Transcription-driven supercoiling of DNA: direct biochemical evidence from in vitro studies

Protein kinase C phosphorylates DNA topoisomerase I

The induction of mammalian cell proliferation requires the expression of a specific set of genes. Tumor promoters stimulate cell growth by activating the Ca2+ and phospholipid-dependent protein kinase, protein kinase C (PKC). DNA topoisomerase I, a nuclear enzyme involved in transcription, was phosphorylated by activated PKC in vitro. Phosphorylation by PKC stimulated the DNA relaxation activity of topoisomerase I two- to three-fold. Therefore, DNA topoisomerase I is a substrate for PKC-mediated activation by phosphorylation and may serve as a nuclear target of mitogenic signals generated by tumor promoters in vivo.

Topoisomerase-targeting antitumor drugs

Much has been learned about the unusual type of DNA damage produced by the topoisomerases. The mechanism by which these lesions trigger cell death, however, remains unclear, but it appears that DNA metabolic machinery transforms reversible single-strand cleavable complexes to overt strand breaks which may be an initial event in the cytotoxic pathway. For the topoisomerase I poisons, they produce breaks at replication forks that appear to be the equivalent of a break in duplex DNA. Indicating that this may be an important cytotoxic lesion is the hypersensitivity to camptothecin of the yeast mutant rad52, which is deficient in double-strand-break-repair. The topoisomerase poisons preferentially kill proliferating cells. In the case of the topoisomerase I poison camptothecin, dramatic S-phase-specific cytotoxicity can explain its preferential action on proliferating cells. For the topoisomerase II poisons, high levels of the enzyme in proliferating cells, and very low levels in quiescent cells appear to explain the resistance of quiescent cells to the drug's cytotoxic effects. Thus, the topoisomerase poisons convert essential enzymes into intracellular, proliferating-cell toxins. The identification of both topoisomerase I and II as the specific targets of cancer chemotherapeutic drugs now provides a rational basis for the development of topoisomerase I poisons for possible clinical use. Knowledge of the molecular mechanisms of cell killing may lead to the identification of new therapies for treating cancer. The topoisomerase poisons appear to be a good tool for studying cell killing mechanisms as they produce highly specific and reversible lesions.

The presence of the region on pBR322 that encodes resistance to tetracycline is responsible for high levels of plasmid DNA knotting in Escherichia coli DNA topoisomerase I deletion mutant

Plasmid pBR322 DNA isolated from Escherichia coli DNA topoisomerase I deletion mutant DM800 is estimated to contain about 10% of the knotted forms (Shishido et al., 1987). These knotted DNA species were shown to have the same primary structure as usual, unknotted pBR322 DNA. Analysis of the knotting level of deletion, insertion and sequence-rearranged derivatives of pBR322 in DM800 showed that the presence of the region on pBR322 encoding resistance to tetracycline (tet) is required for high levels of plasmid knotting. When the entire tet region is present in a native orientation, the level of knotting is highest. Inactivating the tet promoter is manifested by a middle level of knotting. For deletion derivatives lacking various portions of the tet region, the level of knotting ranges from lowest to high depending on the site and length of the tet gene remaining. Inverting the orientation of tet region on the pBR322 genome results in a middle level of knotting. Deleting the ampicillin-resistance (bla)gene outside of its second promoter does not affect the level of knotting, if the entire tet gene remains. A possible mechanism of regulation of plasmid knotting is discussed.

Transcription by RNA polymerase I stimulates mitotic recombination in Saccharomyces cerevisiae

The recombination-stimulating sequence HOT1 is derived from the ribosomal DNA array of Saccharomyces cerevisiae and corresponds to sequences that promote transcription by RNA polymerase I. When inserted at a chromosomal location outside the ribosomal DNA array, HOT1 stimulates mitotic recombination in the adjacent sequences. To investigate the relationship between transcription and recombination, transcription promoted by HOT1 was directly examined. These studies demonstrated that transcription starts at the RNA polymerase I initiation site in HOT1 and proceeds through the chromosomal sequences in which recombination is enhanced. Linker insertion mutations in HOT1 were generated and assayed for recombination stimulation and for promoter function; this analysis demonstrated that the same sequences are required for both activities. These results indicate that the ability of HOT1 to enhance recombination is related to, and most likely dependent on, its ability to promote transcription.

The nucleoskeleton and the topology of transcription

Transcription is conventionally believed to occur by passage of a mobile polymerase along a fixed template. Evidence for this model is derived almost entirely from material prepared using hypotonic salt concentrations. Studies on subnuclear structures isolated using hypertonic conditions, and more recently using conditions closer to the physiological, suggest an alternative. Transcription occurs as the template moves past a polymerase attached to a nucleoskeleton; this skeleton is the active site of transcription. Evidence for the two models is summarised. Much of it is consistent with the polymerase being attached and not freely diffusible. Some consequences of such a model are discussed.

Interaction of topoisomerase 1 with the transcribed region of the Drosophila HSP 70 heat shock gene

Topoisomerase I cleavage sites have been mapped in vivo on the Hsp70 heat shock gene of Drosophila melanogaster cells using the drug camptothecin. Topoisomerase I cleavage was only observed when the Hsp70 gene was transcriptionally active. Site-specific single-strand DNA cleavage by topoisomerase I was confined to the transcribed region of the Hsp70 gene and occurred on both the transcribed and nontranscribed DNA strands. A number of the single-strand breaks on the complementary DNA strands occurred in close proximity giving rise to double-stranded DNA breaks. Inhibition of heat-induced Hsp70 transcription by either Actinomycin D (Act D) or 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB) inhibited topoisomerase I cleavage except at the 5' and to a lesser extent the 3' end of the gene. Camptothecin (100 microM) inhibited transcription of the Hsp70 gene greater than 95%. These results suggest that topoisomerase I is intimately associated with and has an integral part in Hsp70 gene transcription.

Induction of anaerobic gene expression in Rhodobacter capsulatus is not accompanied by a local change in chromosomal supercoiling as measured by a novel assay

In the photosynthetic bacterium Rhodobacter capsulatus, the enzyme DNA gyrase has been implicated in the expression of genes for anaerobic metabolic processes such as nitrogen fixation and photosynthesis. To assess the involvement of supercoiling in anaerobic gene expression, we have developed an assay to detect in vivo changes in superhelicity of small regions of the bacterial chromosome. Our method is based on the preferential intercalaction of psoralen into supercoiled versus relaxed DNA, and we have demonstrated the sensitivity of the assay in vivo on chromosomal regions from 2 to 10 kilobases in size. In experiments with inhibitors of gyrase, the reactivity of individual chromosomal fragments to psoralen decreases by a factor of 1.8 compared with DNA from control cultures. We used our assay to determine whether there is a change in superhelicity near the genes coding for essential proteins for photosynthesis upon a shift from respiratory to anaerobic photosynthetic growth. For comparison, we also examined a restriction fragment containing the fbc operon, which codes for the subunits of cytochrome bc1, a membrane-bound electron transport complex utilized during both aerobic and anaerobic photosynthetic growth. During this shift in growth conditions, the puf and puh mRNAs, coding for structural polypeptides of the photosynthetic apparatus, underwent a six- to eightfold induction, while the amount of mRNA from the fbc locus remained constant. However, we detected no change in the superhelicity of either the genes for photosynthesis or those for the bc1 complex during this metabolic transition. Our data thus do not support a model in which stable changes in chromosomal superhelicity regulate anaerobic gene expression. We suggest instead that the requirement for DNA gyrase in the transcription of photosynthesis genes results from the requirement for a swivel near heavily transcribed regions of the chromosome.

Transcription by RNA polymerase I stimulates mitotic recombination in Saccharomyces cerevisiae

The recombination-stimulating sequence HOT1 is derived from the ribosomal DNA array of Saccharomyces cerevisiae and corresponds to sequences that promote transcription by RNA polymerase I. When inserted at a chromosomal location outside the ribosomal DNA array, HOT1 stimulates mitotic recombination in the adjacent sequences. To investigate the relationship between transcription and recombination, transcription promoted by HOT1 was directly examined. These studies demonstrated that transcription starts at the RNA polymerase I initiation site in HOT1 and proceeds through the chromosomal sequences in which recombination is enhanced. Linker insertion mutations in HOT1 were generated and assayed for recombination stimulation and for promoter function; this analysis demonstrated that the same sequences are required for both activities. These results indicate that the ability of HOT1 to enhance recombination is related to, and most likely dependent on, its ability to promote transcription.

Template supercoiling during ATP-dependent DNA helix tracking: studies with simian virus 40 large tumor antigen

Incubation of topologically relaxed plasmid DNA with simian virus 40 (SV40) large tumor antigen (T antigen), ATP, and eubacterial DNA topoisomerase I resulted in the formation of highly positively supercoiled DNA. Eukaryotic DNA topoisomerase I could not substitute for eubacterial DNA topoisomerase 1 in this reaction. Furthermore, the addition of eukaryotic topoisomerase I to a preincubated reaction mixture containing both T antigen and eubacterial topoisomerase I caused rapid relaxation of the positively supercoiled DNA. These results suggest that SV40 T antigen can introduce topoisomerase-relaxable supercoils into DNA in a reaction coupled to ATP hydrolysis. We interpret the observed T antigen supercoiling reaction in terms of a recently proposed twin-supercoiled-domain model that describes the mechanics of DNA helix-tracking processes. According to this model positive and negative supercoils are generated ahead of and behind the moving SV40 T antigen, respectively. The preferential relaxation of negative supercoils by eubacterial DNA topoisomerase I explains the accumulation of positive supercoils in the DNA template. The supercoiling assay using DNA conformation-specific eubacterial DNA topoisomerase I may be of general use for the detection of ATP-dependent DNA helix-tracking proteins.

Transcription regulation in vitro by an E. coli promoter containing a DNA cruciform in the '-35' region

A promoter with the potential to adopt a 50 basepair (bp) cruciform spanning from -19 to -69 has been constructed in the plasmid pBR322 tetracycline resistance gene (tet) by forming an inverted repeat from '-35' sequences. Compared to a control promoter, the sequence of this cruciform promoter differs only by a 22 bp insertion between -48 and -69, upstream from the usual location of promoter sequences. The cruciform is extruded in a supercoil-dependent manner, and transcription from this promoter in vitro by RNA polymerase decreases as the negative supercoil density of the plasmid DNA increases. In contrast, transcription from the control promoter increases with negative supercoiling. Thus, DNA secondary structure in the '-35' region can affect promoter-polymerase interaction. The tet promoter cruciform also influences expression of the pBR322 beta-lactamase gene (bla). This apparently results when extrusion of the cruciform reduces the superhelicity of the plasmid molecule to a level that is below the optimum for expression from the bla promoter, illustrating one mechanism for how DNA secondary structure may effect action-at-a-distance. Transcription from both promoters in vivo does not differ from controls, suggesting that this cruciform is not generated to a significant extent intracellularly, most probably as a result of the slow kinetics of extrusion.

Topology and formation of triple-stranded H-DNA

Repeating copolymers of (dT-dC)n.(dA-dG)n sequences (TC.AGn) can assume a hinged DNA structure (H-DNA) which is composed of triple-stranded and single-stranded regions. A model for the formation of H-DNA is proposed, based on two-dimensional gel electrophoretic analysis of DNA's with different lengths of (TC.AG)n copolymers. In this model, H-DNA formation is initiated at a small denaturation bubble in the interior of the copolymer, which allows the duplexes on either side to rotate slightly and to fold back, in order to make the first base triplet. This nucleation establishes which of several nonequivalent H-DNA conformations is to be assumed by any DNA molecule, thereby trapping each molecule in one of several metastable conformers that are not freely interconvertible. Subsequently, the acceptor region spools up single-stranded polypyrimidines as they are released by progressive denaturation of the donor region; both the spooling and the denaturation result in relaxation of negative supercoils in the rest of the DNA molecule. From the model, it can be predicted that the levels of supercoiling of the DNA determine which half of the (dT-dC)n repeat is to become the donated third strand.