Integrated Symbiotic Pleiotropy: Long Non-Coding RNAs and Disordered Proteins Interweaving the Functional Layers of the Eukaryotic Cell

Long non-coding RNAs (lncRNAs) and RNA–protein complexes (RNPs) are increasingly recognized as central to the regulatory complexity of modern eukaryotes. This review proposes that the remarkable diversity of eukaryotic systems arises from the long-term integration of ancient RNA/RNP mechanisms, layered with innovations introduced by successive symbioses. We outline four interconnected levels of symbiosis contributing to this process: (1) molecular symbiosis, involving dynamic assemblies of RNAs, proteins, and membraneless organelles (MLOs); (2) genome symbiosis, driven by the expansion of non-coding and repetitive DNA; (3) intracellular symbiosis, initiated by mitochondria acquisition; and (4) intercellular symbiosis, rooted in the cellular cooperation that enables multicellularity. We highlight lncRNAs and intrinsically disordered proteins (IDPs) as versatile mediators that interweave interactions across scales, predominantly within phase-separated condensates. Building upon these multi-level processes, we propose the framework of integrated symbiotic pleiotropy—a concept where molecular components acquire layered functional roles as a direct consequence of successive symbiotic acquisitions. This paradigm unites information layering, functional moonlighting, molecular tinkering, and exaptation into a coherent trajectory for eukaryotic evolution.