Citrate synthase from the thermophilic archaebacterium Thermoplasma acidophilium. Cloning and sequencing of the gene

Heteroexpression and biochemical characterization of thermostable citrate synthase from the cyanobacteria Anabaena sp. PCC7120

The present study recombinantly expressed a citrate synthase from cyanobacteria Anabaena sp. PCC7120 (AnCS) in Escherichia coli and characterized its enzymatic activity. The molecular mass of native AnCS was 88,533.1 Da containing two 44,162.7 Da subunits. Recombinant AnCS revealed the highest activity at pH 9.0 and 25 °C. AnCS displayed high thermal stability with a half-life time (t_1/2) of approximately 6.5 h at 60 °C, which was more thermostable than most CS from general organisms, but less than those from hyperthermophilic bacteria. The K_m values of oxaloacetate and acetyl-CoA were 138.50 and 18.15 μM respectively, suggesting a higher affinity to acetyl-CoA than oxaloacetate. Our inhibition assays showed that AnCS activity was not severely affected by most metal ions, but was strongly inhibited by Cu²⁺ and Zn²⁺. Treatments with ATP, ADP, AMP, NADH, and DTT depressed the AnCS activity. Overall, our results provide information on the enzymatic properties of AnCS, which contributes to the basic knowledge on CS selection for industrial utilizations.

The mechanism of citryl-coenzyme A formation catalyzed by citrate synthase

The enzyme citrate synthase is used by all living cells to catalyze the first step of the citric acid cycle. In this work, we have investigated the enolization and condensation steps catalyzed by citrate synthase, using ab initio (B3LYP/def2-TZVP and MP2/aug-cc-pVDZ) quantum chemical/molecular mechanical hybrid potentials in conjunction with reaction-path-location algorithms and molecular dynamics free energy simulations. The results of the latter indicate that the catalytic His238 residue is in its neutral form, and also argue strongly for the presence of a water molecule in the enzyme's catalytic center. Such a water is observed in some, but not all, of the experimentally resolved structures of the protein. The mechanism itself starts with an enolization that proceeds via an enolate intermediate rather than the enol form, which is much more unstable. This is in agreement with the results of other workers. For the condensation step, we investigated two mechanisms in which there is a direct nucleophilic attack of the enolate intermediate on the oxaloacetate carbonyl carbon, and found the one in which there is no proton transfer from the neighboring arginine to be preferred. Although this residue, Arg329, is not implicated directly in the reaction, it helps to stabilize the negative citryl-CoA formed during the condensation step.

Ab initio QM/MM modelling of acetyl-CoA deprotonation in the enzyme citrate synthase

The first step of the reaction catalysed by the enzyme citrate synthase is studied here with high level combined quantum mechanical/molecular mechanical (QM/MM) methods (up to the MP2/6-31+G(d)//6-31G(d)/CHARMM level). In the first step of the reaction, acetyl-CoA is deprotonated by Asp375, producing an intermediate, which is the nucleophile for attack on the second substrate, oxaloacetate, prior to hydrolysis of the thioester bond of acetyl-CoA and release of the products. A central question has been whether the nucleophilic intermediate is the enolate of acetyl-CoA, the enol, or an 'enolic' intermediate stabilized by a 'low-barrier' hydrogen bond with His274 at the active site. The imidazole sidechain of His274 is neutral, and donates a hydrogen bond to the carbonyl oxygen of acetyl-CoA in substrate complexes. We have investigated the identity of the nucleophilic intermediate by QM/MM calculations on the substrate (keto), enolate, enol and enolic forms of acetyl-CoA at the active site of citrate synthase. The transition states for proton abstraction from acetyl-CoA by Asp375, and for transfer of the hydrogen bonded proton between His274 and acetyl-CoA have been modelled approximately. The effects of electron correlation are included by MP2/6-31G(d) and MP2/6-31+G(d) calculations on active site geometries produced by QM/MM energy minimization. The results do not support the hypothesis that a low-barrier hydrogen bond is involved in catalysis in citrate synthase, in agreement with earlier calculations. The acetyl-CoA enolate is identified as the only intermediate consistent with the experimental barrier for condensation, stabilized by conventional hydrogen bonds from His274 and a water molecule.

The enzymes from extreme thermophiles: bacterial sources, thermostabilities and industrial relevance

This review on enzymes from extreme thermophiles (optimum growth temperature greater than 65 degrees C) concentrates on their characteristics, especially thermostabilities, and their commercial applicability. The enzymes are considered in general terms first, with comments on denaturation, stabilization and industrial processes. Discussion of the enzymes subsequently proceeds in order of their E.C. classification: oxidoreductases, transferases, hydrolases, lyases, isomerases and ligases. The ramifications of cloned enzymes from extreme thermophiles are also discussed.

Photophysics of tryptophan fluorescence: link with the catalytic strategy of the citrate synthase from Thermoplasma acidophilum

The formation of all major intermediates in the reaction catalyzed by the citrate synthase from Thermoplasma acidophilum is accompanied by changes in tryptophan fluorescence. The largest change is the strong quenching observed on formation of the binary complex with substrate, oxaloacetate (OAA). The four tryptophan residues present in the enzyme have been changed to nonfluorescent ones in various combinations without major perturbations in protein stability, enzyme mechanism, or other physical properties. W348, residing in the hydrophobic core of the protein behind the active site wall ca. 9 A from OAA, is responsible for the majority of the protein's intrinsic fluorescence and all of the quenching that accompanies OAA binding. Lifetime studies show that all of the quenching results from excited-state processes. The lack of solvent isotope effects on the quantum yields excludes a quenching mechanism involving proton transfer to an acceptor. There are no significant changes in fluorescence properties in single site mutants of residues near W348 that change conformation and/or interactions when OAA binds. This result excludes these changes from a direct role. Electron transfer from the indole excited state to some acceptor is the major quenching mechanism; the reduced quenching observed in the 5F-W-substituted protein strengthens this conclusion. Using the X-ray structures of the unliganded enzyme and its OAA binary complex, hybrid quantum mechanics-molecular dynamics (QM-MM) calculations show that OAA itself is the most likely quencher with the OAA carbonyl as the electron acceptor. This conclusion is strengthened by the ability of an alpha-keto acid model compound, trimethylpyruvate, to act as a diffusional quencher of indole fluorescence in solution. The theoretical calculations further indicate that the positive electrostatic potential surrounding the OAA carbonyl within the enzymes' active site is essential to its ability to accept an electron from the excited state of W348. These same environmental factors play a major role in activating OAA to react with the carbanion of acetyl-CoA. Since carbonyl polarization plays a role in the catalytic strategies of numerous enzymes whose reactions involve this functional group, tryptophan fluorescence changes might be useful as a mechanistic probe for other systems.

Thermostability and thermoactivity of citrate synthases from the thermophilic and hyperthermophilic archaea, Thermoplasma acidophilum and Pyrococcus furiosus

Citrate synthases from Thermoplasma acidophilum (optimal growth at 55 degrees C) and Pyrococcus furiosus (100 degrees C) are homo-dimeric enzymes that show a high degree of structural homology with each other, and thermostabilities commensurate with the environmental temperatures in which their host cells are found. A comparison of their atomic structures with citrate synthases from mesophilic and psychrophilic organisms has indicated the potential importance of inter-subunit contacts for thermostability, and here we report the construction and analysis of site-directed mutants of the two citrate synthases to investigate the contribution of these interactions. Three sets of mutants were made: (a) chimeric mutants where the large (inter-subunit contact) and small (catalytic) domains of the T. acidophilum and P. furiosus enzymes were swapped; (b) mutants of the P. furiosus citrate synthase where the inter-subunit ionic network is disrupted; and (c) P. furiosus citrate synthase mutants in which the C-terminal arms that wrap around their partner subunits have been deleted. All three sets of mutant enzymes were expressed as recombinant proteins in Escherichia coli and were found to be catalytically active. Kinetic parameters and the dependence of catalytic activity on temperature were determined, and the stability of each enzyme was analysed by irreversible thermal inactivation experiments. The chimeric mutants indicate that the thermostability of the whole enzyme is largely determined by the origin of the large, inter-subunit domain, whereas the dependence of catalytic activity on temperature is a function of the small domain. Disruption of the inter-subunit ionic network and prevention of the C-terminal interactions both generated enzymes that were substantially less thermostable. Taken together, these data demonstrate the crucial importance of the subunit contacts to the stability of these oligomeric enzymes. Additionally, they also provide a clear distinction between thermostability and thermoactivity, showing that stability is necessary for, but does not guarantee, catalytic activity at elevated temperatures.

Microbial genescapes: phyletic and functional patterns of ORF distribution among prokaryotes

We have implemented a statistically based approach to comparative genomics that allows us to define and characterize distributional patterns of conceptually translated open reading frames (ORFs) at different confidence levels based on pairwise FASTA matches. In this report, we apply this methodology to nine microbial genomes, focusing particularly on phyletic and functional patterns of ORF distribution within and between the two prokaryotic domains of life, Bacteria and Archaea. We examine patterns of presence and absence of matches, determine the universal ORF set, analyze features of genome specialization between closely related organisms, and present genomic evidence for the monophyly of Archaea. These analyses illustrate how a quantitative approach to comparative genomics can illuminate questions of fundamental biological significance.

Amino acid substitutions in the subunit interface enhancing thermostability of Thermoplasma acidophilum citrate synthase

We have used citrate synthase from Thermoplasma (Tp.) acidophilum as a thermostable model system to investigate the role of hydrophobic interactions in dimer interface for maintaining high temperature stability. Three mutant enzymes were constructed by single amino acid substitutions in the interface helices: Ala97-->Ser, Ala104-->Thr, and Gly209-->Ala. All of the mutations enhanced the thermostability of Tp. citrate synthase, while improving its catalytic properties (Km, Vmax, and specific activity). The highest thermostability was achieved by the Gly209-->Ala substitution. The half-life of irreversible inactivation of the G209A mutant enzyme at 85 degreesC was about 57 min, and the midpoint of guanidinium chloride (GdmCl) induced irreversible denaturation was at 2.0 M GdmCl. Our results showed that amino acid substitutions increasing or decreasing interface hydrophobicity could further increase the thermostability of the Tp. citrate synthase. Thus, interface substitutions affecting the entropy of the unfolded state did not prove to be so critical in protein thermostabilization at higher temperatures.

Proteins from hyperthermophiles: stability and enzymatic catalysis close to the boiling point of water

It has become clear since about a decade ago, that the biosphere contains a variety of microorganisms that can live and grow in extreme environments. Hyperthermophilic microorganisms, present among Archaea and Bacteria, proliferate at temperatures of around 80-100 degrees C. The majority of the genera known to date are of marine origin, however, some of them have been found in continental hot springs and solfataric fields. Metabolic processes and specific biological functions of these organisms are mediated by enzymes and proteins that function optimally under these extreme conditions. We are now only starting to understand the structural, thermodynamic and kinetic basis for function and stability under conditions of high temperature, salt and extremes of pH. Insights gained from the study of such macromolecules help to extend our understanding of protein biochemistry and -biophysics and are becoming increasingly important for the investigation of fundamental problems in structure biology such as protein stability and protein folding. Extreme conditions in the biosphere require either the adaptation of the amino acid sequence of a protein by mutations, the optimization of weak interactions within the protein and at the protein-solvent boundary, the influence of extrinsic factors such as metabolites, cofactors, compatible solutes. Furthermore folding catalysts, known as chaperones, that assist the folding of proteins may be involved or increased protein protein synthesis in order to compensate for destruction by extreme conditions. The comparison of structure and stability of homologous proteins from mesophiles and hyperthermophiles has revealed important determinants of thermal stability of proteins. Rather than being the consequence of one dominant type of interactions or of a general stabilization strategy, it appears that the adaptation to high temperatures reflects a number of subtle interactions, often characteristic for each protein species, that minimize the surface energy and the hydration of apolar surface groups while burying hydrophobic residues and maximizing packing of the core as well as the energy due to charge-charge interactions and hydrogen bonds. In this article, mechanisms of intrinsic stabilization of proteins are reviewed. These mechanisms are found on different levels of structural organization. Among the extrinsic stabilization factors, emphasis is put on archaea chaperonins and their still strongly debated function. It will be shown, that optimization of weak protein-protein and protein-solvent interactions plays a key role in gaining thermostability. The difficulties in correlating suitable optimization criteria with real thermodynamic stability measures are due to experimental difficulties in measuring stabilization energies in large proteins or protein oligomers and will be discussed. Thus small single domain proteins or isolated domains of larger proteins may serve as model systems for large or multidomain proteins which due to the complexity of their thermal unfolding transitions cannot be analyzed by equilibrium thermodynamics. The analysis of the energetics of the thermal unfolding of a small, hyperthermostable DNA binding protein from Sulfolobus has revealed that a high melting temperature is not synonymous with a larger maximum thermodynamic stability. Finally, it is now well documented, that many thermophilic and hyperthermophilic proteins show a statistically increased number of salt bridges and salt bridge networks. However their contribution to thermodynamic and functional stability is still obscure.

Alpha-keto acid chain elongation reactions involved in the biosynthesis of coenzyme B (7-mercaptoheptanoyl threonine phosphate) in methanogenic Archaea

The biochemistry of the 13 steps involved in the conversion of alpha-ketoglutarate and acetylCoA to alpha-ketosuberate, a precursor to the coenzymes coenzyme B (7-mercapto heptanoylthreonine phosphate) and biotin, has been established in Methanosarcina thermophila. These series of reactions begin with the condensation of alpha-ketoglutarate and acetylCoA to form trans-homoaconitate. The trans-homoaconitate is then hydrated and dehydrated to cis-homoaconitate with (S)-homocitrate serving as an intermediate. Rehydration of the cis-homoaconitate produces (-)-threo-isohomocitrate [(2R,3S)-1-hydroxy-1,2, 4-butanetricarboxylic acid], which undergoes a NADP+-dependent oxidative decarboxylation to produce alpha-ketoadipate. The resulting alpha-ketoadipate then undergoes two consecutive sets of alpha-ketoacid chain elongation reactions to produce alpha-ketosuberate. In each of these sets of reactions, it has been shown that the homologues of cis-homoaconitate, homocitrate, and (-)-threo-isohomocitrate serve as intermediates. The protein product of the Methanococcus jannaschii MJ0503 gene aksA (AksA) was found to catalyze the condensation of alpha-ketoglutarate and acetylCoA to form trans-homoaconitate. This gene product also catalyzed the condensation of alpha-ketoadipate or alpha-ketopimelate with acetylCoA to form, respectively, the (R)-homocitrate homologues of (R)-2-hydroxy-1,2,5-pentanetricarboxylic acid and (R)-2-hydroxy-1,2, 6-hexanetricarboxylic acid. The alpha-ketosuberate resulting from this series of reactions then undergoes a nonoxidative decarboxylation to form 7-oxoheptanoic acid, a precursor to coenzyme B, and an oxidative decarboxylation to form pimelate, the precursor to biotin. Of the 13 intermediates in this pathway, eight have not previously been reported as occurring in biological systems.

Structural adaptations of the cold-active citrate synthase from an Antarctic bacterium

BACKGROUND

The structural basis of adaptation of enzymes to low temperature is poorly understood. Dimeric citrate synthase has been used as a model enzyme to study the structural basis of thermostability, the structure of the enzyme from organisms living in habitats at 55 degrees C and 100 degrees C having previously been determined. Here the study is extended to include a citrate synthase from an Antarctic bacterium, allowing us to explore the structural basis of cold activity and thermostability across the whole temperature range over which life is known to exit.

RESULTS

We report here the first crystal structure of a cold-active enzyme, citrate synthase, isolated from an Antarctic bacterium, at a resolution of 2.09 A. In comparison with the same enzyme from a hyperthermophilic host, the cold-active enzyme has a much more accessible active site, an unusual electrostatic potential distribution and an increased relative flexibility of the small domain compared to the large domain. Several other features of the cold-active enzyme were also identified: reduced subunit interface interactions with no intersubunit ion-pair networks; loops of increased length carrying more charge and fewer proline residues; an increase in solvent-exposed hydrophobic residues; and an increase in intramolecular ion pairs.

CONCLUSIONS

Enzymes from organisms living at the temperature extremes of life need to avoid hot or cold denaturation yet maintain sufficient structural integrity to allow catalytic efficiency. For hyperthermophiles, thermal denaturation of the citrate synthase dimer appears to be resisted by complex networks of ion pairs at the dimer interface, a feature common to other hyperthermophilic proteins. For the cold-active citrate synthase, cold denaturation appears to be resisted by an increase in intramolecular ion pairs compared to the hyperthermophilic enzyme. Catalytic efficiency of the cold-active enzyme appears to be achieved by a more accessible active site and by an increase in the relative flexibility of the small domain compared to the large domain.

Archaea and the prokaryote-to-eukaryote transition

Since the late 1970s, determining the phylogenetic relationships among the contemporary domains of life, the Archaea (archaebacteria), Bacteria (eubacteria), and Eucarya (eukaryotes), has been central to the study of early cellular evolution. The two salient issues surrounding the universal tree of life are whether all three domains are monophyletic (i.e., all equivalent in taxanomic rank) and where the root of the universal tree lies. Evaluation of the status of the Archaea has become key to answering these questions. This review considers our cumulative knowledge about the Archaea in relationship to the Bacteria and Eucarya. Particular attention is paid to the recent use of molecular phylogenetic approaches to reconstructing the tree of life. In this regard, the phylogenetic analyses of more than 60 proteins are reviewed and presented in the context of their participation in major biochemical pathways. Although many gene trees are incongruent, the majority do suggest a sisterhood between Archaea and Eucarya. Altering this general pattern of gene evolution are two kinds of potential interdomain gene transferrals. One horizontal gene exchange might have involved the gram-positive Bacteria and the Archaea, while the other might have occurred between proteobacteria and eukaryotes and might have been mediated by endosymbiosis.

Sequencing and expression of the gene encoding a cold-active citrate synthase from an Antarctic bacterium, strain DS2-3R

The gene encoding citrate synthase from a novel bacterial isolate (DS2-3R) from Antarctica has been cloned, sequenced and over expressed in Escherichia coli. Both the recombinant enzyme and the native enzyme, purified from DS2-3R, are cold-active, with a temperature optimum of 31 degrees C. In addition the enzymes are rapidly inactivated at 45 degrees C, and show significant activity at 10 degrees C and below. Comparison of amino acid sequences indicates that DS2-3R citrate synthase is most closely related to the enzyme from gram-positive bacteria. The amino acid sequence of the DS2-3R enzyme shows several features previously recognised in other cold-active enzymes, including an extended surface loop, an increase in the occurrence of charged residues and a decrease in the number of proline residues in loops. Other changes observed in some psychrophilic enzymes, such as a decrease in isoleucine content and in arginine/(arginine+lysine) content, were not seen in this case.

The B12-dependent ribonucleotide reductase from the archaebacterium Thermoplasma acidophila: an evolutionary solution to the ribonucleotide reductase conundrum

A coenzyme B12-dependent ribonucleotide reductase was purified from the archaebacterium Thermoplasma acidophila and partially sequenced. Using probes derived from the sequence, the corresponding gene was cloned, completely sequenced, and expressed in Escherichia coli. The deduced amino acid sequence shows that the catalytic domain of the B12-dependent enzyme from T. acidophila, some 400 amino acids, is related by common ancestry to the diferric tyrosine radical iron(III)-dependent ribonucleotide reductase from E. coli, yeast, mammalian viruses, and man. The critical cysteine residues in the catalytic domain that participate in the thiyl radical-dependent reaction have been conserved even though the cofactor that generates the radical is not. Evolutionary bridges created by the T. acidophila sequence and that of a B12-dependent reductase from Mycobacterium tuberculosis establish homology between the Fe-dependent enzymes and the catalytic domain of the Lactobacillus leichmannii B12-dependent enzyme as well. These bridges are confirmed by a predicted secondary structure for the Lactobacillus enzyme. Sequence similarities show that the N-terminal domain of the T. acidophila ribonucleotide reductase is also homologous to the anaerobic ribonucleotide reductase from E. coli, which uses neither B12 nor Fe cofactors. A predicted secondary structure of the N-terminal domain suggests that it is predominantly helical, as is the domain in the aerobic E. coli enzyme depending on Fe, extending the homologous family of proteins to include anaerobic ribonucleotide reductases, B12 ribonucleotide reductases, and Fe-dependent aerobic ribonucleotide reductases. A model for the evolution of the ribonucleotide reductase family is presented; in this model, the thiyl radical-based reaction mechanism is conserved, but the cofactor is chosen to best adapt the host organism to its environment. This analysis illustrates how secondary structure predictions can assist evolutionary analyses, each important in "post-genomic" biochemistry.

MICROBIAL DIVERSITY: Domains and Kingdoms

▪ Abstract  With the discovery of the eukaryote nucleus, all living organisms were neatly divided into prokaryotes, which lacked a nucleus, and eukaryotes, which possessed it. As data derived directly from the genome became available, it was clear that prokaryotes were comprised of two groups, Eubacteria and Archaebacteria. These were subsequently renamed at the new taxonomic level of Domain as Bacteria and Archaea, with the eukaryotes named as the Eucarya Domain. The interrelationships of the three Domains are still subject to discussion and evaluation, as is their monophyly. Further data, drawn from various protein sequences, suggest conflicting schemes, and resolution may not be straightforward. Additionally, Bacteria and Archaea as well as Eucarya are largely based on organisms already in culture. Investigation of the potentially enormous quantity of uncultured organisms in nature is likely to have as broad-ranging implications as the exploration of new protein sequences.

Purification and characterization of citrate synthase isoenzymes from Pseudomonas aeruginosa

Two types of citrate synthase (CS) have been purified from Pseudomonas aeruginosa, a 'large' form (CSI) and a 'small' form (CSII). The M(r)s of the CSI and CSII isoenzymes were determined to be 240,000 +/- 16,000 (mean +/- S.E.M.) and 80,300 +/- 3800 respectively. Chemical cross-linking of the native enzymes with either dimethyl suberimidate or glutaraldehyde followed by electrophoretic analysis by SDS/PAGE showed that CSI is a hexamer and CSII is a dimer. SDS/PAGE showed that CSI and CSII each consist of a single subunit type, of M(r) 42,000 +/- 2000 and M(r) 36,500 +/- 2000 respectively. CSI and CSII were also shown to be distinct kinetically, immunologically and in terms of their regulatory properties. It is suggested that the CS isoenzymes are products of different structural genes.

Molecular classification of living organisms

Recent studies in molecular evolution have generated strong conflicts in opinion as to how world living organisms should be classified. The traditional classification of life into five kingdom has been challenged by the molecular analysis carried out mostly on rRNA sequences, which supported the division of the extant living organisms into three major groups: Archaebacteria, Eubacteria, and Eukaryota. As to the problem of placing the root of the tree of life, the analysis carried out on a few genes has provided discrepant results. In order to measure the genetic distances between species, we have carried out an evolutionary analysis of the glutamine synthetase genes, which previously have been revealed to be good molecular clocks, and of the small and large rRNA genes. All data demonstrate that archaebacteria are more closely related to eubacteria than to eukaryota, thus supporting the classical division of living organisms into two main superkingdoms, Prokaryota and Eukaryota.

Molecular characterization of a glyoxysomal citrate synthase that is synthesized as a precursor of higher molecular mass in pumpkin

A cDNA clone for glyoxysomal citrate synthase (gCS) was isolated from a lambda gt11 cDNA library prepared from etiolated pumpkin cotyledons. The cDNA of 1989 bp consisted of a 1548 bp open reading frame that encoded 516 amino acid residues. The deduced amino acid sequence of gCS did not have a typical peroxisomal targeting signal at its carboxyl terminal. A study of expression in vitro of the cDNA and an analysis of the amino-terminal sequence of the citrate synthase indicated that gCS is synthesized as a larger precursor that has a cleavable amino-terminal presequence of 43 amino acids. The predicted amino-terminal sequence of pumpkin gCS was highly homologous to those of other microbody enzymes, such as 3-ketoacyl-CoA thiolase of rat and malate dehydrogenase of watermelon that are also synthesized as precursors of higher molecular mass. Immunoblot analysis showed that the level of gCS protein increased markedly during germination and decreased rapidly during the light-induced transition of microbodies from glyoxysomes to leaf peroxisomes. By contrast, the level of mRNA for gCS reached a maximum earlier than that of the protein and declined even in darkness. The level of the mRNA was low during the microbody transition. These results indicate that the accumulation of the gCS protein does not correspond to that of the mRNA and that degradation of gCS is induced during the microbody transition, suggesting that post-transcriptional regulation plays an important role in the microbody transition.

The crystal structure of citrate synthase from the thermophilic archaeon, Thermoplasma acidophilum

BACKGROUND

The Archaea constitute a phylogenetically distinct, evolutionary domain and comprise organisms that live under environmental extremes of temperature, salinity and/or anaerobicity. Different members of the thermophilic Archaea tolerate temperatures in the range 55-110 degrees C, and the comparison of the structures of their enzymes with the structurally homogolous enzymes of mesophilic organisms (optimum growth temperature range 15-45 degrees C) may provide important information on the structural basis of protein thermostability. We have chosen citrate synthase, the first enzyme of the citric acid cycle, as a model enzyme for such studies.

RESULTS

We have determined the crystal structure of Thermoplasma acidophilum citrate synthase to 2.5 A and have compared it with the citrate synthase from pig heart, with which it shares a high degree of structural homology, but little sequence identity (20%).

CONCLUSIONS

The three-dimensional structural comparison of thermophilic and mesophilic citrate synthases has permitted catalytic and substrate-binding residues to be tentatively assigned in the archaeal, thermophilic enzyme, and has identified structural features that may be responsible for its thermostability.

Nucleotide sequence of a putative succinate dehydrogenase operon in Thermoplasma acidophilum

28 amino acids from the N-terminal region of a putative terminal oxidase from the archaebacterium Thermoplasma acidophilum were determined by Edman degradation. On basis of this amino acid sequence a degenerated oligonucleotide was synthesized and used as a radioactive probe for Southern blot analysis of EcoRI digested genomic DNA. A 2.3 kb EcoRI fragment strongly hybridized to the probe and size selected genomic library from genomic DNA was constructed. Several clones scored positive by screening the library with the degenerated oligonucleotide, from which only one clone contained a EcoRI DNA fragment encoding the 28 amino acid sequence determined by protein sequencing. Sequence analysis revealed the presence of three genes in the typical arrangement of an operon. The first gene codes for a protein containing 11 cystein residues in an arrangement typical for Fe/S proteins. Protein sequence comparison revealed significant homologies to the fumarate reductase and succinate dehydrogenase of other bacteria. The two other genes encode small hydrophobic proteins probably serving as membrane anchor for the Thermoplasma acidophilum succinate dehydrogenase.

Does Escherichia coli possess a second citrate synthase gene?

Escherichia coli possesses a hexameric citrate synthase that exhibits allosteric kinetics and regulatory sensitivity, and for which the gene (gltA) has previously been cloned and sequenced. A citrate-synthase-deficient strain of E. coli (K114) has been mutated to generate a revertant (K114r4) that produces a dimeric citrate synthase with altered kinetic and regulatory properties. On cloning and sequencing the gltA gene from both K114 and K114r4, a single mutation was found that caused the replacement of Asp362 with Asn. Asp362 has been previously shown to be a catalytically essential residue in E. coli citrate synthase, and we demonstrate that the hexameric enzyme produced on expression of the gltA gene from K114 and K114r4 is inactive. The dimeric citrate synthase from K114r4 has been purified and shown to be immunologically distinct from the wild-type hexameric enzyme. Determination of its N-terminal amino acid sequence demonstrates that the mutant citrate synthase is encoded by a gene distinct from the E. coli gltA gene. The N-terminal sequence is compared with those of other eukaryotic, eubacterial and archaebacterial citrate synthases.

Cloning, sequencing and expression of the gene encoding glucose dehydrogenase from the thermophilic archaeon Thermoplasma acidophilum

The gene encoding glucose dehydrogenase has been identified by Southern analysis of doubly restricted genomic Thermoplasma acidophilum DNA, using two redundant 17-residue oligonucleotide probes reverse translated from protein N-terminal sequence data. A 1670-bp BamH1-EcoR1 restriction fragment was ligated into pUC19 and pUC18 (constructs pTaGDH1 and pTaGDH2, respectively) and cloned in Escherichia coli. The sequence of the whole fragment was determined, and a 1059-bp open reading frame identified as the gene encoding glucose dehydrogenase. Cell-free extracts from E. coli carrying construct pTaGDH1 displayed glucose dehydrogenase activity indistinguishable from controls, but extracts from cells carrying pTaGDH2 displayed a 600-fold increase in glucose dehydrogenase activity. For high-level expression and purification of native protein, the glucose dehydrogenase coding sequence was subcloned into pMEX8. Glucose dehydrogenase purified from E. coli expressing the pMEX8 construct was indistinguishable by SDS/PAGE, N-terminal amino-acid sequence and kinetic analysis from the native enzyme purified from Tp. acidophilum. The derived 352-amino-acid sequence shows less than 20% identity with the glucose dehydrogenases of Bacillus subtilis and Bacillus megaterium but, by comparison with other eubacterial and eukaryotic dehydrogenase sequences, a portion of its sequence has been tentatively identified as a cofactor-binding region.

Expression of functional Thermoplasma acidophilum proteasomes in Escherichia coli

The two genes encoding the constituent subunits of the Thermoplasma acidophilum proteasome were expressed in Escherichia coli yielding fully assembled molecules as shown by electron microscopy. The recombinant proteasomes were purified to homogeneity and were shown to have proteolytic activity indistinguishable from proteasomes isolated from T. acidophilum.

Cloning and sequencing of the gene for the cytoplasmic inorganic pyrophosphatase from the thermoacidophilic archaebacterium Thermoplasma acidophilum

The gene (ppa) from the thermoacidophilic archaebacterium Thermoplasma acidophilum, encoding the cytoplasmic pyrophosphatase, has been cloned. Two degenerate oligonucleotide probes, synthesized according to the N-terminal amino acid sequence of the isolated protein, were used to screen subgenomic libraries. The DNA-derived amino acid sequence of the archaebacterial enzyme allows, for the first time, comparative studies of cytoplasmic pyrophosphatases to be extended to all three urkingdoms. The archaebacterial pyrophosphatase more closely resembles the eubacterial enzymes on the basis of sequence similarity and subunit size. The majority of amino acid residues considered to be essential for hydrolysis of pyrophosphate seem to have been conserved throughout evolution, as inferred from the results of an alignment of sequences from all three urkingdoms.

Conversion, by limited proteolysis, of an archaebacterial citrate synthase into essentially a citryl-CoA hydrolase

1. Limited proteolysis of citrate synthase from Sulfolobus solfataricus by trypsin reduced the rate of the overall reaction (acetyl-CoA + oxaloacetate + H2O----citrate + CoASH) to 4% but did not affect the hydrolysis of citryl-CoA. Experimental results indicate that a connecting link between the enzyme's ligase and hydrolase activity becomes impaired specifically on treatment with trypsin. Other proteolytic enzymes like chymotrypsin and subtilisin inactivated catalytic functions of citrate synthase, ligase and hydrolase, equally well. 2. Tryptic hydrolysis occurs at the N-terminal region of citrate synthase, but a study by SDS/PAGE revealed no difference in molecular mass between native and proteolytically nicked citrate synthase. The peptide removed from the enzyme by trypsin, therefore, contains less than about 15 amino acid residues. 3. The Km values of the substrates for both native and nicked enzyme were identical, as was the state of aggregation (dimeric) of the two enzyme species. These could be separated by affinity chromatography on Blue-Sepharose and differentiated by their isoelectric points (pI = 6.68 +/- 0.08 and pI = 6.37 +/- 0.03 for native citrate synthase and the large tryptic peptide, respectively) as well as by the N-terminus which is blocked in the native enzyme only. 4. Edman degradation of the large tryptic fragment yielded the N-terminal sequence GLEDVYIKSTSLTYIDGVNGVLRY, which is 71% identical to the N-terminal region (positions 9-32) of citrate synthase from Thermoplasma acidophilum. 5. The conversion of citrate synthase into essentially a citryl-CoA hydrolase is considered the consequence of a conformational change thought to occur on tryptic removal of the N-terminal small peptide.

The nature of the last universal ancestor and the root of the tree of life, still open questions

The nature of the last universal ancestor to all extent cellular organisms and the rooting of the universal tree of life are fundamental questions which can now be addressed by molecular evolutionists. Several scenarios have been proposed during the last years, based on the phylogenies of ribosomal RNA and of duplicated proteins, which suggest that the last universal ancestor was either an RNA progenote or an hyperthermophilic prokaryote. We discuss these hypotheses in the light of new data on the evolution of DNA metabolizing enzymes and of contradictions between different protein phylogenies. We conclude that the last universal ancestor was a member of the DNA world already containing several DNA polymerases and DNA topoisomerases. Furthermore, we criticize current data which suggest that the rooting of the universal tree of life is located in the eubacterial branch and we conclude that both rooting the universal tree and the nature of the last universal ancestor are still open questions.

Expression and purification of plasmid-encoded Thermoplasma acidophilum citrate synthase from Escherichia coli

The citrate synthase gene from the thermophilic archaebacterium Thermoplasma acidophilum was expressed in Escherichia coli, yielding an active product of the expected molecular weight. Manipulation of the citrate synthase gene in a series of pUC19 constructs showed that the presumed Thermoplasma ribosome binding site is recognized by the E. coli ribosome. A rapid purification of the expression product to homogeneity was achieved, based on the thermostability of Thermoplasma citrate synthase.