Dynamic allostery in the peptide/MHC complex enables TCR neoantigen selectivity.

The inherent cross-reactivity of the T cell receptor (TCR) is balanced by high specificity, which often manifests in confounding ways not easily interpretable from static structures. We show here that TCR discrimination between an HLA-A*03:01 (HLA-A3)-restricted public neoantigen derived from mutant PIK3CA and its wild-type (WT) counterpart emerges from motions within the HLA binding groove that vary with the identity of the peptide's first primary anchor. The motions form a dynamic gate that in the complex with the WT peptide impedes a large conformational change required for TCR binding. The more rigid neoantigen is insusceptible to this limiting dynamic, and with the gate open, is able to transit its central tryptophan residue underneath the peptide backbone to the contralateral side of the HLA-A3 peptide binding groove, facilitating TCR binding. Our findings reveal a novel mechanism driving TCR specificity for a cancer neoantigen that is rooted in the dynamic and allosteric nature of peptide/MHC-I complexes, with implications for resolving long-standing and often confounding questions about the determinants of T cell specificity.

Distinct sets of molecular characteristics define tumor-rejecting neoantigens.

Challenges in identifying tumor-rejecting neoantigens limit the efficacy of neoantigen vaccines to treat cancers, including cutaneous squamous cell carcinoma (cSCC). A minority of human cSCC tumors shared neoantigens, supporting the need for personalized vaccines. Using a UV-induced mouse cSCC model which recapitulated the mutational signature and driver mutations found in human disease, we found that CD8 T cells constrain cSCC. Two MHC class I neoantigens were identified that constrained cSCC growth. Compared to the wild-type peptides, one tumor-rejecting neoantigen exhibited improved MHC binding and the other had increased solvent accessibility of the mutated residue. Across known neoantigens that do not impact MHC binding, structural modeling of the peptide/MHC complexes indicated that increased solvent accessibility, which will facilitate TCR recognition of the neoantigen, distinguished tumor-rejecting from non-immunogenic neoantigens. This work reveals characteristics of tumor-rejecting neoantigens that may be of considerable importance in identifying optimal vaccine candidates in cSCC and other cancers.

Accurate modeling of peptide-MHC structures with AlphaFold.

Major histocompatibility complex (MHC) proteins present peptides on the cell surface for T cell surveillance. Reliable in silico prediction of which peptides would be presented and which T cell receptors would recognize them is an important problem in structural immunology. Here, we introduce an AlphaFold-based pipeline for predicting the three-dimensional structures of peptide-MHC complexes for class I and class II MHC molecules. Our method demonstrates high accuracy, outperforming existing tools in class I modeling accuracy and class II peptide register prediction. We validate its performance and utility with new experimental data on a recently described cancer neoantigen/wild-type peptide pair and explore applications toward improving peptide-MHC binding prediction.

Structural and physical features that distinguish tumor-controlling from inactive cancer neoepitopes.

Neoepitopes arising from amino acid substitutions due to single nucleotide polymorphisms are targets of T cell immune responses to cancer and are of significant interest in the development of cancer vaccines. However, understanding the characteristics of rare protective neoepitopes that truly control tumor growth has been a challenge, due to their scarcity as well as the challenge of verifying true, neoepitope-dependent tumor control in humans. Taking advantage of recent work in mouse models that circumvented these challenges, here, we compared the structural and physical properties of neoepitopes that range from fully protective to immunologically inactive. As neoepitopes are derived from self-peptides that can induce immune tolerance, we studied not only how the various neoepitopes differ from each other but also from their wild-type counterparts. We identified multiple features associated with protection, including features that describe how neoepitopes differ from self as well as features associated with recognition by diverse T cell receptor repertoires. We demonstrate both the promise and limitations of neoepitope structural analysis and predictive modeling and illustrate important aspects that can be incorporated into neoepitope prediction pipelines.

A monomeric mycobacteriophage immunity repressor utilizes two domains to recognize an asymmetric DNA sequence.

Regulation of bacteriophage gene expression involves repressor proteins that bind and downregulate early lytic promoters. A large group of mycobacteriophages code for repressors that are unusual in also terminating transcription elongation at numerous binding sites (stoperators) distributed across the phage genome. Here we provide the X-ray crystal structure of a mycobacteriophage immunity repressor bound to DNA, which reveals the binding of a monomer to an asymmetric DNA sequence using two independent DNA binding domains. The structure is supported by small-angle X-ray scattering, DNA binding, molecular dynamics, and in vivo immunity assays. We propose a model for how dual DNA binding domains facilitate regulation of both transcription initiation and elongation, while enabling evolution of other superinfection immune specificities.

Sphingomonas sp. KT-1 PahZ2 Structure Reveals a Role for Conformational Dynamics in Peptide Bond Hydrolysis.

Poly(aspartic acid) (PAA) is a common water-soluble polycarboxylate used in a broad range of applications. PAA biodegradation and environmental assimilation were first identified in river water bacterial strains, Sphingomonas sp. KT-1 and Pedobacter sp. KP-2. Within Sphingomonas sp. KT-1, PahZ1KT-1 cleaves ß-amide linkages to oligo(aspartic acid) and then is degraded by PahZ2KT-1. Recently, we reported the first structure for PahZ1KT-1. Here, we report novel structures for PahZ2KT-1 bound to either Gd3+/Sm3+ or Zn2+ cations in a dimeric state consistent with M28 metallopeptidase family members. PahZ2KT-1 monomers include a dimerization domain and a catalytic domain with dual Zn2+ cations. MD methods predict the putative substrate binding site to span across the dimerization and catalytic domains, where NaCl promotes the transition from an open conformation to a closed conformation that positions the substrate adjacent to catalytic zinc ions. Structural knowledge of PahZ1KT-1 and PahZ2KT-1 will allow for protein engineering endeavors to develop novel biodegradation reagents.

Examination of the Role of Mg2+ in the Mechanism of Nucleotide Binding to the Monomeric YME1L AAA+ Domain.

The first line of defense in the mitochondrial quality control network involves the stress response from a family of ATP-dependent proteases. We have reported that a solubilized version of the mitochondrial inner membrane ATP-dependent protease YME1L displays nucleotide binding kinetics that are sensitive to the reactive oxygen species hydrogen peroxide under a limiting ATP concentration. Our observations were consistent with an altered YME1L conformational ensemble leading to increased nucleotide binding site accessibility under oxidative stress conditions. To examine this hypothesis further, we report here the results of a comprehensive study of the thermodynamic and kinetic properties underlying the binding of nucleoside di- and triphosphate to the isolated YME1L AAA+ domain (YME1L-AAA+). A combination of fluorescence titrations, molecular dynamics, and stopped-flow fluorescence experiments have demonstrated similarity between nucleotide binding behaviors for YME1L under oxidative conditions and the isolated AAA+ domain. Our data demonstrate that YME1L-AAA+ binds ATP and ADP with affinities equal to ∼30 and 5 µM, respectively, in the absence of Mg2+. We note a negative heterotropic linkage effect between Mg2+ and ATP that arises as the MgCl2 concentration is increased such that the affinity of YME1L-AAA+ for ATP decreases to ∼60 µM in the presence of 10 mM MgCl2. Molecular dynamics methods allow for structural rationalization by revealing condition-dependent conformational populations for YME1L-AAA+. Taken together, these data suggest a preliminary model in which YME1L modulates its affinity for the nucleotide to stabilize against degradation or instability inherent to such stress conditions.

Characterization of Mitochondrial YME1L Protease Oxidative Stress-Induced Conformational State.

Oxidative stress is a common challenge to mitochondrial function where reactive oxygen species are capable of significant organelle damage. The generation of mitochondrial reactive oxygen species occurs in the inner membrane and matrix compartments as a consequence of subunit function in the electron transport chain and citric acid cycle, respectively. Maintenance of mitochondrial proteostasis and stress response is facilitated by compartmentalized proteases that couple the energy of ATP hydrolysis to unfolding and the regulated removal of damaged, misfolded, or aggregated proteins. The mitochondrial protease YME1L functions in the maintenance of proteostasis in the intermembrane space. YME1L is an inner membrane-anchored hexameric protease with distinct N-terminal, transmembrane, AAA+ (ATPases associated with various cellular activities), and C-terminal M41 zinc-dependent protease domains. The effect of oxidative stress on enzymes such as YME1L tasked with maintaining proteostasis is currently unclear. We report here that recombinant YME1L undergoes a reversible conformational change in response to oxidative stress that involves the interaction of one hydrogen peroxide molecule per YME1L monomer with affinities equal to 31 ±â€¯2 and 26 ±â€¯1 mM for conditions lacking or including nucleotide, respectively. Our data also reveal that oxidative stress does not significantly impact nucleotide binding equilibria, but does stimulate a 2-fold increase in the rate constant for high-affinity ATP binding from (8.9 ±â€¯0.2) × 105 M-1 s-1 to (1.5 ±â€¯0.1) × 106 M-1 s-1. Taken together, these data may suggest a mechanism for the regulated processing of YME1L by other inner membrane proteases such as OMA1.