Uncovering the Heterogeneity and Ontogeny of Mouse Thymic Macrophages Reveals an Unexpected Early Checkpoint Role

Thymic macrophages (TMs) are critical for maintaining thymus homeostasis, yet their heterogeneity and specific functions in T cell development remain unclear. Through single-cell RNA sequencing and transgenic reporter mice, we revealed two novel TM subsets characterized by distinct surface markers and transcriptional programs. TIMD4+ VCAM1+ CX3CR1- TMs were enriched for phagocytic and apoptotic cell-clearance pathways, whereas TIMD4- VCAM1+ CX3CR1+ TMs exhibited elevated expression of antigen-presentation machinery and interferon-response genes. Pseudotime trajectory analysis indicated a potential lineage progression from TIMD4- VCAM1+ CX3CR1+ precursors toward TIMD4+ VCAM1+ CX3CR1- effectors. Functional interrogation using fetal thymic organ cultures and the MaFIA depletion mouse model demonstrated that acute loss of TMs severely impaired thymocyte development, particularly at the pre-T cell receptor (TCR) {beta}-selection checkpoint. TM ablation led to marked reductions in post-{beta}-selection thymocyte subsets, implicating TMs in both survival and differentiation signals required for early T cell development. Mechanistically, TM depletion disrupted pre-TCR signaling and hindered transition through {beta}-selection, likely due to absence of both apoptotic-cell clearance and differentiation cues provided by specialized TM subsets. These findings define two distinct TM populations and establish their role in orchestrating thymocyte maturation. By elucidating TM subset specialization and their dynamic contributions to the {beta}-selection process, our findings advance our understanding of thymic microenvironment interactions and highlights macrophage heterogeneity as a key regulator of T cell development.