Quantitative Control of Transposable Elements: From Genome Plasticity to Immune Regulatory Circuits
Irving Jesús Reyes‐BarragánABSTRACT
Transposable elements (TEs) constitute nearly half of the human genome and are increasingly recognized as context‐dependent regulators of genome function rather than passive repetitive DNA. This Review synthesizes classical and recent evidence on TE biology, including TE classification, mechanisms of mobilization, host restriction pathways, insertional mutagenesis, and contributions to gene regulation. We emphasize that TE activity operates across a spectrum: controlled TE expression can contribute cis‐regulatory modules, non‐coding RNAs, chromatin states, and immune enhancers, whereas excessive or misregulated TE activity can promote genome instability, innate immune activation, and inflammatory pathology. To reduce conceptual redundancy, we organize these processes within an integrative framework, the Transposon Circuitry Theory of Immune Regulation (TACTIR), which links TE‐derived modules, chromatin control of TE transcription, stress pathways, and immune gene networks. In this model, TE‐derived enhancers and transcription factor motifs may shape stimulus‐responsive gene expression, while TE transcripts and reverse‐transcribed products can engage innate immune sensors under specific states of derepression. We also discuss how TE‐linked regulatory states may contribute to trained immunity and T‐cell dysfunction, while distinguishing established mechanisms from inferred or hypothetical links. Clinically, we place TE‐mediated insertional disease, cancer‐associated TE dysregulation, and immune modulation in appropriate context, noting that TE insertions account for a minority of genetic disease cases but provide important mechanistic examples of genome vulnerability. Finally, we consider how genome‐editing approaches and transposon‐derived tools can clarify TE function and enable translational applications. Together, this Review frames TEs as regulated genomic elements that connect genome plasticity, immune responsiveness, and disease susceptibility.