Overexpression of type I topoisomerases sensitizes yeast cells to DNA damage

DNA topoisomerases play essential roles in many DNA metabolic processes. It has been suggested that topoisomerases play an essential role in DNA repair. Topoisomerases can introduce DNA damage upon exposure to drugs that stabilize the covalent protein-DNA intermediate of the topoisomerase reaction. Lesions in DNA are also able to trap topoisomerase-DNA intermediates, suggesting that topoisomerases have the potential to either assist in DNA repair by locating sites of damage or exacerbating DNA damage by generation of additional damage at the site of a lesion. We have shown that overexpression of yeast topoisomerase I (TOP1) conferred hypersensitivity to methyl methanesulfonate and other DNA-damaging agents, whereas expression of a catalytically inactive enzyme did not. Overexpression of topoisomerase II did not change the sensitivity of cells to these DNA-damaging agents. Yeast cells lacking TOP1 were not more resistant to DNA damage than cells expressing wild type levels of the enzyme. Yeast topoisomerase I covalent complexes can be trapped efficiently on UV-damaged DNA. We suggest that TOP1 does not participate in the repair of DNA damage in yeast cells. However, the enzyme has the potential of exacerbating DNA damage by forming covalent DNA-protein complexes at sites of DNA damage.     

Analysis of RuvABC and RecG Involvement in the Escherichia coli Response to the Covalent Topoisomerase-DNA Complex

Topoisomerases form a covalent enzyme-DNA intermediate after initial DNA cleavage. Trapping of the cleavage complex formed by type IIA topoisomerases initiates the bactericidal action of fluoroquinolones. It should be possible also to identify novel antibacterial lead compounds that act with a similar mechanism on type IA bacterial topoisomerases. The cellular response and repair pathways for trapped topoisomerase complexes remain to be fully elucidated. The RuvAB and RecG proteins could play a role in the conversion of the initial protein-DNA complex to double-strand breaks and also in the resolution of the Holliday junction during homologous recombination. Escherichia coli strains with ruvA and recG mutations are found to have increased sensitivity to low levels of norfloxacin treatment, but the mutations had more pronounced effects on survival following the accumulation of covalent complexes formed by mutant topoisomerase I defective in DNA religation. Covalent topoisomerase I and DNA gyrase complexes are converted into double-strand breaks for SOS induction by the RecBCD pathway. SOS induction following topoisomerase I complex accumulation is significantly lower in the ruvA and recG mutants than in the wild-type background, suggesting that RuvAB and RecG may play a role in converting the initial single-strand DNA-protein cleavage complex into a double-strand break prior to repair by homologous recombination. The use of a ruvB mutant proficient in homologous recombination but not in replication fork reversal demonstrated that the replication fork reversal function of RuvAB is required for SOS induction by the covalent complex formed by topoisomerase I.DNA topoisomerases can modulate DNA superhelicity and help overcome topological barriers in cellular processes by cleaving the DNA backbone phosphodiester linkage to allow topological changes in DNA substrates. The ends of the cleaved DNA are covalently linked to an active-site tyrosine on the topoisomerase proteins in cleavage complex intermediates. Covalent protein-DNA complexes exist only transiently during catalysis because the cleaved DNA is rapidly religated. The stabilization of covalent complexes formed by human topoisomerase I or II due to the action of certain anticancer drugs results in the apoptotic death of cancer cells. Quinolone antibiotics are highly bactericidal because they cause the accumulation of covalent complexes formed by bacterial DNA gyrase and topoisomerase IV enzymes. Although a similar topoisomerase poison inhibitor remains to be identified for bacterial type IA topoisomerases, bacterial topoisomerase I complex accumulation due to mutations that inhibit DNA religation has also been shown to cause rapid bacterial cell death (4, 36). The requirement of a DNA cleavage step in the mechanism of action of topoisomerases increases the vulnerability of cells to conditions that would trap the covalent protein-DNA complex. These conditions include the presence of DNA intercalators, toxic metabolites, and DNA lesions, as well as protein thiolation (9, 28-31, 38). Response to and repair of the trapped covalent topoisomerase-DNA complex are thus needed for cell survival. In eukaryotes, 3′-tyrosyl DNA phosphodiesterase (TDP1) and 5′-tyrosyl DNA phosphodiesterase (TDP2), which can cleave the covalent linkage between topoisomerases and DNA, have been identified (8, 15, 27). Tyrosyl DNA phosphodiesterases have not been identified in bacteria. Repair of covalent bacterial topoisomerase-DNA complexes may require the action of endonucleases to remove the DNA-bound topoisomerase proteins, similar to the Rad1-Rad10 repair pathway characterized in yeast (37). In Escherichia coli, covalent topoisomerase I and DNA gyrase complexes have been shown to be processed into double-strand DNA breaks (DSB), which are then repaired via the RecBCD-mediated RecA homologous recombination pathway with induction of the SOS regulon (24, 34). The RuvABC and RecG activities could play significant roles in the response to the covalent topoisomerase complexes. They are both capable of resolving the Holliday junctions following DSB formation in the later stages of homologous recombination repair (11). SbcCD has been shown previously to remove protein from a protein-bound DNA end with nucleolytic activity to create a DSB (7). In addition, it is also possible that RuvAB and RecG might act at arrested forks to process replication forks blocked by the covalently bound topoisomerase proteins and generate DSB substrates for RecBCD (1, 32). Previous studies have not clearly elucidated the roles of RuvABC and RecG in the response to covalent topoisomerase complexes. We examine here the effects of mutations in the ruvA and recG genes on both bacterial survival and SOS induction following the accumulation of covalent topoisomerase I or gyrase complexes with cleaved DNA.     

Proteolytic Degradation of Topoisomerase II (Top2) Enables the Processing of Top2·DNA and Top2·RNA Covalent Complexes by Tyrosyl-DNA-Phosphodiesterase 2 (TDP2)

Eukaryotic type II topoisomerases (Top2α and Top2β) are homodimeric enzymes; they are essential for altering DNA topology by the formation of normally transient double strand DNA cleavage. Anticancer drugs (etoposide, doxorubicin, and mitoxantrone) and also Top2 oxidation and DNA helical alterations cause potentially irreversible Top2·DNA cleavage complexes (Top2cc), leading to Top2-linked DNA breaks. Top2cc are the therapeutic mechanism for killing cancer cells. Yet Top2cc can also generate recombination, translocations, and apoptosis in normal cells. The Top2 protein-DNA covalent complexes are excised (in part) by tyrosyl-DNA-phosphodiesterase 2 (TDP2/TTRAP/EAP2/VPg unlinkase). In this study, we show that irreversible Top2cc induced in suicidal substrates are not processed by TDP2 unless they first undergo proteolytic processing or denaturation. We also demonstrate that TDP2 is most efficient when the DNA attached to the tyrosyl is in a single-stranded configuration and that TDP2 can efficiently remove a tyrosine linked to a single misincorporated ribonucleotide or to polyribonucleotides, which expands the TDP2 catalytic profile with RNA substrates. The 1.6-Å resolution crystal structure of TDP2 bound to a substrate bearing a 5′-ribonucleotide defines a mechanism through which RNA can be accommodated in the TDP2 active site, albeit in a strained conformation.     

Vaccinia virus DNA ligase recruits cellular topoisomerase II to sites of viral replication and assembly

Vaccinia virus replication is inhibited by etoposide and mitoxantrone even though poxviruses do not encode the type II topoisomerases that are the specific targets of these drugs. Furthermore, one can isolate drug-resistant virus carrying mutations in the viral DNA ligase and yet the ligase is not known to exhibit sensitivity to these drugs. A yeast two-hybrid screen was used to search for proteins binding to vaccinia ligase, and one of the nine proteins identified comprised a portion (residue 901 to end) of human topoisomerase IIbeta. One can prevent the interaction by introducing a C(11)-to-Y substitution mutation into the N terminus of the ligase bait protein, which is one of the mutations conferring etoposide and mitoxantrone resistance. Coimmunoprecipitation methods showed that the native ligase and a Flag-tagged recombinant protein form complexes with human topoisomerase IIalpha/beta in infected cells and that this interaction can also be disrupted by mutations in the A50R (ligase) gene. Immunofluorescence microscopy showed that both topoisomerase IIalpha and IIbeta antigens are recruited to cytoplasmic sites of virus replication and that less topoisomerase was recruited to these sites in cells infected with mutant virus than in cells infected with wild-type virus. Immunoelectron microscopy confirmed the presence of topoisomerases IIalpha/beta in virosomes, but the enzyme could not be detected in mature virus particles. We propose that the genetics of etoposide and mitoxantrone resistance can be explained by vaccinia ligase binding to cellular topoisomerase II and recruiting this nuclear enzyme to sites of virus biogenesis. Although other nuclear DNA binding proteins have been detected in virosomes, this appears to be the first demonstration of an enzyme being selectively recruited to sites of poxvirus DNA synthesis and assembly.     

Sequence specific interaction of Mycobacterium smegmatis topoisomerase I with duplex DNA.

We have identified strong topoisomerase sites (STS) for Mycobacteruim smegmatis topoisomerase I in double-stranded DNA context using electrophoretic mobility shift assay of enzyme-DNA covalent complexes. Mg2+, an essential component for DNA relaxation activity of the enzyme, is not required for binding to DNA. The enzyme makes single-stranded nicks, with transient covalent interaction at the 5'-end of the broken DNA strand, a characteristic akin to prokaryotic topoisomerases. More importantly, the enzyme binds to duplex DNA having a preferred site with high affinity, a property similar to the eukaryotic type I topoisomerases. The preferred cleavage site is mapped on a 65 bp duplex DNA and found to be CG/TCTT. Thus, the enzyme resembles other prokaryotic type I topoisomerases in mechanistics of the reaction, but is similar to eukaryotic enzymes in DNA recognition properties.     

Molluscum Contagiosum Virus Topoisomerase: Purification, Activities, and Response to Inhibitors

Molluscum contagiosum virus (MCV), the only member of the Molluscipoxvirus genus, causes benign papules in healthy people but disfiguring lesions in immunocompromised patients. The sequence of MCV has been completed, revealing that MCV encodes a probable type I topoisomerase enzyme. All poxviruses sequenced to date also encode type I topoisomerases, and in the case of vaccinia virus the topoisomerase has been shown to be essential for replication. Thus, inhibitors of the MCV topoisomerase might be useful as antiviral agents. We have cloned the gene for MCV topoisomerase, overexpressed and purified the protein, and begun to characterize its activities in vitro. Like other eukaryotic type I topoisomerases, MCV topoisomerase can relax both positive and negative supercoils. An analysis of the cleavage of plasmid and oligonucleotide substrates indicates that cleavage by MCV topoisomerase is favored just 3′ of the sequence 5′ (T/C)CCTT 3′, resulting in formation of a covalent bond to the 3′ T residue, as with other poxvirus topoisomerases. We identified solution conditions favorable for activity and measured the rate of formation and decay of the covalent intermediate. MCV topoisomerase is sensitive to inhibition by coumermycin A1 (50% inhibitory concentration, 32 μM) but insensitive to five other previously reported topoisomerase inhibitors. This work provides the point of departure for studies of the mechanism of function of MCV topoisomerase and the development of medically useful inhibitors.     

RNA capping enzyme and DNA ligase: a superfamily of covalent nucleotidyl transferases

mRNA capping entails GMP transfer from GTP to a 5' diphosphate RNA end to form the structure G(5')ppp(5')N. A similar reaction involving AMP transfer to the 5' monophosphate end of DNA or RNA occurs during strand joining by polynucleotide ligases. In both cases, nucleotidyl transfer occurs through a covalent lysyl-NMP intermediate. Sequence conservation among capping enzymes and ATP-dependent ligases in the vicinity of the active site lysine (KxDG) and at five other co-linear motifs suggests a common structural basis for covalent catalysis. Mutational studies support this view. We propose that the cellular and DNA virus capping enzymes and ATP-dependent ligases constitute a protein superfamily evolved from a common ancestral enzyme. Within this superfamily, the cellular capping enzymes display more extensive similarity to the ligases than they do to the poxvirus capping enzymes. Recent studies suggest that eukaryotic RNA viruses have evolved alternative pathways of cap metabolism catalysed by structurally unrelated enzymes that nonetheless employ a phosphoramidate intermediate. Comparative analysis of these enzymes, particularly at the structural level, should illuminate the shared reaction mechanism while clarifying the basis for nucleotide specificity and end recognition. The capping enzymes merit close attention as potential targets for antiviral therapy.     

Evodiamine, a dual catalytic inhibitor of type I and II topoisomerases, exhibits enhanced inhibition against camptothecin resistant cells

DNA topoisomerases are nuclear enzymes that are the targets for several anticancer drugs. In this study we investigated the antiproliferative activity against human leukaemia cell lines and the effects on topoisomerase I and II of evodiamine, which is a quinazolinocarboline alkaloid isolated from the fruit of a traditional Chinese medicinal plant, Evodia rutaecarpa. We report here the anti-proliferative activity against human leukaemia cells K562, THP-1, CCRF-CEM and CCRF-CEM/C1 and the inhibitory mechanism on human topoisomerases I and II, important anti-cancer drugs targets, of evodiamine. Evodiamine failed to trap [Topo-DNA] complexes and induce any detectable DNA damage in cells, was unable to bind or intercalate DNA, and arrested cells in the G(2)/M phase. The results suggest evodiamine is a dual catalytic inhibitor of topoisomerases I and II, with IC(50) of 60.74 and 78.81 μM, respectively. The improved toxicity towards camptothecin resistant cells further supports its inhibitory mechanism which is different from camptothecin, and its therapeutic potential.     

DNA-topoisomerases of animal cells

The properties and functions of the DNA topoisomerases are reviewed on the basis of the literature and the author's own data. The techniques of isolation and characterization of the covalent complexes of the topoisomerases with DNA are described.     

Norfloxacin-induced DNA gyrase cleavage complexes block Escherichia coli replication forks, causing double-stranded breaks in vivo

Antibacterial quinolones inhibit type II DNA topoisomerases by stabilizing covalent topoisomerase-DNA cleavage complexes, which are apparently transformed into double-stranded breaks by cellular processes such as replication. We used plasmid pBR322 and two-dimensional agarose gel electrophoresis to examine the collision of replication forks with quinolone-induced gyrase-DNA cleavage complexes in Escherichia coli. Restriction endonuclease-digested DNA exhibited a bubble arc with discrete spots, indicating that replication forks had been stalled. The most prominent spot depended upon the strong gyrase binding site of pBR322, providing direct evidence that quinolone-induced cleavage complexes block bacterial replication forks in vivo. We differentiated between stalled forks that do or do not contain bound cleavage complex by extracting DNA under different conditions. Resealing conditions allow gyrase to efficiently reseal the transient breaks within cleavage complexes, while cleavage conditions cause the latent breaks to be revealed. These experiments showed that some stalled forks did not contain a cleavage complex, implying that gyrase had dissociated in vivo and yet the fork had not restarted at the time of DNA isolation. Additionally, some branched plasmid DNA isolated under resealing conditions nonetheless contained broken DNA ends. We discuss a model for the creation of double-stranded breaks by an indirect mechanism after quinolone treatment.     

Topoisomerase inhibitors can selectively interfere with different stages of simian virus 40 DNA replication.

I have found that antineoplastic drugs which are known to be inhibitors of mammalian DNA topoisomerases have pronounced and selective effects on simian virus 40 DNA replication. Ellipticine, 4'-(9-acridinylamino)methanesulfon-m-aniside, and Adriamycin blocked decatenation of newly replicated simian virus 40 daughter chromosomes in vivo. The arrested decatenation intermediates produced by these drugs contained single-strand DNA breaks. Ellipticine in particular produced these catenated dimers rapidly and efficiently. Removal of the drug resulted in rapid reversal of the block and completion of decatenation. The demonstration that these drugs interfere with decatenation suggests that they may exert their cytotoxic and antineoplastic effects by preventing the separation of newly replicated cellular chromosomes. Camptothecin rapidly breaks replication forks in growing Cairns structures. It is likely that the target of camptothecin is the "swivel" topoisomerase required for DNA replication and that it is located at or very near the replication fork in vivo. Evidence is presented that many of the broken Cairns structures are in fact half-completed sister chromatid exchanges. One pathway for the resolution of these structures is completion of the sister chromatid exchange to produce a circular head-to-tail dimer.     

The structure of the transition state of the heterodimeric topoisomerase I of Leishmania donovani as a vanadate complex with nicked DNA

Type IB topoisomerases are essential enzymes that are responsible for relaxing superhelical tension in DNA by forming a transient covalent nick in one strand of the DNA duplex. Topoisomerase I is a target for anti-cancer drugs such as camptothecin, and these drugs also target the topoisomerases I in pathogenic trypanosomes including Leishmania species and Trypanosoma brucei. Most eukaryotic enzymes, including human topoisomerase I, are monomeric. However, for Leishmania donovani, the DNA-binding activity and the majority of residues involved in catalysis are located in a large subunit, designated TOP1L, whereas the catalytic tyrosine residue responsible for covalent attachment to DNA is located in a smaller subunit, called TOP1S. Here, we present the 2.27A crystal structure of an active truncated L.donovani TOP1L/TOP1S heterodimer bound to nicked double-stranded DNA captured as a vanadate complex. The vanadate forms covalent linkages between the catalytic tyrosine residue of the small subunit and the nicked ends of the scissile DNA strand, mimicking the previously unseen transition state of the topoisomerase I catalytic cycle. This structure fills a critical gap in the existing ensemble of topoisomerase I structures and provides crucial insights into the catalytic mechanism.     

Evidence for covalent bonding of native hapten-protein complexes to smooth lipopolysaccharide of Brucella abortus

Abstract Smooth lipopolysaccharide (S-LPS) of Brucella abortus was dissociated from noncovalently attached components by differential centrifugation and exhaustive treatment with guanidinium thiocyanate. Mild alkaline hydrolysis then released ester-linked fatty acids as well as native hapten (NH)-protein complexes. These complexes, comprising 15 to 20% by weight of the S-LPS, failed to dissociate in guanidinium thiocyanate or in boiling SDS, suggesting covalent attachment. Analyses for 2-keto-3-deoxyoctonate demonstrated that the released carbohydrate was NH, rather than degraded O -polysaccharide or intact S-LPS monomers. This provides strong evidence that NH-protein complexes are covalently linked to S-LPS, most likely through ester bonds.     

RNA-Mediated Disease Mechanisms in Neurodegenerative Disorders

RNA is accurately entangled in virtually all pathways that maintain cellular homeostasis. To name but a few, RNA is the “messenger” between DNA encoded information and the resulting proteins. Furthermore, RNAs regulate diverse processes by forming DNA::RNA or RNA::RNA interactions. Finally, RNA itself can be the scaffold for ribonucleoprotein complexes, for example, ribosomes or cellular bodies. Consequently, disruption of any of these processes can lead to disease. This review describes known and emerging RNA-based disease mechanisms like interference with regular splicing, the anomalous appearance of RNA–protein complexes and uncommon RNA species, as well as non-canonical translation. Due to the complexity and entanglement of the above-mentioned pathways, only few drugs are available that target RNA-based disease mechanisms. However, advances in our understanding how RNA is involved in and modulates cellular homeostasis might pave the way to novel treatments.     

A type-II DNA topoisomerase and a catenating protein from the transplantable VX2 carcinoma

It has recently been suggested that topoisomerases could be important targets for several DNA intercalating drugs used in cancer therapy. This prompted us to purify and characterize a type II topoisomerase in a highly tumorigenic transplantable rabbit tumor isolated from a skin carcinoma associated with cottontail rabbit papillomavirus. We have found that the decatenating activity present in tumor cells was 40-100 times higher than that in the rabbit liver, while no activity could be found in skin extracts. The type II topoisomerases purified from tumor and liver cells consist of two subunits with molecular masses of about 160 kDa. The conditions of the reactions of relaxation, unknotting and decatenation catalyzed by these topoisomerases II were found to be similar to those observed with enzymes of other eukaryotic cells. In the course of the purification of the VX2 enzyme, we isolated and characterized a protein of about 30 kDa in whose presence the topoisomerase II was able to catenate very efficiently supercoiled DNA molecules. This protein has the same electrophoretic mobility as an H1-2 histone, and cross-reacts with an anti-H1 antiserum. The VX2 topoisomerase II as well as the VX2 tumor should constitute useful models for assays of antitumoral drugs.