Using X-ray Crystallography, Biophysics, and Functional Assays to Determine the Mechanisms Governing T-cell Receptor Recognition of Cancer Antigens

MacLachlan, Bruce J.; Greenshields‐Watson, Alexander; Mason, Georgina H; Schauenburg, Andrea J. A.; Bianchi, Valentina; Rizkallah, P.J.; Sewell, Andrew K.; Fuller, Anna; Cole, David K.

doi:10.3791/54991

Cited by 5 publications

(5 citation statements)

References 50 publications

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“…This suggests that unmodified lysine residues in the anchoring position are unfavorable for HLA I binding and that the modified state of a lysine residue may be preferred. In contrast, modified arginine such as di/methylated arginine and citrullination are overrepresented in positions 3 to 7, and therefore may impact the T-cell receptor recognition 44 (Figure 2F), as was previously shown for other modifications types. Interestingly, while cysteine modifications on peptides in MS analyses are considered to be introduced by sample processing, in our analysis of the HLA I landscape they have a distinct distribution motif where cysteine carbamidomethyl is enriched in positions 3-4 and cysteinylation is enriched in positions 7-8 (Figure 2C).…”

Section: An Unbiased Search Of 29 Modifications Highlights Ptm-driven Preferencessupporting

confidence: 66%

“…The most critical residues for HLA I binding are the ones that fit into the anchor pockets in the HLA I groove, typically the second and carboxy-terminal positions 43 . By contrast, T-Cell receptors recognition motif is determined by the HLA I-peptide complex and therefore most strongly influenced by the residues in position 3 to 7 of the HLA I-bound peptide 44,45 . In the presented matrix for example, known motifs, such as the tendency of serine phosphorylation modification at position 4 6,7 , were also emphasized as low correlation in this analysis (Pearson 0.41, p value = 0.21) as there was a strong deviation between the phosphorylation and underlying serine distributions (Figure 2D; F-test; p value < 2.2e-16).…”

Section: An Unbiased Search Of 29 Modifications Highlights Ptm-driven Preferencesmentioning

confidence: 96%

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Uncovering the modified immunopeptidome reveals insights into principles of PTM-driven antigenicity

Kacen

Javitt

Kramer

et al. 2021

Preprint

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Antigen processing and presentation are critical for modulating tumor-host interactions. While post-translational modifications (PTMs) can alter the binding and recognition of antigens, their identification remains challenging. Here we uncover the role PTMs may play in antigen presentation and recognition in human cancers by profiling 29 different PTM combinations in immunopeptidomics data from multiple clinical samples and cell lines. We established and validated an antigen discovery pipeline and showed that newly identified modified antigens from a murine cancer model are cancer-specific and can elicit T cell killing. Systematic analysis of PTMs across multiple cohorts defined new haplotype preferences and binding motifs in association with specific PTM types. By expanding the antigenic landscape with modifications, we uncover disease-specific targets, including thousands of novel cancer-specific antigens and reveal insight into PTM-driven antigenicity. Collectively, our findings highlight an immunomodulatory role for modified peptides presented on HLA I, which may have broad implications for T-cell mediated therapies in cancer and beyond.

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Section: An Unbiased Search Of 29 Modifications Highlights Ptm-driven Preferencessupporting

confidence: 66%

Section: An Unbiased Search Of 29 Modifications Highlights Ptm-driven Preferencesmentioning

confidence: 96%

Uncovering the modified immunopeptidome reveals insights into principles of PTM-driven antigenicity

Kacen

Javitt

Kramer

et al. 2021

Preprint

View full text Add to dashboard Cite

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“…All experiments were performed at 25°C in TBSB buffer. Prepared biotinylated pHLA‐DR molecules were immobilized to covalently linked streptavidin coated CM5 sensor chips prepared as previously described [42]. Biotinylated pHLA‐DR molecules were bound to the chip surface at a flow rate of 10 μL/min.…”

Section: Methodsmentioning

confidence: 99%

Molecular characterization of HLA class II binding to the LAG‐3 T cell co‐inhibitory receptor

et al. 2020

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Immune checkpoint inhibitors (antibodies that block the T cell co-inhibitory receptors PD-1/PD-L1 or CTLA-4) have revolutionized the treatment of some forms of cancer. Importantly, combination approaches using drugs that target both pathways have been shown to boost the efficacy of such treatments. Subsequently, several other T cell inhibitory receptors have been identified for the development of novel immune checkpoint inhibitors. Included in this list is the co-inhibitory receptor lymphocyte activation gene-3 (LAG-3), which is upregulated on T cells extracted from tumor sites that have suppressive or exhausted phenotypes. However, the molecular rules that govern the function of LAG-3 are still not understood. Using surface plasmon resonance combined with a novel bead-based assay (AlphaScreen TM), we demonstrate that LAG-3 can directly and specifically interact with intact human leukocyte antigen class II (HLA-II) heterodimers. Unlike the homologue CD4, which has an immeasurably weak affinity using these biophysical approaches, LAG-3 binds with low micromolar affinity. We further validated the interaction at the cell surface by staining LAG-3 + cells with pHLA-II-multimers. These data provide new insights into the mechanism by which LAG-3 initiates T cell inhibition.

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“…HLA A*0201 α‐chain and β2m were expressed separately, without post‐translational modification, as insoluble inclusion bodies (IBs) in competent Rosetta (DE3) Escherichia coli cells, using 0.5 M IPTG to induce expression as thoroughly described recently . Briefly, for a 1L pMHC refold, 30 mg HLA‐A*0201 α‐chain was mixed with 30 mg β2 m and 4 mg peptide at 37°C for 15 min with 10 mM DTT.…”

Section: Methodsmentioning

confidence: 99%

T cell receptor alpha variable 12‐2 bias in the immunodominant response to Yellow fever virus

et al. 2017

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The repertoire of human αβ T‐cell receptors (TCRs) is generated via somatic recombination of germline gene segments. Despite this enormous variation, certain epitopes can be immunodominant, associated with high frequencies of antigen‐specific T cells and/or exhibit bias toward a TCR gene segment. Here, we studied the TCR repertoire of the HLA‐A*0201‐restricted epitope LLWNGPMAV (hereafter, A2/LLW) from Yellow Fever virus, which generates an immunodominant CD8+ T cell response to the highly effective YF‐17D vaccine. We discover that these A2/LLW‐specific CD8+ T cells are highly biased for the TCR α chain TRAV12‐2. This bias is already present in A2/LLW‐specific naïve T cells before vaccination with YF‐17D. Using CD8+ T cell clones, we show that TRAV12‐2 does not confer a functional advantage on a per cell basis. Molecular modeling indicated that the germline‐encoded complementarity determining region (CDR) 1α loop of TRAV12‐2 critically contributes to A2/LLW binding, in contrast to the conventional dominant dependence on somatically rearranged CDR3 loops. This germline component of antigen recognition may explain the unusually high precursor frequency, prevalence and immunodominance of T‐cell responses specific for the A2/LLW epitope.

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Using X-ray Crystallography, Biophysics, and Functional Assays to Determine the Mechanisms Governing T-cell Receptor Recognition of Cancer Antigens

Cited by 5 publications

References 50 publications

Uncovering the modified immunopeptidome reveals insights into principles of PTM-driven antigenicity

Uncovering the modified immunopeptidome reveals insights into principles of PTM-driven antigenicity

Molecular characterization of HLA class II binding to the LAG‐3 T cell co‐inhibitory receptor

T cell receptor alpha variable 12‐2 bias in the immunodominant response to Yellow fever virus

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