Project description:Objective: Antigen-specific immunotherapy is a promising strategy to treat hepatitis B virus (HBV) infection and (HBV-related) hepatocellular carcinoma (HCC). To facilitate killing of malignant and/or infected hepatocytes, it is vital to know which T cell targets are presented by HLA-I complexes on patient-derived hepatocytes. Here, we aimed to reveal the hepatocyte-specific HLA-I peptidome with emphasis on peptides derived from HBV proteins and tumor associated antigens (TAAs) to guide development of antigen-specific immunotherapy. Design: Primary human hepatocytes were isolated with high purity from (HBV infected) non-tumor and HCC tissues using a newly designed perfusion-free procedure. Subsequently, hepatocyte-derived HLA-bound peptides were identified by mass spectrometry after which source proteins were subjected to gene ontology and pathway analysis. Finally, all HBV-antigen and TAA-derived HLA-peptides were extracted and a selection was tested for immunogenicity. Results: We acquired a high quality HLA-I peptidome of 2x105 peptides, of which source proteins were associated with hepatocyte function. Importantly, we demonstrated HLA-I presentation of HBV-derived and TAA-derived peptides for the first time in immune cell-depleted primary liver cell isolates. The peptidome included 8 HBV-derived peptides and 14 peptides from 8 known HCC-associated TAAs that were exclusively identified in tumor eluates. Of these, immunogenicity was demonstrated for 5 HBV-derived and 3 TAA-derived peptides. Conclusion: We present a first HLA-I immunopeptidome of isolated primary human hepatocytes, devoid of immune cells. Our results directly aid development of antigen-specific immunotherapy for HBV infection and HCC. Described methodology can also be applied to personalize immunotherapeutic treatment of liver diseases in the future.

Project description:The human leukocyte antigen (HLA)-bound-viral antigens, serve as an immunological signature that can be selectively recognized by T cells. As viruses evolve by acquiring mutations, it is essential to identify a range of viral presented antigens. Utilizing HLA-peptidomics we Identified SARS-CoV-2-derived peptides presented by highly prevalent HLA Class-I (HLA-I) molecules using infected cells as well as overexpression of SARS-CoV-2 genes. We found 26 HLA-I peptides and 36 HLA class-II (HLA-II) peptides, which are estimated to be presented by at least one HLA allele in 99% of the world population. Among the identified peptides were recurrently presented HLA-I peptides, peptides derived from out-of-frame-ORFs and presentation-hotspots. Seven of these peptides were previously shown to be immunogenic, and we identified two novel immuno-reactive peptides using HLA-multimer staining. These results may aid the development of the next generation of SARS-CoV-2 vaccines based on viral-specific-presented antigens that span several of the viral genes.

Project description:The human leukocyte antigen (HLA)-bound-viral antigens, serve as an immunological signature that can be selectively recognized by T cells. As viruses evolve by acquiring mutations, it is essential to identify a range of viral presented antigens. Utilizing HLA-peptidomics we Identified SARS-CoV-2-derived peptides presented by highly prevalent HLA Class-I (HLA-I) molecules using infected cells as well as overexpression of SARS-CoV-2 genes. We found 26 HLA-I peptides and 36 HLA class-II (HLA-II) peptides, which are estimated to be presented by at least one HLA allele in 99% of the world population. Among the identified peptides were recurrently presented HLA-I peptides, peptides derived from out-of-frame-ORFs and presentation-hotspots. Seven of these peptides were previously shown to be immunogenic, and we identified two novel immuno-reactive peptides using HLA-multimer staining. These results may aid the development of the next generation of SARS-CoV-2 vaccines based on viral-specific-presented antigens that span several of the viral genes.

Project description:In the context of HLA-DP-mismatched allogeneic stem cell transplantation, mismatched HLA-DP alleles can provoke profound allo-HLA-DP-specific immune responses from the donor T-cell repertoire leading to graft-versus-leukemia effect and/or graft-versus-host disease in the patient. The magnitude of allo-HLA-DP-specific immune responses has been shown to depend on the specific HLA-DP disparity between donor and patient and the immunogenicity of the mismatched HLA-DP allele(s). HLA-DP peptidome clustering (DPC) was developed to classify the HLA-DP molecules based on similarities and differences in their peptide-binding motifs. To investigate a possible categorization of HLA-DP molecules based on overlap of presented peptides, we identified and compared the peptidomes of the thirteen most frequently expressed HLA-DP molecules. Our categorization based on shared peptides was in line with the DPC classification. We found that the HLA-DP molecules within the previously defined groups DPC-1 or DPC-3 shared the largest numbers of presented peptides. However, the HLA-DP molecules in DPC-2 segregated into two subgroups based on the overlap in presented peptides. Besides overlap in presented peptides within the DPC groups, a substantial number of peptides was also found to be shared between HLA-DP molecules from different DPC groups, especially for groups DPC-1 and -2. The functional relevance of these findings was illustrated by demonstration of cross-reactivity of allo-HLA-DP-reactive T-cell clones not only against HLA-DP molecules within one DPC group, but also across different DPC groups. The promiscuity of peptides presented in various HLA-DP molecules and the cross-reactivity against different HLA-DP molecules demonstrate that these molecules cannot be strictly categorized in immunogenicity groups.

Project description:Hepatitis B virus (HBV) causes both acute and chronic liver inflammation. Approximately 600,000 CHB patients each year die of HBV-related diseases such as cirrhosis and liver cancer. Therefore, CHB remains a global health concern. Although there have been anti-HBV agents for treating CHB, they have some limitations including viral-drug resistance and adverse effects. Type III IFN or IFN-λ is promising to use as anti-HBV agents because of its anti-viral activities like type I IFNs. In addition, the expression of its receptor, IFNLR1, is limited only in epithelial cells including hepatocytes. Thus, treatment with IFN-lambda results in less side effects compared to IFN-alpha treatment. IFN-lambdas have been shown to inhibit the replication of several viruses including IAV, DENV, EMCV, HIV, HCV, and HBV; however, there have been no studies on the effects of IFN-λ3, the highest activity among other subtypes, on HBV replication. Therefore, this study aims to determine antiviral activities of IFN-λ3 against HBV replication and to investigate its molecular mechanism responsible for suppressing HBV propagation. The results showed that HBV transcripts and amount of intracellular HBV DNA were decreased in HepG2.2.15 cells, stable HBV-transfected hepatoblastoma cell line, treated with IFN-λ3 in a dose-dependent manner. This indicated that IFN-λ3 could inhibit HBV replication. Next, we performed quantitative proteomics to investigate the proteome changes in HepG2.2.15 treated with IFN-λ3. The proteins that changed their expressions were involved in several biological processes such as defense to viral infection, immune responses, cell-cell adhesion, transcription, translation, and metabolism. We further confirmed the proteomics results by immunoblotting assay. Consistent with MS data, it found that the expression of OAS3, SAMHD1 and STAT1 were increased as a result of IFN-λ3 stimulation. These results indicated that proteomics results were reproducible and reliable. Finally, we proposed 3 possible mechanisms involved in suppressing HBV replication including i.) IFN-λ3 induced anti-viral proteins affecting many steps in HBV life cycle ii.) IFN-λ3 promoted antigen processing and antigen presentation and iii.) IFN-λ3 rescued RIG-I signaling to promote both type I and type III IFN production.

Project description:Seven patient paired primary human HLA-G+ extravillous trophoblasts (EVT) and Villous trophoblasts (VT) obtained from 1st trimester (7-9 weeks) villous tissue were obtained. RNA was isolated directly after isolation and purification using FACS sort for CD45-HLA-G+ (EVT) and CD45-HLA-G-EGFR1+ (VT) fractions. Expression profiles were compared to two samples of the choriocarcinoma cell line JEG-3 and four samples of decidual stromal cells (DSC) at passage 2 after cell culture.

Project description:RNA chemical modifications have been found to play important biological functions. Among which, the 5-methylcytosine (m5C) modification has been reported to participate in viral replication through affecting RNA processing, such as export, decay, translation and so on. In this study, we performed bisulfite sequencing (BS-seq) on HBV 1.1-mer-transfected huh7 cells to identify the m5C sites in HBV mRNA and their function in virus replication was verified. To investigate the mechanism by which m5C methyltransferase NSUN2 suppresses HBV replication, altered global m5C levels in host genes in HBV 1.1-mer-transfected cells were examined by BS-seq. We found that the m5C modification of genes associated with antiviral immunity changed significantly after viral infection. Our study provide new molecular insights into the mechanism of HBV-mediated IFN inhibition

Project description:Identification of natural human leukocyte antigen (HLA) ligandome is a key element to understand the cellular immune responses. Advanced high throughput mass spectrometry analyses identify a relevant, but not complete, fraction of the many tens of thousands of self-peptides generated by the antigen processing in live cells. In infected cells, in addition to this complex HLA ligandome, a minority of peptides from degradation of the few proteins encoded by the viral genome are also bound to HLA class I molecules. In this study, the standard immunoproteomics strategy was modified to include the classical acid stripping treatment after virus infection to enrich the HLA ligandome in virus ligands. Complexes of HLA-B*27:05-bound peptide pools were isolated from vaccinia virus (VACV)-infected cells treated with acid stripping after virus infection. The HLA class I ligandome was identified using high throughput mass spectrometry analyses, yielding 42 and 52 natural peptides processed and presented in untreated and after acid stripping treatment VACV-infected human cells, respectively. Most of these virus ligands were identified in both conditions, but a relevant fraction of VACV ligands detected by mass spectrometry was dependent of acid stripping treatment with almost twice more exclusive viral ligands that the untreated VACV-infected condition. Theoretical binding affinity prediction of the VACV HLA-B*27:05 ligands and acute antiviral T cell response characterization in the HLA transgenic mice model showed no differences between HLA ligands identified under the two conditions: untreated and acid stripping condition. These findings indicated that acid stripping treatment could be useful to identify HLA class I ligands from virus-infected cells.

Project description:Hepatitis B virus (HBV) is known for its ability to interact with the host cell DNA methylation machinery. In HBV-infected hepatocytes, this interaction leads to chronic liver diseases, including hepatocellular carcinoma (HCC). We studied the extent of genomic changes induced by natural HBV infection in human primary hepatocytes. Transcriptome and methylome profiles were obtained at different time points post-infection to identify HBV-specific alterations. Although gene expression and DNA methylation do not directly correlate, they both seem to reflect the effect of cell culture and viral infection at different levels.These changes in the hepatocyte cellular program shed light on the initial events leading to HBV-associated liver diseases.

Project description:Human cytomegalovirus infection (CMV) can stimulate robust human leukocyte antigen (HLA)-E restricted CD8 T cell responses. These T cells recognize a peptide from UL40, which differs by as little as a single methyl group from self-peptides that also bind HLA-E, challenging their capacity to avoid self-reactivity. We showed in one donor 2 distinct populations of UL40/HLA-E T cells, with vastly different T cell receptor (TCR) affinities for the UL40/HLA-E complex. However, paradoxically, lower cytokine responses were observed from UL40/HLA-E T cells bearing TCRs with high affinity for HLA-E. To identify why these T cells bearing high affinity T cell receptors were less responsive to antigens, we performed single cell RNAseq analysis. These 2 distinct populations of T cells were single-cell sorted into 96-well plates prior to single cell RNA-seq analysis.