Complete Genome Sequence of the Methanogenic Archaeon,
            <b>
              <i>Methanococcus jannaschii</i>
            </b>

Bult, Carol J.; White, Owen; Olsen, Gary J.; Zhou, Lixin; Fleischmann, R. D.; Sutton, Granger; Blake, Judith A.; Fitzgerald, Lisa M.; Clayton, Rebecca A.; Gocayne, Jeannine D.; Kerlavage, Anthony R.; Dougherty, Brian; Tomb, Jean-François; Adams, Mark D.; Reich, Claudia I.; Overbeek, Ross; Kirkness, Ewen F.; Weinstock, Keith G.; Merrick, Jason R. W.; Glodek, Anna; Scott, J. L.; Geoghagen, N. S. M.; Weidman, Janice; Fuhrmann, Joyce; Nguyen, David N.; Utterback, Teresa; Kelley, Jenny M.; Peterson, Jeremy; Sadow, P. W.; Hanna, M. C.; Cotton, Matthew; Roberts, Kevin; Hurst, M. A.; Kaine, Brian P.; Borodovsky, Mark; Klenk, Hans‐Peter; Fraser, Claire M.; Smith, H; Woese, Carl R.; Venter, J. Craig

doi:10.1126/science.273.5278.1058

Cited by 2,273 publications

(1,577 citation statements)

References 63 publications

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“…The 3Ј end of ORF1 codes for a 57-aa partial sequence too short to be significantly analyzed. ORF2 encodes a 404-aa protein which exhibits high similarities to archaeal adenosylhomocysteine hydrolases: 54% identity with the enzyme from Sulfolobus solfataricus (36) and 57% with that from M. jannaschii (7).…”

Section: Resultsmentioning

confidence: 99%

Reverse gyrase from hyperthermophiles: probable transfer of a thermoadaptation trait from Archaea to Bacteria

et al. 2000

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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 Mg 2؉ -and ATP-dependent process. Its optimal temperature of activity is around 90°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. What are the molecular mechanisms involved in the adaptation of life to elevated temperatures? In terms of DNA dynamics, part of the answer was provided by the discovery in thermophilic organisms of a particular topoisomerase, the reverse gyrase, that modifies the topological state of DNA by introducing positive supercoils in an ATP-dependent process (14). It was suggested that overlinking could compensate for the effect of temperature on DNA structure (16). The enzyme is widely distributed in thermophilic archaea (6,8). The first reverse gyrase characterized was isolated from the hyperthermophilic archaeum Sulfolobus acidocaldarius (23,33). Mechanistic studies showed that it is transiently linked to the DNA by a 5Ј phosphotyrosyl bond (22,24), classifying it in the type I 5Ј topoisomerase family as proposed by Roca (38). Sequence analysis further showed that it is a single polypeptide containing putative helicase and topoisomerase domains located in the amino-and carboxy-terminal, respectively, parts of the protein (9). The helicase domain exhibits motifs found in DNA and RNA helicases, and the topoisomerase domain exhibits a significant similarity with the 5Ј topoisomerase I (protein ) from Escherichia coli. From all of these data, a mechanism of reverse gyration involving the concerted action of two such domains was proposed (9, 14).To date, four other archaeal reverse gyrase genes have been sequenced: from Sulfolobus shibatae (21), Methanopyrus kandleri (26), Pyrococcus furiosus (3), and Methanococcus jannaschii (7). A comparative analysis of reverse gyrases from two members of the order Sulfolobales (S. acidocaldarius and S. shibatae) and M. kandleri with the other type I topoisomerases of the 5Ј family (21) showed that the reverse gyrases constitute a new group within this family distinct from the previously described TopA and TopB groups, represent...

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Section: Resultsmentioning

confidence: 99%

Reverse gyrase from hyperthermophiles: probable transfer of a thermoadaptation trait from Archaea to Bacteria

et al. 2000

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“…Sketched phylogenetic tree, according to the present knowledge (Woese et al+, 1990;Pace, 1997), showing distribution of the tRNA Sec secondary structure models+ The tRNA Sec secondary structure of the Archae M. jannaschii (sequence from Bult et al+, 1996) folds into the 9/4 model+ Dotted line represents a putative U-A base pair+ The tRNA Sec secondary structure of the hyperthermophilic bacterium A. aeolicus (sequence from Deckert et al+, 1998) folds into the 8/5 model, as do the other bacterial tRNAs Sec + An alternate 2D structure can be proposed for the D-stem with a C+C pairing+ The folding is 8/5 in bacteria (E. coli and A. aeolicus), 9/4 in Archaea (M. jannaschii ) and Eukarya (X. laevis)+ The M. jannaschii tRNA Sec sequence was extracted from the TIGR mjdatabase (positions 111766-111855)+ The A. aeolicus tRNA Sec sequence was found at NCBI, accession number AE000720 (positions 8711-8809)+ The E. coli and X. laevis tRNAs Sec sequences were from Tormay et al+ (1994) and Sturchler et al+ (1993), respectively+ D+ It is frequently observed that N1-As (here N1-A63) react rapidly with DMS, even when base paired with a U, sometimes leading to the wrong interpretation that an A could be single stranded+ This reactivity is very likely due to the small size of the reagent and breathing of the helix, providing enough transient accessibility of the N1-A for the chemical to react+ However, in the gel provided in Figure 2A, it is obvious that N1-A63 is protected under native conditions, thus base paired to U51+…”

Section: Discussionmentioning

confidence: 99%

“…In our earlier work (Sturchler et al+, 1993), the Xenopus laevis tRNA Sec molecule was monitored with a variety of enzymatic and chemical probes that led to a convergence of data in favor of the 9/4 model shown in Figure 1B+ The key point was to determine whether Figure 2A+ The presence of the modification is reflected on the gel by a pause of the reverse transcriptase one nucleotide prior to the modified base+ Again, one can see that C66 (pointed by the arrow in Fig+ 2A) is reactive to DMS only under semi-denaturing and denaturing conditions, showing the same reactivity as N3-C61 and N3-C62, which pair to G53 and G52, respectively, and N3-C68, which pairs to G5 (Fig+ 2A, lanes 4 and 6)+ To further strengthen the argument, we made use of lead acetate probing+ This chemical probe has been used with a variety of different RNAs by several authors as a singlestrand-specific probe (Brunel et al+, 1990;Hüttenhofer et al+, 1996;Walczak et al+, 1996)+ In addition, bulges in helices are exquisitely susceptible to this chemical (Hüt-tenhofer et al+, 1996), especially when flanked by two pyrimidines (Ciesiolka et al+, 1998), which is precisely the case in the tRNA Sec examined+ This molecule was submitted to lead acetate cleavage and no strong cleavages appeared in the C64/C66 area (Fig+ 2B)+ Cleavages were indeed observed between U67A and C62, but they are of an extremely low and evenly distributed intensity and, in addition, localized in the C64-C62 base paired region that should not be cut whether it is the 7/5 or 9/4 model (see Fig+ 1A and B for a summary of the cleavages)+ Therefore, these can be considered background cleavages+ Instead, a much stronger intensity of cuts should have been expected at the level of U66-C64 if C66 were bulged+ As anticipated, the T-loop was cleaved efficiently by Pb 2ϩ (Figs+ 1, 2B)+ These two experiments establish that C66 is not bulged, therefore strongly arguing in favor of the 9/4 model+ The tRNA Sec of the Archae M. jannaschii can only adopt the 9/4 folding Elucidation of the complete genomic sequence of the Archae M. jannaschii led the authors to the finding that the transcription and translation machineries in eukaryotes and this archae are very much alike (Bult et al+, 1996)+ When it comes to the tRNA Sec secondary structure of this organism, we found that the sequence constraints absolutely preclude a folding according to the 7/5 model, allowing only the 9/4 possibility (Fig+ 3)+ The complete similarity of the archaeal tRNA Sec secondary structure to that of eukaryotes cannot be taken as a fortuitous argument for two reasons+…”

Section: Chemical Probingmentioning

confidence: 94%

“…The second reason is supplied by evolutionary considerations+ The recent publication of the complete genome sequence of the hyperthermophilic bacterium Aquifex aeolicus (Deckert et al+, 1998) allowed us to fold the tRNA Sec sequence into the 8/5 secondary structure model as for the other bacterial tRNAs Sec (Fig+ 3)+ Several pieces of evidence point to the conclusion that the Archae and Eukarya share a common evolutionary trajectory independent of the lineage of bacteria (Woese et al+, 1990;Bult et al+, 1996; Pace, 1997)+ Also, the kinship degree between the bacterium A. aeolicus and the Archae M. jannaschii is far from being close (reviewed in Pennisi, 1998)+ Thus, the congruence of the 8/5 versus 9/4 tRNA Sec classification with the bacterial versus archaeal/eukaryal phylogenetic kingdom classification provides strong evidence for the 9/4 tRNA Sec structure+ Indeed, a 7/5 structure model for eukaryotes would lead to three different secondary structure models for the three different kingdoms instead of only two (Fig+ 3)+ Therefore, the 8/5 and 9/4 tRNA Sec classification that we posited is relevant, thus providing additional evidence for the merits of the archaeal tRNA Sec argument+…”

Section: Chemical Probingmentioning

confidence: 99%

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The 9/4 secondary structure of eukaryotic selenocysteine tRNA: More pieces of evidence

Hubert

Sturchler

Westhof

et al. 1998

RNA

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“…Phylogenetic distribution of the ATP-grasp enzymes suggests some interesting functional clues. Methanococcus jannaschii encodes two paralogous proteins that are both orthologous to RimK, yet there is no gene for Fraser et al (1995), Synechocystis sp.-from Kaneko et al (1996), M. jannaschii-from Bult et al (1996) A substantial number of enzymes that are similar in function to ATP-dependent carboxylate-amine ligases do not show any detectable sequence similarity to the ATP-grasp superfamily. These include such peptide synthetases as y-glutamyl-cysteine synthetase, eukaryotic GSHase, and bacterial peptidoglycan biosynthesis proteins Mu<, MurD, and MurE.…”

Section: R-co-0-rh-r-co-op03'-/'v R-co-s-coamentioning

confidence: 99%

A diverse superfamily of enzymes with ATP‐dependent carboxylate—amine/thiol ligase activity

1997

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Abstract:The recently developed PSI-BLAST method for sequence database search and methods for motif analysis were used to define and expand a superfamily of enzymes with an unusual nucleotide-binding fold, referred to as palmate, or ATP-grasp fold. In addition to D-alanine-D-alanine ligase, glutathione synthetase, biotin carboxylase, and carbamoyl phosphate synthetase, enzymes with known three-dimensional structures, the ATP-grasp domain is predicted in the ribosomal protein S6 modification enzyme (RimK), urea amidolyase, tubulin-tyrosine ligase, and three enzymes of purine biosynthesis. All these enzymes possess ATP-dependent carboxylate-amine ligase activity, and their catalytic mechanisms are likely to include acylphosphate intermediates. The ATP-grasp superfamily also includes succinate-CoA ligase (both ADP-forming and GDP-forming variants), malate-CoA ligase, and ATP-citrate lyase, enzymes with a carboxylate-thiol ligase activity, and several uncharacterized proteins. These findings significantly extend the variety of the substrates of ATP-grasp enzymes and the range of biochemical pathways in which they are involved, and demonstrate the complementarity between structural comparison and powerful methods for sequence analysis.

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Complete Genome Sequence of the Methanogenic Archaeon, Methanococcus jannaschii

Cited by 2,273 publications

References 63 publications

Reverse gyrase from hyperthermophiles: probable transfer of a thermoadaptation trait from Archaea to Bacteria

Reverse gyrase from hyperthermophiles: probable transfer of a thermoadaptation trait from Archaea to Bacteria

The 9/4 secondary structure of eukaryotic selenocysteine tRNA: More pieces of evidence

A diverse superfamily of enzymes with ATP‐dependent carboxylate—amine/thiol ligase activity

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