Making sense of TCRтАУpMHC topology
Most T cells use a T cell receptor (TCR) that recognizes major histocompatibility complex molecules bound to peptides (pMHCs) derived from both self- and foreign antigens. Although there is great variability in the interface because of the diversity of both partners, this interaction displays a canonical docking topology for reasons that remain contested. Zareie et al. tested an assortment of both canonical and reversed-polarity TCRs that were all specific for the same cognate pMHC-I bearing a peptide derived from influenza A virus (IAV) (see the Perspective by Horkova and Stepanek). The authors determined that docking topology was the primary driver of in vivo T cell activation and recruitment when mice were infected with IAV. The canonical topology was required for the formation of a functional signaling complex, suggesting that T cell signaling constraints dictate how TCR and pMHC meet.
Science, abe9124, this issue p. eabe9124; see also abj2937, p. 1038
Structured Abstract
INTRODUCTION
T cell receptor (TCR) recognition of peptideтАУmajor histocompatibility complexes (pMHCs) is one of the most diverse receptorтАУligand interactions in biology. Nevertheless, these interactions exhibit a highly conserved, or canonical, TCRтАУpMHC docking polarity in both mice and humans. Whether this canonical docking polarity is driven by evolutionarily conserved, germline-encoded complementarity between the TCR and MHC or by signaling constraints imposed by coreceptors has been a question of enduring debate. Here, we demonstrate that although reversed-polarity TCRтАУpMHC recognition is prevalent within a na├пve, viral epitopeтАУspecific T cell repertoire and may exhibit relatively high pMHCI affinity, such TCRs are unable to support TCR signaling in the presence of CD8 coreceptor because of mislocalization of Lck. These data support a paradigm in which the highly conserved TCRтАУpMHCI docking polarity is driven by structural constraints on TCR signaling.
RATIONALE
Evidence suggests that the canonical TCRтАУpMHC docking polarity is driven by evolutionary hardwiring of complementary germline-encoded motifs at the TCR and MHC interface. An alternate model suggests that TCR recognition of pMHC is driven during thymic selection by the need for the CD4 or CD8 coreceptors to bind MHC and deliver coreceptor-associated Lck to the CD3 signaling complex. We previously identified reversed-polarity TRBV17+ TCRs from the preimmune influenza A virus (IAV)тАУspecific repertoire that bound pMHCI (H-2DbNP366) with a moderate affinity but were unable to support robust T cell recruitment. Here, using a range of canonical and reversed TCRs specific for the same cognate pMHCI, we tested the hypothesis that the TCRтАУpMHCI docking polarity precedes binding strength as a key determinant of T cell activation. We hypothesized that the underlying driver of the canonical docking polarity is the colocalization of signaling molecules central to the TCR signal transduction pathway.
RESULTS
In this study, we demonstrate that reversed TCRs are prevalent in a na├пve virusтАУspecific repertoire but are poorly represented in the immune response after virus challenge. We identified antigen-specific TCR╬▒╬▓ clonotypes that were either poorly recruited or clonally expanded and found an overriding association between immune prevalence and canonical TCRтАУpMHCI docking. This was irrespective of pMHCI affinity, catch or slip bond formation, or TCR clustering, demonstrating that a canonical docking polarity is required for T cell activation. This finding was verified after viral challenge of adoptively transferred retrogenic T cells expressing reversed or canonical docking TCRs of varying affinities. The inability of T cells expressing reversed-docking TCRs to be recruited into the antiviral immune response demonstrates that TCRтАУpMHCI docking topology supersedes TCRтАУpMHCI affinity as the primary determinant for effective in vivo immune recruitment. Using fluorescence lifetime imaging microscopy (FLIM)тАУF├╢rster resonance energy transfer (FRET) analyses, we show that canonical TCRтАУpMHCI docking is essential for the colocalization of CD8тАУLck with CD3╬╢, which is impaired when the TCR engages pMHCI with reversed polarity. The requirement for canonical TCRтАУpMHCI docking can be circumvented by the removal of the CD8 coreceptor or by dissociation of Lck from CD8, suggesting that sequestration of Lck by the CD8 coreceptor has a dual role: potentiating signaling arising from canonical TCRтАУpMHCI interactions and impeding reversed-polarity TCRтАУpMHCI signaling.
CONCLUSION
The inability of reversed-polarity TCRs to participate in the immune response occurs independently of TCRтАУpMHCI binding affinity and instead is a direct consequence of reversed TCRтАУpMHCI engagement. Most TCRтАУpMHC complexes that have been solved to date, upon which the canonical TCRтАУpMHCI docking paradigm has been established, were derived from expanded immune repertoires. Thus, we conclude that the highly conserved docking polarity is driven predominantly by the structural constraints imposed on TCR signaling and recruitment into an immune response. In addition to the well-recognized augmentation of signaling resulting from canonical TCRтАУpMHCI engagement, our findings suggest a role for coreceptorтАУLck association in preventing signaling by noncanonical TCRтАУpMHC recognition. Such negative regulation would serve to limit the extent of functional TCR cross-reactivity and constrain the number of signaling-competent TCR-binding modalities.
Schematic shows how canonical TCRтАУpMHC recognition colocalizes Lck and CD3, driving TCR-mediated signaling. By contrast, a reversed TCRтАУpMHC recognition polarity mislocalizes Lck and CD3, impeding signaling.
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Schematic shows how canonical TCRтАУpMHC recognition colocalizes Lck and CD3, driving TCR-mediated signaling. By contrast, a reversed TCRтАУpMHC recognition polarity mislocalizes Lck and CD3, impeding signaling.
Abstract
T cell receptor (TCR) recognition of peptideтАУmajor histocompatibility complexes (pMHCs) is characterized by a highly conserved docking polarity. Whether this polarity is driven by recognition or signaling constraints remains unclear. Using тАЬreversed-dockingтАЭ TCR╬▓-variable (TRBV) 17+ TCRs from the na├пve mouse CD8+ T cell repertoire that recognizes the H-2DbтАУNP366 epitope, we demonstrate that their inability to support T cell activation and in vivo recruitment is a direct consequence of reversed docking polarity and not TCRтАУpMHCI binding or clustering characteristics. Canonical TCRтАУpMHCI docking optimally localizes CD8/Lck to the CD3 complex, which is prevented by reversed TCRтАУpMHCI polarity. The requirement for canonical docking was circumvented by dissociating Lck from CD8. Thus, the consensus TCRтАУpMHC docking topology is mandated by T cell signaling constraints.
