DNA Topoisomerases are essential to resolve topological problems during DNA metabolism in all species. However, the prevalence and function of RNA topoisomerases remain uncertain. Here, we show that RNA topoisomerase activity is prevalent in Type IA topoisomerases from bacteria, archaea, and eukarya. Moreover, this activity always requires the conserved Type IA core domains and the same catalytic residue used in DNA topoisomerase reaction; however, it does not absolutely require the non-conserved carboxyl-terminal domain (CTD), which is necessary for relaxation reactions of supercoiled DNA. The RNA topoisomerase activity of human Top3β differs from that of Escherichia coli topoisomerase I in that the former but not the latter requires the CTD, indicating that topoisomerases have developed distinct mechanisms during evolution to catalyze RNA topoisomerase reactions. Notably, Top3β proteins from several animals associate with polyribosomes, which are units of mRNA translation, whereas the Top3 homologs from E. coli and yeast lack the association. The Top3β-polyribosome association requires TDRD3, which directly interacts with Top3β and is present in animals but not bacteria or yeast. We propose that RNA topoisomerases arose in the early RNA world, and that they are retained through all domains of DNA-based life, where they mediate mRNA translation as part of polyribosomes in animals.
Topoisomerase 3β (Top3β) can associate with the mediator protein Tudor domain-containing protein 3 (TDRD3) to participate in two gene expression processes of transcription and translation. Despite the apparent importance of TDRD3 in binding with Top3β and directing it to cellular compartments critical for gene expression, the biochemical mechanism of how TDRD3 can affect the functions of Top3β is not known. We report here sensitive biochemical assays for the activities of Top3β on DNA and RNA substrates in resolving topological entanglements and for the analysis of TDRD3 functions. TDRD3 stimulates the relaxation activity of Top3β on hypernegatively supercoiled DNA and changes the reaction from a distributive to a processive mode. Both supercoil retention assays and binding measurement by fluorescence anisotropy reveal a heretofore unknown preference for binding single-stranded nucleic acids over duplex. Whereas TDRD3 has a structure-specific binding preference, it does not discriminate between DNA and RNA. This unique property for binding with nucleic acids can have an important function in serving as a hub to form nucleoprotein complexes on DNA and RNA. To gain insight into the roles of Top3β on RNA metabolism, we designed an assay by annealing two singlestranded RNA circles with complementary sequences. Top3β is capable of converting two such single-stranded RNA circles into a double-stranded RNA circle, and this strand-annealing activity is enhanced by TDRD3. These results demonstrate that TDRD3 can enhance the biochemical activities of Top3β on both DNA and RNA substrates, in addition to its function of targeting Top3β to critical sites in subcellular compartments.Tudor domain-containing domain 3 | DNA topoisomerases | RNA topoisomerases | RNA circles | RNA duplex H igher-order structural complexities in nucleic acids can be brought about by the folding and intertwining through interand intramolecular base pairing. They are impediments to the transactions of genetic information, including replication, transcription, recombination, and translation, which involve the unwinding and rewinding of base-paired regions to access encoded information (1-3). DNA topoisomerases are nature's tools to resolve the topological entanglements in nucleic acids. They are ubiquitous in nature, first discovered in bacteria in 1971 (4), and in mammalian cells in 1972 (5), and are characterized by a mechanism involving the formation of a covalent protein/DNA adduct to generate a transient and reversible break allowing for topological transformation (6). Based on whether the strand passage is through a protein-mediated single-stranded gate or a double-stranded gate, the enzymes are classified into type I or type II topoisomerases, respectively. Both types are further classified into A and B families based on their structural and mechanistic features (7). All topoisomerases are essential for the growth and development of an organism, suggesting that they have critical but distinct functions in all cells.Ever since their discovery, t...
Hemicatenane is a structure that forms when two DNA duplexes are physically linked through a single-stranded crossover. It is proposed to be an intermediate resulting from double Holliday junction (dHJ) dissolution, repair of replication stalled forks and late stage replication. Our previous study has shown that hemicatenane can be synthesized and dissolved in vitro by hyperthermophilic type IA topoisomerases. Here we present the protocol of hemicatenane synthesis and its structure detection by 2D agarose gel electrophoresis. The generated product can be used as a substrate to study the biochemical mechanism of hemicatenane processing reactions.
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