Project description:Antibody Sequence Determinants of Viral Antigen Specificity

Project description:Antibody Sequence Determinants of Viral Antigen Specificity

Project description:Clonal expansion is a hallmark of adaptive immunity, and appears to be driven by high antigen-specific receptor avidity as shown by research using murine in vivo models. In humans, however, the functionality of antigen-specific T cell clonotypes that are recruited into primary and recall immune responses remains surprisingly elusive. In this regard, the vaccination program during the SARS-CoV-2 pandemic represented a unique research opportunity by provision of highly standardized cohorts of healthy human individuals receiving immunizations against a previously unseen antigen. Here, we analyzed 30 HLA-typed individuals before, short-term and long-term after three mRNA vaccinations against SARS-CoV-2. We performed an in-depth characterization of the magnitude, phenotype, clonal composition and functionality of antigen-specific CD8 T cell responses by ELISPOT, flow cytometry and single-cell RNA sequencing, including CITE seq of 130 surface antigens and 16 T cell epitope specificities. 89 T cell receptors (TCRs) covering three complete epitope-specific repertoires were re-expressed by CRISPR/Cas9-mediated orthotopic TCR replacement and tested for their avidity. TCR repertoires underwent continuous tailoring, with high TCR avidity being linked to both clonal persistence and expansion. However, epitope-specific repertoires also maintained diversity by concomitant contraction and new emergence of functional T cell clones over time. These data on the phenotype and clonal selection within human antigen-specific T cell responses instruct our understanding of human T cell biology and may guide the development of enhanced or novel vaccines.

Project description:Clonal expansion is a hallmark of adaptive immunity, and appears to be driven by high antigen-specific receptor avidity as shown by research using murine in vivo models. In humans, however, the functionality of antigen-specific T cell clonotypes that are recruited into primary and recall immune responses remains surprisingly elusive. In this regard, the vaccination program during the SARS-CoV-2 pandemic represented a unique research opportunity by provision of highly standardized cohorts of healthy human individuals receiving immunizations against a previously unseen antigen. Here, we analyzed 30 HLA-typed individuals before, short-term and long-term after three mRNA vaccinations against SARS-CoV-2. We performed an in-depth characterization of the magnitude, phenotype, clonal composition and functionality of antigen-specific CD8 T cell responses by ELISPOT, flow cytometry and single-cell RNA sequencing, including CITE seq of 130 surface antigens and 16 T cell epitope specificities. 89 T cell receptors (TCRs) covering three complete epitope-specific repertoires were re-expressed by CRISPR/Cas9-mediated orthotopic TCR replacement and tested for their avidity. TCR repertoires underwent continuous tailoring, with high TCR avidity being linked to both clonal persistence and expansion. However, epitope-specific repertoires also maintained diversity by concomitant contraction and new emergence of functional T cell clones over time. These data on the phenotype and clonal selection within human antigen-specific T cell responses instruct our understanding of human T cell biology and may guide the development of enhanced or novel vaccines.

Project description:Primary B cell receptor (BCR)/antibody variable region exons are generated by V(D)J recombination with junctional diversification creating immensely diverse antigen contact-encoding CDR3s. While most antigen-driven germinal centers (GCs) are transient, gut microbiota-dependent intestinal Peyer’s patch (PP) GCs are chronic. The nature of chronic PP GC BCR repertoires and somatic hyper-mutation (SHM) patterns has remained enigmatic. To elucidate the physiological repertoire of PP GC BCRs, we developed a high throughput antibody repertoire and SHM assay. Remarkably, PP GCs from different mice expanded public clonotypes, each often with identical IgH CDR3. These CDR3s represent innate-like BCRs that appear much more frequently than expected in naïve B cell repertoire by IGoR modeling, but not frequently enough to enter PP GCs at the observed recurrence without cellular selection. Consistently, some public clonotypes are gut microbiota-dependent and encode antibodies reactive to bacteria glycans, while others are not. SPF fecal transfer to germ-free (GF) mice restored two germ-dependent clonotypes, providing direct evidence for BCR selection. In support of this, we identified recurrently selected SHMs in four of the public clonotypes, demonstrating affinity maturation in chronic PP GCs. Our findings suggest that persistent gut antigens select for innate-like BCR clonotypes to seed chronic PP GCs.

Project description:Foxp3+ regulatory T cells (Treg) play a central role for tolerance against self and innocuous environmental antigens. However, the role of antigen-specificity for Treg-mediated tolerance is only incompletely understood. Here we show by direct ex vivo characterization of human CD4+ T cells, that the response against innocuous airborne antigens, such as plant pollen or fungal spores, is dominated by memory-like antigen-specific Treg. Surprisingly, breakdown of tolerance in atopic donors was not accompanied by a quantitatively or qualitatively altered Treg response, but instead correlated with a striking dichotomy of Treg versus Th2 target specificity. Allergenic proteins, are selectively targeted by Th2 cells, but not Treg. Thus human Treg specific for airborne antigens maintain tolerance at mucosal sites and the failure to generate specific Treg against a subgroup of antigens provides a window of opportunity for allergy development. PBMCs from sex and age matched birch pollen allergic patients and healthy controls, were stimulated (7h) with airborne fungal (A. fumigatus) or birch pollen antigen (birch) and sorted into antigen specific conventional and regulatory T cells according to their expression of CD154+ and CD137+ on CD4+ T cells, respectively. Number of samples per group in parentheses: Healthy controls stimulated with A. fumigatus (n=5), allergic patients stimulated with A. fumigatus (n=6), healthy controls stimulated with birch (n=6), allergic patients stimulated with birch (n=4).

Project description:Epitope mapping studies aim to identify the binding sites of antibody-antigen interactions to enhance the development of vaccines, diagnostics and immunotherapeutic compounds. However, mapping is a laborious process employing time- and resource-consuming M-bM-^@M-^Xwet benchM-bM-^@M-^Y techniques or epitope prediction software that are still in their infancy. For polymorphic antigens, another challenge is characterizing cross-reactivity between epitopes, teasing out distinctions between broadly cross-reactive responses, limited cross-reactions among variants and the truly type-specific responses. A refined understanding of cross-reactive antibody binding could guide the selection of the most informative subsets of variants for diagnostics and multivalent subunit vaccines. We explored the antibody binding reactivity of sera from human patients and Peromyscus leucopus rodents infected with Borrelia burgdorferi to the polymorphic outer surface protein C (OspC), an attractive candidate antigen for vaccine and improved diagnostics for Lyme disease. We constructed a protein microarray displaying 23 natural variants of OspC and quantified the degree of cross-reactive antibody binding between all pairs of variants, using Pearson correlation calculated on the reactivity values using three independent transforms of the raw data: (1) logarithmic, (2) rank, and (3) binary indicators. We observed that the global amino acid sequence identity between OspC pairs was a poor predictor of cross-reactive antibody binding. Then we asked if specific regions of the protein would better explain the observed cross-reactive binding and performed in silico screening of the linear sequence and 3-dimensional structure of OspC. This analysis pointed to the C-terminal helix of the structure as a major determinant of type-specific cross-reactive antibody binding. We developed bioinformatics methods to systematically analyze the relationship between local sequence/structure variation and cross-reactive antibody binding patterns among variants of a polymorphic antigen, and this method can be applied to other polymorphic antigens for which immune response data is available for multiple variants. Antibody profiling was performed on sera from Borrelia burgdorferi infected and non-infected humans and Peromyscus leucopus rodents against 23 variants of the surface protein OspC . For infected human serum samples, the OspC type of the infecting B. burgdorferi strain is unknown; for experimentally-infected P. leucopus serum samples, it is known. Of human serum samples, 55 were from infected individuals and 25 from naive controls. Of P. leucopus serum samples, 23 were from infected individuals and 7 were from naive controls.

Project description:Approaches to analyze and cluster T-cell receptor (TCR) repertoires to reflect antigen specificity are critical for the diagnosis and prognosis of immune-related diseases and the development of personalized therapies. Sequence-based approaches showed success but remain restrictive, especially when the amount of experimental data used for the training is scarce. Structure-based approaches which represent powerful alternatives, notably to optimize TCRs affinity toward specific epitopes, show limitations for large-scale predictions. To handle these challenges, TCRpcDist is presented, a 3D-based approach that calculates similarities between TCRs using a metric related to the physico-chemical properties of the loop residues predicted to interact with the epitope. By exploiting private and public datasets and comparing TCRpcDist with competing approaches, it is demonstrated that TCRpcDist can accurately identify groups of TCRs that are likely to bind the same epitopes. Importantly, the ability of TCRpcDist is experimentally validated to determine antigen specificities (neoantigens and tumor-associated antigens) of orphan tumor-infiltrating lymphocytes (TILs) in cancer patients. TCRpcDist is thus a promising approach to support TCR repertoire analysis and TCR deorphanization for individualized treatments including cancer immunotherapies.

Project description:Foxp3+ regulatory T cells (Treg) play a central role for tolerance against self and innocuous environmental antigens. However, the role of antigen-specificity for Treg-mediated tolerance is only incompletely understood. Here we show by direct ex vivo characterization of human CD4+ T cells, that the response against innocuous airborne antigens, such as plant pollen or fungal spores, is dominated by memory-like antigen-specific Treg. Surprisingly, breakdown of tolerance in atopic donors was not accompanied by a quantitatively or qualitatively altered Treg response, but instead correlated with a striking dichotomy of Treg versus Th2 target specificity. Allergenic proteins, are selectively targeted by Th2 cells, but not Treg. Thus human Treg specific for airborne antigens maintain tolerance at mucosal sites and the failure to generate specific Treg against a subgroup of antigens provides a window of opportunity for allergy development.

Project description:Leptospirosis is the most widespread zoonotic disease in the world. The lack of an adequate laboratory test is a major barrier for the diagnosis, especially during the early stages of illness, when antibiotic therapy is most effective. Therefore, there is a critical need for an efficient diagnostic test for this life threatening disease. In order to identify new targets that could be used as diagnostic makers for leptopirosis, we constructed a protein microarray chip comprising 61% of Leptospira interrogans proteome and investigated the IgG response against leptospiral antigens from 274 individuals, including 80 acute-, 80 convalescent-phase patients and 114 healthy control subjects from regions with endemic, high endemic and no endemic transmission of leptospirosis. A nitrocellulose line blot assay was performed to validate the accuracy of the protein microarray results. We found 16 antigens that can discriminate between acute cases and healthy individuals from a region with high endemic transmission of leptospirosis, and 18 antigens that distinguish convalescent cases. Some of the antigens identified in this study, such as LipL32, the non-identical domains of the Lig proteins, GroEL and Loa22 are already known to be recognized by sera from human patients, thus serving as a proof-of-concept for the serodiagnostic antigen discovery approach. Several novel antigens were identified, including the hypothetical protein LIC10215 which showed good sensitivity and specificity rates for both acute- and convalescent-phase patients. Our study is the first large-scale evaluation of immunodominant antigens associated with naturally acquired leptospiral infection and novel as well as known serodiagnostic leptospiral antigens that are recognized by antibodies in the sera of leptospirosis cases were identified. The novel antigens identified here may have potential use in both the development of new tests and the improvement of currently available assays for diagnosing this neglected tropical disease. Further research is needed to assess the accuracy of these antigens in more appropriate diagnostic platforms. Antibody profiling was peformed on sera from infected and non-infected subjects to investigate the IgG response against leptospiral antigens. These samples comprised 80 acute-, 80 convalescent-phase patients and 114 healthy control subjects, including 29 subjects from United States (non-endemic area), 35 blood donors from Salvador/Brazil (endemic area) and 50 healthy individuals from region with high endemicity of leptospirosis.