A two-subunit type I DNA topoisomerase (reverse gyrase) from an extreme hyperthermophile

Current knowledge and clinical perspectives for a unique new phylum: Nanaorchaeota

Nanoarchaea measuring less than 500 nm and encasing an average 600-kb compact genome have been studied for twenty years, after an estimated 4193-million-year evolution. Comprising only four co-cultured representatives, these symbiotic organisms initially detected in deep-sea hydrothermal vents and geothermal springs, have been further distributed in various environmental ecosystems worldwide. Recent isolation by co-culture of Nanopusillus massiliensis from the unique ecosystem of the human oral cavity, prompted us to review the evolutionary diversity of nanaorchaea resulting in a rapidly evolving taxonomiy. Regardless of their ecological niche, all nanoarchaea share limited metabolic capacities correlating with an obligate ectosymbiotic or parasitic lifestyle; focusing on the dynamics of nanoarchaea-bacteria nanoarchaea-archaea interactions at the morphological and metabolic levels; highlighting proteins involved in nanoarchaea attachment to the hosts, as well metabolic exchanges between both organisms; and highlighting clinical nanoarchaeology, an emerging field of research in the frame of the recent discovery of Candidate Phyla radiation (CPR) in human microbiota. Future studies in clinical nanobiology will expand knowledge of the nanaorchaea repertoire associated with human microbiota and diseases, to improve our understanding of the diversity of these nanoorganims and their intreactions with microbiota and host tissues.

Archaea: A Gold Mine for Topoisomerase Diversity

The control of DNA topology is a prerequisite for all the DNA transactions such as DNA replication, repair, recombination, and transcription. This global control is carried out by essential enzymes, named DNA-topoisomerases, that are mandatory for the genome stability. Since many decades, the Archaea provide a significant panel of new types of topoisomerases such as the reverse gyrase, the type IIB or the type IC. These more or less recent discoveries largely contributed to change the understanding of the role of the DNA topoisomerases in all the living world. Despite their very different life styles, Archaea share a quasi-homogeneous set of DNA-topoisomerases, except thermophilic organisms that possess at least one reverse gyrase that is considered a marker of the thermophily. Here, we discuss the effect of the life style of Archaea on DNA structure and topology and then we review the content of these essential enzymes within all the archaeal diversity based on complete sequenced genomes available. Finally, we discuss their roles, in particular in the processes involved in both the archaeal adaptation and the preservation of the genome stability.

A β-hairpin is a Minimal Latch that Supports Positive Supercoiling by Reverse Gyrase

Reverse gyrase is a unique type I topoisomerase that catalyzes the introduction of positive supercoils into DNA in an ATP-dependent reaction. Supercoiling is the result of a functional cooperation of the N-terminal helicase domain with the C-terminal topoisomerase domain. The helicase domain is a nucleotide-dependent conformational switch that alternates between open and closed states with different affinities for single- and double-stranded DNA. The isolated helicase domain as well as full-length reverse gyrase can transiently unwind double-stranded regions in an ATP-dependent reaction. The latch region of reverse gyrase, an insertion into the helicase domain with little conservation in sequence and length, has been proposed to coordinate events in the helicase domain with strand passage by the topoisomerase domain. Latch deletions lead to a reduction in or complete loss of supercoiling activity. Here we show that the latch consists of two functional parts, a globular domain that is dispensable for DNA supercoiling and a β-hairpin that connects the globular domain to the helicase domain and is required for supercoiling activity. The β-hairpin thus constitutes a minimal latch that couples ATP-dependent processes in the helicase domain to DNA processing by the topoisomerase domain.

Expanding the type IIB DNA topoisomerase family: identification of new topoisomerase and topoisomerase-like proteins in mobile genetic elements

The control of DNA topology by DNA topoisomerases is essential for virtually all DNA transactions in the cell. These enzymes, present in every organism, exist as several non-homologous families. We previously identified a small group of atypical type IIB topoisomerases, called Topo VIII, mainly encoded by plasmids. Here, taking advantage of the rapid expansion of sequence databases, we identified new putative Topo VIII homologs. Our analyses confirm the exclusivity of the corresponding genes to mobile genetic elements (MGE) and extend their distribution to nine different bacterial phyla and one archaeal superphylum. Notably, we discovered another subfamily of topoisomerases, dubbed ‘Mini-A’, including distant homologs of type IIB topoisomerases and encoded by extrachromosomal and integrated bacterial and archaeal viruses. Interestingly, a short, functionally uncharacterized motif at the C-terminal extremity of type IIB topoisomerases appears sufficient to discriminate between Mini-A, Topo VI and Topo VIII subfamilies. This motif could be a key element for understanding the differences between the three subfamilies. Collectively, this work leads to an updated model for the origin and evolution of the type IIB topoisomerase family and raises questions regarding the role of topoisomerases during replication of MGE in bacteria and archaea.

Transformation of a Thermostable G-Quadruplex Structure into DNA Duplex Driven by Reverse Gyrase

Reverse gyrase is a topoisomerase that can introduce positive supercoils to its substrate DNA. It is demonstrated in our studies that a highly thermal stable G-quadruplex structure in a mini-plasmid DNA was transformed into its duplex conformation after a treatment with reverse gyrase. The structural difference of the topoisomers were verified and analyzed by gel electrophoresis, atomic force microscopy examination, and endonuclease digestion assays. All evidence suggested that the overwinding structure of positive supercoil could provide a driven force to disintegrate G-quadruplex and reform duplex. The results of our studies could suggest that hyperthermophiles might use reverse gyrase to manipulate the disintegration of non-B DNA structures and safekeep their genomic information.

Reverse gyrase--recent advances and current mechanistic understanding of positive DNA supercoiling

Reverse gyrases are topoisomerases that introduce positive supercoils into DNA in an ATP-dependent reaction. They consist of a helicase domain and a topoisomerase domain that closely cooperate in catalysis. The mechanism of the functional cooperation of these domains has remained elusive. Recent studies have shown that the helicase domain is a nucleotide-regulated conformational switch that alternates between an open conformation with a low affinity for double-stranded DNA, and a closed state with a high double-stranded DNA affinity. The conformational cycle leads to transient separation of DNA duplexes by the helicase domain. Reverse gyrase-specific insertions in the helicase module are involved in binding to single-stranded DNA regions, DNA unwinding and supercoiling. Biochemical and structural data suggest that DNA processing by reverse gyrase is not based on sequential action of the helicase and topoisomerase domains, but rather the result of an intricate cooperation of both domains at all stages of the reaction. This review summarizes the recent advances of our understanding of the reverse gyrase mechanism. We put forward and discuss a refined, yet simple model in which reverse gyrase directs strand passage toward increasing linking numbers and positive supercoiling by controlling the conformation of a bound DNA bubble.

RNA-Seq analyses reveal the order of tRNA processing events and the maturation of C/D box and CRISPR RNAs in the hyperthermophile Methanopyrus kandleri

The methanogenic archaeon Methanopyrus kandleri grows near the upper temperature limit for life. Genome analyses revealed strategies to adapt to these harsh conditions and elucidated a unique transfer RNA (tRNA) C-to-U editing mechanism at base 8 for 30 different tRNA species. Here, RNA-Seq deep sequencing methodology was combined with computational analyses to characterize the small RNome of this hyperthermophilic organism and to obtain insights into the RNA metabolism at extreme temperatures. A large number of 132 small RNAs were identified that guide RNA modifications, which are expected to stabilize structured RNA molecules. The C/D box guide RNAs were shown to exist as circular RNA molecules. In addition, clustered regularly interspaced short palindromic repeats RNA processing and potential regulatory RNAs were identified. Finally, the identification of tRNA precursors before and after the unique C8-to-U8 editing activity enabled the determination of the order of tRNA processing events with termini truncation preceding intron removal. This order of tRNA maturation follows the compartmentalized tRNA processing order found in Eukaryotes and suggests its conservation during evolution.

Crystal structures of Thermotoga maritima reverse gyrase: inferences for the mechanism of positive DNA supercoiling

Reverse gyrase is an ATP-dependent topoisomerase that is unique to hyperthermophilic archaea and eubacteria. The only reverse gyrase structure determined to date has revealed the arrangement of the N-terminal helicase domain and the C-terminal topoisomerase domain that intimately cooperate to generate the unique function of positive DNA supercoiling. Although the structure has elicited hypotheses as to how supercoiling may be achieved, it lacks structural elements important for supercoiling and the molecular mechanism of positive supercoiling is still not clear. We present five structures of authentic Thermotoga maritima reverse gyrase that reveal a first view of two interacting zinc fingers that are crucial for positive DNA supercoiling. The so-called latch domain, which connects the helicase and the topoisomerase domains is required for their functional cooperation and presents a novel fold. Structural comparison defines mobile regions in parts of the helicase domain, including a helical insert and the latch that are likely important for DNA binding during catalysis. We show that the latch, the helical insert and the zinc fingers contribute to the binding of DNA to reverse gyrase and are uniquely placed within the reverse gyrase structure to bind and guide DNA during strand passage. A possible mechanism for positive supercoiling by reverse gyrases is presented.

Reverse gyrase transiently unwinds double-stranded DNA in an ATP-dependent reaction

Reverse gyrase is a unique DNA topoisomerase that catalyzes the introduction of positive supercoils into DNA in an ATP-dependent reaction. It consists of a helicase domain that functionally cooperates with a topoisomerase domain. Different models for the catalytic mechanism of reverse gyrase that predict a central role of the helicase domain have been put forward. The helicase domain acts as a nucleotide-dependent conformational switch that alternates between open and closed states with different affinities for single- and double-stranded DNA. It has been suggested that the helicase domain can unwind double-stranded regions, but helicase activity has not been demonstrated as yet. Here, we show that the isolated helicase domain and full-length reverse gyrase can transiently unwind double-stranded regions in an ATP-dependent reaction. The latch region of reverse gyrase, an insertion into the helicase domain, is required for DNA supercoiling. Strikingly, the helicase domain lacking the latch cannot unwind DNA, linking unwinding to DNA supercoiling. The unwinding activity may provide and stabilize the single-stranded regions required for strand passage by the topoisomerase domain, either de novo or by expanding already existing unpaired regions that may form at high temperatures.

TopR2, the second reverse gyrase of Sulfolobus solfataricus, exhibits unusual properties

Whereas reverse gyrase is considered as a strong marker of thermophily, the function of this peculiar type IA topoisomerase still remains to be elucidated. The archaeon Sulfolobus solfataricus encodes two reverse gyrases, TopR1 and TopR2. This duplication seems to be important because most of Crenarcheota exhibit two copies of reverse gyrase. However, to date, while TopR1 has been well characterized, no characterization of TopR2 has been reported. In this study, we describe for the first time the activity of S. solfataricus TopR2 that appears as a new reverse gyrase. Indeed, in spite of the sequence similarities between TopR1 and TopR2, we evidence unexpected great differences between the two enzymes. While TopR1 exhibits ATP-independent relaxation activity, TopR2 does not, and its activity is strictly dependent on the presence of ATP. Whereas TopR1 is a distributive topoisomerase, TopR2 exhibits an amazing high intrinsic processivity compared to all the topoisomerases studied so far. TopR2 is able to introduce a very high number of positive superturns in DNA, while TopR1 generates weakly positively supercoiled DNA. Finally, TopR2 behaves differently from TopR1 when incubated at different assay temperatures. All the results presented in this study indicate that TopR1 and TopR2 have, in vitro, different activities suggesting different functions in vivo.

Separate and combined biochemical activities of the subunits of a naturally split reverse gyrase

Reverse gyrase reanneals denatured DNA and induces positive supercoils in DNA, an activity that is critical for life at very high temperatures. Positive supercoiling occurs by a poorly understood mechanism involving the coordination of a topoisomerase domain and a helicase-like domain. In the parasitic archaeon Nanoarchaeum equitans, these domains occur as separate subunits. We express the subunits, and characterize them both in isolation and as a heterodimer. Each subunit tightly associates and interacts with the other. The topoisomerase subunit enhances the catalytic specificity of the DNA-dependent ATPase activity of the helicase-like subunit, and the helicase-like subunit inhibits the relaxation activity of the topoisomerase subunit while promoting positive supercoiling. DNA binding preference for both single- and double-stranded DNA is partitioned between the subunits. Based on a sensitive topological shift assay, the binding preference of helicase-like subunit for underwound DNA is modulated by its binding with ATP cofactor. These results provide new insight into the mechanism of positive supercoil induction by reverse gyrase.

The reverse gyrase helicase-like domain is a nucleotide-dependent switch that is attenuated by the topoisomerase domain

Reverse gyrase is a topoisomerase that introduces positive supercoils into DNA in an ATP-dependent manner. It is unique to hyperthermophilic archaea and eubacteria, and has been proposed to protect their DNA from damage at high temperatures. Cooperation between its N-terminal helicase-like and the C-terminal topoisomerase domain is required for positive supercoiling, but the precise role of the helicase-like domain is currently unknown. Here, the characterization of the isolated helicase-like domain from Thermotoga maritima reverse gyrase is presented. We show that the helicase-like domain contains all determinants for nucleotide binding and ATP hydrolysis. Its intrinsic ATP hydrolysis is significantly stimulated by ssDNA, dsDNA and plasmid DNA. During the nucleotide cycle, the helicase-like domain switches between high- and low-affinity states for dsDNA, while its affinity for ssDNA in the ATP and ADP states is similar. In the context of reverse gyrase, the differences in DNA affinities of the nucleotide states are smaller, and the DNA-stimulated ATPase activity is strongly reduced. This inhibitory effect of the topoisomerase domain decelerates the progression of reverse gyrase through the nucleotide cycle, possibly providing optimal coordination of ATP hydrolysis with the complex reaction of DNA supercoiling.

Transcriptional analysis of the two reverse gyrase encoding genes of Sulfolobus solfataricus P2 in relation to the growth phases and temperature conditions

Sulfolobus solfataricus, a hyperthermophilic crenarchaeon, contains two genes encoding reverse gyrases, topR1 and topR2. The steady-state level of their transcripts were quantified during the growth phases for cells maintained either at 72, or 80 degrees C, and after temperature changes from one to the other temperature. The transcripts of both genes are weakly expressed, but the highest level is observed in actively dividing cells, and is almost undetectable in cells in decline phase. During the temperature shift experiments, there is no significant topR2 variation. By contrast, there is a maximum 2.4-fold increase in topR1 transcripts within 30 min after the downshift. After 1 h, the transcript level reaches the level characteristic of cells adapted to the new temperature. After an upward shift, the topR1 expression pattern is inversely regulated with a transient decrease with the same time course. The topR1 expression profile is completely different from that of topR2 after temperature shift experiments; this suggests a different regulation process for the two reverse gyrase genes. The fine tuning of the topR1 transcript expression within a short interval of time after a temperature shift illustrates a rapid adaptation response to temperature change.

SSoNDelta and SSoNDeltalong: two thermostable esterases from the same ORF in the archaeon Sulfolobus solfataricus?

Previously, we reported from the Sulfolobus solfataricus open reading frame (ORF) SSO2517 the cloning, overexpression and characterization of an esterase belonging to the hormone-sensitive lipase (HSL) family and apparently having a deletion at the N-terminus, which we named SSoNDelta. Searching the recently reported Sulfolobus acidocaldarius genome by sequence alignment, using SSO2517 as a query, allowed identity of a putative esterase (ORF SAC1105) sharing high sequence similarity (82%) with SSO2517. This esterase displays an N-terminus and total length similar to other known esterases of the HSL family. Analysis of the upstream DNA sequence of SS02517 revealed the possibility of expressing a longer version of the protein with an extended N-terminus; however, no clear translation signal consistent with a longer protein version was detected. This new version of SSO2517 was cloned, over-expressed, purified and characterized. The resulting protein, named SSoNDeltalong, was 15-fold more active with the substrate p-nitrophenyl hexanoate than SSoNDelta. Furthermore, SSoNDeltalong and SSoNDelta displayed different substrate specificities for triacylglycerols. These results and the phylogenetic relationship between S. solfataricus and S. acidocaldarius suggest a common origin of SSO2517 and SAC1105 from an ancestral gene, followed by divergent evolution. Alternatively, a yet-to-be discovered mechanism of translation that directs the expression of SSoNDeltalong under specific metabolic conditions could be hypothesized.

Reverse gyrase: an insight into the role of DNA-topoisomerases

Reverse gyrase was discovered more than twenty years ago. Recent biochemical and structural results have greatly enhanced our understanding of their positive supercoiling mechanism. In addition to new biochemical properties, a fine tuning of reverse gyrase regulation in response to DNA damaging agents has been recently described. These data give us a new insight in the cellular role of reverse gyrase. Moreover, it has been proposed that reverse gyrase has been implicated in genome stability.

Type IA topoisomerases: a simple puzzle?

Type IA topoisomerases are enzymes that can modify DNA topology. They form a distinct family of proteins present in all domains of life, from bacteria to archaea and higher eukaryotes. They are composed of two domains: a core domain containing all the conserved motifs involved in the trans-esterification reactions, and a carboxyl-terminal domain that is highly variable in size and sequence. The latter appears to interact with other proteins, defining the physiological use of the topoisomerase activity. The evolutionary relevance of this topoisomerase-cofactor complex, also known as the "toposome", as well as its enzymatic consequences are discussed in this review.

The origin and evolution of Archaea: a state of the art

Environmental surveys indicate that the Archaea are diverse and abundant not only in extreme environments, but also in soil, oceans and freshwater, where they may fulfil a key role in the biogeochemical cycles of the planet. Archaea display unique capacities, such as methanogenesis and survival at temperatures higher than 90 degrees C, that make them crucial for understanding the nature of the biota of early Earth. Molecular, genomics and phylogenetics data strengthen Woese's definition of Archaea as a third domain of life in addition to Bacteria and Eukarya. Phylogenomics analyses of the components of different molecular systems are highlighting a core of mainly vertically inherited genes in Archaea. This allows recovering a globally well-resolved picture of archaeal evolution, as opposed to what is observed for Bacteria and Eukarya. This may be due to the fact that no rapid divergence occurred at the emergence of present-day archaeal lineages. This phylogeny supports a hyperthermophilic and non-methanogenic ancestor to present-day archaeal lineages, and a profound divergence between two major phyla, the Crenarchaeota and the Euryarchaeota, that may not have an equivalent in the other two domains of life. Nanoarchaea may not represent a third and ancestral archaeal phylum, but a fast-evolving euryarchaeal lineage. Methanogenesis seems to have appeared only once and early in the evolution of Euryarchaeota. Filling up this picture of archaeal evolution by adding presently uncultivated species, and placing it back in geological time remain two essential goals for the future.

Reverse gyrase functions as a DNA renaturase: annealing of complementary single-stranded circles and positive supercoiling of a bubble substrate

Reverse gyrase is a hyperthermophile-specific enzyme that can positively supercoil DNA concomitant with ATP hydrolysis. However, the DNA supercoiling activity is inefficient and requires an excess amount of enzyme relative to DNA. We report here several activities that reverse gyrase can efficiently mediate with a substoichiometric amount of enzyme. In the presence of a nucleotide cofactor, reverse gyrase can readily relax negative supercoils, but not the positive ones, from a plasmid DNA substrate. Reverse gyrase can completely relax positively supercoiled DNA, provided that the DNA substrate contains a single-stranded bubble. Reverse gyrase efficiently anneals complementary single-stranded circles. A substoichiometric amount of reverse gyrase can insert positive supercoils into DNA with a single-stranded bubble, in contrast to plasmid DNA substrate. We have designed a novel method based on phage-mid DNA vectors to prepare a circular DNA substrate containing a single-stranded bubble with defined length and sequence. With these bubble DNA substrates, we demonstrated that efficient positive supercoiling by reverse gyrase requires a bubble size larger than 20 nucleotides. The activities of annealing single-stranded DNA circles and positive supercoiling of bubble substrate demonstrate that reverse gyrase can function as a DNA renaturase. These biochemical activities also suggest that reverse gyrase can have an important biological function in sensing and eliminating unpaired regions in the genome of a hyperthermophilic organism.

Asymmetry in the burial of hydrophobic residues along the histone chains of eukarya, archaea and a transcription factor

Background

The histone fold is a common structural motif of proteins involved in the chromatin packaging of DNA and in transcription regulation. This single chain fold is stabilized by either homo- or hetero-dimer formation in archaea and eukarya. X-ray structures at atomic resolution have shown the eukaryotic nucleosome core particle to consist of a central tetramer of two bound H3-H4 dimers flanked by two H2A-H2B dimers. The c-terminal region of the H3 histone fold involved in coupling the two eukaryotic dimers of the tetramer, through a four-fold helical bundle, had previously been shown to be a region of reduced burial of hydrophobic residues within the dimers, and thereby provide a rationale for the observed reduced stability of the H3-H4 dimer compared with that of the H2A-H2B dimer. Furthermore, comparison between eukaryal and archaeal histones had suggested that this asymmetry in the distribution of hydrophobic residues along the H3 histone chains could be due to selective evolution that enhanced the coupling between the eukaryotic dimers of the tetramer.

Results and discussion

The present work describes calculations utilizing the X-ray structures at atomic resolution of a hyperthermophile from Methanopyrus kandleri (HMk) and a eukaryotic transcription factor from Drosophila melanogaster (DRm), that are structurally homologous to the eukaryotic (H3-H4)₂ tetramer. The results for several other related structures are also described. Reduced burial of hydrophobic residues, at the homologous H3 c-terminal regions of these structures, is found to parallel the burial at the c-terminal regions of the H3 histones and is, thereby, expected to affect dimer stability and the processes involving histone structural rearrangement. Significantly different sequence homology between the two histones of the HMk doublet with other archaeal sequences is observed, and how this might have occurred during selection to enhance tetramer stability is described.

Nanoarchaea: representatives of a novel archaeal phylum or a fast-evolving euryarchaeal lineage related to Thermococcales?

An analysis of the position of Nanoarcheum equitans in the archaeal phylogeny using a large dataset of concatenated ribosomal proteins from 25 archaeal genomes suggests that N. equitans is likely to be the representative of a fast-evolving euryarchaeal lineage.

Background

Cultivable archaeal species are assigned to two phyla - the Crenarchaeota and the Euryarchaeota - by a number of important genetic differences, and this ancient split is strongly supported by phylogenetic analysis. The recently described hyperthermophile Nanoarchaeum equitans, harboring the smallest cellular genome ever sequenced (480 kb), has been suggested as the representative of a new phylum - the Nanoarchaeota - that would have diverged before the Crenarchaeota/Euryarchaeota split. Confirming the phylogenetic position of N. equitans is thus crucial for deciphering the history of the archaeal domain.

Results

We tested the placement of N. equitans in the archaeal phylogeny using a large dataset of concatenated ribosomal proteins from 25 archaeal genomes. We indicate that the placement of N. equitans in archaeal phylogenies on the basis of ribosomal protein concatenation may be strongly biased by the coupled effect of its above-average evolutionary rate and lateral gene transfers. Indeed, we show that different subsets of ribosomal proteins harbor a conflicting phylogenetic signal for the placement of N. equitans. A BLASTP-based survey of the phylogenetic pattern of all open reading frames (ORFs) in the genome of N. equitans revealed a surprisingly high fraction of close hits with Euryarchaeota, notably Thermococcales. Strikingly, a specific affinity of N. equitans and Thermococcales was strongly supported by phylogenies based on a subset of ribosomal proteins, and on a number of unrelated molecular markers.

Conclusion

We suggest that N. equitans may more probably be the representative of a fast-evolving euryarchaeal lineage (possibly related to Thermococcales) than the representative of a novel and early diverging archaeal phylum.

Nucleotide- and stoichiometry-dependent DNA supercoiling by reverse gyrase

Reverse gyrase is a unique type IA topoisomerase that can introduce positive supercoils into DNA. We have investigated some of the biochemical properties of Archaeoglobus fulgidus reverse gyrase. It can mediate three distinct supercoiling reactions depending on the adenine nucleotide cofactor that is present in the reaction. Besides the ATP-driven positive supercoiling reaction, the enzyme can introduce negative supercoils with a nonhydrolyzable analog, adenylyl imidodiphosphate. In the presence of ADP the plasmid DNA is relaxed almost completely, leaving a very low level of positive supercoiling. Surprisingly, the final supercoiling extent for all three distinct reactions depends on the stoichiometry of enzyme to DNA. This dependence is not due to the difference of reaction rate, suggesting that the amount of enzyme bound to DNA is an important determinant for the final supercoiling state of the reaction product. Reverse gyrase also displays exquisite sensitivity toward temperature. Raising the reaction temperatures from 80 to 85 degrees C, both of which are within the optimal growth temperature of A. fulgidus, greatly increases enzyme activity for all the supercoiling reactions. For the reaction with AMPPNP, the product is a hypernegatively supercoiled DNA. This dramatic enhancement of the reverse gyrase activity is also correlated with the appearance of DNA in a pre-melting state at 85 degrees C, likely due to the presence of extensively unwound regions in the plasmid. The possible mechanistic insights from these findings will be presented here.

Archaeal phylogeny based on proteins of the transcription and translation machineries: tackling the Methanopyrus kandleri paradox

This article presents a phylogenetic analysis of the Archea based on sets of transcription and translation proteins. The phylogenies shed light on the evolutionary position of Methanopyrus kandleri.

Background

Phylogenetic analysis of the Archaea has been mainly established by 16S rRNA sequence comparison. With the accumulation of completely sequenced genomes, it is now possible to test alternative approaches by using large sequence datasets. We analyzed archaeal phylogeny using two concatenated datasets consisting of 14 proteins involved in transcription and 53 ribosomal proteins (3,275 and 6,377 positions, respectively).

Results

Important relationships were confirmed, notably the dichotomy of the archaeal domain as represented by the Crenarchaeota and Euryarchaeota, the sister grouping of Sulfolobales and Aeropyrum pernix, and the monophyly of a large group comprising Thermoplasmatales, Archaeoglobus fulgidus, Methanosarcinales and Halobacteriales, with the latter two orders forming a robust cluster. The main difference concerned the position of Methanopyrus kandleri, which grouped with Methanococcales and Methanobacteriales in the translation tree, whereas it emerged at the base of the euryarchaeotes in the transcription tree. The incongruent placement of M. kandleri is likely to be the result of a reconstruction artifact due to the high evolutionary rates displayed by the components of its transcription apparatus.

Conclusions

We show that two informational systems, transcription and translation, provide a largely congruent signal for archaeal phylogeny. In particular, our analyses support the appearance of methanogenesis after the divergence of the Thermococcales and a late emergence of aerobic respiration from within methanogenic ancestors. We discuss the possible link between the evolutionary acceleration of the transcription machinery in M. kandleri and several unique features of this archaeon, in particular the absence of the elongation transcription factor TFS.

The genome of Nanoarchaeum equitans: insights into early archaeal evolution and derived parasitism

The hyperthermophile Nanoarchaeum equitans is an obligate symbiont growing in coculture with the crenarchaeon Ignicoccus. Ribosomal protein and rRNA-based phylogenies place its branching point early in the archaeal lineage, representing the new archaeal kingdom Nanoarchaeota. The N. equitans genome (490,885 base pairs) encodes the machinery for information processing and repair, but lacks genes for lipid, cofactor, amino acid, or nucleotide biosyntheses. It is the smallest microbial genome sequenced to date, and also one of the most compact, with 95% of the DNA predicted to encode proteins or stable RNAs. Its limited biosynthetic and catabolic capacity indicates that N. equitans' symbiotic relationship to Ignicoccus is parasitic, making it the only known archaeal parasite. Unlike the small genomes of bacterial parasites that are undergoing reductive evolution, N. equitans has few pseudogenes or extensive regions of noncoding DNA. This organism represents a basal archaeal lineage and has a highly reduced genome.

A hot story from comparative genomics: reverse gyrase is the only hyperthermophile-specific protein

I have looked for proteins that are present in all hyperthermophile genomes, but absent from all mesophile or thermophile genomes by using the phylogenetic pattern search program of the COG database. Surprisingly, this search retrieved only one such hyperthermophile-specific protein: reverse gyrase. This result emphasizes the importance of reverse gyrase in the adaptation of life to very high temperatures, and strengthens the idea that evolution of this enzyme was crucial in the origin of hyperthermophiles.

The complete genome of hyperthermophile Methanopyrus kandleri AV19 and monophyly of archaeal methanogens

We have determined the complete 1,694,969-nt sequence of the GC-rich genome of Methanopyrus kandleri by using a whole direct genome sequencing approach. This approach is based on unlinking of genomic DNA with the ThermoFidelase version of M. kandleri topoisomerase V and cycle sequencing directed by 2'-modified oligonucleotides (Fimers). Sequencing redundancy (3.3x) was sufficient to assemble the genome with less than one error per 40 kb. Using a combination of sequence database searches and coding potential prediction, 1,692 protein-coding genes and 39 genes for structural RNAs were identified. M. kandleri proteins show an unusually high content of negatively charged amino acids, which might be an adaptation to the high intracellular salinity. Previous phylogenetic analysis of 16S RNA suggested that M. kandleri belonged to a very deep branch, close to the root of the archaeal tree. However, genome comparisons indicate that, in both trees constructed using concatenated alignments of ribosomal proteins and trees based on gene content, M. kandleri consistently groups with other archaeal methanogens. M. kandleri shares the set of genes implicated in methanogenesis and, in part, its operon organization with Methanococcus jannaschii and Methanothermobacter thermoautotrophicum. These findings indicate that archaeal methanogens are monophyletic. A distinctive feature of M. kandleri is the paucity of proteins involved in signaling and regulation of gene expression. Also, M. kandleri appears to have fewer genes acquired via lateral transfer than other archaea. These features might reflect the extreme habitat of this organism.

DNA topoisomerases: structure, function, and mechanism

DNA topoisomerases solve the topological problems associated with DNA replication, transcription, recombination, and chromatin remodeling by introducing temporary single- or double-strand breaks in the DNA. In addition, these enzymes fine-tune the steady-state level of DNA supercoiling both to facilitate protein interactions with the DNA and to prevent excessive supercoiling that is deleterious. In recent years, the crystal structures of a number of topoisomerase fragments, representing nearly all the known classes of enzymes, have been solved. These structures provide remarkable insights into the mechanisms of these enzymes and complement previous conclusions based on biochemical analyses. Surprisingly, despite little or no sequence homology, both type IA and type IIA topoisomerases from prokaryotes and the type IIA enzymes from eukaryotes share structural folds that appear to reflect functional motifs within critical regions of the enzymes. The type IB enzymes are structurally distinct from all other known topoisomerases but are similar to a class of enzymes referred to as tyrosine recombinases. The structural themes common to all topoisomerases include hinged clamps that open and close to bind DNA, the presence of DNA binding cavities for temporary storage of DNA segments, and the coupling of protein conformational changes to DNA rotation or DNA movement. For the type II topoisomerases, the binding and hydrolysis of ATP further modulate conformational changes in the enzymes to effect changes in DNA topology.

Unwinding the 'Gordian knot' of helicase action

Helicases are enzymes involved in every aspect of nucleic acid metabolism. Recent structural and biochemical evidence is beginning to provide details of their molecular mechanism of action. Crystal structures of helicases have revealed an underlying common structural fold. However, although there are many similarities between the mechanisms of different classes of helicase, not all aspects of the helicase activity are the same in all members of this enzyme family.

The Zn(II) binding motifs of E. coli DNA topoisomerase I is part of a high-affinity DNA binding domain

Escherichia coli DNA topoisomerase I binds three Zn(II) with three tetracysteine motifs. Three subclones containing these tetracysteine motifs were expressed and purified. Subclone ZD1 contained the minimal tetracysteine motifs sequence. A larger subclone ZD2 corresponded to a region bordered by two protease sensitive sites. Subclone ZD3 also included the 14-kDa C-terminal domain that has been shown to bind DNA. Subclones ZD1 and ZD2 were found to bind one and two Zn(II), respectively, and neither had detectable DNA binding activity. ZD3 could bind three Zn(II) and had higher DNA binding affinity than the 14-kDa C-terminal domain. The complex formed between ZD3 and a single-stranded 31mer could be detected by the gel shift assay while the complex formed by the 14-kDa C-terminal domain was not stable under gel electrophoresis conditions. The three Zn(II) binding motifs appeared to be part of a high-affinity DNA binding domain.

Structure of DNA topoisomerases

Over the last several years topoisomerases have finally begun to yield to high-resolution structural studies. These models have greatly aided our understanding of the mechanisms of topoisomerase catalysis and drug interactions. This review will cover advances in the structural biology of topoisomerases and discuss their implications for topoisomerase function.

Bacterial and archeal type I topoisomerases

Bacterial and archeal type I topoisomerases, including topoisomerase I, topoisomerase III and reverse gyrase, have different potential roles in the control of DNA topology including regulation of supercoiling and maintenance of genetic stability. Analysis of their coding sequences in different organisms shows that they belong to the type IA family of DNA topoisomerases, but there is variability in organization of various enzymatic domains necessary for topoisomerase activity. The torus-like structure of the conserved transesterification domain with the active site tyrosine for DNA cleavage/rejoining suggests steps of enzyme conformational change driven by DNA substrate and Mg(II) cofactor binding, that are required for catalysis of change in DNA linking number.

Site-directed mutagenesis of conserved aspartates, glutamates and arginines in the active site region of Escherichia coli DNA topoisomerase I

To catalyze relaxation of supercoiled DNA, DNA topoisomerases form a covalent enzyme-DNA intermediate via nucleophilic attack of a tyrosine hydroxyl group on the DNA phosphodiester backbone bond during the step of DNA cleavage. Strand passage then takes place to change the linking number. This is followed by DNA religation during which the displaced DNA hydroxyl group attacks the phosphotyrosine linkage to reform the DNA phosphodiester bond. Mg(II) is required for the relaxation activity of type IA and type II DNA topoisomerases. A number of conserved amino acids with acidic and basic side chains are present near Tyr-319 in the active site of the crystal structure of the 67-kDa N-terminal fragment of Escherichia coli DNA topoisomerase I. Their roles in enzyme catalysis were investigated by site-directed mutation to alanine. Mutation of Arg-136 abolished all the enzyme relaxation activity even though DNA cleavage activity was retained. The Glu-9, Asp-111, Asp-113, Glu-115, and Arg-321 mutants had partial loss of relaxation activity in vitro. All the mutants failed to complement chromosomal topA mutation in E. coli AS17 at 42 degreesC, possibly accounting for the conservation of these residues in evolution.

Reverse gyrase from the hyperthermophilic bacterium Thermotoga maritima: properties and gene structure

The hyperthermophilic bacterium Thermotoga maritima MSB8 possesses a reverse gyrase whose enzymatic properties are very similar to those of archaeal reverse gyrases. It catalyzes the positive supercoiling of the DNA in an Mg2+- and ATP-dependent process. Its optimal temperature of activity is around 90 degrees C, and it is highly thermostable. We have cloned and DNA sequenced the corresponding gene (T. maritima topR). This is the first report describing the analysis of a gene encoding a reverse gyrase in bacteria. The T. maritima topR gene codes for a protein of 1,104 amino acids with a deduced molecular weight of 128,259, a value in agreement with that estimated from the denaturing gel electrophoresis of the purified enzyme. Like its archaeal homologs, the T. maritima reverse gyrase exhibits helicase and topoisomerase domains, and its sequence matches very well the consensus sequence for six reverse gyrases now available. Phylogenetic analysis shows that all reverse gyrases, including the T. maritima enzyme, form a very homogeneous group, distinct from the type I 5' topoisomerases of the TopA subfamily, for which we have previously isolated a representative gene in T. maritima (topA). The coexistence of these two distinct genes, coding for a reverse gyrase and an omega-like topoisomerase, respectively, together with the recent description of a gyrase in T. maritima (O. Guipaud, E. Marguet, K. M. Noll, C. Bouthier de la Tour, and P. Forterre, Proc. Natl. Acad. Sci. USA 94:10606-10611, 1977) addresses the question of the control of the supercoiling in this organism.

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.

When helicase and topoisomerase meet!

Several examples of direct interactions between helicases and topoisomerases have recently been described. The data suggest a possible cooperation between these enzymes in major DNA events such as the progression of a replication fork, segregation of newly replicated chromosomes, disruption of nucleosomal structure, DNA supercoiling, and finally recombination, repair, and genomic stability. A first example is the finding of a strong interaction between T antigen and topoisomerase I in mammalian cells, that may trigger unwinding of the parental DNA strands at the replication forks of Simian Virus 40. A second example is the reverse gyrase from thermophilic prokaryotes, composed of a putative helicase domain, and a topoisomerase domain in the same polypeptide. This enzyme may be required to maintain genomic stability at high temperature. A third example is the finding of an interaction between type II topoisomerase and the helicase Sgs1 in yeast. This interaction possibly allows the faithful segregation of newly replicated chromosomes in eukaryotic cells. A fourth example is the interaction between the same helicase Sgs1 and topoisomerase III in yeast, that may control recombination level and genetic stability of repetitive sequences. Recently, in humans, mutations in genes similar to Sgs1 have been found to be responsible for Bloom's and Werner's syndromes. The cooperation between helicases and topoisomerases is likely to be extended to many aspects of DNA mechanisms including chromatin condensation/decondensation.

Reverse gyrase from Methanopyrus kandleri. Reconstitution of an active extremozyme from its two recombinant subunits

Reverse gyrases are ATP-dependent type I 5'-topoisomerases that positively supercoil DNA. Reverse gyrase from Methanopyrus kandleri is unique as the first heterodimeric type I 5'-topoisomerase described, consisting of a 138-kDa subunit involved in the hydrolysis of ATP (RgyB) and a 43-kDa subunit that forms the covalent complex with DNA during the topoisomerase reaction (RgyA). Here we report the reconstitution of active reverse gyrase from the two recombinant proteins overexpressed in Escherichia coli. Both proteins have been purified by column chromatography to >90% homogeneity. RgyB has a DNA-dependent ATPase activity at high temperature (80 degrees C) and is independent of the presence of RgyA. RgyA alone has no detectable activity. The addition of RgyA to RgyB reconstitutes positive supercoiling activity, but the RgyB and RgyA subunits form a stable heterodimer only after being heated together. This is the first case in which it has been possible to reconstitute an active heterodimeric enzyme of a hyperthermophilic prokaryote from recombinant proteins.

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.

Downregulation of DNA topoisomerase I in old versus young human diploid fibroblasts

DNA topoisomerase I (Topo I) is an enzyme that alters the superhelicity of DNA. It has been implicated in such critical cellular functions as transcription, DNA replication, and recombination. Roles for Topo I in DNA repair following DNA damage have also been studied extensively. In the present investigation, we examined the regulation of Topo I expression and activity during cellular replicative senescence. We found that the capacity of Topo I to relax supercoiled DNA molecules is significantly decreased in senescent diploid fibroblasts when compared to young (early passage) fibroblasts. We also found that the steady-state expression level of Topo I mRNA is correlated with enzyme activity, i.e., decreased in early vs. late passage cells. We also treated early and late passage cells with agents that may modulate the process of cellular senescence: UV light, retinoic acid, and interleukin-1 beta. We found that all three agents decreased the activity of Topo I in young fibroblasts and increased the activity of Topo I in senescent fibroblasts. This effect was most striking following exposure of the cells to retinoic acid, so to analyze this effect, we postulated an age-dependent kinetics of Topo I mRNA induction in response to retinoic acid. Consistent with this postulate, we found that whereas exposure of early passage cells to retinoic acid results, in a matter of hours, in a decrease in the expression of Topo I mRNA, exposure of the senescent cells to retinoic acid results in an increased expression. These observations suggest that processes that are altered in senescent fibroblasts, such as DNA replication and repair, may be due, in part, to alteration in the expression and activity of DNA Topo I.

Reverse gyrase gene from Sulfolobus shibatae B12: gene structure, transcription unit and comparative sequence analysis of the two domains

We cloned and sequenced a DNA fragment from the thermophilic archaeal strain Sulfolobus shibatae B12 that includes the gene topR encoding the reverse gyrase. The RNA of the reverse gyrase gene was characterized indicating that the topR gene is fully functional in vivo. We showed by primer extension analysis that transcription of topR initiates 28 bp downstream from a consensus A-box promoter. In order to understand how this particular type I DNA topoisomerase introduces positive superturns into the DNA, we compared the amino acid sequence of reverse gyrase from S.shibatae with the two other known reverse gyrases. This comparison indicates a common organization of these proteins: the carboxy-terminal domain is related to the type I-5' topoisomerase family while the amino-terminal domain possesses some motifs of proteins described as RNA or DNA helicases. By using local alignments, we showed that (i) reverse gyrases constitute a new and rather homogenous group within the type I-5' DNA topoisomerase family; (ii) a careful sequence analysis of the amino-terminal domain allows us to relate the presence of some motifs with an ATP binding and hydrolysis reaction coupled to a DNA binding and unwinding activity.

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.