Asymmetric Switching in a Homodimeric ABC Transporter: A Simulation Study

ABC transporters are a large family of membrane proteins involved in a variety of cellular processes, including multidrug and tumor resistance and ion channel regulation. Advances in the structural and functional understanding of ABC transporters have revealed that hydrolysis at the two canonical nucleotide-binding sites (NBSs) is co-operative and non-simultaneous. A conserved core architecture of bacterial and eukaryotic ABC exporters has been established, as exemplified by the crystal structure of the homodimeric multidrug exporter Sav1866. Currently, it is unclear how sequential ATP hydrolysis arises in a symmetric homodimeric transporter, since it implies at least transient asymmetry at the NBSs. We show by molecular dynamics simulation that the initially symmetric structure of Sav1866 readily undergoes asymmetric transitions at its NBSs in a pre-hydrolytic nucleotide configuration. MgATP-binding residues and a network of charged residues at the dimer interface are shown to form a sequence of putative molecular switches that allow ATP hydrolysis only at one NBS. We extend our findings to eukaryotic ABC exporters which often consist of two non-identical half-transporters, frequently with degeneracy substitutions at one of their two NBSs. Interestingly, many residues involved in asymmetric conformational switching in Sav1866 are substituted in degenerate eukaryotic NBS. This finding strengthens recent suggestions that the interplay of a consensus and a degenerate NBS in eukaroytic ABC proteins pre-determines the sequence of hydrolysis at the two NBSs.     

An engineered blockage within the ammonia tunnel of carbamoyl phosphate synthetase prevents the use of glutamine as a substrate but not ammonia

The heterodimeric carbamoyl phosphate synthetase (CPS) from Escherichia coli catalyzes the formation of carbamoyl phosphate from bicarbonate, glutamine, and two molecules of ATP. The enzyme catalyzes the hydrolysis of glutamine within the small amidotransferase subunit and then transfers ammonia to the two active sites within the large subunit. These three active sites are connected via an intermolecular tunnel, which has been located within the X-ray crystal structure of CPS from E. coli. It has been proposed that the ammonia intermediate diffuses through this molecular tunnel from the binding site for glutamine within the small subunit to the phosphorylation site for bicarbonate within the large subunit. To provide experimental support for the functional significance of this molecular tunnel, residues that define the interior walls of the "ammonia tunnel" within the small subunit were targeted for site-directed mutagenesis. These structural modifications were intended to either block or impede the passage of ammonia toward the large subunit. Two mutant proteins (G359Y and G359F) display kinetic properties consistent with a constriction or blockage of the ammonia tunnel. With both mutants, the glutaminase and bicarbonate-dependent ATPase reactions have become uncoupled from one another. However, these mutant enzymes are fully functional when external ammonia is utilized as the nitrogen source but are unable to use glutamine for the synthesis of carbamoyl-P. These results suggest the existence of an alternate route to the bicarbonate phosphorylation site when ammonia is provided as an external nitrogen source.     

Systematic study of the functions for the residues around the nucleotide pocket in simian virus 40 AAA+ hexameric helicase

The high-resolution structural data for simian virus 40 large-T-antigen helicase revealed a set of nine residues bound to ATP/ADP directly or indirectly. The functional role of each of these residues in ATP hydrolysis and also the helicase function of this AAA+ (ATPases associated with various cellular activities) molecular motor are unclear. Here, we report our mutational analysis of each of these residues to examine their functionality in oligomerization, DNA binding, ATP hydrolysis, and double-stranded DNA (dsDNA) unwinding. All mutants were capable of oligomerization in the presence of ATP and could bind single-stranded DNA and dsDNA. ATP hydrolysis was substantially reduced for proteins with mutations of residues making direct contact with the gamma-phosphate of ATP or the apical water molecule. A potentially noncanonical "arginine finger" residue, K418, is critical for ATP hydrolysis and helicase function, suggesting a new type of arginine finger role by a lysine in the stabilization of the transition state during ATP hydrolysis. Interestingly, our mutational data suggest that the positive- and negative-charge interactions in the uniquely observed residue pairs, R498/D499 and R540/D502, in large-T-antigen helicase are critically involved in the transfer of energy of ATP binding/hydrolysis to DNA unwinding.     

Hydrolysis at One of the Two Nucleotide-binding Sites Drives the Dissociation of ATP-binding Cassette Nucleotide-binding Domain Dimers

The functional unit of ATP-binding cassette (ABC) transporters consists of two transmembrane domains and two nucleotide-binding domains (NBDs). ATP binding elicits association of the two NBDs, forming a dimer in a head-to-tail arrangement, with two nucleotides “sandwiched” at the dimer interface. Each of the two nucleotide-binding sites is formed by residues from the two NBDs. We recently found that the prototypical NBD MJ0796 from Methanocaldococcus jannaschii dimerizes in response to ATP binding and dissociates completely following ATP hydrolysis. However, it is still unknown whether dissociation of NBD dimers follows ATP hydrolysis at one or both nucleotide-binding sites. Here, we used luminescence resonance energy transfer to study heterodimers formed by one active (donor-labeled) and one catalytically defective (acceptor-labeled) NBD. Rapid mixing experiments in a stop-flow chamber showed that NBD heterodimers with one functional and one inactive site dissociated at a rate indistinguishable from that of dimers with two hydrolysis-competent sites. Comparison of the rates of NBD dimer dissociation and ATP hydrolysis indicated that dissociation followed hydrolysis of one ATP. We conclude that ATP hydrolysis at one nucleotide-binding site drives NBD dimer dissociation.     

Mitochondrial ATPase subunit 6 and cytochrome B gene polymorphisms in young obese adults.

We hypothesized that the mutational strand asymmetry is more strongly exerted upon the mitochondrial cytochrome b (Cytb) gene, which is distant from the origin of the light-strand replication (Ori(L)), than upon the ATPase subunit 6 (ATP6) gene, which is close to the Ori(L). To test this hypothesis, we determined the sequences of these two genes in 96 Japanese young obese adults. The frequency of G-->A transitions was significantly higher than that of C-->T transitions in the Cytb gene, whereas the frequencies of G-->A and C-->T transitions were not significantly different in the ATP6 gene. The marked mutational strand asymmetry in the Cytb gene can be explained by the deamination of C to uracil in the long single-stranded state of the heavy strand during replication. The ratio of the nonsynonymous substitutions at the second codon positions to those at the first codon positions was significantly lower in the Cytb gene than in the ATP6 gene. The physicochemical differences between the standard and the replaced amino acid residues were significantly smaller in the Cytb gene than in ATP6 one. The present study indicates that amino acid sequences are less variable for Cytb than for ATP6 in spite of the strong mutational strand asymmetry for the Cytb gene.     

“Fuzzy oil drop” model applied to individual small proteins built of 70 amino acids

The proteins composed of short polypeptides (about 70 amino acid residues) representing the following functional groups (according to PDB notation): growth hormones, serine protease inhibitors, antifreeze proteins, chaperones and proteins of unknown function, were selected for structural and functional analysis. Classification based on the distribution of hydrophobicity in terms of deficiency/excess as the measure of structural and functional specificity is presented. The experimentally observed distribution of hydrophobicity in the protein body is compared to the idealized one expressed by a three-dimensional Gauss function. The differences between these two distributions reveal the specificity of structural/functional characteristics of the protein. The residues of hydrophobicity deficiency versus the idealized distribution are assumed to indicate cavities with the potential to bind ligands, while the residues of hydrophobicity excess are interpreted as potentially participating in protein-protein complexation. The distribution of hydrophobicity irregularity seems to be specific for particular structures and functions of proteins. A comparative analysis of such profiles is carried out to identify the potential biological activity of proteins of unknown function.     

Identification of active site residues in mevalonate diphosphate decarboxylase: implications for a family of phosphotransferases

A combination of sequence homology analyses of mevalonate diphosphate decarboxylase (MDD) proteins and structural information for MDD leads to the hypothesis that Asp 302 and Lys 18 are active site residues in MDD. These residues were mutated to replace acidic/basic side chains and the mutant proteins were isolated and characterized. Binding and competitive displacement studies using trinitrophenyl-ATP, a fluorescent analog of substrate ATP, indicate that these mutant enzymes (D302A, D302N, K18M) retain the ability to stoichiometrically bind nucleotide triphosphates at the active site. These observations suggest the structural integrity of the mutant MDD proteins. The functional importance of mutated residues was evaluated by kinetic analysis. The 10(3) and 10(5)-fold decreases in k(cat) observed for the Asp 302 mutants (D302N and D302A, respectively) support assignment of a crucial catalytic role to Asp 302. A 30-fold decrease in activity and a 16-fold inflation of the K(m) for ATP is documented for the K18M mutant, indicating that Lys 18 influences the active site but is not crucial for reaction chemistry. Demonstration of the influence of conserved aspartate 302 appears to represent the first documentation of the functional importance of a residue in the MDD catalytic site and affords insight into phosphotransferase reactions catalyzed by a variety of enzymes in the galactokinase, homoserine kinase, mevalonate kinase, phosphom-evalonate kinase (GHMP kinase) family.     

Access to the carbamate tunnel of carbamoyl phosphate synthetase

The X-ray crystal structure of carbamoyl phosphate synthetase (CPS) from Escherichia coli revealed the existence of a molecular tunnel that has been proposed to facilitate the translocation of reaction intermediates between remotely located active sites. Five highly conserved glutamate residues, including Glu-25, Glu-383, Glu-577, Glu-604, and Glu-916, are close together in two clusters in the interior wall of the molecular tunnel that enables the intermediate carbamate to migrate from the site of synthesis to the site of utilization. Two arginines, Arg-306 and Arg-848, are located at either end of the carbamate tunnel and participate in the binding of ATP at each of the two active sites within the large subunit of CPS. The mutation of Glu-25 or Glu-577 results in a diminution in the overall rate of carbamoyl phosphate formation. Similar effects are observed upon mutation of Arg-306 and Arg-848 to alanine residues. The conserved glutamate and arginine residues may function in concert with one another to control entry of carbamate into the tunnel prior to phosphorylation to carbamoyl phosphate. The electrostatic environment of tunnel interior may help to stabilize the tunnel architecture and prevent decomposition of carbamate through protonation.     

The use of double mutants to detect structural changes in the active site of the tyrosyl-tRNA synthetase (Bacillus stearothermophilus)

In a previous study, a mutant of tyrosyl-tRNA synthetase in which a threonine residue (Thr51) was converted to proline dramatically improved the affinity of the enzyme for its ATP substrate. How does Pro51 improve the enzyme's affinity for ATP? A priori, Pro51 might interact directly with the ATP, or it might distort the polypeptide backbone and thereby force new or improved contacts elsewhere from the enzyme to ATP. By making mutants of the Pro51 enzyme at two residues that make hydrogen bonds to the ATP substrate, we show that Pro51 greatly improves the strength of one of these contacts. Thus the propagation of a structural change in an enzyme induced by mutation may be detected by the introduction of further mutations.     

Structural dynamics of the DnaK-peptide complex

The molecular chaperone DnaK recognizes and binds substrate proteins via a stretch of seven amino acid residues that is usually only exposed in unfolded proteins. The binding kinetics are regulated by the nucleotide state of DnaK, which alternates between DnaK.ATP (fast exchange) and DnaK.ADP (slow exchange). These two forms cycle with a rate mainly determined by the ATPase activity of DnaK and nucleotide exchange. The different substrate binding properties of DnaK are mainly attributed to changes of the position and mobility of a helical region in the C-terminal peptide-binding domain, the so-called LID. It closes the peptide-binding pocket and thus makes peptide binding less dynamic in the ADP-bound state, but does not (strongly) interact with peptides directly. Here, we address the question if nucleotide-dependent structural changes may be observed in the peptide-binding region that could also be connected to peptide binding kinetics and more importantly could induce structural changes in peptide stretches using the energy available from ATP hydrolysis. Model peptides containing two cysteine residues at varying positions were derived from the structurally well-documented peptide NRLLLTG and labelled with electron spin sensitive probes. Measurements of distances and mobilities of these spin labels by electron paramagnetic resonance spectroscopy (EPR) of free peptides or peptides bound to the ATP and ADP-state of DnaK, respectively, showed no significant changes of mobility nor distance of the two labels. This indicates that no structural changes that could be sensed by the probes at the position of central leucine residues located in the center of the binding region occur due to different nucleotide states. We conclude from these studies that the ATPase activity of DnaK is not connected to structural changes of the peptide-binding pocket but rather only has an effect on the LID domain or other further remote residues.     

The ATP hydrolysis cycle of the nucleotide-binding domain of the mitochondrial ATP-binding cassette transporter Mdl1p

The ABC transporter Mdl1p, a structural and functional homologue of the transporter associated with antigen processing (TAP) plays an important role in intracellular peptide transport from the mitochondrial matrix of Saccharomyces cerevisiae. To characterize the ATP hydrolysis cycle of Mdl1p, the nucleotide-binding domain (NBD) was overexpressed in Escherichia coli and purified to homogeneity. The isolated NBD was active in ATP binding and hydrolysis with a turnover of 25 ATP per minute and a Km of 0.6 mm and did not show cooperativity in ATPase activity. However, the ATPase activity was non-linearly dependent on protein concentration (Hill coefficient of 1.7), indicating that the functional state is a dimer. Dimeric catalytic transition states could be trapped either by incubation with orthovanadate or beryllium fluoride, or by mutagenesis of the NBD. The nucleotide composition of trapped intermediate states was determined using [alpha-32P]ATP and [gamma-32P]ATP. Three different dimeric intermediate states were isolated, containing either two ATPs, one ATP and one ADP, or two ADPs. Based on these experiments, it was shown that: (i) ATP binding to two NBDs induces dimerization, (ii) in all isolated dimeric states, two nucleotides are present, (iii) phosphate can dissociate from the dimer, (iv) both nucleotides are hydrolyzed, and (v) hydrolysis occurs in a sequential mode. Based on these data, we propose a processive-clamp model for the catalytic cycle in which association and dissociation of the NBDs depends on the status of bound nucleotides.     

ATP binding to two sites is necessary for dimerization of nucleotide-binding domains of ABC proteins

ATP binding cassette (ABC) transporters have a functional unit formed by two transmembrane domains and two nucleotide binding domains (NBDs). ATP-bound NBDs dimerize in a head-to-tail arrangement, with two nucleotides sandwiched at the dimer interface. Both NBDs contribute residues to each of the two nucleotide-binding sites (NBSs) in the dimer. In previous studies, we showed that the prototypical NBD MJ0796 from Methanocaldococcus jannaschii forms ATP-bound dimers that dissociate completely following hydrolysis of one of the two bound ATP molecules. Since hydrolysis of ATP at one NBS is sufficient to drive dimer dissociation, it is unclear why all ABC proteins contain two NBSs. Here, we used luminescence resonance energy transfer (LRET) to study ATP-induced formation of NBD homodimers containing two NBSs competent for ATP binding, and NBD heterodimers with one active NBS and one binding-defective NBS. The results showed that binding of two ATP molecules is necessary for NBD dimerization. We conclude that ATP hydrolysis at one nucleotide-binding site drives NBD dissociation, but two binding sites are required to form the ATP-sandwich NBD dimer necessary for hydrolysis.     

Interactions of caged-ATP and photoreleased ATP with alkaline phosphatase

Photolytic release of ATP from inactive P(3)-[1-(2-nitrophenyl)]ethyl ester of ATP (NPE-caged ATP) provides a means to reveal molecular interactions between nucleotide and enzyme by using infrared spectroscopy. Reaction-induced infrared difference spectra of bovine intestinal alkaline phosphatase (BIAP) and of NPE-caged ATP revealed small structural alterations on the peptide backbone affecting one or two amino-acid residues. After photorelease of ATP, the substrate could be hydrolyzed sequentially by the enzyme producing three Pi, adenosine, and the photoproduct nitrosoacetophenone. It was concluded that NPE-caged ATP could bind to BIAP prior to the photolytic cleavage of ATP and that Pi could interact with BIAP after photolysis of NPE-caged ATP and hydrolysis, yielding infrared spectra with distinct structure changes of BIAP. This suggests that the molecular mechanism of ATP hydrolysis by BIAP involved small structural adjustments of the peptide backbone in the vicinity of the active site during ATP hydrolysis which continued during Pi binding.     

Active site mapping of yeast aspartyl-tRNA synthetase by in vivo selection of enzyme mutations lethal for cell growth.

The active site of yeast aspartyl-tRNA synthetase has been characterised by structural and functional approaches. However, residues or structural elements that indirectly contribute to the active site organisation have still to be described. They have not been assessed by simple analysis of structural data or site-directed mutagenesis analysis, since rational targetting has proven difficult. Here, we attempt to locate these functional features by using a genetic selection method to screen a randomly mutated yeast AspRS library for mutations lethal for cell growth. This approach is an efficient method to map the active site residues, since of the 23 different mutations isolated, 13 are in direct contact with the substrates. Most of the mutations are located in a 15 A radius sphere around the ATP molecule, where they affect the very conserved residues of the class-defining motifs. The results also showed the importance of the dimer interface for the enzyme activity: a single mutation of the invariant proline residue of motif 1 led to a structural defect inactivating the enzyme. From in vivo complementation studies it appeared that the enzyme activity can be recovered by reconstitution of an intact interface through the formation of heterodimers. We also show that a single mutation affecting an interaction with G34 of the tRNA can inactivate the enzyme by inducing a relaxation of the tRNA recognition specificity. Finally, several mutants whose functional importance could not be assessed from the structural data were selected, demonstrating the importance of this type of approach in the context of a structure-function relationship study.     

Structural Models of Human eEF1A1 and eEF1A2 Reveal Two Distinct Surface Clusters of Sequence Variation and Potential Differences in Phosphorylation

Background

Despite sharing 92% sequence identity, paralogous human translation elongation factor 1 alpha-1 (eEF1A1) and elongation factor 1 alpha-2 (eEF1A2) have different but overlapping functional profiles. This may reflect the differential requirements of the cell-types in which they are expressed and is consistent with complex roles for these proteins that extend beyond delivery of tRNA to the ribosome.

Methodology/Principal Findings

To investigate the structural basis of these functional differences, we created and validated comparative three-dimensional (3-D) models of eEF1A1 and eEF1A2 on the basis of the crystal structure of homologous eEF1A from yeast. The spatial location of amino acid residues that vary between the two proteins was thereby pinpointed, and their surface electrostatic and lipophilic properties were compared. None of the variations amongst buried amino acid residues are judged likely to have a major structural effect on the protein fold, or to affect domain-domain interactions. Nearly all the variant surface-exposed amino acid residues lie on one face of the protein, in two proximal but distinct sub-clusters. The result of previously performed mutagenesis in yeast may be interpreted as confirming the importance of one of these clusters in actin-bundling and filament disorganization. Interestingly, some variant residues lie in close proximity to, and in a few cases show differences in interactions with, residues previously inferred to be directly involved in binding GTP/GDP, eEF1Bα and aminoacyl-tRNA. Additional sequence-based predictions, in conjunction with the 3-D models, reveal likely differences in phosphorylation sites that could reconcile some of the functional differences between the two proteins.

Conclusions

The revelation and putative functional assignment of two distinct sub-clusters on the surface of the protein models should enable rational site-directed mutagenesis, including homologous reverse-substitution experiments, to map surface binding patches onto these proteins. The predicted variant-specific phosphorylation sites also provide a basis for experimental verification by mutagenesis. The models provide a structural framework for interpretation of the resulting functional analysis.     

A Conserved Motif in Intracellular Loop 1 Stabilizes the Outward-Facing Conformation of TmrAB

The ATP binding cassette (ABC) family of transporters moves small molecules (lipids, sugars, peptides, drugs, nutrients) across membranes in nearly all organisms. Transport activity requires conformational switching between inward-facing and outward-facing states driven by ATP-dependent dimerization of two nucleotide binding domains (NBDs). The mechanism that connects ATP binding and hydrolysis in the NBDs to conformational changes in a substrate binding site in the transmembrane domains (TMDs) is currently an outstanding question. Here we use sequence coevolution analyses together with biochemical characterization to investigate the role of a highly conserved region in intracellular loop 1 we define as the GRD motif in coordinating domain rearrangements in the heterodimeric peptide exporter from Thermus thermophilus, TmrAB. Mutations in the GRD motif alter ATPase activity as well as transport. Disulfide crosslinking, evolutionary trace, and evolutionary coupling analysis reveal that these effects are likely due to the destabilization of a network in which the GRD motif in TmrA bridges residues of the Q-loop, X-loop, and ABC motif in the NBDs to residues in the TmrAB peptide substrate binding site, thus providing an avenue for conformational coupling. We further find that disruption of this network in TmrA versus TmrB has different functional consequences, hinting at an intrinsic asymmetry in heterodimeric ABC transporters extending beyond that of the NBDs. These results support a mechanism in which the GRD motifs help coordinate a transition to an outward open conformation, and each half of the transporter likely plays a different role in the conformational cycle of TmrAB.     

Mutation of recombinant catalytic subunit alpha of the protein kinase CK2 that affects catalytic efficiency and specificity

In order to understand better the structural and functional relations between protein kinase CK2 catalytic subunit, the triphosphate moiety of ATP, the catalytic metal and the peptidic substrate, we built a structural model of Yarrowia lipolytica protein kinase CK2 catalytic subunit using the recently solved three-dimensional structure of the maize enzyme and the structure of cAMP-dependent protein kinase peptidic inhibitor (1CDK) as templates. The overall structure of the catalytic subunit is close to the structure solved by Niefind et al. It comprises two lobes, which move relative to each other. The peptide used as substrate is tightly bound to the enzyme, at specific locations. Molecular dynamic calculations in combination with the study of the structural model led us to identify amino acid residues close to the triphosphate moiety of ATP and a residue sufficiently far from the peptide that could be mutated so as to modify the specificity of the enzyme. Site-directed mutagenesis was used to replace by charged residues both glycine-48, a residue located within the glycine-rich loop, involved in binding of ATP phosphate moiety, and glycine-177, a residue close to the active site. Kinetic properties of purified wild-type and mutated subunits were studied with respect to ATP, MgCl(2) and protein kinase CK2 specific peptide substrates. The catalytic efficiency of the G48D mutant increased by factors of 4 for ATP and 17.5 for the RRRADDSDDDDD peptide. The mutant G48K had a low activity with ATP and no detectable activity with peptide substrates and was also inhibited by magnesium. An increased velocity of ADP release by G48D and the building of an electrostatic barrier between ATP and the peptidic substrate in G48K could explain these results. The kinetic properties of the mutant G177K with ATP were not affected, but the catalytic efficiency for the RRRADDSDDDDD substrate increased sixfold. Lysine 177 could interact with the lysine-rich cluster involved in the specificity of protein kinase CK2 towards acidic substrate, thereby increasing its activity.     

The crystal structure of a novel bacterial adenylyltransferase reveals half of sites reactivity

Phosphopantetheine adenylyltransferase (PPAT) is an essential enzyme in bacteria that catalyses a rate-limiting step in coenzyme A (CoA) biosynthesis, by transferring an adenylyl group from ATP to 4'-phosphopantetheine, yielding dephospho-CoA (dPCoA). Each phosphopantetheine adenylyltransferase (PPAT) subunit displays a dinucleotide-binding fold that is structurally similar to that in class I aminoacyl-tRNA synthetases. Superposition of bound adenylyl moieties from dPCoA in PPAT and ATP in aminoacyl-tRNA synthetases suggests nucleophilic attack by the 4'-phosphopantetheine on the alpha-phosphate of ATP. The proposed catalytic mechanism implicates transition state stabilization by PPAT without involving functional groups of the enzyme in a chemical sense in the reaction. The crystal structure of the enzyme from Escherichia coli in complex with dPCoA shows that binding at one site causes a vice-like movement of active site residues lining the active site surface. The mode of enzyme product formation is highly concerted, with only one trimer of the PPAT hexamer showing evidence of dPCoA binding. The homologous active site attachment of ATP and the structural distribution of predicted sequence-binding motifs in PPAT classify the enzyme as belonging to the nucleotidyltransferase superfamily.     

Functional analysis of the glycero-manno-heptose 7-phosphate kinase domain from the bifunctional HldE protein, which is involved in ADP-L-glycero-D-manno-heptose biosynthesis

The core oligosaccharide component of the lipopolysaccharide can be subdivided into inner and outer core regions. In Escherichia coli, the inner core consists of two 3-deoxy-d-manno-octulosonic acid and three glycero-manno-heptose residues. The HldE protein participates in the biosynthesis of ADP-glycero-manno-heptose precursors used in the assembly of the inner core. HldE comprises two functional domains: an N-terminal region with homology to the ribokinase superfamily (HldE1 domain) and a C-terminal region with homology to the cytidylyltransferase superfamily (HldE2 domain). We have employed the structure of the E. coli ribokinase as a template to model the HldE1 domain and predict critical amino acids required for enzyme activity. Mutation of these residues renders the protein inactive as determined in vivo by functional complementation analysis. However, these mutations did not affect the secondary or tertiary structure of purified HldE1, as judged by fluorescence spectroscopy and circular dichroism. Furthermore, in vivo coexpression of wild-type, chromosomally encoded HldE and mutant HldE1 proteins with amino acid substitutions in the predicted ATP binding site caused a dominant negative phenotype as revealed by increased bacterial sensitivity to novobiocin. Copurification experiments demonstrated that HldE and HldE1 form a complex in vivo. Gel filtration chromatography resulted in the detection of a dimer as the predominant form of the native HldE1 protein. Altogether, our data support the notions that the HldE functional unit is a dimer and that structural components present in each HldE1 monomer are required for enzymatic activity.