Abstract
In comparison with the pervasive use of protein dimers and multimers in all domains of life, functional RNA oligomers have so far rarely been observed in nature. Their diminished occurrence contrasts starkly with the robust intrinsic potential of RNA to multimerize through long-range base-pairing (“kissing”) interactions, self-annealing of palindromic or complementary sequences, and stable tertiary contact motifs, such as the GNRA tetraloop-receptors. To explore the general mechanics of RNA dimerization, we performed a meta-analysis of a collection of exemplary RNA homodimer structures consisting of viral genomic elements, ribozymes, riboswitches, etc., encompassing both functional and fortuitous dimers. Globally, we found that domain-swapped dimers and antiparallel, head-to-tail arrangements are predominant architectural themes. Locally, we observed that the same structural motifs, interfaces and forces that enable tertiary RNA folding also drive their higher-order assemblies. These feature prominently long-range kissing loops, pseudoknots, reciprocal base intercalations and A-minor interactions. We postulate that the scarcity of functional RNA multimers and limited diversity in multimerization motifs may reflect evolutionary constraints imposed by host antiviral immune surveillance and stress sensing. A deepening mechanistic understanding of RNA multimerization is expected to facilitate investigations into RNA and RNP assemblies, condensates, and granules and enable their potential therapeutical targeting.
Highlights
Quaternary structures of biological macromolecules are frequently at the core of functional assemblies that enable life.Such higher-order structures form through a network of intermolecular interactions between individual modules employing recurring interfacial motifs to drive multimerization
We maintain a focus on RNA dimerization interfaces and structural motifs used to drive self-assembly with an emphasis on tertiary contacts in addition to base pairing
Retroviral genomic RNA (gRNA) dimerization frequently occurs a segment of their 50 leader region termed the dimer linkage site (DLS), as detailed below [38,39,40]
Summary
Quaternary structures of biological macromolecules are frequently at the core of functional assemblies that enable life. Mg2+ ions play the dual roles of serving as diffuse counter ions that ameliorate the electrostatic stress from juxtaposing densely charged phosphate backbones, as well as bridging specific tertiary contacts in the form of chelated ions [13] In contrast to their apparent biological rarity in cells, RNA multimers frequently emerge in vitro and often present a nuisance in the laboratory. Most of such in vitro multimers are believed to occur via fortuitous pairing of short segments of complementary sequences, when the RNA was heat-denatured and cooled slowly—a process that encourages strand annealing As such these in vitro multimers are similar in origin to those dsRNAs produced by sense-antisense hybridization events in cells. We maintain a focus on RNA dimerization interfaces and structural motifs used to drive self-assembly with an emphasis on tertiary contacts in addition to base pairing This meta-analysis revealed that kissing-loop interactions and complementary strand swapping are the predominant dimerization motifs.
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