Negative constrained DNA supercoiling in archaeal nucleosomes

Archaeal histones have significant sequence and structural similarity to their eukaryal counterparts. However, whereas DNA is wrapped in negatively constrained supercoils in eukaryal nucleosomes, it has been reported that DNA is positively supercoiled by archaeal nucleosomes. This was inferred from experiments performed at low temperature and low salt concentrations, conditions markedly different from those expected for many archaea in vivo. Here, we report that the archaeal histones HMf and HTz wrap DNA in negatively constrained supercoils in buffers containing potassium glutamate (K-Glu) above 300 mM, either at 37 degrees C or at 70 degrees C. This suggests that high salt concentrations allow an alternate archaeal nucleosome topology: a left-handed tetramer rather than the right-handed tetramer seen in low salt conditions. In contrast, the archaeal histone MkaH produces DNA negative supercoiling at all salt concentrations, suggesting that this duality of structure is not possible for this atypical protein, which is formed by the association of two histone folds in a single polypeptide. These results extend the already remarkable similarity between archaeal and eukaryal nucleosomes, as it has been recently shown that DNA can be wrapped into either positive or negative supercoils around the H3/H4 tetramer. Negative supercoiling could correspond to the predominant physiological mode of DNA supercoiling in archaeal nucleosomes.

Where is the root of the universal tree of life?

The currently accepted universal tree of life based on molecular phylogenies is characterised by a prokaryotic root and the sisterhood of archaea and eukaryotes. The recent discovery that each domain (bacteria, archaea, and eucarya) represents a mosaic of the two others in terms of its gene content has suggested various alternatives in which eukaryotes were derived from the merging of bacteria and archaea. In all these scenarios, life evolved from simple prokaryotes to complex eukaryotes. We argue here that these models are biased by overconfidence in molecular phylogenies and prejudices regarding the primitive nature of prokaryotes. We propose instead a universal tree of life with the root in the eukaryotic branch and suggest that many prokaryotic features of the information processing mechanisms originated by simplification through gene loss and non-orthologous displacement.

The root of the tree of life in the light of the covarion model

A few duplicated genes have been found useful to root the universal tree of life. Despite controversial results, the consensus led to locate the root in the eubacterial branch. However, we demonstrated (Philippe and Forterre 1999) that all these markers were in fact unsuitable for any firm conclusion, mainly because of their high level of mutational saturation, which masks a major part of the phylogenetic signal. But then, the very persistence of signal for events as early as the separation of the three domains becomes puzzling. This paradox was studied here for translation elongation factor proteins, EF-1alpha and EF-2, which appeared to be one of the least confusing markers. We showed that these proteins do not conform to a classical rate-across-sites pattern, as those modeled by a gamma law, but rather to a covarion-based model, because the evolutionary rate of a given position often changes between taxonomic groups. Conservation of the very ancient signal can thus be better explained by the covarion model: a substitution can occur in deep branches, and the position remains constant afterward, as "fossilized" by a change of covation. As no reconstruction method has up to now taken into account this complex model, we devised a simple method for extracting the phylogenetic signal, by considering the variability of sequence positions within predefined phylogenetic groups. We showed that noise quantitatively prevailed upon signal. Parsimony will produce erroneous topologies, because it has to minimize primarily the number of steps of the noise. In contrast, our method effectively concentrated the signal and was more suitable for inferring ancient events. We consequently found the eubacterial rooting to be presumably due to a long branch attraction artifact, because of the higher evolutionary rate of Eubacteria for these proteins. Among the two other rooting possibilities, the eukaryotic rooting appeared to be more supported, although not enough to be conclusive.

The rooting of the universal tree of life is not reliable

Several composite universal trees connected by an ancestral gene duplication have been used to root the universal tree of life. In all cases, this root turned out to be in the eubacterial branch. However, the validity of results obtained from comparative sequence analysis has recently been questioned, in particular, in the case of ancient phylogenies. For example, it has been shown that several eukaryotic groups are misplaced in ribosomal RNA or elongation factor trees because of unequal rates of evolution and mutational saturation. Furthermore, the addition of new sequences to data sets has often turned apparently reasonable phylogenies into confused ones. We have thus revisited all composite protein trees that have been used to root the universal tree of life up to now (elongation factors, ATPases, tRNA synthetases, carbamoyl phosphate synthetases, signal recognition particle proteins) with updated data sets. In general, the two prokaryotic domains were not monophyletic with several aberrant groupings at different levels of the tree. Furthermore, the respective phylogenies contradicted each others, so that various ad hoc scenarios (paralogy or lateral gene transfer) must be proposed in order to obtain the traditional Archaebacteria-Eukaryota sisterhood. More importantly, all of the markers are heavily saturated with respect to amino acid substitutions. As phylogenies inferred from saturated data sets are extremely sensitive to differences in evolutionary rates, present phylogenies used to root the universal tree of life could be biased by the phenomenon of long branch attraction. Since the eubacterial branch was always the longest one, the eubacterial rooting could be explained by an attraction between this branch and the long branch of the outgroup. Finally, we suggested that an eukaryotic rooting could be a more fruitful working hypothesis, as it provides, for example, a simple explanation to the high genetic similarity of Archaebacteria and Eubacteria inferred from complete genome analysis.

Control of DNA topology during thermal stress in hyperthermophilic archaea: DNA topoisomerase levels, activities and induced thermotolerance during heat and cold shock in Sulfolobus

Plasmid topology varies transiently in hyperthermophilic archaea during thermal stress. As in mesophilic bacteria, DNA linking number (Lk) increases during heat shock and decreases during cold shock. Despite this correspondence, plasmid DNA topology and proteins presumably involved in DNA topological control in each case are different. Plasmid DNA in hyperthermophilic archaea is found in a topological form from relaxed to positively supercoiled in contrast to the negatively supercoiled state typical of bacteria, eukaryotes and mesophilic archaea. We have analysed the regulation of DNA topological changes during thermal stress in Sulfolobus islandicus (kingdom Crenarchaeota), which harbours two plasmids, pRN1 and pRN2. In parallel with plasmid topological variations, we analysed levels of reverse gyrase, topoisomerase VI (Topo VI) and the small DNA-binding protein Sis7, as well as topoisomerase activities in crude extracts during heat shock from 80 degrees C to 85-87 degrees C, and cold shock from 80 degrees C to 65 degrees C. Quantitative changes in reverse gyrase, Topo VI and Sis7 were not significant. In support of this, inhibition of protein synthesis in S. islandicus during shocks did not alter plasmid topological dynamics, suggesting that an increase in topoisomerase levels is not needed for control of DNA topology during thermal stress. A reverse gyrase activity was detected in crude extracts, which was strongly dependent on the assay temperature. It was inhibited at 65 degrees C, but was greatly enhanced at 85 degrees C. However, the intrinsic reverse gyrase activity did not vary with heat or cold shock. These results suggest that the control of DNA topology during stress in Sulfolobus relies primarily on the physical effect of temperature on topoisomerase activities and on the geometry of DNA itself. Additionally, we have detected an enhanced thermoresistance of reverse gyrase activities in cultures subject to prolonged heat shock (but not cold shock). This acquired thermotolerance at the enzymatic level is abolished when cultures are treated with puromycin, suggesting a requirement for protein synthesis.

Displacement of cellular proteins by functional analogues from plasmids or viruses could explain puzzling phylogenies of many DNA informational proteins

Comparative genomics has revealed many examples in which the same function is performed by unrelated or distantly related proteins in different cellular lineages. In some cases, this has been explained by the replacement of the original gene by a paralogue or non-homologue, a phenomenon known as non-orthologous gene displacement. Such gene displacement probably occurred early on in the history of proteins involved in DNA replication, repair, recombination and transcription (DNA informational proteins), i.e. just after the divergence of archaea, bacteria and eukarya from the last universal cellular ancestor (LUCA). This would explain why many DNA informational proteins are not orthologues between the three domains of life. However, in many cases, the origin of the displacing genes is obscure, as they do not even have detectable homologues in another domain. I suggest here that the original cellular DNA informational proteins have often been replaced by proteins of viral or plasmid origin. As viral and plasmid-encoded proteins are usually very divergent from their cellular counterparts, this would explain the puzzling phylogenies and distribution of many DNA informational proteins between the three domains of life.

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.

The active site of the rolling circle replication protein Rep75 is involved in site-specific nuclease, ligase and nucleotidyl transferase activities

The plasmid pGT5 from the hyperthermophilic archaeon Pyrococcus abyssi replicates via a rolling circle mechanism. The protein Rep75, encoded by this plasmid, exhibits a nicking-closing (NC) activity in vitro on single-stranded oligonucleotides containing the pGT5 double-stranded origin sequence. In addition, Rep75 catalyses a site-specific nucleotidyl terminal transferase (NTT) activity, e.g. it can transfer one AMP or dAMP (from ATP or dATP) to the 3'-OH of an oligonucleotide corresponding to the left part of the nicking site. The Rep75 sequence contains a motif similar to the active-site motifs of Rep proteins from the PhiX174/pC194 superfamily. We show here that the tyrosine present in this motif is indeed essential for DNA cleavage by Rep75, but is dispensable for its NTT activity. However, a nearby arginine, which is not required for DNA cleavage, is involved in both NTT and closing, indicating that the same active site is involved in the NC and NTT activities of Rep75. For both NTT and NC, the G residue in 3' of the nicking site is essential, whereas the A residue in 5' is dispensable for NC, despite its conservation in RC plasmids of the PhiX174/pC194 superfamily. The NTT and closing activities have an optimal temperature lower than the nicking activity. These data indicate that the three reactions catalysed by Rep75 can be uncoupled, although they share part of their mechanisms. Finally, we show that NC is inhibited by ATP or dATP at concentrations that promote NTT. We propose a model in which the NTT activity of Rep75 plays a role in the regulation of pGT5 replication in vivo.

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.

Isolation of a minD-like gene in the hyperthermophilic archaeon Pyrococcus AL585, and phylogenetic characterization of related proteins in the three domains of life

The region upstream of the dinF-like gene of the hyperthermophilic archaeon Pyrococcus strain AL585 has been cloned and sequenced. This region contains an open reading frame (ORF) that encodes a polypeptide with a high similarity to MinD proteins and their Mrp paralogues. Transcripts of the dinF-like and the minD-like genes were detected by RT-PCR, indicating that they are both expressed in vivo. The MinD and MinD-like proteins belong to a broad family of ATPases involved in chromosome and plasmid partitioning. MinD-like proteins can be defined by specific amino-acid sequence signatures. A systematic search for proteins sharing these signatures in current databases and newly sequenced genomes show that MinD-like proteins are present in all archaeal genomes sequenced so far, often in several copies. Phylogenetic analysis identifies two groups of MinD-like proteins which are also characterized by more conserved amino-acid motifs. A first group, which includes the Escherichia coli MinD and the Pyrococcus AL585 MinDL protein, contains only procaryotic proteins. This group can be further divided into a subgroup of archaeal proteins and two subgroups of bacterial proteins. A second group includes proteins more related to the E. coli Mrp protein and contains representants of the three domains of life. The conservation of MinD-like proteins in the three domains of life suggests that these proteins play a central role in cellular metabolism.

In vitro DNA binding of the archaeal protein Sso7d induces negative supercoiling at temperatures typical for thermophilic growth

The topological state of DNA in hyperthermophilic archaea appears to correspond to a linking excess in comparison with DNA in mesophilic organisms. Since DNA binding proteins often contribute to the control of DNA topology by affecting DNA geometry in the presence of DNA topoisomerases, we tested whether the histone-like protein Sso7d from the hyperthermophilic archaeon Sulfolobus solfataricus alters DNA conformation. In ligase-mediated supercoiling assays carried out at 37, 60, 70, 80 and 90 degrees C we found that DNA binding of increasing amounts of Sso7d led to a progressive decrease in plasmid linking number (Lk), producing negative supercoiling. Identical unwinding effects were observed when recombinant non-methylated Sso7d was used. For a given Sso7d concentration the DNA unwinding induced was augmented with increasing temperature. However, after correction for the overwinding effect of high temperature on DNA, plasmids ligated at 60-90 degrees C exhibited similar sigma values at the highest Sso7d concentrations assayed. These results suggest that Sso7d may play a compensatory role in vivo by counteracting the overwinding effect of high temperature on DNA. Additionally, Sso7d unwinding could be involved in the topological changes observed during thermal stress (heat and cold shock), playing an analogous role in crenarchaeal cells to that proposed for HU in bacteria.

Protection of DNA by salts against thermodegradation at temperatures typical for hyperthermophiles

The effect of physiological concentrations of KCl and MgCl2 on the chemical stability of double-stranded and single-stranded DNA has been studied at temperatures typical for hyperthermophiles. These tow salts protect both double and single-stranded DNA against heat-induced cleavage by inhibiting depurination. High KCl concentration also protect DNA cleavage at apurinic sites, while high MgCl2 concentrations stimulate this cleavage. It has been previously proposed that salt protects double-stranded DNA against depurination by stabilizing the double helix. However, the inhibition of the depurination of single-stranded DNA by KCl and MgCl2 indicates that this effect is more probably due to a direct interaction of salts with purine nucleotides. These results suggest that the number and nature of heat-induced DNA lesions which have to be repaired might be quite different from one hyperthermophile to another, depending on their intracellular salt concentration. High salt concentrations might be also useful to protect DNA in long polymerase chain reaction (PCR) experiments and for long-term preservation.

Insights into the molecular basis of salt tolerance from the study of glutamate dehydrogenase from Halobacterium salinarum

A homology-based modeling study on the extremely halophilic glutamate dehydrogenase from Halobacterium salinarum has been used to provide insights into the molecular basis of salt tolerance. The modeling reveals two significant differences in the characteristics of the surface of the halophilic enzyme that may contribute to its stability in high salt. The first of these is that the surface is decorated with acidic residues, a feature previously seen in structures of halophilic enzymes. The second is that the surface displays a significant reduction in exposed hydrophobic character. The latter arises not from a loss of surface-exposed hydrophobic residues, as has previously been proposed, but from a reduction in surface-exposed lysine residues. This is the first report of such an observation.

A rolling circle replication initiator protein with a nucleotidyl-transferase activity encoded by the plasmid pGT5 from the hyperthermophilic archaeon Pyrococcus abyssi

The plasmid pGT5 from the hyperthermophilic archaeon Pyrococcus abyssi presents similarities to plasmids from the pC194 family that replicate by the rolling circle mechanism. These plasmids encode a replication initiator protein, which activates the replication origin by nicking one of the two DNA strands. The gene encoding the putative Rep protein of pGT5 (Rep75) has been cloned and overexpressed in Escherichia coli, and the recombinant protein has been purified to homogeneity. Rep75 exhibits a highly thermophilic nicking-closing activity in vitro on single-stranded oligonucleotides containing the putative double-stranded replication origin sequence of pGT5. Gel shift analyses on single-stranded oligonucleotides indicate that Rep75 recognizes the single-stranded DNA region upstream of the nicking site via non-covalent interaction and remains covalently linked to the 5'-phosphate of the downstream fragment after nicking. Besides these expected activities, Rep75 contains a dATP (and ATP) terminal transferase activity at the 3'-OH extremity of the nicking site, which had not been reported previously for proteins of this type. Rep75, which is the first replication initiator protein characterized in an archaeon, offers an attractive new model for the study of rolling circle replication.

[Compact genomes]

The number of procaryotic genomes (both Archaea and Bacteria) completely sequenced is rapidly increasing since the publication in 1995 of the first ever finished one, Haemophilis influenzae. The small size and "simplicity" of these genomes make them ideal models for training in genomic before attacking more complex genomes, but they have also great intrinsic interest. Preliminary analyses of these compact genomes have detected many orphan genes, even in organisms previously extensively studied, as well as many families of duplicated genes. A major task now is to identify the function of these orphans by a combination of in silico, biochemical and genetic analyses (examples will be presented). Several genomes of hyperthermophiles have been or will be completely sequenced soon. Many of their genes have commercial (stable proteins), as well as medical interest (crystallization of proteins with eucaryotic homologs involved in pathogenesis). However, further work with these genomes will require the development of genetic tools for these hyperthermophiles. The complete understanding of genome evolution, structure and function will require the sequencing of many genomes at the different levels of the evolutionary scale. Sequencing of genomes from closely related organisms can be relevant to study genome plasticity, whilst sequencing of genome from different domains (Archaea, Bacteria, Eucarya) can help to reconstruct the Last Universal Common Ancestor (LUCA). The latter is a difficult task and will require not only classical molecular phylogenetic studies (which can be sometimes greatly misleading) but also in depth comparative analyses of all central genetic mechanisms in the three domains to infer their respective evolution. The fundamental problem is to determine if the compact genome of procaryotes is indeed a primitive one (as suggested by the term procaryote itself) or if it has been compacted from a more complex one by evolutionary forces related to the procaryotic way of life. Finally, taking into account the extreme diversity of procaryotes and their metabolism, it should be kept in mind that beside a core of genes essential for cellular life, the myriad of procaryotic genomes contain a mine of non essential genes with potential commercial or medical application. The total number of these genes probably outnumber the total number of eucaryotic genes.

Isolation of new plasmids from hyperthermophilic Archaea of the order Thermococcales

A collection of 57 strains of hyperthermophilic Archaea from the order Thermococcales was screened for the presence of plasmids; 9 plasmids present in six of these strains were isolated and characterized in terms of size and cross-hybridization. The Notl macrorestriction patterns of genomic DNA of strains harbouring these plasmids were obtained. Pyrococcus abyssi strains GE27 and GE23 as well as Thermococcus sp. GE31 contained a single plasmid of 3.5 kb (pGN27), 16.8 kb (pGN23) and 5.3 kb (pGN31), respectively, whilst the three strains I559, I560 and I690 all contained two plasmids of 3.5 kb (pSN559, pSN560, pSN690) and 24 kb (pLN559, pLN560, pLN690), respectively. Plasmid pGN27 strongly cross-hybridized with the previously described plasmid pGT5 from P. abyssi strain GE5, whilst plasmids pGN23 and pGN31 did not cross-hybridize with each other, nor with any other plasmid. The three small plasmids of strains I559, I560 and I690 cross-hybridized, as well as their three large plasmids. Macrorestriction pattern analysis and the results of plasmid cross-hybridization experiments indicated that these three strains were different but closely related, and likely belonged to the genus Thermococcus. This study shows that plasmids are widespread in hyperthermophilic archaea, and significantly increases the number and diversity of plasmids available for laboratory work.

Archaea: what can we learn from their sequences?

Gene-by-gene and traditional biochemical approaches continue to reveal surprising molecular features in the archaeal domain. In addition, the complete sequencing of several archaeal genomes has further confirmed the phenotypic coherence of these micro-organisms at the molecular level. Nevertheless, the phylogeny of Archaea and the nature of the last universal common ancestor are still matters for debate.

Both DNA gyrase and reverse gyrase are present in the hyperthermophilic bacterium Thermotoga maritima

Like all hyperthermophiles yet tested, the bacterium Thermotoga maritima contains a reverse gyrase. Here we show that it contains also a DNA gyrase. The genes top2A and top2B encoding the two subunits of a DNA gyrase-like enzyme have been cloned and sequenced. The Top2A (type II DNA topoisomerase A protein) is more similar to GyrA (DNA gyrase A protein) than to ParC [topoisomerase IV (Topo IV) C protein]. The difference is especially striking at the C-terminal domain, which differentiates DNA gyrases from Topo IV. DNA gyrase activity was detected in T. maritima and purified to homogeneity using a novobiocin-Sepharose column. This hyperhermophilic DNA gyrase has an optimal activity around 82-86 degrees C. In contrast to plasmids from hyperthermophilic archaea, which are from relaxed to positively supercoiled, we found that the plasmid pRQ7 from Thermotoga sp. RQ7 is negatively supercoiled. pRQ7 became positively supercoiled after addition of novobiocin to cell cultures, indicating that its negative supercoiling is due to the DNA gyrase of the host strain. The findings concerning DNA gyrase and negative supercoiling in Thermotogales put into question the role of reverse gyrase in hyperthermophiles.

A protein related to eucaryal and bacterial DNA-motor proteins in the hyperthermophilic archaeon Sulfolobus acidocaldarius

We have isolated a new gene encoding a putative 103-kDa protein from the hyperthermophilic archaeon Sulfolobus acidocaldarius. Analysis of the deduced amino-acid sequence shows an extended central domain, predicted to form coiled-coil structures, and two terminal domains that display purine NTPase motifs. These features are reminiscent of mechanochemical motor proteins which use the energy of ATP hydrolysis to move specific cellular components. Comparative analysis of the amino-acid sequence of the terminal domains and predicted structural organization of this putative purine NTPase show that it is related both to eucaryal proteins from the "SMC family" involved in the condensation of chromosomes and to several bacterial and eucaryal proteins involved in DNA recombination/repair. Further analyses revealed that these proteins are all members of the so called "UvrA-related NTP-binding proteins superfamily" and form a large subgroup of motor-like NTPases involved in different DNA processing mechanisms. The presence of such protein in Archaea, Bacteria, and Eucarya suggests an early origin of DNA-motor proteins that could have emerged and diversified by domain shuffling.

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.