Abstract
A critical unresolved problem involving the many demonstrated functional roles of lncRNAs is how they generate coordinated regulatory effects that scale from local gene control to genome-wide programs. Pervasive transcription places lncRNAs in antisense, divergent, intronic, and intergenic configurations, yet no current model links these arrangements to their regulatory scope or reconciles local cis effects with long-range trans communication. Here, a Topological Regulatory Logic (TRL) framework is proposed in which lncRNA functions are organized by genomic topology and are manifested through seven mechanistic layers operating within a five-tier hierarchy. As used here, topology refers to the positional and relational organization of transcription units within both linear genomic sequence and three-dimensional nuclear space. In the TRL framework, topology defines regulatory opportunity and coordinative capacity, whereas molecular mechanisms determine the magnitude and direction of regulatory effects. This distinction suggests that genome regulation operates through two complementary levels of control. Protein-based regulators provide precision through sequence-specific recognition, whereas lncRNA topology enables coordination across genomic space through overlap, divergence, intronic embedding, chromatin-domain association, and subnuclear localization. Three organizing principles—spatial coupling, kinetic buffering, and architectural memory—unify these diverse functions. This Perspective develops the TRL framework not simply as a classification system but as a conceptual model for understanding how pervasive transcription contributes to coordinated genome regulation across multiple biological scales.