Biochemical characterization of DNA-binding proteins from Pyrobaculum aerophilum and Aeropyrum pernix

Several representatives of the Crenarchaeal branch of the Archaea contain highly abundant, small, positively charged proteins exemplified by the Sso7d protein from Sulfolobus solfataricus. These proteins bind to DNA in a non-sequence-specific manner. Using publicly available genomic sequence information, we identified a second class of small Crenarchaeal DNA-binding proteins represented by the Pyrobaculum aerophilum open reading frame 3192–encoded (Pae3192) protein and its paralogs. We investigated the biochemical properties of the Pae3192 protein and an orthologous protein (Ape1322b) from Aeropyrum pernix in side-by-side experiments with the Sso7d protein. We demonstrate that the recombinant Ape1322b, Pae3192 and Sso7d proteins bind to DNA and that the DNA-protein complexes formed are slightly different for each protein. We show that like Sso7d, Pae3192 constrains negative supercoils in DNA. In addition, we show that all three proteins raise the melting temperature of duplex DNA upon binding. Finally, we present the equilibrium affinity constants and kinetic association constants of each protein for single-stranded and double-stranded DNA.     

Lessons from the Aeropyrum pernix genome

Aeropyrum pernix is the first crenarchaeote and first aerobic member of the Archaea for which the complete genome sequence has been determined. The sequence confirms the distinct nature of crenarchaeotes and provides new insight into the relationships between the three domains: Bacteria, Archaea and Eukaryotes.     

Provirus induction in hyperthermophilic archaea: characterization of Aeropyrum pernix spindle-shaped virus 1 and Aeropyrum pernix ovoid virus 1

By in silico analysis, we have identified two putative proviruses in the genome of the hyperthermophilic archaeon Aeropyrum pernix, and under special conditions of A. pernix growth, we were able to induce their replication. Both viruses were isolated and characterized. Negatively stained virions of one virus appeared as pleomorphic spindle-shaped particles, 180 to 210 nm by 40 to 55 nm, with tails of heterogeneous lengths in the range of 0 to 300 nm. This virus was named Aeropyrum pernix spindle-shaped virus 1 (APSV1). Negatively stained virions of the other virus appeared as slightly irregular oval particles with one pointed end, while in cryo-electron micrographs, the virions had a regular oval shape and uniform size (70 by 55 nm). The virus was named Aeropyrum pernix ovoid virus 1 (APOV1). Both viruses have circular, double-stranded DNA genomes of 38,049 bp for APSV1 and 13,769 bp for APOV1. Similarities to proteins of other archaeal viruses were limited to the integrase and Dna1-like protein. We propose to classify APOV1 into the family Guttaviridae.     

Structure and characterization of the 3-deoxy-D-arabino-heptulosonate 7-phosphate synthase from Aeropyrum pernix

The first enzyme in the shikimic acid biosynthetic pathway, 3-deoxy-D-arabino-heptulosonate 7-phosphate synthase (DAH7PS), varies significantly in size and complexity in the bacteria and plants that express it. The DAH7PS from the archaebacterium Aeropyrum pernix (DAH7PS(Ap)) is among the smallest and least complex of the DAH7PS enzymes, leading to the hypothesis that DAH7PS(Ap) would not be subject to feedback regulation by shikimic acid pathway products. We overexpressed DAH7PS(Ap) in Escherichia coli, purified it, and characterized its enzymatic activity. We then solved its X-ray crystal structure with a divalent manganese ion and phosphoenolpyruvate bound (PDB ID: 1VS1). DAH7PS(Ap) is a homodimeric metalloenzyme in solution. Its enzymatic activity increases dramatically above 60 °C, with optimum activity at 95 °C. Its pH optimum at 60 °C is 5.7. DAH7PS(Ap) follows Michaelis-Menten kinetics at 60 °C, with a K(M) for erythrose 4-phosphate of 280 μM, a K(M) for phosphoenolpyruvate of 891 μM, and a k(cat) of 1.0 s(-1). None of the downstream products of the shikimate biosynthetic pathway we tested inhibited the activity of DAH7PS(Ap). The structure of DAH7PS(Ap) is similar to the structures of DAH7PS from Thermatoga maritima (PDB ID: 3PG8) and Pyrococcus furiosus (PDB ID: 1ZCO), and is consistent with its designation as an unregulated DAH7PS.     

Biochemical analysis of a DNA replication origin in the archaeon Aeropyrum pernix

We have characterised the interaction of the Aeropyrum pernix origin recognition complex proteins (ORC1 and ORC2) with DNA using DNase I footprinting. Each protein binds upstream of its respective gene. However, ORC1 protein alone interacts more tightly with an additional region containing multiple origin recognition box (ORB) sites that we show to be a replication origin. At this origin, there are four ORB elements disposed either side of an A+T-rich region. An ORC1 protein dimer binds at each of these ORB sites. Once all four ORB sites have bound ORC1 protein, there is a transition to a higher-order assembly with a defined alteration in topology and superhelicity. Furthermore, after this transition, the A+T-rich region becomes sensitive to digestion by DNase I and P1 nuclease, revealing that the transition promotes distortion of the DNA in this region, presumably as a prelude to loading of MCM helicase.     

Identification and characterization of thioredoxin and thioredoxin reductase from Aeropyrum pernix K1.

We have identified and characterized a thermostable thioredoxin system in the aerobic hyperthermophilic archaeon Aeropyrum pernix K1. The gene (Accession no. APE0641) of A. pernix encoding a 37 kDa protein contains a redox active site motif (CPHC) but its N-terminal extension region (about 200 residues) shows no homology within the genome database. A second gene (Accession no. APE1061) has high homology to thioredoxin reductase and encodes a 37 kDa protein with the active site motif (CSVC), and binding sites for FAD and NADPH. We cloned the two genes and expressed both proteins in E. coli. It was observed that the recombinant proteins could act as an NADPH-dependent protein disulfide reductase system in the insulin reduction. In addition, the APE0641 protein and thioredoxin reductase from E. coli could also catalyze the disulfide reduction. These indicated that APE1061 and APE0641 express thioredoxin (ApTrx) and thioredoxin reductase (ApTR) of A. pernix, respectively. ApTR is expressed as an active homodimeric flavoprotein in the E. coli system. The optimum temperature was above 90 degrees C, and the half-life of heat inactivation was about 4 min at 110 degrees C. The heat stability of ApTR was enhanced in the presence of excess FAD. ApTR could reduce both thioredoxins from A. pernix and E. coli and showed a similar molar specific activity for both proteins. The standard state redox potential of ApTrx was about -262 mV, which was slightly higher than that of Trx from E. coli (-270 mV). These results indicate that a lower redox potential of thioredoxin is not necessary for keeping catalytic disulfide bonds reduced and thereby coping with oxidative stress in an aerobic hyperthermophilic archaea. Furthermore, the thioredoxin system of aerobic hyperthermophilic archaea is biochemically close to that of the bacteria.     

Characterization of novel hexadecameric thioredoxin peroxidase from Aeropyrum pernix K1

A gene (APE2278) encoding the peroxiredoxin (Prx) homologous protein of yeast and human was identified in the genome data base of the aerobic hyperthermophilic archaeon Aeropyrum pernix. We cloned the gene and produced the encoded protein in Escherichia coli cells. The isolated recombinant protein showed peroxidase activity in vitro and used the thioredoxin system of A. pernix as an electron donor. These results indicate that the recombinant protein is in fact thioredoxin peroxidase (ApTPx) of A. pernix. Immunoblot analysis revealed that the expression of ApTPx was induced as a cellular adaptation in response to the addition of exogenous H2O2 and may exert an antioxidant activity in vivo. An analysis of the ApTPx oligomers by high pressure liquid chromatography and electron microscopic studies showed that ApTPx exhibited the hexadecameric protein forming 2-fold toroid-shaped structure with outer and inner diameters of 14 and 6 nm, respectively. These results indicated that ApTPx is a novel hexadecameric protein composed of two identical octamers. Although oligomerization of individual subunits does not take place through an intersubunit-disulfide linkage involving Cys50 and Cys213, Cys50 is essential for the formation of the hexadecamer. Mutagenesis studies suggest that the sulfhydryl group of Cys50 is the site of oxidation by peroxide and that oxidized Cys50 reacts with the sulfhydryl group of Cys213 of another subunit to form an intermolecular disulfide bond. The resulting disulfide can then be reduced by thioredoxin. In support of this hypothesis, ApTPx mutants lacking either Cys50 or Cys213 showed no TPx activity, whereas the mutant lacking Cys207 had a TPx activity. This is the first report on the biochemical and structural features of a novel hexadecameric thioredoxin peroxidase from the archaea.     

Gene expression and characterization of two 2-oxoacid:ferredoxin oxidoreductases from Aeropyrum pernix K1

A hyperthermophilic and aerobic crenarchaeon, Aeropyrum pernix K1, has two sets of genes possibly encoding 2-oxoacid:ferredoxin oxidoreductases. One is encoded in open reading frames (ORFs) ape2126 and ape2128, and the other in ORFs ape1473 and ape1472. The two sets of genes were expressed. The product enzymes, Ape2126/2128 and Ape1473/1472, showed optimal temperatures of 105 and over 110 degrees C, and optimal pHs of 8.5 and 9.0, respectively, using pyruvate as a substrate. Pyruvate, 2-oxobutyrate, and glyoxylate were the best substrates for both enzymes, and additionally Ape1473/1472 was able to act on 2-oxoglutarate, suggesting the enzyme operates in the TCA cycle.     

Identification of the first archaeal oligopeptide-binding protein from the hyperthermophile Aeropyrum pernix

The archaeon Aeropyrum pernix grows optimally at 90°C and derives energy primarily from aerobic degradation of complex proteinaceous substrates. The ability of these nutrients to sustain growth is generally associated with the presence of oligopeptide transport systems, such as the well-known protein-dependent ATP-binding cassette (ABC) transporters. This study is concerned with the isolation and characterisation of the first archaeal oligopeptide-binding protein (OppA_Ap) from the extracellular medium of A. pernix. The protein shows a pI of 3.9 and a molecular mass of about 90 kDa under native conditions. By using a proteomic approach, the OppA_Ap-encoding gene was identified (APE1583) and about 55% of the protein amino-acid sequence was validated. The extracellular purified protein was able to efficiently bind oligopeptide substrates such as Xenopsin. The amount of a liganded peptide to OppA_Ap was about 70% at 90°C using a 1/100 (w/w) OppA_Ap/substrate ratio. Sequence comparisons showed a weak but significant similarity of OppA_Ap with bacterial oligopeptide binding proteins. Furthermore, APE1583 neighbouring genes encode for the cognate components of an ABC transport system, suggesting that these ORFs are organised in an operon-like structure, with OppA_Ap as the extracellular component for the uptake of oligopeptides.     

Crystal structure of the RNA 2'-phosphotransferase from Aeropyrum pernix K1

In the final step of tRNA splicing, the 2'-phosphotransferase catalyzes the transfer of the extra 2'-phosphate from the precursor-ligated tRNA to NAD. We have determined the crystal structure of the 2'-phosphotransferase protein from Aeropyrum pernix K1 at 2.8 Angstroms resolution. The structure of the 2'-phosphotransferase contains two globular domains (N and C-domains), which form a cleft in the center. The N-domain has the winged helix motif, a subfamily of the helix-turn-helix family, which is shared by many DNA-binding proteins. The C-domain of the 2'-phosphotransferase superimposes well on the NAD-binding fold of bacterial (diphtheria) toxins, which catalyze the transfer of ADP ribose from NAD to target proteins, indicating that the mode of NAD binding by the 2'-phosphotransferase could be similar to that of the bacterial toxins. The conserved basic residues are assembled at the periphery of the cleft and could participate in the enzyme contact with the sugar-phosphate backbones of tRNA. The modes by which the two functional domains recognize the two different substrates are clarified by the present crystal structure of the 2'-phosphotransferase.     

Characterization of a novel thermostable O-acetylserine sulfhydrylase from Aeropyrum pernix K1

An O-acetylserine sulfhydrylase (OASS) from the hyperthermophilic archaeon Aeropyrum pernix K1, which shares the pyridoxal 5'-phosphate binding motif with both OASS and cystathionine beta-synthase (CBS), was cloned and expressed by using Escherichia coli Rosetta(DE3). The purified protein was a dimer and contained pyridoxal 5'-phosphate. It was shown to be an enzyme with CBS activity as well as OASS activity in vitro. The enzyme retained 90% of its activity after a 6-h incubation at 100 degrees C. In the O-acetyl-L-serine sulfhydrylation reaction, it had a pH optimum of 6.7, apparent K(m) values for O-acetyl-L-serine and sulfide of 28 and below 0.2 mM, respectively, and a rate constant of 202 s(-1). In the L-cystathionine synthetic reaction, it showed a broad pH optimum in the range of 8.1 to 8.8, apparent K(m) values for L-serine and L-homocysteine of 8 and 0.51 mM, respectively, and a rate constant of 0.7 s(-1). A. pernix OASS has a high activity in the L-cysteine desulfurization reaction, which produces sulfide and S-(2,3-hydroxy-4-thiobutyl)-L-cysteine from L-cysteine and dithiothreitol.     

嗜热酯酶APE1547催化活性的定向进化研究

对来源于嗜热古菌Aeropyrum pernix的酯酶(APE1547)催化活性进行定向进化研究。利用APE1547特殊的稳定性,建立了准确的高通量高温酯酶筛选方法。对第一代随机突变库筛选获得了催化活性较野生型提高1.5倍的突变体M010,序列分析表明其氨基酸突变为R526S。从第二代突变库中筛选出的总活力提高5.8倍突变体M020,突变位点为R526S/E88G/A200T/I519L,其比活力与M010一致,但表达量比野生型提高约4倍。对M020酶学性质表征发现,其最适pH为8.5,比野生型向碱性偏移0.5;活性中心残基酸性基团的解离常数(pK1)由野生型的7.0提高至7.5。晶体结构分析表明,突变位点R526距离活性中心较近,将其突变为Ser降低了活性中心的极性,抑制了催化残基His的解离,使酸性基团的解离常数升高。     

Crystal structure of an acylpeptide hydrolase/esterase from Aeropyrum pernix K1

Acylpeptide hydrolases (APH; also known as acylamino acid releasing enzyme) catalyze the removal of an N-acylated amino acid from blocked peptides. The crystal structure of an APH from the thermophilic archaeon Aeropyrum pernix K1 to 2.1 A resolution confirms it to be a member of the prolyl oligopeptidase family of serine proteases. The structure of apAPH is a symmetric homodimer with each subunit comprised of two domains. The N-terminal domain is a regular seven-bladed beta-propeller, while the C-terminal domain has a canonical alpha/beta hydrolase fold and includes the active site and a conserved Ser445-Asp524-His556 catalytic triad. The complex structure of apAPH with an organophosphorus substrate, p-nitrophenyl phosphate, has also been determined. The complex structure unambiguously maps out the substrate binding pocket and provides a basis for substrate recognition by apAPH. A conserved mechanism for protein degradation from archaea to mammals is suggested by the structural features of apAPH.     

The structure of an alcohol dehydrogenase from the hyperthermophilic archaeon Aeropyrum pernix

The structure of the recombinant medium chain alcohol dehydrogenase (ADH) from the hyperthermophilic archaeon Aeropyrum pernix has been solved by the multiple anomalous dispersion technique using the signal from the naturally occurring zinc ions. The enzyme is a tetramer with 222 point group symmetry. The ADH monomer is formed from a catalytic and a cofactor-binding domain, with the overall fold similar to previously solved ADH structures. The 1.62 A resolution A.pernix ADH structure is that of the holo form, with the cofactor NADH bound into the cleft between the two domains. The electron density found in the active site has been interpreted to be octanoic acid, which has been shown to be an inhibitor of the enzyme. This inhibitor is positioned with its carbonyl oxygen atom forming the fourth ligand of the catalytic zinc ion. The structural zinc ion of each monomer is present at only partial occupancy and in its absence a disulfide bond is formed. The enhanced thermal stability of the A.pernix ADH is thought to arise primarily from increased ionic and hydrophobic interactions on the subunit interfaces.     

In vivo characterization of thermal stabilities of Aeropyrum pernix cellular components by differential scanning calorimetry

Revival studies of Aeropyrum pernix show that the viability of cells and cell recovery after heat treatment depends on the temperature of treatment. Differential scanning calorimetry (DSC) is used to analyze the relative thermal stabilities of cellular components of A. pernix and to identify the cellular components responsible for the observed lag phase and reduced maximum growth following a heat treatment. DSC thermograms show 5 visible endothermic transitions with 2 major transitions. DSC analysis of isolated crude ribosomes aids the assignment of the 2 major peaks observed in whole-cell thermograms to denaturation of ribosomal structures. A comparison of partial and immediate full rescan thermograms of A. pernix whole cells indicates that both major peaks represent irreversible thermal transitions. A DNA peak is also identified in the whole-cell thermogram by comparison with the optical data of isolated pure DNA. DNA melting is shown to be irreversible in dilute solution, whereas it is partially reversible in whole cells, owing at least in part, to restricted volume effects. In contrast to mesophilic organisms, hyperthermophilic A. pernix ribosomes are more thermally stable than DNA, but in both organisms, irreversible changes leading to cell death occur owing to ribosomal denaturation.     

Isoprenoid quinones in an aerobic hyperthermophilic archaeon, Aeropyrum pernix

Aeropyrum pernix is the first strictly aerobic hyperthermophile known to grow heterotrophically at neutral pH and at temperatures up to 100°C. Using a simple and sensitive frit-fast atom bombardment liquid chromatography/mass spectrometry quinone analysis method, we analyzed the quinones in A. pernix. This organism contained demethylmenaquinone analogs (DMK-6(H_n)) and methionaquinone analogs (MTK-6(H_n)) when it was grown under vigorous shaking in the presence of air. The quinones were partially or fully saturated with six isoprenyl units. Although DMK and MTK are the quinones found in eubacteria, this is the first report to demonstrate the simultaneous occurrence of DMK and MTK in archaea. The effect of Na₂S₂O₃ on the quinone composition was studied at concentrations of 0, 0.1 and 0.5% under aerobic growth conditions with shaking. The total quinone content was highest (83.4 μg g⁻¹ dry cell weight) at 0.1% Na₂S₂O₃. In the absence of Na₂S₂O₃, only DMK-6 analogs were detected. While DMK analogs such as DMK-6(H₁₂), DMK-6(H₁₀) and DMK-6(H₈) were the major quinones at 0.1% Na₂S₂O₃, MTK analogs such as MTK-6(H₁₂) and MTK-6(H₁₀) were also detected. When the Na₂S₂O₃ concentration was increased to 0.5%, both DMK-6(H₈) and MTK-6(H₁₀) disappeared, while MTK-6(H₁₂) increased to approximately 20% of the total quinone content. When A. pernix was grown under oxygen limitation in a tightly closed bottle without gas phase, MK-6(H₁₀) appeared.