHC-II and 54 presented by MHC-I, from 76 and 41 antigens, respectively. The sequences of selected peptides were confirmed by spectral match validation and immunogenicity evaluated by IFN-gamma ELISpot against peripheral blood mononuclear cells from volunteers vaccinated with BCG, M.tb latently infected subjects or patients with tuberculosis disease. Three antigens were expressed in viral vectors, and evaluated as vaccine candidates alone or in combination in a murine aerosol M.tb challenge model. When delivered in combination, the three candidate vaccines conferred significant protection in the lungs and spleen compared with BCG alone, demonstrating proof-of-concept for this unbiased approach to identifying novel candidate antigens.

Project description:This study aimed to identify Tumor Associated Antigens (TAA)s by Immunoaffinity purification of MHC peptides and LCMS analysis, verifying their immunogenicity and testing their tumor control potential in a highly aggressive preclinical model of triple-negative breast cancer in mice. Among the MHC peptides thus identified, an Endogenous Retroviral (ERV) peptide was also found, and this peptide, as well as several other peptides from TAAs, were shown to possess tumor control potential in a cancer vaccine setting in mice, by restricting tumor growth compared to controls.

Project description:Tuberculosis (TB), caused by Mycobacterium tuberculosis (Mtb), is a leading cause of infectious disease mortality worldwide for which no sufficiently protective vaccine exists. CD8+ T cells contribute to protective immunity to TB, but the antigenic targets presented on MHC-I by macrophages infected with virulent Mtb for recognition by CD8+ T cells have not been conclusively defined. Here, we use mass spectrometry to directly identify Mtb-derived peptides presented on MHC class I (MHC-I) by infected primary human monocyte-derived macrophages. We identified 16 MHC-I peptides derived from 12 Mtb proteins, and validated these identifications using internal standard parallel reaction monitoring (SureQuant). Our results show that this set of antigens is highly enriched for substrates of type VII secretion systems (T7SS) relative to the Mtb proteome. Our results identify specific Mtb proteins that may be suitable targets for subunit vaccines designed to elicit protective CD8+ T cell-mediated immunity and suggest that T7SS substrates may be a fruitful class of antigens to prioritize for further vaccine target discovery efforts. Note: donors labeled A, C, D, E, H, and I in file names here are renamed sequentially (A, B, C, D, E, and F) in the manuscript describing this study to avoid confusion.

Project description:The array of peptides presented to CD8+ T cells by major histocompatibility complex (MHC) class I molecules is referred to as the MHC class I immunopeptidome. Although the MHC class I immunopeptidome is ubiquitous in mammals and represents a critical component of the adaptive immune system, very little is known about its baseline composition across all tissues and organs in vivo. In this study, we applied mass spectrometry (MS) technologies to draft a tissue-based atlas of the MHC class I immunopeptidome in the C56BL/6 mouse model. Overall, 19 normal mouse tissues were extracted and a total number of ~30,000 high-confidence H2Db/Kb-associated peptides were identified and annotated in the atlas. The raw MS output files, the catalogue of H2Db/Kb-associated peptides, the tissue origin(s) of individual peptides and the H2Db/Kb-specific peptide spectral libraries, which consist of consensus spectra calculated from repeat measurements of the same peptide sequence, were shared via the SysteMHC Atlas project (dataset identifier SYSMHC00018). We expect that this unique dataset will be further expended in the future and will be re-used by the community to 1) investigate the tissue-specificity of the immunopeptidome, 2) perform highly reproducible spectral library-based analysis of immunopeptidomes from mice cohorts, and 3) rapidly identify disease-specific H2Db/Kb peptide antigens from various mouse models of autoimmune diseases and cancers.

Project description:We sought to build a catalog of epitopes presented by breast cancers using a renewable resource of well-characterized breast cancer cell lines. Starting from 70 breast cancer cell lines, we measured MHC class I abundance and used pre-existing RNAseq data to identify either HLA-A*02 or MHC class I-positive cell lines. For 20 of these cell lines, we used “reverse” immunogenetics, in which MHC class I-loaded peptides are recovered and their sequences are determined by mass spectrometry. We identified more than 2,700 unique MHC class I-bound peptides from a panel of basal, luminal, and claudin-low subtype of cell lines. HLA-A*02 binding prediction across all tested cell lines revealed a model which described the distribution of HLA-A*02-binding peptides and allowed us to identify those peptides most likely to be presented on HLA-A*02. Comparing the peptides that we identified to published literature found that more than 1500 peptides had been identified in previous studies and that 18 of these peptides have been shown to be immunogenic. Overall, this high throughput identification of MHC class I-loaded peptides is an effective strategy for systematic characterization of cancer epitopes and could be employed in a design of multipeptide-based anticancer vaccine.

Project description:Defining the repertoire of peptides presented by the major histocompatibility complex class I (MHC I) is a key step towards the identification of relevant antigens for cancer immunotherapy. However, the identification of the cancer-specific antigens is a significant analytical challenge in view of their low abundance and low mutational load found in primary cancer specimens. Here, we describe the application of isobaric peptide labeling with tandem mass tag (TMT) to improve the detection of the MHC I peptides. Isobaric peptide labeling was found to promote the formation of multiply-charged ions and to enhance the formation of b-type fragment ions, thus resulting in a 50% improvement of MHC I peptide identification. The gain in sensitivity obtained using TMT labeling enabled the detection of low abundance MHC I peptides including tumor-specific antigens (TSAs) and minor histocompatibility antigens (MiHAs). We further demonstrate the application of this approach to quantify MiHAs presented by B-cell lymphocytes and determined their expression levels by LC-MS/MS using both synchronous precursor selection (SPS) and high field asymmetric waveform ion mobility spectrometry (FAIMS).

Project description:The elucidation of therapy-induced changes to the class I major histocompatibility complex (MHC-I)-bound tumor antigens is crucial for understanding immune-mediated tumor eradication and identifying potential targets for peptide vaccines to enhance the efficacy of immunotherapies. Here, we investigated how oncolytic reovirus therapy with and without immune checkpoint blockade (ICB) alters the tumor peptide-MHC repertoire. Using mass spectrometry analysis of immunoaffinity purified MHC peptides, we first showed that changes to the MHC immunopeptidome following reovirus treatment is cancer type-dependent, where a murine fibrosarcoma model displayed quantitative and qualitative variance in differentially expressed peptides (DEPs) as compared to those identified in a murine ovarian cancer model. We then determined that the combination therapy of reovirus and ICB in the fibrosarcoma model resulted in higher numbers of DEPs relative to either monotherapy alone. Most importantly, we identified reovirus and ICB-induced MHC peptides that are biologically active in stimulating interferon-gamma response in cognate CD8+ T cells, which likely contribute to cancer immunoediting. These findings highlight the importance of therapy-induced changes to the MHC immunopeptidome in shaping the underlying anti-tumor immune responses during reovirus and ICB combination therapy.

Project description:The T cell response to Chlamydia genital tract infections in humans and mice is unusual in that the majority of antigen-specific CD8 T cells are not restricted by HLA/MHC class I and therefore have been referred to as “unrestricted” or “atypical”.   We previously reported that a subset of unrestricted murine Chlamydia-specific CD8 T cells had an unusual cytokine polarization pattern that included IFN-ɣ and IL-13.  For this report, we investigated the transcriptome of Chlamydia-specific CD8ɣ13 T cells, comparing them to Chlamydia-specific multifunctional Tc1 clones using gene expression micro array analysis.  The molecular study revealed that CD8ɣ13 polarization included IL-5 in addition to IFN-γ and IL-13.  Adoptive transfer studies were performed with Tc1 clone and CD8ɣ13 T cell clones to determine whether either influenced bacterial clearance or immunopathology during Chlamydia muridarum (Cm) genital tract infections.  To our surprise, an adoptively transferred CD8ɣ13 T cell clone was remarkably proficient at preventing chlamydia immunopathology while the multifunctional Tc1 clone did not enhance clearance or significantly protect from immunopathology.  Mapping studies with MHC class I- and class II-deficient splenocytes showed our previously published Chlamydia-specific CD8 T cell clones are MHC class II-restricted.   MHC class II-restricted CD8 T cells may play important roles in protection from intracellular pathogens that limit class I antigen presentation or deplete the CD4 T cell compartment.

Project description:Immunoglobulin gene rearrangement and somatic hypermutation have the potential to create neoantigens in non-Hodgkin B cell lymphoma. However, the presentation of these putative immunoglobulin neoantigens by B cell lymphomas has not been proven. We used MHC immunoprecipitation followed by liquid chromatography and tandem mass spectrometry (LC-MS/MS) to define antigens presented by follicular lymphomas (FL), chronic lymphocytic leukemias (CLL), diffuse large B cell lymphoma (DLBCL) and mantle cell lymphomas (MCL). We found presentation of the clonal immunoglobulin molecule, including neoantigens by both class I and class II MHC, though more commonly in class II MHC. To determine whether B cell activation could promote presentation of immunoglobulin neoantigens, we used a toll-like receptor 9 (TLR9) agonists to upregulate expression of MHC-II. This resulted in enhanced class II MHC presentation of the immunoglobulin variable region including neoantigens. These findings demonstrate that immunoglobulin neoantigens are presented across most subtypes of B cell lymphomas. Activation of lymphoma cells to upregulate antigen presentation boosts presentation of immunoglobulin neoantigens and represents a strategy for augmenting lymphoma immunotherapies.

Project description:Immunopeptidomics is an emerging field that fuels and guides the development of vaccines and immunotherapies. More specifically, it refers to the science of investigating the composition of peptides presented by major histocompatibility complex (MHC) class I and class II molecules using mass spectrometry (MS) technology platforms. Among all the steps in a MS-based immunopeptidomic workflow, sample preparationis critically important for capturing high-quality data of therapeutic relevance. Here, we describe step-by-step instructions to isolate MHC class I and II-associated peptides by immunoaffinity purification from quality control (QC) samples. Our QC samples are MHC class I and class II peptides isolated from mouse (EL4 and A20) and human (JY) cell lines. We thoroughly describe the various reagents and specfic antibodies that are used too isolate MHC-associated peptides from these cell lines, including the steps to verify the beads-binding efficiency of the antibody and the elution efficiency of the MHC-peptide complexes from the beads. QC samples generated using the described protocol can be used to establish and standardize immunopeptidomic workflow, as well as to benchmark new protocols. We anticipate that the visualized protocol provided in this report will represent a great starting point for any non-expert in addition to foster the instra- and inter-laboratory reproducibility of the sample preparation procedure in immunopeptidomics.