RNA Topoisomerase Research Articles

DNA supercoiling enhances DNA condensation by ParB proteins.

The ParABS system plays a critical role in bacterial chromosome segregation. The key component of this system, ParB, loads and spreads along DNA to form a local protein-DNA condensate known as a partition complex. As bacterial chromosomes are heavily supercoiled due to the continuous action of RNA polymerases, topoisomerases and nucleoid-associated proteins, it is important to study the impact of DNA supercoiling on the ParB-DNA partition complex formation. Here, we use an in-vitro single-molecule assay to visualize ParB on supercoiled DNA. Unlike most DNA-binding proteins, individual ParB proteins are found to not pin plectonemes on supercoiled DNA, but freely diffuse along supercoiled DNA. We find that DNA supercoiling enhances ParB-DNA condensation, which initiates at lower ParB concentrations than on DNA that is torsionally relaxed. ParB proteins induce a DNA-protein condensate that strikingly absorbs all supercoiling writhe. Our findings provide mechanistic insights that have important implications for our understanding of bacterial chromosome organization and segregation.

Structural and biochemical basis for DNA and RNA catalysis by human Topoisomerase 3β

In metazoans, topoisomerase 3β (TOP3B) regulates R-loop dynamics and mRNA translation, which are critical for genome stability, neurodevelopment and normal aging. As a Type IA topoisomerase, TOP3B acts by general acid-base catalysis to break and rejoin single-stranded DNA. Passage of a second DNA strand through the transient break permits dissipation of hypernegative DNA supercoiling and catenation/knotting. Additionally, hsTOP3B was recently demonstrated as the human RNA topoisomerase, required for normal neurodevelopment and proposed to be a potential anti-viral target upon RNA virus infection. Here we elucidate the biochemical mechanisms of human TOP3B. We delineate the roles of divalent metal ions, and of a conserved Lysine residue (K10) in the differential catalysis of DNA and RNA. We also demonstrate that three regulatory factors fine-tune the catalytic performance of TOP3B: the TOP3B C-terminal tail, its protein partner TDRD3, and the sequence of its DNA/RNA substrates.

Interaction between transcribing RNA polymerase and topoisomerase I prevents R-loop formation in E. coli

Bacterial topoisomerase I (TopoI) removes excessive negative supercoiling and is thought to relax DNA molecules during transcription, replication and other processes. Using ChIP-Seq, we show that TopoI of Escherichia coli (EcTopoI) is colocalized, genome-wide, with transcribing RNA polymerase (RNAP). Treatment with transcription elongation inhibitor rifampicin leads to EcTopoI relocation to promoter regions, where RNAP also accumulates. When a 14 kDa RNAP-binding EcTopoI C-terminal domain (CTD) is overexpressed, colocalization of EcTopoI and RNAP along the transcription units is reduced. Pull-down experiments directly show that the two enzymes interact in vivo. Using ChIP-Seq and Topo-Seq, we demonstrate that EcTopoI is enriched upstream (within up to 12-15 kb) of highly-active transcription units, indicating that EcTopoI relaxes negative supercoiling generated by transcription. Uncoupling of the RNAP:EcTopoI interaction by either overexpression of EcTopoI competitor (CTD or inactive EcTopoI Y319F mutant) or deletion of EcTopoI domains involved in the interaction is toxic for cells and leads to excessive negative plasmid supercoiling. Moreover, uncoupling of the RNAP:EcTopoI interaction leads to R-loops accumulation genome-wide, indicating that this interaction is required for prevention of R-loops formation.

Small molecule targeting topoisomerase 3β for cancer therapy

DNA topoisomerases are proved cancer therapeutic targets with clinically successful anticancer drugs for decades. However, the role of RNA topoisomerase (TOP3β) remained mysterious especially in cancer, and no targeted agent has been reported yet. In a target identification assay of anti-cancer compound using a modified DrugTargetSeqR strategy, mutation of TOP3B was detected in cancer cells acquired resistance to cinobufagin (CBG), a key compound of Huachansu that has been approved for cancer therapy in China. We demonstrated that CBG directly engaged with TOP3β, and promoted TOP3β depletion in wildtype but not mutant cancer cells. Notably, knockout of TOP3β in cancer cells significantly reduced tumor enlargement but not initiation, and inhibited colony formation upon nutrient deprivation. We also demonstrated that CBG induced formation of stress granule, RNA-loop and asymmetric DNA damages in cancer cells, and all these phenotypes were significantly attenuated in TOP3B knockout cells. Of note, examination of a panel of cancer cell lines revealed associations among cell growth inhibition and induction of DNA damage as well as TOP3B depletion upon CBG treatment. Our findings not only highlighted TOP3β as a promising therapeutic target of cancer, but also identified CBG as a lead chemical inhibitor of TOP3β for cancer therapy.

Abundant Transmission of Corona Virus Nsp2 RNA Topoisomerse I120F Mutants with Concurrence D614G Spike Protein Mutation in Australia

We previously predicted Nsp2 Corona virus protein as RNA topoisomerase through amino acid homology among Vibrio haemolytica DNA topoisomerase IA/IV as well as DNA primase, DNA gyrase and bi-subunit Trypanosoma brucei DNA topoisomerase IB. Many DNA topoisomerase I/III have RNA topoisomerase activity and such ubiquitous enzymes are conserved and involved in the regulation of replication and transcription. We have checked here mutational profile of Nsp2 RNA topoisomerase analyzing >10000 orf 1a 4405 amino acid length Corona virus polyprotein. Mutant proteins were selected by BLAST search having 99.84% sequence similarity and 181- 818 aa portion NsP2 protein (protein id. QIU82057) was analyzed using CLUSTAL Omega software. We found 26 different mutations where most changes were selected at Isoleucine and Alanine into Valine or Leucine into Phenylanaline pinpointing conserved nature of the Corona virus RNA topoisomerase. Major nonsense very abundant mutations were found at I120F (Isoleucine to Phenylalanine). Other important mutations were R27C, I198V, T85I, L410F, I559V and P583S. The I120F mutation was abundant in Australian isolates and its spread was seen in the Bangladesh and other countries like USA. We suggest that abundant I120F mutation of Nsp2 Topoisomerase may increase transmission of Corona virus by stabilizing RNA structure for efficient virus packaging. Interestingly, such mutations were found in association of D614G mutation of Spike protein, known to >70% increase infectivity. On the contrary, all P583S Nsp2 mutants analyzed had no concurrence D614G spike protein mutation. Many silent mutations (5-7) were detected by genome wide analysis but no N501Y Spike protein mutation. This is first report that predicts a link of greater Corona virus transmission with Nsp2 protein I120F mutation and may be important to discover new anti-viral drugs.

A Type IA DNA/RNA Topoisomerase with RNA Hydrolysis Activity Participates in Ribosomal RNA Processing

Topoisomerases maintain topological homeostasis of bacterial chromosomes by catalysing changes in DNA linking number. The resolution of RNA entanglements occurring in the cell would also require catalytic action of topoisomerases. We describe RNA topoisomerase and hydrolysis activities in DNA topoisomerase I (topo I) from mycobacteria. The interaction of topo I with mRNA, tRNA and rRNA suggested its role in some aspect of RNA metabolism; the enzyme participates in rRNA maturation via its RNA hydrolysis activity. Accumulation of rRNA precursors in a topo I knockdown strain and the rescue of rRNA processing deficiency in RNaseE knockdown cells by topo I expression indicated the enzyme’s back-up support to RNases involved in rRNA processing. We demonstrate that the active-site tyrosine of the enzyme mediates catalytic reactions with both DNA/RNA substrates, and RNA topoisomerase activity can follow two reaction paths in contrast to its DNA topoisomerase activity. Mutation in the canonical proton relay pathway impacts DNA topoisomerase activity whilst retaining activity on RNA substrates. The mycobacterial topo I thus exemplifies the resourcefulness and parsimony of biological catalysis in harnessing the limited chemical repertoire at its disposal to find common solutions to mechanistically related challenges of phosphodiester breakage/exchange reactions in DNA and RNA that are essential for cell survival.

Coronavirus Nsp2 Protein Homologies to the Bacterial DNA Topoisomerase I and IV Suggest Nsp2 Protein is an Unique RNA Topoisomerase with Novel Target for Drug and Vaccine Development

COVID-19 is a deadly infectious (+) stranded RNA Virus which produces a 7098AA length polyprotein that degraded into sixteen polypeptides in infected human cells. As the Coronavirus infections now pandemic claiming >300000 peoples worldwide, discovery of molecular target is great. The biological functions of the Coronavirus non-structural nsp2 protein is unknown. BLAST search is the best method to understand the function of unknown protein on the basis of sequence homology among the known protein amino acid sequence available in the Genbank Database. Few type I DNA topoisomerases show RNA Topoisomerase activity and such activity was found in Nsp2 protein by homology search with Vibrio haemolyticus Type I and type IV DNA topoisomerase as well as E. coli DNA gyrase and DNA primase. The RNA topoisomearse activity of COVID-19 needed to release the RNA-RNA knots and supercoils during (-) strand synthesis followed by sub-genomic mRNA synthesis. Such enzyme would be a target for DNA topoisomerases inhibitors used against bacterial infections and cancer. We concluded that Nsp2 protein is related to Type I and type IVDNA Topoisomerase of Vibrio haemolyticawhere NH2-terminas of topoVI has similarity to CO2H terminas of Nsp2 protein and CO2H domains of topoI has similarity stretches to the NH2-terminus of Nsp2 protein. Deep sea thermophillic bacteria like Desulfococcus sp and Marinobacter sp DNA topoisomerase I have 25%-30% homologies with stretches. Thus, Nsp2 protein is a RNA Topoisomerase of Coronavirus and is a strong candidate for drug design and vaccine development. Thirty amino acids length peptide of Nsp2 protein (H2N-LVN KFL ALC ADSIII GGA KLK ALNLGE TFV-CO2H) may be a good peptide vaccine against Coronavirus. We also designed nsp2F1 primer (5’-CCT GAT AGT CTT GCC GA-3’) and nsp2R1 primer (5’-GAG CAG TTT CAA GAG TGC GG-3’) for RT-PCR based diagnosis of COVID-19 infection. We are first to determine the function of Nsp2 protein of Coronavirus using bioinformatics approach.

Single-Molecule Analysis and Engineering of DNA Motors.

Molecular motors are diverse enzymes that transduce chemical energy into mechanical work and, in doing so, perform critical cellular functions such as DNA replication and transcription, DNA supercoiling, intracellular transport, and ATP synthesis. Single-molecule techniques have been extensively used to identify structural intermediates in the reaction cycles of molecular motors and to understand how substeps in energy consumption drive transitions between the intermediates. Here, we review a broad spectrum of single-molecule tools and techniques such as optical and magnetic tweezers, atomic force microscopy (AFM), single-molecule fluorescence resonance energy transfer (smFRET), nanopore tweezers, and hybrid techniques that increase the number of observables. These methods enable the manipulation of individual biomolecules via the application of forces and torques and the observation of dynamic conformational changes in single motor complexes. We also review how these techniques have been applied to study various motors such as helicases, DNA and RNA polymerases, topoisomerases, nucleosome remodelers, and motors involved in the condensation, segregation, and digestion of DNA. In-depth analysis of mechanochemical coupling in molecular motors has made the development of artificially engineered motors possible. We review techniques such as mutagenesis, chemical modifications, and optogenetics that have been used to re-engineer existing molecular motors to have, for instance, altered speed, processivity, or functionality. We also discuss how single-molecule analysis of engineered motors allows us to challenge our fundamental understanding of how molecular motors transduce energy.

Combined cellomics and proteomics analysis reveals shared neuronal morphology and molecular pathway phenotypes for multiple schizophrenia risk genes

An enigma in studies of neuropsychiatric disorders is how to translate polygenic risk into disease biology. For schizophrenia, where > 145 significant GWAS loci have been identified and only a few genes directly implicated, addressing this issue is a particular challenge. We used a combined cellomics and proteomics approach to show that polygenic risk can be disentangled by searching for shared neuronal morphology and cellular pathway phenotypes of candidate schizophrenia risk genes. We first performed an automated high-content cellular screen to characterize neuronal morphology phenotypes of 41 candidate schizophrenia risk genes. The transcription factors Tcf4 and Tbr1 and the RNA topoisomerase Top3b shared a neuronal phenotype marked by an early and progressive reduction in synapse numbers upon knockdown in mouse primary neuronal cultures. Proteomics analysis subsequently showed that these three genes converge onto the syntaxin-mediated neurotransmitter release pathway, which was previously implicated in schizophrenia, but for which genetic evidence was weak. We show that dysregulation of multiple proteins in this pathway may be due to the combined effects of schizophrenia risk genes Tcf4, Tbr1, and Top3b. Together, our data provide new biological functions for schizophrenia risk genes and support the idea that polygenic risk is the result of multiple small impacts on common neuronal signaling pathways.

Topoisomerase 3\u03b2 interacts with RNAi machinery to promote heterochromatin formation and transcriptional silencing in Drosophila

Topoisomerases solve topological problems during DNA metabolism, but whether they participate in RNA metabolism remains unclear. Top3β represents a family of topoisomerases carrying activities for both DNA and RNA. Here we show that in Drosophila, Top3β interacts biochemically and genetically with the RNAi-induced silencing complex (RISC) containing AGO2, p68 RNA helicase, and FMRP. Top3β and RISC mutants are similarly defective in heterochromatin formation and transcriptional silencing by position-effect variegation assay. Moreover, both Top3β and AGO2 mutants exhibit reduced levels of heterochromatin protein HP1 in heterochromatin. Furthermore, expression of several genes and transposable elements in heterochromatin is increased in the Top3β mutant. Notably, Top3β mutants defective in either RNA binding or catalytic activity are deficient in promoting HP1 recruitment and silencing of transposable elements. Our data suggest that Top3β may act as an RNA topoisomerase in siRNA-guided heterochromatin formation and transcriptional silencing.

An Assay for Detecting RNA Topoisomerase Activity.

RNA topoisomerase activity has recently been detected in multiple Type IA DNA topoisomerases from all three domains of life: bacteria, archaea, and eukarya. Many, but not all, Type IA topoisomerases are found to possess activities for not only DNA, but also RNA, suggesting that they may solve topological problems for both types of nucleic acids. Here we describe a detailed assay used by our group to detect RNA topoisomerase activity for many Type IA topoisomerases. We discuss the strategy, experimental procedures, troubleshooting, and limitations for this assay.

Type IA DNA Topoisomerases: A Universal Core and Multiple Activities.

All the type IA topoisomerases display universal characteristics relying on a core region basically responsible for the transesterification and the strand passage reaction. First limited to the bacterial domain for a long time, these enzymes were further retrieved in Archaea and Eukarya as well. This is representative of an extremely ancient origin, probably due to an inheritance from the RNA world. As remaining evidence, some current topoisomerases IA have retained a RNA topoisomerase activity. Despite the presence of this core region in all of these TopoIAs, some differences exist and are originated from variable regions, located essentially within both extremities, conferring on them their specificities. During the last 2 decades the evidence of multiple activities and dedicated roles highlighted the importance of the topoisomerases IA. It is now obvious that topoisomerases IA are key enzymes involved in the maintenance of the genome stability. The discovery of these new activities was done thanks to the use of more accurate assays, based on new sophisticated DNA substrates.

Distinct Mechanism Evolved for Mycobacterial RNA Polymerase and Topoisomerase I Protein–Protein Interaction

We report here a distinct mechanism of interaction between topoisomerase I and RNA polymerase in Mycobacterium tuberculosis and Mycobacterium smegmatis that has evolved independently from the previously characterized interaction between bacterial topoisomerase I and RNA polymerase. Bacterial DNA topoisomerase I is responsible for preventing the hyper-negative supercoiling of genomic DNA. The association of topoisomerase I with RNA polymerase during transcription elongation could efficiently relieve transcription-driven negative supercoiling. Our results demonstrate a direct physical interaction between the C-terminal domains of topoisomerase I (TopoI-CTDs) and the β′ subunit of RNA polymerase of M. smegmatis in the absence of DNA. The TopoI-CTDs in mycobacteria are evolutionarily unrelated in amino acid sequence and three-dimensional structure to the TopoI-CTD found in the majority of bacterial species outside Actinobacteria, including Escherichia coli. The functional interaction between topoisomerase I and RNA polymerase has evolved independently in mycobacteria and E. coli, with distinctively different structural elements of TopoI-CTD utilized for this protein–protein interaction. Zinc ribbon motifs in E. coli TopoI-CTD are involved in the interaction with RNA polymerase. For M. smegmatis TopoI-CTD, a 27-amino-acid tail that is rich in basic residues at the C-terminal end is responsible for the interaction with RNA polymerase. Overexpression of recombinant TopoI-CTD in M. smegmatis competed with the endogenous topoisomerase I for protein–protein interactions with RNA polymerase. The TopoI-CTD overexpression resulted in decreased survival following treatment with antibiotics and hydrogen peroxide, supporting the importance of the protein–protein interaction between topoisomerase I and RNA polymerase during stress response of mycobacteria.

Type IA topoisomerases can be “magicians” for both DNA and RNA in all domains of life

ABSTRACTTopoisomerases solve critical topological problems in DNA metabolism and have long been regarded as the “magicians” of the DNA world. Here we present views from 2 of our recent studies indicating that Type IA topoisomerases from all domains of life often possess dual topoisomerase activities for both DNA and RNA. In animals, one of the 2 Type IA topoisomerases, Top3β, contains an RNA-binding domain, possesses RNA topoisomerase activity, binds mRNAs, interacts with mRNA-binding proteins, and associates with active mRNA translation machinery. The RNA-binding domain is required for Top3β to bind mRNAs and promote normal neurodevelopment. Top3β forms a highly conserved complex with Tudor-domain-containing 3 (TDRD3), a protein known to interact with translation factors, histones, RNA polymerase II, single stranded DNA and RNA. Top3β requires TDRD3 for its association with the mRNA translation machinery. We suggest that Type IA topoisomerases can be “magicians” for not only DNA, but also RNA; and they may solve topological problems for both nucleic acids in all domains of life. In animals, Top3β-TDRD3 is a dual-activity topoisomerase complex that can act on DNA to stimulate transcription, and on mRNA to promote translation.

Selective Inhibition of Escherichia coli RNA and DNA Topoisomerase I by Hoechst 33258 Derived Mono- and Bisbenzimidazoles.

A series of Hoechst 33258 based mono- and bisbenzimidazoles have been synthesized and their Escherichia coli DNA topoisomerase I inhibition, binding to B-DNA duplex, and antibacterial activity has been evaluated. Bisbenzimidazoles with alkynyl side chains display excellent E. coli DNA topoisomerase I inhibition properties with IC50 values <5.0 μM. Several bisbenzimidazoles (3, 6, 7, 8) also inhibit RNA topoisomerase activity of E. coli DNA topoisomerase I. Bisbenzimidazoles inhibit bacterial growth much better than monobenzimidazoles for Gram-positive strains. The minimum inhibitory concentration (MIC) was much lower for Gram positive bacteria (Enterococcus spp. and Staphylococcus spp., including two MRSA strains 0.3-8 μg/mL) than for the majority of Gram negative bacteria (Pseudomonas aeruginosa, 16-32 μg/mL, Klebsiella pneumoniae > 32 μg/mL). Bisbenzimidazoles showed varied stabilization of B-DNA duplex (1.2-23.4 °C), and cytotoxicity studies show similar variation dependent upon the side chain length. Modeling studies suggest critical interactions between the inhibitor side chain and amino acids of the active site of DNA topoisomerase I.

Synthesizing topological structures containing RNA

Though knotting and entanglement have been observed in DNA and proteins, their existence in RNA remains an enigma. Synthetic RNA topological structures are significant for understanding the physical and biological properties pertaining to RNA topology, and these properties in turn could facilitate identifying naturally occurring topologically nontrivial RNA molecules. Here we show that topological structures containing single-stranded RNA (ssRNA) free of strong base pairing interactions can be created either by configuring RNA–DNA hybrid four-way junctions or by template-directed synthesis with a single-stranded DNA (ssDNA) topological structure. By using a constructed ssRNA knot as a highly sensitive topological probe, we find that Escherichia coli DNA topoisomerase I has low RNA topoisomerase activity and that the R173A point mutation abolishes the unknotting activity for ssRNA, but not for ssDNA. Furthermore, we discover the topological inhibition of reverse transcription (RT) and obtain different RT–PCR patterns for an ssRNA knot and circle of the same sequence.

Exploring Molecular Interactions between Escherichia coli RNA Polymerase and Topoisomerase I by Molecular Simulations

Exploring Molecular Interactions between Escherichia coli RNA Polymerase and Topoisomerase I by Molecular Simulations

Topoisomerase 3β is the major topoisomerase for mRNAs and linked to neurodevelopment and mental dysfunction.

Human cells contain five topoisomerases in the nucleus and cytoplasm, but which one is the major topoisomerase for mRNAs is unclear. To date, Top3β is the only known topoisomerase that possesses RNA topoisomerase activity, binds mRNA translation machinery and interacts with an RNA-binding protein, FMRP, to promote synapse formation; and Top3β gene deletion has been linked to schizophrenia. Here, we show that Top3β is also the most abundant mRNA-binding topoisomerase in cells. Top3β, but not other topoisomerases, contains a distinctive RNA-binding domain; and deletion of this domain diminishes the amount of Top3β that associates with mRNAs, indicating that Top3β is specifically targeted to mRNAs by its RNA binding domain. Moreover, Top3β mutants lacking either its RNA-binding domain or catalytic residue fail to promote synapse formation, suggesting that Top3β requires both its mRNA-binding and catalytic activity to facilitate neurodevelopment. Notably, Top3β proteins bearing point mutations from schizophrenia and autism individuals are defective in association with FMRP; whereas one of the mutants is also deficient in binding mRNAs, catalyzing RNA topoisomerase reaction, and promoting synapse formation. Our data suggest that Top3β is the major topoisomerase for mRNAs, and requires both RNA binding and catalytic activity to promote neurodevelopment and prevent mental dysfunction.

DNA and RNA topoisomerase activities of Top3β are promoted by mediator protein Tudor domain-containing protein 3

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 single-stranded 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.

RNA topoisomerase is prevalent in all domains of life and associates with polyribosomes in animals

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.