Abstract
ATP synthases produce ATP from ADP and inorganic phosphate with energy from a transmembrane proton motive force. Bacterial ATP synthases have been studied extensively because they are the simplest form of the enzyme and because of the relative ease of genetic manipulation of these complexes. We expressed the Bacillus PS3 ATP synthase in Eschericia coli, purified it, and imaged it by cryo-EM, allowing us to build atomic models of the complex in three rotational states. The position of subunit ε shows how it is able to inhibit ATP hydrolysis while allowing ATP synthesis. The architecture of the membrane region shows how the simple bacterial ATP synthase is able to perform the same core functions as the equivalent, but more complicated, mitochondrial complex. The structures reveal the path of transmembrane proton translocation and provide a model for understanding decades of biochemical analysis interrogating the roles of specific residues in the enzyme.
Introduction
Adenosine triphosphate (ATP) synthases are multi-subunit protein complexes that use an electrochemical proton motive force across a membrane to make the cell’s supply of ATP from adenosine diphosphate (ADP) and inorganic phosphate (Pi). These enzymes are found in bacteria and chloroplasts as monomers, and in mitochondria as rows of dimers that bend the inner membrane to facilitate formation of the mitochondrial cristae 1,2. Proton translocation across the membrane-embedded FO region of the complex occurs via two offset half-channels 3,4. Studies with Bacillus PS3 ATP synthase in liposomes showed that proton translocation may be driven by ΔpH or ΔΨ alone 5. The passage of protons causes rotation of a rotor subcomplex, inducing conformational change in the catalytic F1 region to produce ATP 6 while a peripheral stalk subcomplex holds the F1 region stationary relative to the spinning rotor during catalysis. For the mitochondrial enzyme, X-ray crystallography has been used to determine structures of the soluble F1 region 7, partial structures of the peripheral stalk subcomplex alone 8 and with the F1 region 9, and structures of the F1 region with the membrane-embedded ring of c-subunits attached 10,11. Recent breakthroughs in electron cryomicroscopy (cryo-EM) allowed the structures of the membrane-embedded FO regions from mitochondrial and chloroplast ATP synthases to be determined to near-atomic resolutions 12–15.
Compared to their mitochondrial counterparts, bacterial ATP synthases have a simpler subunit composition. The F1 region consists of subunits α3β3γδε, while the FO region is usually formed by three subunits with the stoichiometry ab2c9-15. Chloroplasts and a few bacteria, such as Paracoccus denitrificans, possess two different but homologous copies of subunit b, named subunits b and b′ 6. Each copy of subunit α and β contains a nucleotide binding site. The non-catalytic α subunits each bind to a magnesium ion (Mg2+) and a nucleotide, while the catalytic β subunits can adopt different conformations and bind to Mg-ADP (βDP), Mg-ATP (βTP), or remain empty (βE). Crystal structures of bacterial F1-ATPases and c-rings from the FO regions of several species have been determined 16–24. Structures of intact ATP synthases from E. coli have been determined to overall resolutions of 6 to 7 Å by cryo-EM, with the FO region showing lower quality than the rest of the maps, presumably due to conformational flexibility 25. In structures of both intact ATP synthase 25 and dissociated F1-ATPase 17,19 from bacteria, subunit ε adopts an “up” conformation that inhibits the ATP hydrolysis by the enzyme. In the thermophilic bacterium Bacillus PS3, this subunit ε mediated inhibition is dependent on the concentration of free ATP 26–28. Low ATP concentrations (eg. < 0.7 mM) promote the inhibitory up conformation while a permissive “down” conformation can be induced by a high concentration of ATP (eg. > 1 mM). This mechanism would allow the Bacillus PS3 ATP synthase to run in reverse, establishing a proton motive force by ATP hydrolysis, when the ATP concentration is sufficient to do so without depleting the cell’s supply of ATP. In E. coli, however, in the absence of a sufficient proton motive force to drive ATP synthesis, inhibition of ATP hydrolysis by subunit ε persists even when the concentration of free ATP is high 29,30.
Although bacterial ATP synthases have been subjected to extensive biochemical analysis, high-resolution structural information is lacking for the intact enzyme or the membrane-embedded proton-conducting subunit a and the associated subunit b. We determined structures of intact ATP synthase from Bacillus PS3 in three rotational states by cryo-EM. The structures reached overall resolutions of 2.9 to 3.1 Å (Fig. 1), allowing construction of nearly complete atomic models for the entire complex. The structures reveal how loops in subunit a of the bacterial enzyme fill the role of additional subunits in the FO region of the mitochondrial enzyme. Most significantly, the structures provide a framework for understanding decades of mutagenesis experiments designed to probe the mechanism of ATP synthases.
Results and discussions
Structure determination and overall architecture
Subunits of Bacillus PS3 ATP synthase, including subunit β bearing an N-terminal 10×His tag, were expressed from a plasmid in E. coli strain DK8, which lacks endogenous ATP synthase 31,32. The complex was extracted from membranes with detergent, purified by metal-affinity chromatography, and subjected to cryo-EM analysis (Fig. 1 - figure supplement 1). Three conformations corresponding to different rotational states of the enzyme were identified by abinitio 3D classification and refined to high resolution. The 3D classes contain 45, 35, and 20 % of particle images and the overall resolutions of the corresponding cryo-EM maps were 2.9, 2.9, and 3.1 Å, respectively (Fig. 1 - figure supplements 2 and 3). Estimation of local resolution suggests that the F1 regions of the maps, which are larger than the FO regions and appear to dominate the image alignment process, are mostly at between 2.5 and 3.5 Å resolution, whereas the FO regions were limited to lower resolution (Fig. 1 - figure supplement 3). Focused refinement 33 of the FO region and peripheral stalk subunits ab2c10 and δ (corresponding to the subunit OSCP in mitochondrial ATP synthase) improved the resolution of the FO regions considerably for all three classes but not enough to resolve density for most of the amino acid side chains. An improved map of the FO region was obtained by focused refinement of the membrane-embedded region only, excluding the soluble portion of subunit b with particle images from all three classes (Fig. 1 - figure supplement 2). Overall, amino acid side chain detail can be seen for subunits α3, α3, γ, δ, ε, a, c10-ring, and the transmembrane α -helices of b2 (Fig.1 - figure supplements 4). The soluble region of the two b-subunits was modeled as poly-alanine.
The general architecture of the enzyme resembles E. coli ATP synthase 25 and the more distantly related spinach chloroplast enzyme 15 but with striking differences. As observed previously in a Bacillus PS3 F1-ATPase crystal structure (PDB 4XD7) 19, the three catalytic β subunits adopt “open”, “closed”, and “open” conformations, different from the “half-closed”, “closed”, and “open” conformations seen in the auto-inhibited E. coli F1-ATPase 17, and the “closed”, “closed”, and “open” conformations seen in chloroplast ATP synthase 15 and most mitochondrial ATP synthase structures 7,10. This difference, with the half-closed βDP of the E. coli enzyme appearing as open in the Bacillus PS3 enzyme, suggests species-specific differences in inhibition by subunit ε (Fig. 1B, pink density), which inserts into the α/β interface and forces βDP into the open conformation.
In the FO region, one copy of subunit b is positioned at a location equivalent to that of the mitochondrial subunit b, while the second copy occupies the position of yeast subunit 8 (mammalian A6L) on the other side of subunit a (Fig. 1B). Despite the different c-ring sizes (10 c-subunits in Bacillus PS3 versus 14 in spinach chloroplasts), the backbone positions of subunits ab2 from Bacillus PS3 overlap with subunits abb′ from spinach chloroplast ATP synthase 15 (Fig. 1 - figure supplement 5A). Comparison of the atomic model of the FO region from Bacillus PS3 and the backbone model of the E. coli complex from cryo-EM at ~7 Å resolution (PDB 5T4O) 25 showed significant structural differences in transmembrane α-helices of subunit b relative to subunit a (Fig. 1 - figure supplement 5B). Rather than reflecting true differences between E. coli and Bacillus PS3 ATP synthase structures, these deviations likely suggest that the 6 to 8 Å resolution E. coli maps were not at sufficient resolution to allow accurate backbone tracing of FO subunits.
Flexibility in the peripheral and central stalks
As expected, the most striking difference between the three rotational states of the Bacillus PS3 structure is the angular position of the rotor (subunits γεc10) (Fig. 2A, Video 1). The structure of the ATP synthase, with three αβ pairs in the F1 region and ten c-subunits in the FO region, results in symmetry mismatch between the 120° steps of the F1 motor and 36° steps of the FO motor. The 120° steps of the F1 motor gives an average rotational step of 3.3 c-subunits, with the closest integer steps being 3, 4 and 3 c-subunits. By comparing the positions of equivalent c-subunits in different rotational states, the observed rotational step sizes in the three rotational states of the ATP synthase appear to be almost exactly 3, 4 and 3 c-subunits (Fig. 2B). At the present resolution, the structures of subunit a and the c-ring do not appear to differ between rotary states. Similar integer step sizes were found in yeast ATP synthase 34 and V-ATPase 35, which also contain 10 c-subunits. However, non-integer steps were seen in the chloroplast (14 c-subunits) 15 and bovine (8 c-subunits) 36 ATP synthases, indicating that the c-subunit steps between the rotational states of rotary ATPases likely depends on the number of c-subunits.
Flexibility is thought to be important for the smooth transmission of power between the F1 and FO regions, which often have mismatched symmetries 37–39. Earlier studies suggested that the central stalk (subunits γ and ε in bacteria) is the main region responsible for the transient storage of torsional energy in rotary ATPases 40,41. Comparison of the three rotational states of the Bacillus PS3 enzyme also shows that C-terminal water-soluble part of subunit b displays the most significant conformational variability between states, while the subunits in the F1 region show little flexibility beyond the catalytic states of the αβ pairs (Fig. 2C; Video 1). The structure of the yeast ATP synthase FO dimer 12, which lacked the the F1 region and an intact peripheral stalk, showed that the c-ring and subunit a are held together by hydrophobic interactions rather than by the peripheral stalk. In Bacillus PS3 ATP synthase, the peripheral stalk is structurally simpler and more flexible than in yeast mitochondria 14, suggesting that the bacterial subunits a and the c-ring are also held together by hydrophobic interactions and not the peripheral stalk. Given that these structures represent resting states of the bacterial ATP synthase, additional subunits, such as those in the central stalk, may show flexibility while under strain during rotation.
Nucleotide binding in the F1 region and inhibition by subunit ε
The structure of the F1 region of the intact Bacillus PS3 ATP synthase and the earlier crystal structure of the dissociated F1-ATPase (PDB 4XD7) 19 both show that the three catalytic β-subunits (βE, βTP, and βDP) adopt “open”, “closed”, and “open” conformations, respectively (Fig. 3A). In the crystal structure, which was prepared in the presence of CyDTA (trans-1,2-Diaminocyclohexane-N, N, N′, N′-tetraacetic acid monohydrate) as a chelating agent, there was no nucleotide in the three noncatalytic sites of the three α-subunits and the only nucleotide in a catalytic site was an ADP molecule without a Mg2+ ion in the βTP site. In contrast, all three non-catalytic sites in the cryo-EM map are occupied by Mg-ATP, while a Mg-ADP molecule and a weak density tentatively assigned to Pi are found in the βTP site and by the p-loop of βE, respectively. The presence of physiological Mg2+ ions and nucleotide occupancy 42 in the cryo-EM map suggest that it shows a snapshot of the enzyme in the middle of its physiological catalytic cycle.
Bacillus PS3 ATP synthase is found in a conformation where ATP synthesis is permitted but ATP hydrolysis is auto-inhibited. In this state subunit ε maintains an up conformation and inserts into the αDPβDP interface, forcing βDP to adopt an open conformation (Fig. 3A, lower, dashed box) 19. In the crystal structure (PDB 4XD7) 19, the C-terminal sequence of subunit ε was modeled as two α-helical segments broken at Ser 106, while the cryo-EM structures show the C-terminal part is in fact entirely α-helical. In comparison, subunit ε from the auto-inhibited E. coli F1-ATPase structure (PDB 3OAA) 17 maintains its two C-terminal α-helices (Fig. 3B), with its βDP adopting a half-closed conformation that binds to Mg-ADP. The C-terminal α-helix of the E. coli subunit α inserts slightly deeper into the αDPβDP interface but overall in a manner similar to that of the Bacillus PS3 subunit ε. However, the second α-helix in E. coli is offset by a ten-residue loop that allows it to interact with subunit γ. This interaction (Fig. 3B, lower, dashed box) may stabilize the up conformation of subunit ε in E. coli, explaining why auto-inhibition in E. coli does not depend on ATP concentration 29,30 while in Bacillus PS3 it does. Interestingly, during ATP synthesis, Bacillus PS3 subunit ε maintains the up conformation 27, suggesting that it only blocks ATP hydrolysis but not ATP synthesis. For a canonical ATP synthase, the substrates ADP and Pi bind to an open βE. The βE subsequently transitions to become the closed βDP and then βTP, driven by rotation of the central rotor, producing an ATP molecule that is ultimately released when the closed βTP converts back to an open βE 7. For the Bacillus PS3 ATP synthase to produce ATP with subunit ε in the up conformation, substrate would need to bind to the βDP site instead of the usual βE site, with an ATP molecule produced on transition to a closed βTP. The cryo-EM maps show that a clash between subunit ε and βTP blocks the central rotor turning in the direction of ATP hydrolysis while it is still free to turn in the direction of ATP synthesis (Fig. 3C), explaining the ability of subunit ε to selectively inhibit ATP hydrolysis 27.
Subunit organization in the FO region
In the bacterial ATP synthase structure, the FO subunits ab2 display an organization similar to the yeast FO complex (PDB 6B2Z, Fig. 4A) 12. Subunit a and the first copy of subunit b occupy the same positions as their yeast counterparts, while the second copy of subunit b is found at a position equivalent to subunit 8 in the yeast enzyme, which is known as A6L in mammals. Atomic models for ATP synthase from mitochondria 12–14 and chloroplasts 15 support the idea that transmembrane proton translocation in ATP synthases occurs via two offset half-channels formed by subunit a 3,4. Subunit a from Bacillus PS3 shares 21.0% and 29.1% sequence identity with its yeast and chloroplast homologs, respectively, and the atomic model shows that the folding of these homologs is mostly conserved (Fig. 4 - figure supplement 1). Multi-sequence alignment of subunit a from different species indicates that bacterial and chloroplast subunit a contain a larger periplasmic loop between α-helices 3 and 4 than found in the mitochondrial subunit (Fig. 4A, left; Fig. 4 - figure supplement 2). The sequence for this loop varies significantly among species, suggesting that it is unlikely to be involved in the core function of proton translocation, despite being proximal to the cytosolic proton half-channel. Yeast and mammalian mitochondrial ATP synthases contain subunit f, which has a transmembrane α-helix adjacent to the transmembrane α-helix 1 of subunit a (Fig. 4A, right), anchoring subunit b between α-helices 5 and 6 of subunit a. The location of the loop between α-helices 3 and 4 of the Bacillus PS3 subunit a suggests that it serves a similar structural role, compensating for the lack of subunit f in bacteria. The loop forms an additional interface with subunit b near the periplasmic side of the membrane region and may interact with the N terminus of subunit b in the periplasm as well. Two interfaces are also present between the second copy of subunit b and subunit a, one with the first transmembrane α-helix, and the other with the hairpin of α-helices 3 and 4 (Fig. 4A). The structure suggests that two interfaces are necessary for subunits a and b to maintain a stable interaction.
Proton translocation through the FO region
The Bacillus PS3 ATP synthase structure implies a path for proton translocation through the bacterial complex involving two half-channels and similar to the paths described for the mitochondrial and chloroplast enzymes. The cytoplasmic half-channel consists of an aqueous cavity at the interface of subunit a and the c-ring (Fig. 4B, left). The periplasmic half-channel is formed from a cavity between α-helices 1, 3, 4 and 5 of subunit a, and reaches the c-ring via a gap between α-helices 5 and 6 (Fig. 4B, right). In the atomic model, both channels are visible when modelling the surface with a 1.4 Å sphere that mimics a water molecule 43 (Fig. 4B). The channels are wide and hydrophilic, suggesting that water molecules could pass freely through each of the channels before accessing the conserved Glu 56 of the c-subunits. During ATP synthesis, protons travel to the middle of the c-ring via the periplasmic half-channel and bind to the Glu 56 residue of a subunit c (Fig. 4C). Protonation of the glutamate allows rotation of the ring counter-clockwise, when viewed from F1 towards FO, delivering the subunit c into the hydrophobic lipid bilayer. Protonation of the remaining nine subunits in the c-ring returns the first glutamate to subunit a, now into the cytoplasmic half-channel, where it releases its proton to the cytoplasm due to interaction with the positively charged Arg 169 of subunit a.
In eukaryotes, subunit a is encoded by the mitochondrial genome, limiting genetic interrogation of the roles of different residues. In contrast, numerous mutagenesis studies have been performed on bacterial subunits a and b, with E. coli ATP synthase being the most frequently studied 44,45. A single G9D mutation in the E. coli subunit b (positionally equivalent to Y13D in Bacillus PS3), results in assembled but non-functional ATP synthase 46, while multiple N-terminal mutations in subunit b can either disrupt enzyme assembly or ATP hydrolysis 47. In Bacillus PS3, Tyr 13 is part of the transmembrane α-helix of subunit b and is adjacent to Gly 188 of subunit a (Fig. 4 - figure supplement 3, dashed box). In E. coli subunit a, Gly 188 is replaced by a leucine (Leu 229). Therefore, the G9D mutation in E. coli not only introduces a charged residue into a hydrophobic transmembrane α-helix, but also creates a steric clash with Leu 229 of subunit a, explaining why the mutation leads to an inactive enzyme. Remarkably, the single N-terminal membrane-embedded α-helix in each of the two copies of subunit b in the Bacillus PS3 ATP synthase forms different interactions with subunit a (Fig. 4A). One surface interacts with transmembrane α-helices 1, 2, 3, and 4 of subunit a while the other interacts with α-helices 5 and 6 and the loop between α-helices 3 and 4 of subunit a. Given that the N-terminal α-helix of subunit b makes interactions with different regions of subunit a, it is not surprising that mutations in this region are often detrimental to the assembly and activity of the complex. Cross-linking experiments suggested that the N terminus of the two copies of subunit b are in close proximity with each other 48. However, the atomic model shows that the transmembrane α-helix of the b-subunits are on opposite sides of subunit a, suggesting that the cross-linking results may be due to non-specific interactions of b-subunits from neighboring ATP synthases.
In E. coli, Arg 210 of subunit a (Arg 169 in Bacillus PS3) tolerates the fewest mutations 49–52. Recent structures of rotary ATPases suggest that the importance of this residue derives from its role in releasing protons bound to the Glu residues of the c-subunits as they enter the cytoplasmic half-channel, as well as preventing short-circuiting of the proton path by protons flowing between half-channels without rotation of the c-ring 18,35,36,53,54. Other residues in the E. coli subunit a identified by mutation as being functionally important include Glu 196 (Glu 159 in Bacillus PS3) 55,56, Glu 219 (Glu 178) 55–57, His 245 (Ser 210) 51,58,59, Asp 44 (Asp 19) 60, Asn 214 (Asn 173) 49, and Gln 252 (Gln 217) 57,61 (Fig. 4D). When mapped to the Bacillus PS3 structure, only Glu 196 (Glu 159 in Bacillus PS3) is close to the cytoplasmic half-channel. Extensive mutations of E. coli Glu 196 showed that enzyme activity depends on the charge and polarity of the residue with Glu > Asp > Gln = Ser = His > Asn > Ala > Lys 55. Therefore, the negative surface charge from Glu 196 (Glu 159) near the cytoplasmic half-channel facilitates proton transport across the lipid bilayer. The atomic model of subunit a also suggests that other residues such as Bacillus PS3 Thr 165, Asn 162, Glu 158, Tyr 228, and His 231, which are close to the cytoplasmic half-channel, may contribute to channel formation. Many functional residues identified by mutagenesis are clustered around the periplasmic half-channel. In the atomic model of the Bacillus PS3 subunit a, Asp 19 and Glu 178 are close to the periplasm, while Ser 210, Asn 173, and Gln 217 are deeper inside the membrane. Among these residues, Glu 178 and Ser 210 are considered to be more important to enzyme function than Asn 173 and Gln 217, as mutations of corresponding residues in E. coli are more likely to abolish the proton translocation by the complex 44. Interestingly, although many of these functional residues appear important, their mutation to amino acids that cannot be protonated or deprotonated often does not completely abolish proton translocation 44. The atomic model of Bacillus PS3 subunit a shows that the proton half-channels are wide enough for water molecule to pass through freely. This observation suggests that the function of these conserved polar and charged residues is not the direct transfer of protons during translocation. Rather, their presence may help maintain a hydrophilic environment for water-filled proton channels. This role allows different species to use unique sets of polar and charged residues forming their proton half-channels. For instance, the function of the Glu 219/His 245 pair in E. coli 59 is replaced by a Glu 178/Ser 210 pair in Bacillus PS3, and a His 185/Glu223 pair in yeast and human ATP synthases (Fig. 4 - figure supplement 2). This variability suggests a remarkably flexible proton translocation mechanism for this highly efficient macromolecular machine.
Acknowledgements
We thank Dr. Samir Benlekbir (the Hospital for Sick Children) for helping with cryo-EM data collection and Prof. Tomitake Tsukihara (Osaka University, Japan) for discussions. This work was supported by Canadian Institutes of Health Research operating grant MOP 81294. Cryo-EM data was collected at the Toronto High-Resolution High-Throughput cryo-EM facility, supported by the Canada Foundation for Innovation and Ontario Research Fund. HG was supported by an Ontario Graduate Scholarship and a University of Toronto Excellence Award. TS was supported by Japan Society for the Promotion of Science Grants-in-Aid for Scientific Research (KAKENHI) Grant JP18H02409. JLR was supported by the Canada Research Chairs program. Cryo-EM maps are deposited in the Electron Microscopy Data Bank (EMD-XXXX and EMD-XXXX) and Protein Data Bank (PDB-XXX and PDB-XXX).