Advances in high-throughput sequencing, single-cell profiling, and genome engineering have transformed the study of T cell receptors (TCRs), enabling the identification and functional interrogation of antigen-specific repertoires at an unprecedented scale. This review discusses how recent methodological developments-including high-dimensional TCR discovery strategies, physiological receptor engineering, and longitudinal in vivo analyses-have reshaped our understanding of TCR-driven immune responses. Recruitment into immune responses originates from diverse naïve precursor pools and results in polyclonal populations in which multiple clonotypes contribute to antigen recognition. Within such populations, receptor properties, such as TCR avidity, influence the likelihood of recruitment, expansion, and persistence. However, the impact of these parameters depends strongly on biological context, including antigen availability, cellular competition, and tissue environment. Physiological engineering approaches, such as orthotopic TCR replacement, now enable causal interrogation of receptor function while preserving endogenous regulatory control. Together with advances in spatial and longitudinal profiling of human immune responses, these approaches allow increasingly precise analyses of connections between TCR identity and T cell fate. Integrating insights across antigen discovery, receptor engineering, and in vivo dynamics suggests that TCR biology is shaped by the interplay of receptor sequence, regulatory context, and tissue environment across time. Understanding these relationships will be essential for interpreting immune responses and for guiding the rational design of T cell-based immunotherapies.
Kilian Schober (Thu,) studied this question.