Decoding the interactions between T cell receptors and peptide-MHC

解码 T 细胞受体和肽-MHC 之间的相互作用

基本信息

批准号：
10158266
负责人：
Paul G. Thomas
金额：
$ 68.19万
依托单位：
ST. JUDE CHILDREN'S RESEARCH HOSPITAL
依托单位国家：
美国
项目类别：
财政年份：
2018
资助国家：
美国
起止时间：
2018-06-20 至 2023-05-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10158266
关键词：
Address Algorithms Binding Biological Cells Classification Complex Computer Analysis Data Development Epitopes Generations Goals Heart Immune Individual MHC Class I Genes Major Histocompatibility Complex Maps Measures Mediating Methods Modeling Mutate Mutation Nature Pattern Peptide Library Peptide Receptor Peptide/MHC Complex Peptides Sensitivity and Specificity Shapes Specificity Structure T cell receptor repertoire sequencing T cell response T-Cell Antigen Receptor Specificity T-Cell Receptor T-Lymphocyte T-cell diversity T-cell receptor repertoire TCR Activation Training Validation Visual Visualization algorithm development analytical tool antigen-specific T cells base computerized tools cross reactivity design experimental study improved insight mutant next generation novel novel strategies prediction algorithm predictive modeling receptor recruit sequencing platform success tool

项目摘要

PROJECT SUMMARY T cell receptor (TCR) recognition of a cognate peptide-major histocompatibility complex (pMHC) is central to adaptive immune recognition. Certain features of this interaction are well-understood, including many of the rules governing peptide binding to MHC. However, our ability to model the ternary TCR:pMHC complex remains limited for three primary reasons: (1) Data availability; (2) Binding; and (3) Cross-reactivity. In elucidating the rules by which the TCR:pMHC interface operates, these efforts stand to address fundamental questions at the heart of adaptive immune recognition, with important theoretical and practical implications that include the potential for the forward design of novel receptors with selected specificities, the “decoding” of the recent influx of TCR sequencing data for specific antigenic targets, and an understanding of the cross-reactive potential of the repertoire. Previously, we developed novel approaches that provided training data for the construction of algorithms that predict various aspects of TCR specificity (1), including an algorithm we call TCRdist - a simple and effective distance measure to compare TCR sequences. TCRdist can be used to cluster antigen-specific TCR sequences and can be incorporated into a distance-based classifier capable of correctly assigning previously unobserved TCRs to characterized repertoires with robust sensitivity and specificity. Taken together, the results of these experiments and the general success of the TCRdist algorithm provide compelling evidence for the central premises of this proposal: Given a sufficient number of experimentally verified epitope- specific TCR sequences, the epitope specificity of a TCR can be predicted from its sequence; furthermore, the generation of epitope-specific TCR sequence data, in combination with structurally informed computational analysis, provides a roadmap for building a predictive model of the TCR:pMHC interaction. While we have made significant progress in this line of inquiry, the largest remaining hurdle is the apparent broad cross-reactivity within the repertoire. In order to fully elucidate the complex network of interactions among TCRs and pMHCs, the questions we must address then are: what do diverse TCRs that see the same pMHC have in common? And what do diverse pMHCs that are seen by the same TCRs have in common? The ultimate consequence of these studies, beyond their immediate biological applications, will be to assist in the development of the next generation of analytical tools for the modeling of TCR:pMHC interaction, leading to the ultimate goal of a true “decoder” for this essential interface.

项目概要 T 细胞受体 (TCR) 对同源肽-主要组织相容性复合物 (pMHC) 的识别至关重要适应性免疫识别。这种相互作用的某些特征是众所周知的，包括许多规则。然而，我们对三元 TCR:pMHC 复合物进行建模的能力仍然有限。出于三个主要原因：(1) 数据可用性；(2) 约束力；以及 (3) 阐明规则。 TCR:pMHC 接口运作，这些努力旨在解决核心的基本问题适应性免疫识别具有重要的理论和实践意义，包括潜在的具有选定特异性的新型受体的正向设计，最近涌入的 TCR 的“解码” 特定抗原靶点的测序数据，以及对交叉反应潜力的了解之前，我们开发了新的方法，为构建提供训练数据。预测 TCR 特异性各个方面的算法 (1)，包括我们称为 TCRdist 的算法 - 一个简单的算法比较 TCR 序列的有效距离测量可用于对抗原特异性进行聚类。 TCR 序列，可以合并到基于距离的分类器中，能够正确分配以前未观察到的 TCR 具有强大的敏感性和特异性。这些实验的结果和 TCRdist 算法的普遍成功提供了令人信服的证据对于这个提议的中心前提：给定足够数量的经过实验验证的表位- 特定的TCR序列，可以从其序列预测TCR的表位特异性；此外，表位特异性 TCR 序列数据的生成，结合结构知情的计算分析，为构建 TCR:pMHC 的预测模型提供了路线图虽然我们在这方面的调查中取得了重大进展，但剩下的最大障碍是库内明显广泛的交叉反应性，以充分阐明复杂的网络。 TCR 和 pMHC 之间的相互作用，我们必须解决的问题是：不同的 TCR 看到了什么？相同的 pMHC 有什么共同点？相同 TCR 看到的不同 pMHC 有什么共同点？除了直接的生物学应用之外，这些研究的最终结果将是协助开发用于 TCR:pMHC 相互作用建模的下一代分析工具，从而实现这个基本接口的真正“解码器”的最终目标。

项目成果

期刊论文数量（0）

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科研奖励数量（0）

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Paul G. Thomas其他文献

Pre-existing immunity to a nucleic acid contaminant-derived antigen mediates transaminitis and resultant diminished transgene expression in a mouse model of hepatic rAAV-mediated gene transfer.

在肝 rAAV 介导的基因转移小鼠模型中，对核酸污染物衍生抗原的预先存在的免疫力介导转氨炎，并由此导致转基因表达减少。

DOI：
发表时间：
2024
期刊：
Human Gene Therapy
影响因子：
4.2
作者：
Mark A. Brimble;Christopher L Morton;Stephen M. Winston;Isaiah L. Reeves;Yunyu Spence;Pei;Jungfang Zhou;A. Nathwani;Paul G. Thomas;Aisha Souquette;A. Davidoff
通讯作者：
A. Davidoff

copepodTCR: Identification of Antigen-Specific T Cell Receptors with combinatorial peptide pooling

coppodTCR：通过组合肽池鉴定抗原特异性 T 细胞受体

DOI：
发表时间：
2023
期刊：
bioRxiv
影响因子：
0
作者：
Vasilisa A. Kovaleva;David J. Pattinson;Carl Barton;Sarah R. Chapin;Anastasia A. Minervina;K. Richards;Andrea J. Sant;Paul G. Thomas;M. Pogorelyy;Hannah V. Meyer
通讯作者：
Hannah V. Meyer

Biologic and clinical features of childhood gamma delta T-ALL: identification of STAG2/LMO2 Î³Î´ T-ALL as an extremely high risk leukemia in the very young

儿童 γ δ T-ALL 的生物学和临床特征：将 STAG2/LMO2 γδ T-ALL 鉴定为幼儿中的极高风险白血病

DOI：
10.1101/2023.11.06.23298028
发表时间：
2023-11-08
期刊：
medRxiv : the preprint server for health sciences
影响因子：
0
作者：
Shunsuke Kimura;Petri Polonen;Lindsey Montefiori;Chun Shik Park;Ilaria Iacobucci;Allen Yeoh;A. Attarbaschi;Andrew S Moore;Anthony Brown;Atsushi Manabe;B. Buldini;Burgess B Freeman;Chelsey Chen;Cheng Cheng;Chiew Kean Hui;Chi;Ching;Chunxu Qu;D. Tomizawa;D. Teachey;Elena Varotto;E. Paietta;Elizabeth D. Arnold;Franco Locatelli;G. Escherich;Hannah Elisa Muhle;H. Marquart;H. D. de Groot;Jacob M. Rowe;Jan Stary;J. Trka;John K. Choi;J. Meijerink;Jun J Yang;J. Takita;K. Pawińska;K. Roberts;Katie Han;Kenneth J. Caldwell;K. Schmiegelow;K. Crews;Mariko Eguchi;Martin Schrappe;M. Zimmerman;Masatoshi Takagi;Mellissa Maybury;M. Svatoň;M. Reiterová;M. Kicinski;Mollie S Prater;Motohiro Kato;Noemi Reyes;O. Spinelli;Paul G. Thomas;Pauline Mazilier;Qingsong Gao;Riccardo Masetti;R. Kotecha;Rob Pieters;S. Elitzur;S. Luger;Sharnise Mitchell;Shondra M. Pruett;Shuhong Shen;S. Jeha;S. Köhrer;S. Kornblau;S. Skoczeń;T. Miyamura;T. Vincent;T. Imamura;V. Conter;Yan;Yen;Yunchao Chang;Zhaohui Gu;Zhong;Yinmei Zhou;H. Inaba;C. Mullighan
通讯作者：
C. Mullighan

Tracing household transmission of SARS-CoV-2 in New Zealand using genomics

使用基因组学追踪新西兰 SARS-CoV-2 的家庭传播情况

DOI：
10.1038/s44298-024-00032-6
发表时间：
2024-06-03
期刊：
npj Viruses
影响因子：
0
作者：
L. Jelley;N. Aminisani;Meaghan O’Neill;Tineke Jennings;Jordan Douglas;Srushti Utekar;Helen Johnston;David Welch;James Hadfield;Nikki Turner;Tony Dowell;A. Nesdale;Hazel C. Dobinson;P. Campbell;Michelle Balm;Cameron C. Grant;Karen Daniells;Peter McIntyre;A. Trenholme;Cass Byrnes;R. Seeds;Tim Wood;Megan Rensburg;Jort Cueto;Ernest Caballero;Joshma John;Emmanuel Penghulan;D. Currin;Mary Ryan;Andrea Bowers;Chor Ee Tan;J. Bocacao;W. Gunn;Bryden Bird;Tegan Slater;Farjana Ahmed;Mai Anh Sam;Elaisa Glampe;Gabriella Davey;J. de Ligt;David Winter;Nigel French;Paul G. Thomas;R. Webby;Sue Huang;J. Geoghegan
通讯作者：
J. Geoghegan

Transmission Studies Resume for Avian Flu

禽流感传播研究恢复

DOI：
发表时间：
2013
期刊：
Science
影响因子：
56.9
作者：
R. Fouchier;Adolfo García;Yoshihiro Kawaoka;Yoshihiro Kawaoka;Wendy S. Barclay;Nicole M. Bouvier;Ian H. Brown;Ilaria Capua;Hualan Chen;R. Compans;Robert B. Couch;Nancy J. Cox;Peter C. Doherty;R. Donis;Heinz Feldmann;Y. Guan;J. Katz;Oleg I. Kiselev;Hans;G. Kobinger;Jinhua Liu;Xiufan Liu;Anice C. Lowen;T. Mettenleiter;A. Osterhaus;P. Palese;J. S. M. Peiris;Daniel R. Perez;J. Richt;S. Schultz‐Cherry;J. Steel;Kanta Subbarao;D. Swayne;Toru Takimoto;Masato Tashiro;J. Taubenberger;Paul G. Thomas;Ralph A. Tripp;T. Tumpey;R. Webby;R. G. Webster
通讯作者：
R. G. Webster