Nicolas Glansdorff

About the last common ancestor, the universal life-tree and lateral gene transfer: a reappraisal.

An organismal tree rooted in the bacterial branch and derived from a hyperthermophilic last common ancestor (LCA) is still widely assumed to represent the path followed by evolution from the most primeval cells to the three domains recognized among contemporary organisms: Bacteria, Archaea and Eucarya. In the past few years, however, more and more discrepancies between this pattern and individual protein trees have been brought to light. There has been an overall tendency to attribute these incongruities to widespread lateral gene transfer. However, recent developments, a reappraisal of earlier evidence and considerations of our own lead us to a quite different view. It would appear (i) that the role of lateral gene transfer was overemphasized in recent discussions of molecular phylogenies; (ii) that the LCA was probably a non‐thermophilic protoeukaryote from which both Archaea and Bacteria emerged by reductive evolution but not as sister groups, in keeping with a current evolutionary scheme for the biosynthesis of membrane lipids; and (iii) that thermophilic Archaea may have been the first branch to diverge from the ancestral line.

Pathways of arginine biosynthesis in extreme thermophilic archaeo- and eubacteria

Summary: The pathway of arginine biosynthesis was investigated in two thermophilic eubacteria, Thermus aquaticus and Thermotoga maritima, and in two thermophilic archaeobacteria, Sulfolobus solfataricus and Pyrococcus furiosus. In the first three organisms, arginine biosynthesis proceeds via N-acetylated intermediates as in mesophilic microorganisms. Only the enzymes catalysing the three last steps of the pathway could be detected in P. furiosus. The two eubacterial strains possess an ornithine acetyltransferase and are thus able to recycle the acetyl group from acetylornithine to glutamate. The archaeobacterium, S. solfataricus, uses the linear pathway in which the formation of ornithine is mediated by the hydrolytic enzyme acetylornithinase. Repression of enzyme synthesis by arginine was observed for most of the enzymes tested in T. aquaticus and S. solfataricus. Feedback inhibition by arginine was shown only on the ornithine acetyltransferase from T. aquaticus. This inhibition pattern is of interest since it would be the first example of control of arginine biosynthesis at this particular step. Data concerning the thermal stability of the arginine biosynthetic enzymes are presented.

Purification and Characterization of Sa-Lrp, a DNA-Binding Protein from the Extreme Thermoacidophilic Archaeon Sulfolobus acidocaldarius Homologous to the Bacterial Global Transcriptional Regulator Lrp

Archaea, constituting the third primary domain of life, harbor a basal transcription apparatus of the eukaryotic type, whereas curiously, a large fraction of the potential transcription regulation factors appear to be of the bacterial type. To date, little information is available on these predicted regulators and on the intriguing interplay that necessarily has to occur with the transcription machinery. Here, we focus on Sa-lrp of the extremely thermoacidophilic crenarchaeote Sulfolobus acidocaldarius, encoding an archaeal homologue of the Escherichia coli leucine-responsive regulatory protein Lrp, a global transcriptional regulator and genome organizer. Sa-lrp was shown to produce a monocistronic mRNA that was more abundant in the stationary-growth phase and produced in smaller amounts in complex medium, this down regulation being leucine independent. We report on Sa-Lrp protein purification from S. acidocaldarius and from recombinant E. coli, both identified by N-terminal amino acid sequence determination. Recombinant Sa-Lrp was shown to be homotetrameric and to bind to its own control region; this binding proved to be leucine independent and was stimulated at high temperatures. Interference binding experiments suggested an important role for minor groove recognition in the Sa-Lrp-DNA complex formation, and mutant analysis indicated the importance for DNA binding of the potential helix-turn-helix motif present at the N terminus of Sa-Lrp. The DNA-binding capacity of purified Sa-Lrp was found to be more resistant to irreversible heat inactivation in the presence of L-leucine, suggesting a potential physiological role of the amino acid as a cofactor.

Retrieving sequences of enzymes experimentally characterized but erroneously annotated : the case of the putrescine carbamoyltransferase.

BackgroundAnnotating genomes remains an hazardous task. Mistakes or gaps in such a complex process may occur when relevant knowledge is ignored, whether lost, forgotten or overlooked. This paper exemplifies an approach which could help to ressucitate such meaningful data.ResultsWe show that a set of closely related sequences which have been annotated as ornithine carbamoyltransferases are actually putrescine carbamoyltransferases. This demonstration is based on the following points : (i) use of enzymatic data which had been overlooked, (ii) rediscovery of a short NH2-terminal sequence allowing to reannotate a wrongly annotated ornithine carbamoyltransferase as a putrescine carbamoyltransferase, (iii) identification of conserved motifs allowing to distinguish unambiguously between the two kinds of carbamoyltransferases, and (iv) comparative study of the gene context of these different sequences.ConclusionsWe explain why this specific case of misannotation had not yet been described and draw attention to the fact that analogous instances must be rather frequent. We urge to be especially cautious when high sequence similarity is coupled with an apparent lack of biochemical information. Moreover, from the point of view of genome annotation, proteins which have been studied experimentally but are not correlated with sequence data in current databases qualify as orphans, just as unassigned genomic open reading frames do. The strategy we used in this paper to bridge such gaps in knowledge could work whenever it is possible to collect a body of facts about experimental data, homology, unnoticed sequence data, and accurate informations about gene context.

Metabolic Enzymes from Psychrophilic Bacteria: Challenge of Adaptation to Low Temperatures in Ornithine Carbamoyltransferase from Moritella abyssi

The enzyme ornithine carbamoyltransferase (OTCase) of Moritella abyssi (OTCase(Mab)), a new, strictly psychrophilic and piezophilic bacterial species, was purified. OTCase(Mab) displays maximal activity at rather low temperatures (23 to 25 degrees C) compared to other cold-active enzymes and is much less thermoresistant than its homologues from Escherichia coli or thermophilic procaryotes. In vitro the enzyme is in equilibrium between a trimeric state and a dodecameric, more stable state. The melting point and denaturation enthalpy changes for the two forms are considerably lower than the corresponding values for the dodecameric Pyrococcus furiosus OTCase and for a thermolabile trimeric mutant thereof. OTCase(Mab) displays higher K(m) values for ornithine and carbamoyl phosphate than mesophilic and thermophilic OTCases and is only weakly inhibited by the bisubstrate analogue delta-N-phosphonoacetyl-L-ornithine (PALO). OTCase(Mab) differs from other, nonpsychrophilic OTCases by substitutions in the most conserved motifs, which probably contribute to the comparatively high K(m) values and the lower sensitivity to PALO. The K(m) for ornithine, however, is substantially lower at low temperatures. A survey of the catalytic efficiencies (k(cat)/K(m)) of OTCases adapted to different temperatures showed that OTCase(Mab) activity remains suboptimal at low temperature despite the 4.5-fold decrease in the K(m) value for ornithine observed when the temperature is brought from 20 to 5 degrees C. OTCase(Mab) adaptation to cold indicates a trade-off between affinity and catalytic velocity, suggesting that optimization of key metabolic enzymes at low temperatures may be constrained by natural limits.

The highly thermostable arginine repressor of Bacillus stearothermophilus: gene cloning and repressor–operator interactions

We report here the cloning of the arginine repressor gene argR of Bacillus stearothermophilus and the characterization and purification to homogeneity of its product. The deduced amino acid sequence of the 16.8‐kDa ArgR subunit shares 72% identity with its mesophilic homologue AhrC of Bacilus subtilis. Sequence analysis of B. stearothermophilus ArgR and comparisons with mesophilic arginine repressors suggest that the thermostable repressor comprises an N‐terminal DNA‐binding and a C‐terminal oligomerization and arginine‐binding region. B. stearothermophilus ArgR has been overexpressed in E. coli and purified as a 48.0‐kDa trimeric protein. The repressor inhibits the expression of a B. stearothermophilus argC–lacZ fusion in E. coli cells. In the presence of arginine, the purified protein binds tightly and specifically to the argC operator, which largely overlaps the argC promoter. The purified B. stearothermophilus repressor proved to be very thermostable with a half‐life of approximatelyu200330u2003min at 90°C, whereas B. subtilis AhrC was largely inactivated at 65°C. Moreover, ArgR operator complexes were found to be remarkably thermostable and could be formed efficiently at up to 85°C, well above the optimal growth temperature of the moderate thermophile B. stearothermophilus. This pronounced resistance of the repressor–operator complexes to heat treatment suggests that the same type of regulatory mechanism could operate in extreme thermophiles.

Moritella Cold-Active Dihydrofolate Reductase: Are There Natural Limits to Optimization of Catalytic Efficiency at Low Temperature?

Adapting metabolic enzymes of microorganisms to low temperature environments may require a difficult compromise between velocity and affinity. We have investigated catalytic efficiency in a key metabolic enzyme (dihydrofolate reductase) of Moritella profunda sp. nov., a strictly psychrophilic bacterium with a maximal growth rate at 2 degrees C or less. The enzyme is monomeric (Mr=18,291), 55% identical to its Escherichia coli counterpart, and displays Tm and denaturation enthalpy changes much lower than E. coli and Thermotoga maritima homologues. Its stability curve indicates a maximum stability above the temperature range of the organism, and predicts cold denaturation below 0 degrees C. At mesophilic temperatures the apparent Km value for dihydrofolate is 50- to 80-fold higher than for E. coli, Lactobacillus casei, and T. maritima dihydrofolate reductases, whereas the apparent Km value for NADPH, though higher, remains in the same order of magnitude. At 5 degrees C these values are not significantly modified. The enzyme is also much less sensitive than its E. coli counterpart to the inhibitors methotrexate and trimethoprim. The catalytic efficiency (kcat/Km) with respect to dihydrofolate is thus much lower than in the other three bacteria. The higher affinity for NADPH could have been maintained by selection since NADPH assists the release of the product tetrahydrofolate. Dihydrofolate reductase adaptation to low temperature thus appears to have entailed a pronounced trade-off between affinity and catalytic velocity. The kinetic features of this psychrophilic protein suggest that enzyme adaptation to low temperature may be constrained by natural limits to optimization of catalytic efficiency.

High resolution contact probing of the Lrp-like DNA-binding protein Ss-Lrp from the hyperthermoacidophilic crenarchaeote Sulfolobus solfataricus P2.

Ss‐Lrp, from Sulfolobus solfataricus, is an archaeal homologue of the global bacterial regulator Lrp (Leucine‐responsive regulatory protein), which out of all genome‐encoded proteins is most similar to Escherichia coli Lrp (E‐value of 5.6 e−14). The recombinant protein has been purified as a 68u2003kDa homotetramer. The specific binding of Ss‐Lrp to its own control region is suggestive of negative autoregulation. A high resolution contact map of Ss‐Lrp binding was established by DNase I and hydroxyl radical footprinting, small non‐intercalating groove‐specific ligand‐binding interference, and various base‐specific premodification and base removal binding interference techniques. We show that Ss‐Lrp binds one face of the DNA helix and establishes the most salient contacts with two major groove segments and the intervening minor groove, in a region that overlaps the TATA‐box and BRE promoter elements. Therefore, Ss‐Lrp most likely exerts autoregulation by preventing promoter recognition by TBP and TFB. Moreover, the results demonstrate profound Ss‐Lrp induced structural alterations of sequence stretches flanking the core contact site, and reveal that the deformability of these regions significantly contributes to binding selectivity.

Experimental Evolution of Enzyme Temperature Activity Profile: Selection In Vivo and Characterization of Low-Temperature-Adapted Mutants of Pyrococcus furiosus Ornithine Carbamoyltransferase

We have obtained mutants of Pyrococcus furiosus ornithine carbamoyltransferase active at low temperatures by selecting for complementation of an appropriate yeast mutant after in vivo mutagenesis. The mutants were double ones, still complementing at 15 degrees C, a temperature already in the psychrophilic range. Their kinetic analysis is reported.

Was our ancestor a hyperthermophilic procaryote

In this paper we critically review the classical model for the emergence of the three domains (Archaea, Bacteria, Eucarya), which presents hyperthermophilic procaryotes as the ancestors of all life on this planet. We come to the conclusion that our last common ancestor is likely to have been rather a non-hyperthermophilic protoeucaryote endowed with sn-1,2 glycerol ester lipids (as in modern Bacteria and Eucarya), from which Archaea emerged by streamlining under pressure for adapting to heat, a process which involved an important molecular innovation: the advent of sn-2,3 glycerol ether lipids. The nature of the primeval bacterial lines of descent is less clear; it would appear, nevertheless, that the first extreme- and hyperthermophilic Bacteria emerged by converging mechanisms; lateral gene transfer from Archaea may have played a role in this adaptation.