High-Throughput Sequencing of the T-Cell Receptor Beta Chain Gene Repertoire in Chronic Lymphocytic Leukemia.

High-throughput, next-generation sequencing (NGS) offers a unique opportunity for in-depth characterization of adaptive immune receptor repertoires. Nevertheless, limitations and pitfalls exist in every step of both the experimental and the analytical procedure, leading to discrepancies in the literature and incomprehensive and/or altogether misleading results. Thus, standardization of protocols in NGS immunogenetics is urgently needed.Here, we describe the experimental protocol that we developed for T-cell receptor beta chain (TRB) gene repertoire analysis in chronic lymphocytic leukemia, aiming to provide a reproducible and biologically meaningful output. Although optimized for TRBV-TRBD-TRBJ gene rearrangements, this protocol may be customized for other adaptive immune receptor sequences, as well.

Restrictions in the T-cell repertoire of chronic lymphocytic leukemia: high-throughput immunoprofiling supports selection by shared antigenic elements.

Immunoglobulin (IG) gene repertoire restrictions strongly support antigen selection in the pathogenesis of chronic lymphocytic leukemia (CLL). Given the emerging multifarious interactions between CLL and bystander T cells, we sought to determine whether antigen(s) are also selecting T cells in CLL. We performed a large-scale, next-generation sequencing (NGS) study of the T-cell repertoire, focusing on major stereotyped subsets representing CLL subgroups with undisputed antigenic drive, but also included patients carrying non-subset IG rearrangements to seek for T-cell immunogenetic signatures ubiquitous in CLL. Considering the inherent limitations of NGS, we deployed bioinformatics algorithms for qualitative curation of T-cell receptor rearrangements, and included multiple types of controls. Overall, we document the clonal architecture of the T-cell repertoire in CLL. These T-cell clones persist and further expand overtime, and can be shared by different patients, most especially patients belonging to the same stereotyped subset. Notably, these shared clonotypes appear to be disease-specific, as they are found in neither public databases nor healthy controls. Altogether, these findings indicate that antigen drive likely underlies T-cell expansions in CLL and may be acting in a CLL subset-specific context. Whether these are the same antigens interacting with the malignant clone or tumor-derived antigens remains to be elucidated.