PCNA from Thermococcus gammatolerans: A protein involved in chromosomal DNA metabolism intrinsically resistant at high levels of ionizing radiation.

Proliferating cell nuclear antigen (PCNA) is an essential protein for cell viability in archaea and eukarya, since it is involved in DNA replication and repair. In order to obtain insights regarding the characteristics that confer radioresistance, the structural study of the PCNA from Thermococcus gammatolerans (PCNATg ) in a gradient of ionizing radiation by X-ray crystallography was carried out, together with a bioinformatic analysis of homotrimeric PCNA structures, their sequences, and their molecular interactions. The results obtained from the datasets and the accumulated radiation dose for the last collection from three crystals revealed moderate and localized damage, since even with the loss of resolution, the electron density map corresponding to the last collection allowed to build the whole structure. Attempting to understand this behavior, multiple sequence alignments, and structural superpositions were performed, revealing that PCNA is a protein with a poorly conserved sequence, but with a highly conserved structure. The PCNATg presented the highest percentage of charged residues, mostly negatively charged, with a proportion of glutamate more than double aspartate, lack of cysteines and tryptophan, besides a high number of salt bridges. The structural study by X-ray crystallography reveals that the PCNATg has the intrinsic ability to resist high levels of ionizing radiation, and the bioinformatic analysis suggests that molecular evolution selected a particular composition of amino acid residues, and their consequent network of synergistic interactions for extreme conditions, as a collateral effect, conferring radioresistance to a protein involved in the chromosomal DNA metabolism of a radioresistant microorganism.

ADP-dependent glucose/glucosamine kinase from Thermococcus kodakarensis: cloning and characterization.

The genome sequence of Thermococcus kodakarensis contains an open reading frame, TK1110, annotated as ADP-dependent glucokinase. The encoding gene was expressed in Escherichia coli and the gene product, TK-GLK, was produced in soluble and active form. The recombinant enzyme was extremely thermostable. Thermostability was increased significantly in the presence of ammonium sulfate. ADP was the preferred co-factor for TK-GLK, which could be replaced with CDP but with a 60% activity. TK-GLK was a metal ion-dependent enzyme which exhibited glucokinase, glucosamine kinase and glucose 6-phosphatase activities. It catalyzed the phosphorylation of both glucose and glucosamine with nearly the same rate and affinity. The apparent Km values for glucose and glucosamine were 0.48 ± 0.03 and 0.47 ± 0.09 mM, respectively. The catalytic efficiency (kcat/Km) values against these two substrates were 6.2 × 105 ± 0.25 and 5.8 × 105 ± 0.75 M-1 s-1. The apparent Km value for dephosphorylation of glucose 6-phosphate was ~14-fold higher than that of glucose phosphorylation. Similarly, catalytic efficiency (kcat/Km) for phosphatase reaction was ~19-fold lower than that for the kinase reaction. To the best of our knowledge, this is the first report that describes the reversible nature of a euryarchaeal ADP-dependent glucokinase.

Branched-chain polyamine stabilizes RNA polymerase at elevated temperatures in hyperthermophiles.

Branched-chain polyamines (BCPAs) are unique polycations found in (hyper)thermophiles. Thermococcus kodakarensis grows optimally at 85 °C and produces the BCPA N4-bis(aminopropyl)spermidine by sequential addition of decarboxylated S-adenosylmethionine (dcSAM) aminopropyl groups to spermidine (SPD) by BCPA synthase A (BpsA). The T. kodakarensis bpsA deletion mutant (DBP1) did not grow at temperatures at or above 93 °C, and grew at 90 °C only after a long lag period following accumulation of excess cytoplasmic SPD. This suggests that BCPA plays an essential role in cell growth at higher temperatures and raises the possibility that BCPA is involved in controlling gene expression. To examine the effects of BCPA on transcription, the RNA polymerase (RNAP) core fraction was extracted from another bpsA deletion mutant, DBP4 (RNAPDBP4), which carried a His-tagged rpoL, and its enzymatic properties were compared with those of RNAP from wild-type (WT) cells (RNAPWT). LC-MS analysis revealed that nine ribosomal proteins were detected from RNAPWT but only one form RNAPDBP4. These results suggest that BCPA increases the linkage between RNAP and ribosomes to achieve efficient coupling of transcription and translation. Both RNAPs exhibited highest transcription activity in vitro at 80 °C, but the specific activity of RNAPDBP4 was lower than that of RNAPWT. Upon addition of SPD and BCPA, both increased the transcriptional activity of RNAPDBP4; however, elevation by BCPA was achieved at a tenfold lower concentration. Addition of BCPA also protected RNAPDBP4 against thermal inactivation at 90 °C. These results suggest that BCPA increases transcriptional activity in T. kodakarensis by stabilizing the RNAP complex at high temperatures.

Second Messenger cA4 Formation within the Composite Csm1 Palm Pocket of Type III-A CRISPR-Cas Csm Complex and Its Release Path.

Target RNA binding to crRNA-bound type III-A CRISPR-Cas multi-subunit Csm surveillance complexes activates cyclic-oligoadenylate (cAn) formation from ATP subunits positioned within the composite pair of Palm domain pockets of the Csm1 subunit. The generated cAn second messenger in turn targets the CARF domain of trans-acting RNase Csm6, triggering its HEPN domain-based RNase activity. We have undertaken cryo-EM studies on multi-subunit Thermococcus onnurineus Csm effector ternary complexes, as well as X-ray studies on Csm1-Csm4 cassette, both bound to substrate (AMPPNP), intermediates (pppAn), and products (cAn), to decipher mechanistic aspects of cAn formation and release. A network of intermolecular hydrogen bond alignments accounts for the observed adenosine specificity, with ligand positioning dictating formation of linear pppAn intermediates and subsequent cAn formation by cyclization. We combine our structural results with published functional studies to highlight mechanistic insights into the role of the Csm effector complex in mediating the cAn signaling pathway.

CRISPR-Cas III-A Csm6 CARF Domain Is a Ring Nuclease Triggering Stepwise cA4 Cleavage with ApA>p Formation Terminating RNase Activity.

Type III-A CRISPR-Cas surveillance complexes containing multi-subunit Csm effector, guide, and target RNAs exhibit multiple activities, including formation of cyclic-oligoadenylates (cAn) from ATP and subsequent cAn-mediated cleavage of single-strand RNA (ssRNA) by the trans-acting Csm6 RNase. Our structure-function studies have focused on Thermococcus onnurineus Csm6 to deduce mechanistic insights into how cA4 binding to the Csm6 CARF domain triggers the RNase activity of the Csm6 HEPN domain and what factors contribute to regulation of RNA cleavage activity. We demonstrate that the Csm6 CARF domain is a ring nuclease, whereby bound cA4 is stepwise cleaved initially to ApApApA>p and subsequently to ApA>p in its CARF domain-binding pocket, with such cleavage bursts using a timer mechanism to regulate the RNase activity of the Csm6 HEPN domain. In addition, we establish T. onnurineus Csm6 as an adenosine-specific RNase and identify a histidine in the cA4 CARF-binding pocket involved in autoinhibitory regulation of RNase activity.

Distinct molecular assembly of homologous peroxiredoxins from Pyrococcus horikoshii and Thermococcus kodakaraensis.

Peroxiredoxins from Pyrococcus horikoshii (PhPrx) and Thermococcus kodakaraensis (TkPrx) are highly homologous proteins sharing 196 of the 216 residues. We previously reported a pentagonal ring-type decameric structure of PhPrx. Here, we present the crystal structure of TkPrx. Despite their homology, unlike PhPrx, the quaternary structure of TkPrx was found to be a dodecamer comprised of six homodimers arranged in a hexagonal ring-type assembly. The possibility of the redox-dependent conversion of the molecular assembly, which had been observed in PhPrx, was excluded for TkPrx based on the crystal structure of a mutant in which all of the cysteine residues were substituted with serine. The monomer structures of the dodecameric TkPrx and decameric PhPrx coincided well, but there was a slight difference in the relative orientation of the two domains. Molecular assembly of PhPrx and TkPrx in solution evaluated by gel-filtration chromatography was consistent with the crystallographic results. For both PhPrx and TkPrx, the gel-filtration elution volume slightly increased with a decrease in the protein concentration, suggesting the existence of an equilibrium state between the decameric/dodecameric ring and lower-order assembly. This structural assembly difference between highly homologous Prxs suggests a significant influence of quaternary structure on function, worthy of further exploration.

Identification of Branched-Chain Polyamines in Hyperthermophiles.

Thermophiles are organisms that grow optimally at temperatures higher than 55 °C. They contain two types of unusual longer/branched-chain polyamines in addition to common polyamines such as spermidine and putrescine. These unusual polyamines contribute to the survival of hyperthermophiles at high temperatures. Recently, the novel aminopropyltransferase BpsA was found to be responsible for the biosynthesis of branched-chain polyamines in the hyperthermophilic archaeon Thermococcus kodakarensis, which contains N 4-bis(aminopropyl)spermidine as the major polyamine. This compound is synthesized by the sequential addition of decarboxylated S-adenosylmethionine (dcSAM) aminopropyl groups to spermidine via the bifunctional catalytic action of BpsA. In this chapter, methods for the extraction and identification of branched-chain polyamines are presented, along with methods for the production and characterization of recombinant T. kodakarensis BpsA as a model aminopropyltransferase.

Expression, purification and characterization of a catalytic domain of human protein tyrosine phosphatase non-receptor 12 (PTPN12) in Escherichia coli with FKBP-type PPIase as a chaperon.

Protein tyrosine phosphatase non-receptor type 12 (PTPN12), also known as PTP-PEST, was broadly expressed in hemopoietic cells. Recent research has shown that this enzyme is involved in tumorigenesis, as well as in tumor progression and transfer, as it can suppress multiple oncogenic tyrosine kinases. However, the difficulty of soluble expression of PTP-PEST in prokaryotic cells has resulted in great limitations in investigating its structure and functions. In this study, we successfully carried out soluble expression of the catalytic domain of PTP-PEST (ΔPTP-PEST) in Escherichia coli and performed an enzymatic characterization and kinetics. To confirm expression efficiency, we also induced the expression of the chaperon, FKBP_C. FKBP_C expression indicated efficacious prokaryotic expression of ΔPTP-PEST. In conclusion, our work yielded a practical expression system and two-step chromatography purification method that may serve as a valuable tool for the structural and functional analysis of proteins that are difficult to express in the soluble form in prokaryotic cells.

The structure of the Pfp1 protease from the hyperthermophilic archaeon Thermococcus thioreducens in two crystal forms.

The Pfp1 protease, a cysteine protease of unknown specificity from the hyperthermophilic archaeon Thermococcus thioreducens, was crystallized in two distinctive crystal forms: from concentrated citrate in one case and PEG in the other. X-ray data were collected from both crystal forms at room temperature to about 1.9 Šresolution using a laboratory source and detector, and the structures were solved by molecular replacement using the Pfp1 protease from Pyrococcus horikoshii as the search model. In the T. thioreducens protease structures, Cys18 residues on adjacent molecules in the asymmetric units form intermolecular disulfide bonds, thereby yielding hexamers composed of three cross-linked, quasi-dyad-related dimers with crystallographically exact threefold axes and exhibiting almost exact 32 symmetry. The corresponding residue in P. horikoshii Pfp1 is Tyr18. An individual active site containing Cys100 and His101 also includes a Glu74 residue contributed by a quasi-twofold-related, non-cross-linked subunit. Two catalytic triads are therefore closely juxtaposed about the quasi-twofold axis at the interface of these subunits, and are relatively sequestered within the hexamer cavity. The cysteine in the active site is observed to be oxidized in both of the crystal forms that were studied.

Calcium, Ammonia, Redox-Active Tyrosine YZ, and Proton-Coupled Electron Transfer in the Photosynthetic Oxygen-Evolving Complex.

A redox-active tyrosine, YZ (Y161 in the D1 polypeptide), is essential in photosystem II (PSII), which conducts photosynthetic oxygen evolution. On each step of the light-driven oxygen evolving reaction, YZ radical is formed by a chlorophyll cation radical. YZ radical is then reduced by a Mn4CaO5 cluster in a proton coupled electron transfer (PCET) reaction. YZ is hydrogen bonded to His190-D1 and to water molecules in a hydrogen-bonding network, involving calcium. This network is sensitive to disruption with ammonia and to removal and replacement of calcium. Only strontium supports activity. Here, we use electron paramagnetic resonance (EPR) spectroscopy to define the influence of ammonia treatment, calcium removal, and strontium/barium substitution on YZ radical PCET at two pH values. A defined oxidation state of the metal cluster (S2) was trapped by illumination at 190 K. The net reduction and protonation of YZ radical via PCET were monitored by EPR transients collected after a 532 nm laser flash. At 190 K, YZ radical cannot oxidize the Mn4CaO5 cluster and decays on the seconds time scale by recombination with QA-. The overall decay half-time and biexponential fits were used to analyze the results. The reaction rate was independent of pH in control, calcium-reconstituted PSII (Ca-PSII). At pH 7.5, the YZ radical decay rate decreased in calcium-depleted (CD-PSII) and barium/strontium-reconstituted PSII (Ba-PSII, Sr-PSII), relative to Ca-PSII. At pH 6.0, the YZ radical decay rate was not significantly altered in CD-PSII and Sr-PSII but decreased in Ba-PSII. A two-pathway model, involving two competing proton donors with different pKa values, is proposed to explain these results. Ammonia treatment decreased the YZ decay rate in Ca-PSII, Sr-PSII, and CD-PSII, consistent with a reaction that is mediated by the hydrogen-bonding network. However, ammonia treatment did not alter the rate in Ba-PSII. This result is interpreted in terms of the large ionic radius of barium and the elevated pKa of barium-bound water, which are expected to disrupt hydrogen bonding. In addition, evidence for a functional interaction between the S2 protonated water cluster (Wn+) and the YZ proton donation pathway is presented. This interaction is proposed to increase the rate of the YZ PCET reaction.

The Proteome and Lipidome of Thermococcus kodakarensis across the Stationary Phase.

The majority of cells in nature probably exist in a stationary-phase-like state, due to nutrient limitation in most environments. Studies on bacteria and yeast reveal morphological and physiological changes throughout the stationary phase, which lead to an increased ability to survive prolonged nutrient limitation. However, there is little information on archaeal stationary phase responses. We investigated protein- and lipid-level changes in Thermococcus kodakarensis with extended time in the stationary phase. Adaptations to time in stationary phase included increased proportion of membrane lipids with a tetraether backbone, synthesis of proteins that ensure translational fidelity, specific regulation of ABC transporters (upregulation of some, downregulation of others), and upregulation of proteins involved in coenzyme production. Given that the biological mechanism of tetraether synthesis is unknown, we also considered whether any of the protein-level changes in T. kodakarensis might shed light on the production of tetraether lipids across the same period. A putative carbon-nitrogen hydrolase, a TldE (a protease in Escherichia coli) homologue, and a membrane bound hydrogenase complex subunit were candidates for possible involvement in tetraether-related reactions, while upregulation of adenosylcobalamin synthesis proteins might lend support to a possible radical mechanism as a trigger for tetraether synthesis.

Structural and functional analyses of the archaeal tRNA m2G/m22G10 methyltransferase aTrm11 provide mechanistic insights into site specificity of a tRNA methyltransferase that contains common RNA-binding modules.

N(2)-methylguanosine is one of the most universal modified nucleosides required for proper function in transfer RNA (tRNA) molecules. In archaeal tRNA species, a specific S-adenosyl-L-methionine (SAM)-dependent tRNA methyltransferase (MTase), aTrm11, catalyzes formation of N(2)-methylguanosine and N(2),N(2)-dimethylguanosine at position 10. Here, we report the first X-ray crystal structures of aTrm11 from Thermococcus kodakarensis (Tko), of the apo-form, and of its complex with SAM. The structures show that TkoTrm11 consists of three domains: an N-terminal ferredoxinlike domain (NFLD), THUMP domain and Rossmann-fold MTase (RFM) domain. A linker region connects the THUMP-NFLD and RFM domains. One SAM molecule is bound in the pocket of the RFM domain, suggesting that TkoTrm11 uses a catalytic mechanism similar to that of other tRNA MTases containing an RFM domain. Furthermore, the conformation of NFLD and THUMP domains in TkoTrm11 resembles that of other tRNA-modifying enzymes specifically recognizing the tRNA acceptor stem. Our docking model of TkoTrm11-SAM in complex with tRNA, combined with biochemical analyses and pre-existing evidence, provides insights into the substrate tRNA recognition mechanism: The THUMP domain recognizes a 3'-ACCA end, and the linker region and RFM domain recognize the T-stem, acceptor stem and V-loop of tRNA, thereby causing TkoTrm11 to specifically identify its methylation site.

A small protein inhibits proliferating cell nuclear antigen by breaking the DNA clamp.

Proliferating cell nuclear antigen (PCNA) forms a trimeric ring that encircles duplex DNA and acts as an anchor for a number of proteins involved in DNA metabolic processes. PCNA has two structurally similar domains (I and II) linked by a long loop (inter-domain connector loop, IDCL) on the outside of each monomer of the trimeric structure that makes up the DNA clamp. All proteins that bind to PCNA do so via a PCNA-interacting peptide (PIP) motif that binds near the IDCL. A small protein, called TIP, binds to PCNA and inhibits PCNA-dependent activities although it does not contain a canonical PIP motif. The X-ray crystal structure of TIP bound to PCNA reveals that TIP binds to the canonical PIP interaction site, but also extends beyond it through a helix that relocates the IDCL. TIP alters the relationship between domains I and II within the PCNA monomer such that the trimeric ring structure is broken, while the individual domains largely retain their native structure. Small angle X-ray scattering (SAXS) confirms the disruption of the PCNA trimer upon addition of the TIP protein in solution and together with the X-ray crystal data, provides a structural basis for the mechanism of PCNA inhibition by TIP.

Structural basis for the ATP-independent proteolytic activity of LonB proteases and reclassification of their AAA+ modules.

Lon proteases degrade defective or denature proteins as well as some folded proteins for the control of cellular protein quality. There are two types of Lon proteases, LonA and LonB. Each consists of two functional components: a protease component and an ATPase associated with various cellular activities (AAA+ module). Here, we report the 2.03 -resolution crystal structure of the isolated AAA+ module (iAAA+ module) of LonB from Thermococcus onnurineus NA1 (TonLonB). The iAAA+ module, having no bound nucleotide, adopts a conformation virtually identical to the ADP-bound conformation of AAA+ modules in the hexameric structure of TonLonB; this provides insights into the ATP-independent proteolytic activity observed in a LonB protease. Structural comparison of AAA+ modules between LonA and LonB revealed that the AAA+ modules of Lon proteases are separated into two distinct clades depending on their structural features. The AAA+ module of LonB belongs to the -H2 & Ins1 insert clade (HINS clade)- defined for the first time in this study, while the AAA+ module of LonA is a member of the HCLR clade.

Chaperone-Like Activity of a Bacterioferritin Comigratory Protein from Thermococcus kodakaraensis KOD1.

Peroxiredoxins (Prxs) are ubiquitous and conserved proteins that can catalyze the reduction of inorganic and organic hydroperoxides to protect against damage by reactive oxygen species. In this study, a Prx subfamily member, and specifically a bacterioferritin comigratory protein from hyperthermophilic Thermococcus kodakaraensis KOD1 (TkBcp), was overexpressed, purified and characterized. Based on the conserved cysteine (Cys) residues in its amino acids sequence, TkBcp can be grouped into 1-Cys Prx family. Size exclusion chromatography analysis showed that TkBcp exists in three oligomeric forms: 700 kDa, 70 kDa, and 20 kDa. The peroxidase function was found to predominate in the lowmolecular- weight (MW) form, whereas the high-MW complex has the chaperone function. Oxidative reagents caused the protein structure of TkBcp to shift from low-MW form to high-MW complexes, whereas reducing reagents caused a shift in the reverse direction. Furthermore, the high-MW form of TkBcp preferred to tightly bind DNA. The relationship of TkBcp with other homologs was also examined.

Inter-ring communication is dispensable in the reaction cycle of group II chaperonins.

Chaperonins are ubiquitous molecular chaperones with the subunit molecular mass of 60kDa. They exist as double-ring oligomers with central cavities. An ATP-dependent conformational change of the cavity induces the folding of an unfolded protein that is captured in the cavity. In the group I chaperonins, which are present in eubacteria and eukaryotic organelles, inter-ring communication takes important role for the reaction cycle. However, there has been limited study on the inter-ring communication in the group II chaperonins that exist in archaea and the eukaryotic cytosol. In this study, we have constructed the asymmetric ring complex of a group II chaperonin using circular permutated covalent mutants. Although one ring of the asymmetric ring complex lacks ATPase or ATP binding activity, the other wild-type ring undergoes an ATP-dependent conformational change and maintains protein-folding activity. The results clearly demonstrate that inter-ring communication is dispensable in the reaction cycle of group II chaperonins.

Structure analysis of archaeal AMP phosphorylase reveals two unique modes of dimerization.

AMP phosphorylase (AMPpase) catalyzes the initial reaction in a novel AMP metabolic pathway recently found in archaea, converting AMP and phosphate into adenine and ribose 1,5-bisphosphate. Gel-filtration chromatography revealed that AMPpase from Thermococcus kodakarensis (Tk-AMPpase) forms an exceptionally large macromolecular structure (>40-mers) in solution. To investigate its unique multimerization feature, we determined the first crystal structures of Tk-AMPpase, in the apo-form and in complex with substrates. Structures of two truncated forms of Tk-AMPpase (Tk-AMPpaseΔN84 and Tk-AMPpaseΔC10) clarified that this multimerization is achieved by two dimer interfaces within a single molecule: one by the central domain and the other by the C-terminal domain, which consists of an unexpected domain-swapping interaction. The N-terminal domain, characteristic of archaeal enzymes, is essential for enzymatic activity, participating in multimerization as well as domain closure of the active site upon substrate binding. Moreover, biochemical analysis demonstrated that the macromolecular assembly of Tk-AMPpase contributes to its high thermostability, essential for an enzyme from a hyperthermophile. Our findings unveil a unique archaeal nucleotide phosphorylase that is distinct in both function and structure from previously known members of the nucleoside phosphorylase II family.

Systematic functional comparative analysis of four single-stranded DNA-binding proteins and their affection on viral RNA metabolism.

The accumulation of single-stranded DNA-binding (SSB) proteins is essential for organisms and has various applications. However, no study has simultaneously and systematically compared the characteristics of SSB proteins. In addition, SSB proteins may bind RNA and play an unknown biological role in RNA metabolism. Here, we expressed a novel species of SSB protein derived from Thermococcus kodakarensis KOD1 (KOD), as well as SSB proteins from Thermus thermophilus (TTH), Escherichia coli, and Sulfolobus Solfataricus P2 (SSOB), abbreviated kod, tth, bl21, and ssob, respectively. These SSB proteins could bind ssDNA and viral RNA. bl21 resisted heat treatment for more than 9 h, Ssob and kod could withstand 95°C for 10 h and retain its ssDNA- and RNA-binding ability. Four SSB proteins promoted the specificity of the DNA polymerase in PCR-based 5- and 9-kb genome fragment amplification. kod also increased the amplification of a 13-kb PCR product, and SSB protein-bound RNA resisted Benzonase digestion. The SSB proteins could also enter the host cell bound to RNA, which resulted in modulation of viral RNA metabolism, particularly ssob and bl21.

Identification of a novel ligand binding site in phosphoserine phosphatase from the hyperthermophilic archaeon Thermococcus onnurineus.

Phosphoserine phosphatase (PSP) catalyzes the final and irreversible step of L-serine synthesis by hydrolyzing phosphoserine to produce L-serine and inorganic phosphate. Developing a therapeutic drug that interferes with serine production is of great interest to regulate the pathogenicity of some bacteria and control D-serine levels in neurological diseases. We determined the crystal structure of PSP from the hyperthermophilic archaeon Thermococcus onnurineus at 1.8 Å resolution, revealing an NDSB ligand bound to a novel site that is located in a fissure between the catalytic domain and the CAP module. The structure shows a half-open conformation of the CAP 1 module with a unique protruding loop of residues 150-155 that possesses a helical conformation in other structures of homologous PSPs. Activity assays indicate that the enzyme exhibits marginal PSP activity at low temperature but a sharp increase in the k(cat)/K(M) value, approximately 22 fold, when the temperature is increased. Structural and biochemical analyses suggest that the protruding loop in the active site might be an essential component for the regulation of the activity of PSP from hyperthermophilic T. onnurineus. Identification of this novel binding site distantly located from the catalytic site may be exploited for the development of effective therapeutic allosteric inhibitors against PSP activity.

Oxidized NADH oxidase inhibits activity of an ATP/NAD kinase from a Thermophilic archaeon.

NADH oxidases (NOXs) are important enzymes in detoxifying oxidative stress and regenerating oxidized pyridine nucleotides. In the present study, a NOX from Thermococcus kodakarensis KOD1 (NOXtk) was recombinantly expressed in Escherichia coli and purified to homogeneity. NOXtk displayed NADH oxidase activity that was inhibited by oxidization. Under physiological conditions, unoxidized and oxidized NOXtk formed dimers and hexamers, respectively. Mutating the single cysteine residue Cys45 to alanine (NOXtkC45A) decreased NADH oxidase activity without affecting dimerization or hexamerization, suggesting that oligomerization does not occur through disulfide bond formation. Pull-down assay results indicated that an ATP/NAD kinase from T. kodakarensis KOD1 (ANKtk) binds to NOXtk. Use of several assays revealed that ANKtk can only bind to oxidized hexameric NOXtk, through which it inhibits ANKtk activity. Because ANKtk converts NADH to NADPH (an important factor in oxidative stress protection), a model based on in vitro result was proposed in which NOXtk hexamerization under oxic conditions inhibits both NOXtk and ANKtk activities, thereby sensitizing cells to oxidative stress-induced death.