Cell-free transcription at 95 degrees: thermostability of transcriptional components and DNA topology requirements of Pyrococcus transcription.

Cell-free transcription of archaeal promoters is mediated by two archaeal transcription factors, aTBP and TFB, which are orthologues of the eukaryotic transcription factors TBP and TFIIB. Using the cell-free transcription system described for the hyperthermophilic Archaeon Pyrococcus furiosus by Hethke et al., the temperature limits and template topology requirements of archaeal transcription were investigated. aTBP activity was not affected after incubation for 1 hr at 100 degrees. In contrast, the half-life of RNA polymerase activity was 23 min and that of TFB activity was 3 min. The half-life of a 328-nt RNA product was 10 min at 100 degrees. Best stability of RNA was observed at pH 6, at 400 mm K-glutamate in the absence of Mg(2+) ions. Physiological concentrations of K-glutamate were found to stabilize protein components in addition, indicating that salt is an important extrinsic factor contributing to thermostability. Both RNA and proteins were stabilized by the osmolyte betaine at a concentration of 1 m. The highest activity for RNA synthesis at 95 degrees was obtained in the presence of 1 m betaine and 400 mm K-glutamate. Positively supercoiled DNA, which was found to exist in Pyrococcus cells, can be transcribed in vitro both at 70 degrees and 90 degrees. However, negatively supercoiled DNA was the preferred template at all temperatures tested. Analyses of transcripts from plasmid topoisomers harboring the glutamate dehydrogenase promoter and of transcription reactions conducted in the presence of reverse gyrase indicate that positive supercoiling of DNA inhibits transcription from this promoter.

Reconstitution of DNA topoisomerase VI of the thermophilic archaeon Sulfolobus shibatae from subunits separately overexpressed in Escherichia coli.

DNA topoisomerase VI from the hyperthermophilic archaeon Sulfolobus shibatae is the prototype of a novel family of type II DNA topoisomerases that share little sequence similarity with other type II enzymes, including bacterial and eukaryal type II DNA topoisomerases and archaeal DNA gyrases. DNA topoisomerase VI relaxes both negatively and positively supercoiled DNA in the presence of ATP and has no DNA supercoiling activity. The native enzyme is a heterotetramer composed of two subunits, A and B, with apparent molecular masses of 47 and 60 kDa, respectively. Here wereport the overexpression in Escherichia coli and the purification of each subunit. The A subunit exhibits clusters of arginines encoded by rare codons in E.coli . The expression of this protein thus requires the co-expression of the minor E.coli arginyl tRNA which reads AGG and AGA codons. The A subunit expressed in E.coli was obtained from inclusion bodies after denaturation and renaturation. The B subunit was overexpressed in E.coli and purified in soluble form. When purified B subunit was added to the renatured A subunit, ATP-dependent relaxation and decatenation activities of the hyperthermophilic DNA topoisomerase were reconstituted. The reconstituted recombinant enzyme exhibits a specific activity similar to the enzyme purified from S.shibatae . It catalyzes transient double-strand cleavage of DNA and becomes covalently attached to the ends of the cleaved DNA. This cleavage is detected only in the presence of both subunits and in the presence of ATP or its non-hydrolyzable analog AMPPNP.

An atypical topoisomerase II from Archaea with implications for meiotic recombination.

Type II topoisomerases help regulate DNA topology during transcription, replication and recombination by catalysing DNA strand transfer through transient double-stranded breaks. All type II topoisomerases described so far are members of a single protein family. We have cloned and sequenced the genes encoding the A and B subunits of topoisomerase II from the archaeon Sulfolobus shibatae. This enzyme is the first of a new family. It has no similarity with other type II topoisomerases, except for three motifs in the B subunit probably involved in ATP binding and hydrolysis. We also found these motifs in proteins of the Hsp90 and MutL families. The A subunit has similarities with four proteins of unknown function. One of them, the Saccharomyces cerevisiae Spo11 protein, is required for the initiation of meiotic recombination. Mutagenesis, performed on SPO11, of the single tyrosine conserved between the five homologues shows that this amino acid is essential for Spo11 activity. By analogy with the mechanism of action of known type II topoisomerases, we suggest that Spo11 catalyses the formation of double-strand breaks that initiate meiotic recombination in S. cerevisiae.

Characterization of the reverse gyrase from the hyperthermophilic archaeon Pyrococcus furiosus.

The reverse gyrase gene rgy from the hyperthermophilic archaeon Pyrococcus furiosus was cloned and sequenced. The gene is 3,642 bp (1,214 amino acids) in length. The deduced amino acid sequence has relatively high similarity to the sequences of the Methanococcus jannaschii reverse gyrase (48% overall identity), the Sulfolobus acidocaldarius reverse gyrase (41% identity), and the Methanopynrus kandleri reverse gyrase (37% identity). The P. furiosus reverse gyrase is a monomeric protein, containing a helicase-like module and a type I topoisomerase module, which resembles the enzyme from S. acidocaldarius more than that from M. kandleri, a heterodimeric protein encoded by two separate genes. The control region of the P. furiosus rgy gene contains a typical archaeal putative box A promoter element which is located at position -26 from the transcription start identified by primer extension experiments. The initiating ATG codon is preceded by a possible prokaryote-type ribosome-binding site. Purified P. furiosus reverse gyrase has a sedimentation coefficient of 6S, suggesting a monomeric structure for the native protein. The enzyme is a single polypeptide with an apparent molecular mass of 120 kDa, in agreement with the gene structure. The sequence of the N terminus of the protein corresponded to the deduced amino acid sequence. Phylogenetic analysis indicates that all known reverse gyrase topoisomerase modules form a subgroup inside subfamily IA of type I DNA topoisomerases (sensu Wang [J. C. Wang, Annu. Rev. Biochem. 65:635-692, 1996]). Our results suggest that the fusion between the topoisomerase and helicase modules of reverse gyrase occurred before the divergence of the two archaeal phyla, Crenoarchaeota and Euryarchaeota.

The unique DNA topology and DNA topoisomerases of hyperthermophilic archaea.

Hyperthermophilic archaea exhibit a unique pattern of DNA topoisomerase activities. They have a peculiar enzyme, reverse gyrase, which introduces positive superturns into DNA at the expense of ATP. This enzyme has been found in all hyperthermophiles tested so far (including Bacteria) but never in mesophiles. Reverse gyrases are formed by the association of a helicase-like domain and a 5'-type 1 DNA topoisomerase. These two domains might be located on the same polypeptide. However, in the methanogenic archaeon Methanopyrus kandleri, the topoisomerase domain is divided between two subunits. Besides reverse gyrase, Archaea contain other type 1 DNA topoisomerases; in particular, M. kandleri harbors the only known procaryotic 3'-type 1 DNA topoisomerase (Topo V). Hyperthermophilic archaea also exhibit specific type II DNA topoisomerases (Topo II), i.e. whereas mesophilic Bacteria have a Topo II that produces negative supercoiling (DNA gyrase), the Topo II from Sulfolobus and Pyrococcus lack gyrase activity and are the smallest enzymes of this type known so far. This peculiar pattern of DNA topoisomerases in hyperthermophilic archaea is paralleled by a unique DNA topology, i.e. whereas DNA isolated from Bacteria and Eucarya is negatively supercoiled, plasmidic DNA from hyperthermophilic archaea are from relaxed to positively supercoiled. The possible evolutionary implications of these findings are discussed in this review. We speculate that gyrase activity in mesophiles and reverse gyrase activity in hyperthermophiles might have originated in the course of procaryote evolution to balance the effect of temperature changes on DNA structure.

Purification of a DNA topoisomerase II from the hyperthermophilic archaeon Sulfolobus shibatae. A thermostable enzyme with both bacterial and eucaryal features.

A type II DNA topoisomerase has been purified to homogeneity from the hyperthermophilic archaeon Sulfolobus shibatae. The enzyme is composed of two subunits of 60 and 47 kDa. It has a Stokes radius of 69 A and has a sedimentation coefficient of 7.8 S which gives a calculated native molecular mass of approximately 230 kDa, indicating a heterotetrameric structure. This enzyme is ATP and Mg2+ dependent and can relax both negatively and positively supercoiled DNA, but presents no supercoiling activity. The S. shibatae DNA topoisomerase II is more efficient in decatenation than in relaxation. The optimal temperature for the enzymatic activity is approximately 80 degrees C. This archaeal enzyme is not inhibited by the gyrase inhibitor novobiocin but is sensitive to several inhibitors of eucaryotic DNA topoisomerases of type II such as amsacrines, ellipticine, and the quinolone CP-115,953. Like all prokaryotic DNA topoisomerase II, the S. shibatae DNA topoisomerase II is a heterotetramer but the absence of supercoiling activity, the strong decatenase activity, and the pattern of antibiotic sensitivity of the S. shibatae DNA topoisomerase II is reminiscent of eucaryotic enzymes.

Allosteric and catalytic binding of S-adenosylmethionine to Escherichia coli DNA adenine methyltransferase monitored by 3H NMR.

Adenine methylation of GATC sequences in DNA is carried out by the DNA adenine methyltransferase with the methyl group source being the cofactor S-adenosylmethionine. We report 3H NMR studies on the interaction of DNA adenine methyltransferase with S-adenosylmethionine and the reaction when the ternary complex is formed with an oligonucleotide containing a GATC site. The methylation reaction was also studied in the presence of a competitive inhibitor and this showed two successive stages involved in the methylation and two sites of binding for S-adenosylmethionine.

The double role of methyl donor and allosteric effector of S-adenosyl-methionine for Dam methylase of E. coli.

The turnover of DNA-adenine-methylase of E. coli strongly decreases when the temperature is lowered. This has allowed us to study the binding of Dam methylase on 14 bp DNA fragments at 0 degrees C by gel retardation in the presence of Ado-Met, but without methylation taking place. The enzyme can bind non-specific DNA with low affinity. Binding to the specific sequence occurs in the absence of S-adenosyl-methionine (Ado-Met), but is activated by the presence of the methyl donor. The two competitive inhibitors of Ado-Met, sinefungin and S-adenosyl-homocysteine, can neither activate this binding to DNA by themselves, nor inhibit this activation by Ado-Met. This suggests that Ado-Met could bind to Dam methylase in two different environments. In one of them, it could play the role of an allosteric effector which would reinforce the affinity of the enzyme for the GATC site. The analogues can not compete for such binding. In the other environment Ado-Met would be in the catalytic site and could be exchanged by its analogues. We have also visualized conformational changes in Dam methylase induced by the simultaneous binding of Ado-Met and the specific target sequence of the enzyme, by an anomaly of migration and partial resistance to proteolytic treatment of the ternary complex Ado-Met/Dam methylase/GATC.

Preferential site-specific hemimethylation of GATC sites in pBR322 DNA by Dam methyltransferase from Escherichia coli.

The methylation pattern of the 22 GATC sites of pBR322 (dam-) by Dam methyltransferase from Escherichia coli has been studied. Preferential hemimethylation took place at positions 3042 and 349. It was found that these preferential methylations were the same in supercoiled circular and linear DNAs. The flanking regions of these preferentially methylated sites contain three G.C pairs on one side and two A.T pairs and one G.C pair on the other. This preferential methylation was confirmed on a 126-base pair oligonucleotide containing two GATC sites with different flanking sequences. The next sites methylated were, in both cases, the first GATC site on the A.T-rich side, although the orientation was different. The rapid methylation of a second and third neighboring GATC site on the same plasmid suggests a processive mechanism. The implications of the orientation of hemimethylation are discussed in the context of the recognition of a palindromic target site by a monomeric DNA-binding protein.