Identification of antigen-specific TCR sequences based on biological and statistical enrichment in unselected individuals
Neal P. Smith, … , J. Christopher Love, Wayne G. Shreffler
Neal P. Smith, … , J. Christopher Love, Wayne G. Shreffler
Published May 25, 2021
Citation Information: JCI Insight. 2021;6(13):e140028. https://doi.org/10.1172/jci.insight.140028.
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Resource and Technical Advance Immunology

Identification of antigen-specific TCR sequences based on biological and statistical enrichment in unselected individuals

Abstract

Recent advances in high-throughput T cell receptor (TCR) sequencing have allowed for new insights into the human TCR repertoire. However, methods for capturing antigen-specific repertoires remain an area of development. Here, we describe a potentially novel approach that utilizes both a biological and statistical enrichment to define putatively antigen-specific complementarity-determining region 3 (CDR3) repertoires in unselected individuals. The biological enrichment entailed FACS of in vitro antigen-activated memory CD4+ T cells, followed by TCRβ sequencing. The resulting TCRβ sequences were then filtered by selecting those that are statistically enriched when compared with their frequency in the autologous resting T cell compartment. Applying this method to define putatively peanut protein–specific repertoires in 27 peanut-allergic individuals resulted in a library of 7345 unique CDR3β amino acid sequences that had similar characteristics to other validated antigen-specific repertoires in terms of homology and diversity. In-depth analysis of these CDR3βs revealed 36 public sequences that demonstrated high levels of convergent recombination. In a network analysis, the public CDR3βs were shown to be core sequences with more edges than their private counterparts. This method has the potential to be applied to a wide range of T cell–mediated disorders and to yield new biomarkers and biological insights.

Authors

Neal P. Smith, Bert Ruiter, Yamini V. Virkud, Ang A. Tu, Brinda Monian, James J. Moon, J. Christopher Love, Wayne G. Shreffler

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Figure 5

Network analysis reveals that public putatively peanut-specific CDR3β sequences are core sequences with more structure than activated and resting CDR3βs.

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Network analysis reveals that public putatively peanut-specific CDR3β se...
(A) Network analysis of putatively peanut-specific CDR3β sequences (ps-CDR3s), where each node represents a unique ps-CDR3 amino acid sequence. Edges were created between the nodes if these were within a Levenshtein distance of 1 or if the nodes shared an enriched motif. Self-edges were created on nodes to represent additional unique nucleotide sequences encoding the same amino acid sequence (i.e., convergence). Blue nodes represent private ps-CDR3s, and red nodes represent public ps-CDR3s. (B) The percentage of public ps-CDR3s with an edge to another ps-CDR3 (as shown in A) was higher than that of private ps-CDR3s (**P < 0.01, Fisher’s exact test). (C) The overall node degree (number of edges per node) of public ps-CDR3s was higher than that of private ps-CDR3s. Box plots represent distribution of the node degree of all private (blue) and public (red) ps-CDR3s in the graph (**P < 0.01, Mann-Whitney U test). (D) The number of total edges created among the ps-CDR3s compared with the median number of edges created among 100 equal-sized random resamplings of total activated and resting CDR3βs. Error bars represent standard deviation (**P < 0.01, Z test).