Self-association and conformational variation of NS5A domain 1 of hepatitis C virus.

Direct-acting antivirals (DAAs) targeting the non-structural 5A (NS5A) protein of the hepatitis C virus (HCV) are crucial drugs that have shown exceptional clinical success in patients. However, their mode of action (MoA) remains unclear, and drug-resistant HCV strains are rapidly emerging. It is critical to characterize the behaviour of the NS5A protein in solution, which can facilitate the development of new classes of inhibitors or improve the efficacy of the currently available DAAs. Using biophysical methods, including dynamic light scattering, size exclusion chromatography and chemical cross-linking experiments, we showed that the NS5A domain 1 from genotypes 1b and 1a of the HCV intrinsically self-associated and existed as a heterogeneous mixture in solution. Interestingly, the NS5A domain 1 from genotypes 1b and 1a exhibited different dynamic equilibria of monomers to higher-order structures. Using small-angle X-ray scattering, we studied the structural dynamics of the various states of the NS5A domain 1 in solution. We also tested the effect of daclatasvir (DCV), the most prominent DAA, on self-association of the wild and DCV-resistant mutant (Y93H) NS5A domain 1 proteins, and demonstrated that DCV induced the formation of large and irreversible protein aggregates that eventually precipitated out. This study highlights the conformational variability of the NS5A domain 1 of HCV, which may be an intrinsic structural behaviour of the HCV NS5A domain 1 in solution.

Structural and mechanistic insights into Mycothiol Disulphide Reductase and the Mycoredoxin-1-alkylhydroperoxide reductase E assembly of Mycobacterium tuberculosis.

Mycobacteria employ a versatile machinery of the mycothiol-dependent system, containing the proteins mycothiol disulfide reductase (Mtr), the oxido-reductase Mycoredoxin-1 (Mrx-1) and the alkyl-hydroperoxide subunit E (AhpE). The mycothiol-dependent protein ensemble regulates the balance of oxidized-reduced mycothiol, to ensure a reductive intracellular environment for optimal functioning of its proteins even upon exposure to oxidative stress. Here, we determined the first low-resolution solution structure of Mycobacterium tuberculosis Mtr (MtMtr) derived from small-angle X-ray scattering data, which provides insight into its dimeric state. The solution shape reveals the two NADPH-binding domains inside the dimeric MtMtr in different conformations. NMR-titration shows that the MtMtr-MtMrx-1 interaction is characterized by a fast exchange regime and critical residues involved in the protein-protein interaction were identified. Using NMR spectroscopy and docking studies, the epitopes of MtMrx-1 and MtAhpE interaction are described, shedding new light into the interaction interface and mechanism of action. Finally, the essential residue of MtMrx-1 identified in the interaction with MtMtr and MtAhpE form a platform for structure-guided drug design against the versatile enzyme machinery of the mycothiol-dependent system inside M. tuberculosis.

Novel insights into the vancomycin-resistant Enterococcus faecalis (V583) alkylhydroperoxide reductase subunit F.

The ability of the vancomycin-resistant Enterococcus faecalis (V583) to restore redox homeostasis via antioxidant defense mechanism is of importance, and knowledge into this defense is essential to understand its antibiotic-resistance and survival in hosts. The flavoprotein disulfide reductase AhpR, composed of the subunits AhpC and AhpF, represents one such vital part. Circular permutation was found to be a feature of the AhpF protein family. E. faecalis (V583) AhpF (EfAhpF) appears to be a representative of a minor subclass of this family, the typically N-terminal two-fold thioredoxin-like domain (NTD_N/C) is located at the C-terminus, whereas the pyridine nucleotide-disulfide oxidoreductase domain is encoded in the N-terminal part of its sequence. In EfAhpF, these two domains are connected via an unusually long linker region providing optimal communication between both domains. EfAhpF forms a dimer in solution similar to Escherichia coli AhpF. The crystallographic 2.3Å resolution structure of the NTD_N/C domain reveals a unique loop-helix stretch (409ILKDTEPAKELLYGIEKM426) not present in homologue domains of other prokaryotic AhpFs. Deletion of the unique 415PAKELLY421-helix or of 415PAKELL420 affects protein stability or attenuates peroxidase activity. Furthermore, mutation of Y421 is described to be essential for E. faecalis AhpF's optimal NADH-oxidative activity.

Crystal structure of subunits D and F in complex gives insight into energy transmission of the eukaryotic V-ATPase from Saccharomyces cerevisiae.

Eukaryotic V1VO-ATPases hydrolyze ATP in the V1 domain coupled to ion pumping in VO. A unique mode of regulation of V-ATPases is the reversible disassembly of V1 and VO, which reduces ATPase activity and causes silencing of ion conduction. The subunits D and F are proposed to be key in these enzymatic processes. Here, we describe the structures of two conformations of the subunit DF assembly of Saccharomyces cerevisiae (ScDF) V-ATPase at 3.1 Å resolution. Subunit D (ScD) consists of a long pair of α-helices connected by a short helix ((79)IGYQVQE(85)) as well as a ß-hairpin region, which is flanked by two flexible loops. The long pair of helices is composed of the N-terminal α-helix and the C-terminal helix, showing structural alterations in the two ScDF structures. The entire subunit F (ScF) consists of an N-terminal domain of four ß-strands (ß1-ß4) connected by four α-helices (α1-α4). α1 and ß2 are connected via the loop (26)GQITPETQEK(35), which is unique in eukaryotic V-ATPases. Adjacent to the N-terminal domain is a flexible loop, followed by a C-terminal α-helix (α5). A perpendicular and extended conformation of helix α5 was observed in the two crystal structures and in solution x-ray scattering experiments, respectively. Fitted into the nucleotide-bound A3B3 structure of the related A-ATP synthase from Enterococcus hirae, the arrangements of the ScDF molecules reflect their central function in ATPase-coupled ion conduction. Furthermore, the flexibility of the terminal helices of both subunits as well as the loop (26)GQITPETQEK(35) provides information about the regulatory step of reversible V1VO disassembly.

Crystallographic and solution studies of NAD(+)- and NADH-bound alkylhydroperoxide reductase subunit F (AhpF) from Escherichia coli provide insight into sequential enzymatic steps.

Redox homeostasis is significant for the survival of pro- and eukaryotic cells and is crucial for defense against reactive oxygen species like superoxide and hydrogen peroxide. In Escherichia coli, the reduction of peroxides occurs via the redox active disulfide center of the alkyl hydroperoxide reductase C subunit (AhpC), whose reduced state becomes restored by AhpF. The 57kDa EcAhpF contains an N-terminal domain (NTD), which catalyzes the electron transfer from NADH via an FAD of the C-terminal domain into EcAhpC. The NTD is connected to the C-terminal domain via a linker. Here, the first crystal structure of E. coli AhpF bound with NADH and NAD(+) has been determined at 2.5Å and 2.4Å resolution, respectively. The NADH-bound form of EcAhpF reveals that the NADH-binding domain is required to alter its conformation to bring a bound NADH to the re-face of the isoalloxazine ring of the flavin, and thereby render the NADH-domain dithiol center accessible to the NTD disulfide center for electron transfer. The NAD(+)-bound form of EcAhpF shows conformational differences for the nicotinamide end moieties and its interacting residue M467, which is proposed to represent an intermediate product-release conformation. In addition, the structural alterations in EcAhpF due to NADH- and NAD(+)-binding in solution are shown by small angle X-ray scattering studies. The EcAhpF is revealed to adopt many intermediate conformations in solution to facilitate the electron transfer from the substrate NADH to the C-terminal domain, and subsequently to the NTD of EcAhpF for the final step of AhpC reduction.

ATP synthases from archaea: the beauty of a molecular motor.

Archaea live under different environmental conditions, such as high salinity, extreme pHs and cold or hot temperatures. How energy is conserved under such harsh environmental conditions is a major question in cellular bioenergetics of archaea. The key enzymes in energy conservation are the archaeal A1AO ATP synthases, a class of ATP synthases distinct from the F1FO ATP synthase ATP synthase found in bacteria, mitochondria and chloroplasts and the V1VO ATPases of eukaryotes. A1AO ATP synthases have distinct structural features such as a collar-like structure, an extended central stalk, and two peripheral stalks possibly stabilizing the A1AO ATP synthase during rotation in ATP synthesis/hydrolysis at high temperatures as well as to provide the storage of transient elastic energy during ion-pumping and ATP synthesis/-hydrolysis. High resolution structures of individual subunits and subcomplexes have been obtained in recent years that shed new light on the function and mechanism of this unique class of ATP synthases. An outstanding feature of archaeal A1AO ATP synthases is their diversity in size of rotor subunits and the coupling ion used for ATP synthesis with H(+), Na(+) or even H(+) and Na(+) using enzymes. The evolution of the H(+) binding site to a Na(+) binding site and its implications for the energy metabolism and physiology of the cell are discussed.

Extended structure of rat islet amyloid polypeptide in solution.

The process of islet amyloid polypeptide (IAPP) formation and the prefibrillar oligomers are supposed to be one of the pathogenic agents causing pancreatic ß-cell dysfunction. The human IAPP (hIAPP) aggregates easily and therefore, it is difficult to characterize its structural features by standard biophysical tools. The rat version of IAPP (rIAPP) that differs by six amino acids when compared with hIAPP, is not prone to aggregation and does not form amyloid fibrils. Similar to hIAPP it also demonstrates random-coiled nature in solution. The structural propensity of rIAPP has been studied as a hIAPP mimic in recent works. However, the overall shape of it in solution still remains elusive. Using small angle X-ray scattering (SAXS) measurements combined with nuclear magnetic resonance (NMR) and molecular dynamics simulations (MD) the solution structure of rIAPP was studied. An unambiguously extended structural model with a radius of gyration of 1.83 nm was determined from SAXS data. Consistent with previous studies, an overall random-coiled feature with residual helical propensity in the N-terminus was confirmed. Combined efforts are necessary to unambiguously resolve the structural features of intrinsic disordered proteins.

Crystal and NMR structures give insights into the role and dynamics of subunit F of the eukaryotic V-ATPase from Saccharomyces cerevisiae.

Subunit F of V-ATPases is proposed to undergo structural alterations during catalysis and reversible dissociation from the V1VO complex. Recently, we determined the low resolution structure of F from Saccharomyces cerevisiae V-ATPase, showing an N-terminal egg shape, connected to a C-terminal hook-like segment via a linker region. To understand the mechanistic role of subunit F of S. cerevisiae V-ATPase, composed of 118 amino acids, the crystal structure of the major part of F, F(1-94), was solved at 2.3 Å resolution. The structural features were confirmed by solution NMR spectroscopy using the entire F subunit. The eukaryotic F subunit consists of the N-terminal F(1-94) domain with four-parallel ß-strands, which are intermittently surrounded by four α-helices, and the C terminus, including the α5-helix encompassing residues 103 to 113. Two loops (26)GQITPETQEK(35) and (60)ERDDI(64) are described to be essential in mechanistic processes of the V-ATPase enzyme. The (26)GQITPETQEK(35) loop becomes exposed when fitted into the recently determined EM structure of the yeast V1VO-ATPase. A mechanism is proposed in which the (26)GQITPETQEK(35) loop of subunit F and the flexible C-terminal domain of subunit H move in proximity, leading to an inhibitory effect of ATPase activity in V1. Subunits D and F are demonstrated to interact with subunit d. Together with NMR dynamics, the role of subunit F has been discussed in the light of its interactions in the processes of reversible disassembly and ATP hydrolysis of V-ATPases by transmitting movements of subunit d and H of the VO and V1 sector, respectively.

Variations of subunit {varepsilon} of the Mycobacterium tuberculosis F1Fo ATP synthase and a novel model for mechanism of action of the tuberculosis drug TMC207.

The subunit ε of bacterial F(1)F(O) ATP synthases plays an important regulatory role in coupling and catalysis via conformational transitions of its C-terminal domain. Here we present the first low-resolution solution structure of ε of Mycobacterium tuberculosis (Mtε) F(1)F(O) ATP synthase and the nuclear magnetic resonance (NMR) structure of its C-terminal segment (Mtε(103-120)). Mtε is significantly shorter (61.6 Å) than forms of the subunit in other bacteria, reflecting a shorter C-terminal sequence, proposed to be important in coupling processes via the catalytic ß subunit. The C-terminal segment displays an α-helical structure and a highly positive surface charge due to the presence of arginine residues. Using NMR spectroscopy, fluorescence spectroscopy, and mutagenesis, we demonstrate that the new tuberculosis (TB) drug candidate TMC207, proposed to bind to the proton translocating c-ring, also binds to Mtε. A model for the interaction of TMC207 with both ε and the c-ring is presented, suggesting that TMC207 forms a wedge between the two rotating subunits by interacting with the residues W15 and F50 of ε and the c-ring, respectively. T19 and R37 of ε provide the necessary polar interactions with the drug molecule. This new model of the mechanism of TMC207 provides the basis for the design of new drugs targeting the F(1)F(O) ATP synthase in M. tuberculosis.

Solution structure of subunit γ (γ(1-204)) of the Mycobacterium tuberculosis F-ATP synthase and the unique loop of γ(165-178), representing a novel TB drug target.

Tuberculosis, caused by the strain Mycobacterium tuberculosis, is in focus of interest due to the emergence of multi- and extensive drug-resistant TB strains. The F(1)F(O) ATP synthase is one of the essential enzymes in energy requirement of both proliferating aerobic and hypoxic dormant stage of mycobacterium life cycle, and therefore a potential TB drug target. Subunit γ of F-ATP synthases plays an important role in coupling and catalysis via conformational transitions of its N- and C-termini as well as the bottom segment of the globular domain of γ, which is in close proximity to the rotating and ion-pumping c-ring. Here we describe the first production, purification and low resolution solution structure of subunit γ (γ(1-204), Mtγ(1-204)) of the M. tuberculosis F-ATP synthase. Mtγ(1-204) is a pear-like shaped protein with a molecular weight of 23 ± 2 kDa. Protein sequence analysis of Mtγ revealed differences in the amino acid composition to γ subunits from other sources, in particular the presence of a unique stretch of 13 amino acid residues (Mtγ(165-178)). NMR studies showed that Mtγ(165-178) forms a loop of polar residues. Mtγ(165-178) has been aligned at the bottom of the globular domain of the Escherichia coli subunit γ, being in close vicinity to the polar residues R41, Q42, E44 and Q46 (M. tuberculosis nomenclature) of the c-ring. The putative role(s) of Mtγ(165-178) in coupling and as a potential drug target are discussed.

Relevance of the conserved histidine and asparagine residues in the phosphate-binding loop of the nucleotide binding subunit B of A1A0 ATP synthases.

The nucleotide binding sites in A-ATP synthases are located at the interfaces of subunit A and B, which is proposed to play a regulatory role. Differential binding of MgATP and -ADP to subunit B has been described, which does not exist in the related α and B subunits of F-ATP synthases and V-ATPases, respectively. The conserved phosphate loop residues, histidine and asparagine, of the A-ATP synthase subunit B have been proposed to be essential for γ-phosphate interaction. To investigate the role of these conserved P-loop residues in nucleotide-binding, subunit B residues H156 and N157 of the Methanosarcina mazei Gö1 A-ATP synthase were separately substituted with alanine. In addition, N157 was mutated to threonine, because it is the corresponding amino acid in the P-loop of F-ATP synthase subunit α. The structures of the subunit B mutants H156A, N157A/T were solved up to a resolution of 1.75 and 1.7 Å. The binding constants for MgATP and -ADP were determined, demonstrating that the H156A and N157A mutants have a preference to the nucleotide over the wild type and N157T proteins. Importantly, the ability to distinguish MgATP or -ADP was lost, demonstrating that the histidine and asparagine residues are crucial for nucleotide differentiation in subunit B. The structures reveal that the enhanced binding of the alanine mutants is attributed to the increased accessibility of the nucleotide binding cavity, explaining that the structural arrangement of the conserved H156 and N157 define the nucleotide-binding characteristics of the regulatory subunit B of A-ATP synthases.

Crystallization and preliminary X-ray crystallographic analysis of subunit F (F(1-94)), an essential coupling subunit of the eukaryotic V(1)V(O)-ATPase from Saccharomyces cerevisiae.

V-ATPases are very complex multi-subunit enzymes which function as proton-pumping rotary nanomotors. The rotary and coupling subunit F (F(1-94)) was crystallized by the hanging-drop vapour-diffusion method. The native crystals diffracted to a resolution of 2.64 Å and belonged to space group C222(1), with unit-cell parameters a = 47.21, b = 160.26, c = 102.49 Å. The selenomethionyl form of the F(1-94) I69M mutant diffracted to a resolution of 2.3 Å and belonged to space group C222(1), with unit-cell parameters a = 47.22, b = 160.83, c = 102.74 Å. Initial phasing and model building suggested the presence of four molecules in the asymmetric unit.

Engineered tryptophan in the adenine-binding pocket of catalytic subunit A of A-ATP synthase demonstrates the importance of aromatic residues in adenine binding, forming a tool for steady-state and time-resolved fluorescence spectroscopy.

A reporter tryptophan residue was individually introduced by site-directed mutagenesis into the adenine-binding pocket of the catalytic subunit A (F427W and F508W mutants) of the motor protein A(1)A(O) ATP synthase from Pyrococcus horikoshii OT3. The crystal structures of the F427W and F508W mutant proteins were determined to 2.5 and 2.6 Å resolution, respectively. The tryptophan substitution caused the fluorescence signal to increase by 28% (F427W) and 33% (F508W), with a shift from 333 nm in the wild-type protein to 339 nm in the mutant proteins. Tryptophan emission spectra showed binding of Mg-ATP to the F427W mutant with a K(d) of 8.5 µM. In contrast, no significant binding of nucleotide could be observed for the F508W mutant. A closer inspection of the crystal structure of the F427W mutant showed that the adenine-binding pocket had widened by 0.7 Å (to 8.70 Å) in comparison to the wild-type subunit A (8.07 Å) owing to tryptophan substitution, as a result of which it was able to bind ATP. In contrast, the adenine-binding pocket had narrowed in the F508W mutant. The two mutants presented demonstrate that the exact volume of the adenine ribose binding pocket is essential for nucleotide binding and even minor narrowing makes it unfit for nucleotide binding. In addition, structural and fluorescence data confirmed the viability of the fluorescently active mutant F427W, which had ideal tryptophan spectra for future structure-based time-resolved dynamic measurements of the catalytic subunit A of the ATP-synthesizing enzyme A-ATP synthase.

The effect of NBD-Cl in nucleotide-binding of the major subunit alpha and B of the motor proteins F1FO ATP synthase and A1AO ATP synthase.

Subunit alpha of the Escherichia coli F(1)F(O) ATP synthase has been produced, and its low-resolution structure has been determined. The monodispersity of alpha allowed the studies of nucleotide-binding and inhibitory effect of 4-Chloro-7-nitrobenzofurazan (NBD-Cl) to ATP/ADP-binding. Binding constants (K ( d )) of 1.6 microM of bound MgATP-ATTO-647N and 2.9 microM of MgADP-ATTO-647N have been determined from fluorescence correlation spectroscopy data. A concentration of 51 microM and 55 microM of NBD-Cl dropped the MgATP-ATTO-647N and MgADP-ATTO-647N binding capacity to 50% (IC(50)), respectively. In contrast, no effect was observed in the presence of N,N'-dicyclohexylcarbodiimide. As subunit alpha is the homologue of subunit B of the A(1)A(O) ATP synthase, the interaction of NBD-Cl with B of the A-ATP synthase from Methanosarcina mazei Gö1 has also been shown. The data reveal a reduction of nucleotide-binding of B due to NBD-Cl, resulting in IC(50) values of 41 microM and 42 microM for MgATP-ATTO-647N and MgADP-ATTO-647N, respectively.

Crystal and solution structure of the C-terminal part of the Methanocaldococcus jannaschii A1AO ATP synthase subunit E revealed by X-ray diffraction and small-angle X-ray scattering.

The structure of the C-terminus of subunit E (E(101-206)) of Methanocaldococcus jannaschii A-ATP synthase was determined at 4.1 A. E(101-206) consist of a N-terminal globular domain with three alpha-helices and four antiparallel beta-strands and an alpha-helix at the very C-terminus. Comparison of M. jannaschii E(101-206) with the C-terminus E(81-198) subunit E from Pyrococcus horikoshii OT3 revealed that the kink in the C-terminal alpha-helix of E(81-198), involved in dimer formation, is absent in M. jannaschii E(101-206). Whereas a major dimeric surface interface is present between the P. horikoshii E(81-198) molecules in the asymmetric unit, no such interaction could be found in the M. jannaschii E(101-206) molecules. To verify the oligomeric behaviour, the low resolution structure of the recombinant E(85-206) from M. jannaschii was determined using small angle X-ray scattering. Rigid body modeling of two copies of one of the monomer established a fit with a tail to tail arrangement.

Antituberculosis Activity of the Antimalaria Cytochrome bcc Oxidase Inhibitor SCR0911.

The ability to respire and generate adenosine triphosphate (ATP) is essential for the physiology, persistence, and pathogenicity of Mycobacterium tuberculosis, which causes tuberculosis. By employing a lead repurposing strategy, the malarial cytochrome bc1 inhibitor SCR0911 was tested against mycobacteria. Docking studies were carried out to reveal potential binding and to understand the binding interactions with the target, cytochrome bcc. Whole-cell-based and in vitro assays demonstrated the potency of SCR0911 by inhibiting cell growth and ATP synthesis in both the fast- and slow-growing M. smegmatis and M. bovis bacillus Calmette-Guérin, respectively. The variety of biochemical assays and the use of a cytochrome bcc deficient mutant strain validated the cytochrome bcc oxidase as the direct target of the drug. The data demonstrate the broad-spectrum activity of SCR0911 and open the door for structure-activity relationship studies to improve the potency of new mycobacteria specific SCR0911 analogues.

A second transient position of ATP on its trail to the nucleotide-binding site of subunit B of the motor protein A(1)A(0) ATP synthase.

The adenosine triphosphate (ATP) entrance into the nucleotide-binding subunits of ATP synthases is a puzzle. In the previously determined structure of subunit B mutant R416W of the Methanosarcina mazei Gö1 A-ATP synthase one ATP could be trapped at a transition position, close to the phosphate-binding loop. Using defined parameters for co-crystallization of an ATP-bound B-subunit, a unique transition position of ATP could be found in the crystallographic structure of this complex, solved at 3.4 A resolution. The nucleotide is found near the helix-turn-helix motif in the C-terminal domain of the protein; the location occupied by the gamma-subunit to interact with the empty beta-subunit in the thermoalkaliphilic Bacillus sp. TA2.A1 of the related F-ATP synthase. When compared with the determined structure of the ATP-transition position, close to the P-loop, and the nucleotide-free form of subunit B, the C-terminal domain of the B mutant is rotated by around 6 degrees, implicating an ATP moving pathway. We propose that, in the nucleotide empty state the central stalk subunit D is in close contact with subunit B and when the ATP molecule enters, D moves slightly, paving way for it to interact with the subunit B, which makes the C-terminal domain rotate by 6 degrees.

Spectroscopic and crystallographic studies of the mutant R416W give insight into the nucleotide binding traits of subunit B of the A1Ao ATP synthase.

A strategically placed tryptophan in position of Arg416 was used as an optical probe to monitor adenosine triphosphate and adenosine-diphosphate binding to subunit B of the A(1)A(O) adenosine triphosphate (ATP) synthase from Methanosarcina mazei Gö1. Tryptophan fluorescence and fluorescence correlation spectroscopy gave binding constants indicating a preferred binding of ATP over ADP to the protein. The X-ray crystal structure of the R416W mutant protein in the presence of ATP was solved to 2.1 A resolution, showing the substituted Trp-residue inside the predicted adenine-binding pocket. The cocrystallized ATP molecule could be trapped in a so-called transition nucleotide-binding state. The high resolution structure shows the phosphate residues of the ATP near the P-loop region (S150-E158) and its adenine ring forms pi-pi interaction with Phe149. This transition binding position of ATP could be confirmed by tryptophan emission spectra using the subunit B mutant F149W. The trapped ATP position, similar to the one of the binding region of the antibiotic efrapeptin in F(1)F(O) ATP synthases, is discussed in light of a transition nucleotide-binding state of ATP while on its way to the final binding pocket. Finally, the inhibitory effect of efrapeptin C in ATPase activity of a reconstituted A(3)B(3)- and A(3)B(R416W)(3)-subcomplex, composed of subunit A and the B subunit mutant R416W, of the A(1)A(O) ATP synthase is shown.

Naturally-Occurring Polymorphisms in QcrB Are Responsible for Resistance to Telacebec in Mycobacterium abscessus.

Mycobacterium abscessus (M. abscessus) is a rapidly growing nontuberculous mycobacteria that is quickly emerging as a global health concern. M. abscessus pulmonary infections are frequently intractable due to the high intrinsic resistance to most antibiotics. Therefore, there is an urgent need to discover effective pharmacological options for M. abscessus infections. In this study, the potency of the antituberculosis drug Telacebec (Q203) was evaluated against M. abscessus. Q203 is a clinical-stage drug candidate targeting the subunit QcrB of the cytochrome bc1:aa3 terminal oxidase. We demonstrated that the presence of four naturally-occurring polymorphisms in the M. abscessus QcrB is responsible for the high resistance of the bacterium to Q203. Genetics reversion of the four polymorphisms sensitized M. abscessus to Q203. While this study highlights the limitation of a direct drug repurposing approach of Q203 and related drugs for M. abscessus infections, it reveals that the M. abscessus cytochrome bc1:aa3 respiratory branch is sensitive to chemical inhibition.

Structure of the nucleotide-binding subunit B of the energy producer A1A0 ATP synthase in complex with adenosine diphosphate.

A1A0 ATP synthases are the major energy producers in archaea. Like the related prokaryotic and eukaryotic F1F0 ATP synthases, they are responsible for most of the synthesis of adenosine triphosphate. The catalytic events of A1A0 ATP synthases take place inside the A3B3 hexamer of the A1 domain. Recently, the crystallographic structure of the nucleotide-free subunit B of Methanosarcina mazei Gö1 A1A0 ATP synthase has been determined at 1.5 A resolution. To understand more about the nucleotide-binding mechanism, a protocol has been developed to crystallize the subunit B-ADP complex. The crystallographic structure of this complex has been solved at 2.7 A resolution. The ADP occupies a position between the essential phosphate-binding loop and amino-acid residue Phe149, which are involved in the binding of the antibiotic efrapeptin in the related F1F0 ATP synthases. This trapped ADP location is about 13 A distant from its final binding site and is therefore called the transition ADP-binding position. In the trapped ADP position the structure of subunit B adopts a different conformation, mainly in its C-terminal domain and also in the final nucleotide-binding site of the central alphabeta-domain. This atomic model provides insight into how the substrate enters into the nucleotide-binding protein and thereby into the catalytic A3B3 domain.