Cross-reactive public TCR sequences undergo positive selection in the human thymic repertoire
Mohsen Khosravi-Maharlooei, … , Todd M. Brusko, Megan Sykes
Mohsen Khosravi-Maharlooei, … , Todd M. Brusko, Megan Sykes
Published March 28, 2019
Citation Information: J Clin Invest. 2019;129(6):2446-2462. https://doi.org/10.1172/JCI124358.
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Research Article Autoimmunity Immunology

Cross-reactive public TCR sequences undergo positive selection in the human thymic repertoire

Abstract

We studied human T cell repertoire formation using high-throughput T cell receptor β (TCRβ) complementarity-determining region 3 (CDR3) sequencing in immunodeficient mice receiving human hematopoietic stem cells (HSCs) and human thymus grafts. Replicate humanized mice generated diverse and highly divergent repertoires. We observed repertoire narrowing and increased CDR3β sharing during thymocyte selection. Whereas hydrophobicity analysis implicated self-peptides in positive selection of the overall repertoire, positive selection favored shorter shared sequences that had reduced hydrophobicity at positions 6 and 7 of CDR3βs, suggesting weaker interactions with self-peptides than were observed with unshared sequences, possibly allowing escape from negative selection. Sharing was similar between autologous and allogeneic thymi and occurred between different cell subsets. Shared sequences were enriched for allo–cross-reactive CDR3βs and for type 1 diabetes–associated autoreactive CDR3βs. Single-cell TCR sequencing showed increased sharing of CDR3αs compared with CDR3βs between mice. Our data collectively implicate preferential positive selection for shared human CDR3βs that are highly cross-reactive. Although previous studies suggested a role for recombination bias in producing “public” sequences in mice, our study is the first to our knowledge to demonstrate a role for thymic selection. Our results implicate positive selection for promiscuous TCRβ sequences that probably evade negative selection, given their low affinity for self-ligands, in the abundance of “public” human TCRβ sequences.

Authors

Mohsen Khosravi-Maharlooei, Aleksandar Obradovic, Aditya Misra, Keshav Motwani, Markus Holzl, Howard R. Seay, Susan DeWolf, Grace Nauman, Nichole Danzl, Haowei Li, Siu-hong Ho, Robert Winchester, Yufeng Shen, Todd M. Brusko, Megan Sykes

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Figure 5

Overlap between different cell subsets and enrichment for cross-reactive/autoreactive CDR3βs among shared sequences.

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Overlap between different cell subsets and enrichment for cross-reactive...
(A) Proportions of shared CDR3βs between paired cell populations in each thymus graft in experiment 2 (aa level) among all versus the 100 most frequent CDR3βs (n = 6). Potentially ambiguous sequences present in more than 1 cell population were not removed from this analysis. Supplemental Table 11 shows the average number of unique nucleotide sequences per aa sequence for shared versus unshared CDR3βs between SP-CD4 and SP-CD8 cells. (B) Proportion of shared CDR3βs with a shared Vβ gene, Jβ gene, and Vβ-Jβ pair, comparing each pair of SP cell populations in each mouse in experiment 2. (C and D) ORs of cross-reactivity in shared versus unshared sequences, sharing in cross-reactive versus allo–non–cross-reactive sequences, and T1D reactivity in shared versus unshared sequences for experiments 1, 2, and 3. P values are shown in Supplemental Table 12. (E) Clone fraction and cumulative frequency of T1D-reactive CDR3βs in different cell subsets in experiment 2. *P < 0.05 and ***P < 0.001, by unpaired t test with Bonferroni’s correction (A) and paired t test with Bonferroni’s correction (paired by mouse) (E). Box-and-whisker plots show the median, range, interquartile range, and outliers.