2.1. Protein expression and purification

Recombinant MtTFE was produced in E. coli BL21 (DE3) cells and purified using a previously standardized protocol (Venkatesan & Wierenga, 2013). Once purified, the enzyme was concentrated in storage buffer [20 mM 4-(2-hydroxy­ethyl)-1-piperazineethanesulfonic acid (HEPES–NaOH) pH 7.2, 120 mM KCl, 1 mM EDTA, 1 mM NaN₃], flash-frozen using liquid nitrogen and stored at −70°C for further use.

2.2. Protein crystallization

MtTFE was crystallized in its unliganded form using a previously described protocol (Venkatesan & Wierenga, 2013). For this, 0.5 µl MtTFE solution (6 mg ml⁻¹ in storage buffer) was mixed with crystallization well solution consisting of 2 M ammonium sulfate in 100 mM tris(hydroxymethyl)aminomethane (Tris–HCl) buffer pH 8.5 in a 1:1 ratio using a Mosquito nanodispensing robot (TTP Labtech) and crystallized by vapor diffusion in hanging drops (total volume 1 µl) at room temperature. The plates were imaged using a Formulatrix Rock Imager (RI54) at regular time intervals and the formation of the crystals was monitored using the IceBear software (Daniel et al., 2021).

2.3. Choice of fragment libraries and preparation of the fragment-containing drops

2.4. Fragment soaking

For fragment soaking, the individual soaking experimental approach was adopted, in which 5–10 unliganded crystals of MtTFE were transferred into each of the 226 pre-spotted fragment-containing drops and incubated at room temperature for at least 24 h before cryocooling in liquid nitrogen. The suitability of the MtTFE crystals for the fragment-soaking experiments was assessed by the visual inspection of images obtained from IceBear (Daniel et al., 2021). Mostly larger crystals (larger than 100 µm in diameter) that had grown in drops with a single or a few crystals per drop were selected. Once selected, crystals were harvested and manually transferred using a loop into the sitting drop that contained the pre-spotted fragment. Subsequently, the crystals were allowed to equilibrate in the fragment solution for 24–48 h at room temperature, directly cryocooled in liquid nitrogen and subsequently stored in liquid nitrogen for the diffraction experiment. In some cases the crystals cracked or dissolved during the soaking step before they could be cooled, and in some cases crystals that survived the soaking step diffracted to less than 3.2 Å resolution. Thus, these could not be checked further for binding studies and were excluded from the data-processing and analysis steps.

2.5. Data collection, data processing and structure refinement

Frozen fragment-soaked crystals were transferred in dry shippers to various European synchrotrons for data collection. X-ray diffraction data sets were collected on different beamlines at BESSY II, DLS, MAX IV and PETRA III. All data collection was performed at a temperature of 100 K. Data reduction was either performed manually using XDS (Kabsch, 2010) and AIMLESS (Evans & Murshudov, 2013) or by using the various data-processing pipelines available at the different synchrotron facilities, including XDSAPP (Sparta et al., 2016; Krug et al., 2012), xia2 (Winter, 2010), xia2_3dii (Winter, 2010), fast_dp (Winter & McAuley, 2011), xia2_DIALS (Winter et al., 2018), autoPROC (Vonrhein et al., 2011) and STARANISO (Tickle et al., 2016). Only data sets that could be processed to a resolution of 3.2 Å or better were used for molecular-replacement calculations to obtain initial phases. As a criterion for the resolution limit, the CC_1/2, I/σ(I) and completeness were monitored. The data-collection and data-processing statistics are listed in Supplementary Tables S2 and S3. The model used as a search model in molecular replacement was derived from PDB entry 4b3h, after removing bound ligands and water molecules, using either Phaser (McCoy et al., 2007) or MOLREP (Vagin & Teplyakov, 2010). The positioned coordinates after molecular replacement were used as the initial model to perform iterative rounds of model building and refinement using Coot (Emsley et al., 2010), phenix.refine from Phenix (Afonine et al., 2012; Liebschner et al., 2019) and REFMAC5 from CCP4 (Murshudov et al., 2011; Potterton et al., 2018; Agirre et al., 2023). Ligands were built into their electron density only after several rounds of manual model building and refinement and after adding sulfate ions and water molecules. Disordered side chains were included in the model, but not always at the beginning and end of the built protein chains. In a few cases side chains were built in double conformations. The obtained refined structures of the MtTFE–fragment complexes were subsequently analyzed with PDB-REDO (Joosten et al., 2011), in particular with regard to the protein model and the water structure. Refinement of all structures was completed using phenix.refine. The structure quality was assessed using MolProbity (Williams et al., 2018) as well as by inspecting the validation report from the PDB validation server (Feng et al., 2021; Smart et al., 2018b). Three regions of the protein part of the structure were difficult to build in several structures: domain C of the α-subunit (in particular in chain A, because of the few crystal contacts), residues 570–580 of the α-subunit (in particular in chain B) and residues 225–231 of both thiolase β-subunits (referred to as the KAT225 loop). Domain C is the somewhat flexible domain of the HAD active site. The region 570–580 of the α-subunit is not near any of the active sites. In some structures this loop was not completely built. As discussed in Section 3, the KAT225 region of the β-chain is of functional relevance; it adopts either a helical conformation (as seen in structures with CoA bound in the thiolase active site; PDB entry 7o4t) or a looped-out conformation (as seen in the unliganded structure; PDB entry 7o4q), and in some structures it is disordered and was not built. The C^β1–C^α1 region of the thiolase subunit, which contributes to the shape of its acyl-tail binding pocket, has high B factors (Dalwani et al., 2021) and this region was not completely built in the structure of the M-80 complex.

The quality of fit between the modeled fragment and the observed electron-density map was assessed by manually checking the electron-density maps as well as by using the real-space correlation coefficient (RSCC) of the bound fragment (as provided in the PDB validation report; Smart et al., 2018a). An RSCC value of 0.8 was chosen for accepting bound fragments, with a few exceptions in cases where fragments were found to be present in both copies of the asymmetric unit or where the binding of another similar fragment at the same binding site was observed. In addition, omit mF_o − DF_c difference maps, obtained from PDB-REDO refinement calculations using models in which the fragments were omitted, were inspected. A bound fragment was only retained if positive electron-density features corresponding to the bound fragment were present in these unbiased omit mF_o − DF_c difference maps. Occupancies were not refined, but in some cases the occupancies were manually set from the information in the difference maps (Supplementary Table S4). The final refinement statistics are listed in Supplementary Tables S2 and S3. A summary of the data-processing and refinement statistics of the refined structures is provided in Table 1. The unbiased omit mF_o − DF_c difference maps (Tables 2 and 3, Supplementary Table S1) were calculated after refinement using phenix.refine of a model in which the relevant ligand had been deleted.

Table 2 Representative omit mFo − DFc difference maps of fragment-binding events at the three active sites as observed at the subsites defined in Table 4 The contour level of these maps is 2.5σ. Further information on the listed fragments is provided in Supplementary Table S1. Binding site Subsite Residue Omit mFo − DFc difference map ECH E1 M-72 (A809) E2 M-83 (A812) E3 M-83 (A811) HAD H0 M-1 (A814) H1 M-83 (B811, A/B) (double conformation) H2 M-83 (A813) H3 M-83 (A809) KAT K1 No binding — K2/K3 M-83 (C508)

Table 3 Representative omit mFo − DFc difference maps of fragment-binding events as observed at the CoA-C(ECH/HAD) site at the subsites defined in Table 4 The contour level of these maps is at 2.5σ. Further information on the listed fragments is provided in Supplementary Table S1. Binding site Subsite Residue Omit mFo − DFc difference map CoA-C(ECH/HAD) I2 (center) B-E1 (B807)   I1 (to ECH) B-H11 (B806)   H1 (to HAD) M-76 (A810)   I3 (to KAT) M-72 (A810)

2.6. Ligand restraints

The restraints for the fragments were generated according to the structural formulae provided in Supplementary Table S1. Coordinates and geometry restraints for the HZB compounds were provided by HZB. Coordinates and restraints for the set of compounds that were provided by Philipps-University Marburg were generated from SMILES strings using the GRADE web server (Smart et al., 2011). For fragment M-1 (PDB Chemical Component ID A9J), the REEL software from Phenix (Moriarty et al., 2017) was used to fix the ligand geometry in the restraints file available from the PDB. For fragment M-72 the electron-density maps showed the mode of binding of 11 fragments. In six binding events it involved molecules with the structure as provided in Supplementary Table S1 (PDB Chemical Component ID JXL). In two cases a dimeric derivative (Supplementary Fig. S1) was observed (PDB Chemical Component ID YLN) [covalently bound to the side chain of His(−9) of the A and B chains] and in three other binding events either the monomeric form (two binding events) or the dimeric form (one binding event) were suggested by the electron-density map to be modified, which was modeled as a partially ordered glycerol moiety (PDB Chemical Component IDs YLZ and YMK, respectively). The geometries of these modified fragments are in agreement with known boron chemistry (Diaz & Yudin, 2017). The restraints of the covalent link between the dimer fragment and the histidine side chain were generated using JLigand from CCP4 (Nicholls et al., 2021). In the M-10 structure the electron-density map also suggested (in two cases) a modification which was modeled as a dimeric derivative of the used fragment (Supplementary Fig. S1).

2.7. Mass spectrometry

Fragments M-80, M-83, M-92 and M-109 were provided as aqueous solutions created through hydrolysis of the corresponding sulfonyl chlorides by dissolving them in 1 M aqueous NaOH. The conversion of these sulfonyl chlorides to the respective sulfonic acids (Supplementary Table S1) was checked using electrospray ionization mass spectrometry (ESI-MS). In addition, the oligomeric state of fragment M-72 was also checked using ESI-MS, due to its exhibiting the formation of a dimeric species in some binding events of this compound in the electron-density maps of the crystal structures. Each fragment was diluted 100-fold from the initial stock solution into 50% methanol/50% water. The diluted fragment solution was directly injected at a rate of 5 µl min⁻¹ into a Q-Exactive Plus Mass Spectrometer (Thermo Scientific) and measured in negative mode. Raw data were analyzed using X-Calibur Qual Browser (Thermo Scientific) to identify the compounds of interest by their accurate mass. The mass-spectrometric analysis confirmed that the samples of fragments M-80, M-83, M-92 and M-109 contained the respective sulfonic acids, whereas the corresponding sulfonyl chlorides were not detected, and that the M-72 sample also contained a dimeric derivative of fragment M-72 (Supplementary Fig. S1).

2.8. Structure analysis

The mode of binding of CoA at the CoA-A(HAD/KAT), CoA-B(ECH2) and CoA-C(ECH/HAD) binding sites is provided by the coordinates of PDB entries 7o4r (2.8 Å resolution, referred to as the CoA-A structure), 7o4s (2.8 Å resolution, referred to as the CoA-B structure) and 7o4t (2.1 Å resolution, referred to as the CoA-C structure), respectively (Dalwani et al., 2021). The mode of binding of CoA in the ECH and KAT active sites is also provided by these structures, and the CoA-C structure (PDB entry 7o4t) is used as the reference coordinate set. The reference structure for the unliganded complex is PDB entry 7o4q. The electrostatic potential at the molecular surface of the MtTFE tetramer was calculated and visualized using CCP4MG (McNicholas et al., 2011) using the CoA-C structure (PDB entry 7o4t) as the model. In this structure, the main chain of all four chains is completely built. To generate the model for the electrostatic surface calculations, all of the ligand and water molecules were first deleted, and the disordered missing side chains of arginine, lysine, glutamate and aspartate residues were then modeled into the structure. The structures of the MtTFE–fragment complexes were superimposed onto the CoA-C structure using the SSM tool (Krissinel & Henrick, 2004) in Coot and the fragment binding with respect to the electrostatic surface was also visualized using CCP4MG (McNicholas et al., 2011). Supplementary Movie S1 was generated using CCP4MG (McNicholas et al., 2011). All structural figures were generated using PyMOL (version 2.0; Schrödinger).

3.1. The 16 structures of MtTFE–fragment complexes identify new binding sites on the surface of MtTFE

Crystallographic fragment screening of a total of 226 fragments was performed for MtTFE using two compound libraries: (i) a library of 96 chemically diverse small molecules from HZB and (ii) a collection of 130 small molecules obtained from the University of Marburg, selected to include a negative charge, as also present in the substrates and reaction intermediates of MtTFE. Of the 226 fragments that were tested, 19 hits, i.e. MtTFE structures with bound fragments, were obtained, 14 of which belonged to the Marburg collection, indicating that the choice of a library that has more negatively charged fragments was more successful for MtTFE. For three of the 19 structures, the features of the electron-density map at the ligand-binding sites were insufficient to satisfactorily decide the ligand orientation. For these three structures, the fragment-binding sites overlapped with sites that were also identified in the structures of other MtTFE–fragment complexes; therefore, these three structures were excluded from further refinement and the structures of 16 fragment-binding experiments (five HZB fragments and 11 Marburg fragments) were selected and used for further analysis (Table 1, Supplementary Movie S1). Of these, the structures of 12 fragments were refined to a resolution of 2.8 Å or better, two fragments to 2.9 Å resolution and two fragments to low resolutions of 3.0 and 3.2 Å, respectively. Unlike typical fragment-screening campaigns that are carried out to identify the precise binding modes of fragments as starting points for the development of lead candidates for drug-discovery purposes, our fragment-screening experiments were aimed at identifying low-affinity binding sites on the surface of MtTFE. Therefore, data sets of somewhat lower resolution are also informative and these low-resolution structures were also retained for further analysis. Key structure-refinement statistics are provided in Supplementary Tables S2 and S3. All of the built fragments have a good fit to the electron-density map, as described in Section 2 (their RSCC values are listed in Supplementary Table S4). Representative omit mF_o − DF_c difference maps are shown in Tables 2 and 3 and Supplementary Table S1.

The 16 fragments are bound over a total of 121 individual binding events. In seven binding events double conformations are observed (Supplementary Table S4), in two cases because the binding event is on a crystallographic twofold. The 121 binding events overlap to a great extent with the previously identified CoA binding sites at the ECH, HAD and KAT active sites as well as with the CoA-A(HAD/KAT), CoA-B(ECH2) and CoA-C(ECH/HAD) binding sites (Table 4). Most fragments bind at multiple binding sites (Table 5), for example fragment M-1 (25 binding events) and fragment M-76 (14 binding events). In most instances, binding at each site is observed in both copies of the αβ dimer of the MtTFE tetramer. 94 out of 121 binding events (14 out of 16 fragments) have an aromatic moiety and 107 out of 121 binding events involve negatively charged fragments (11 out of 16 fragments, eight of which contain a sulfonic acid group) (Supplementary Table S1). Although the mother liquor of the crystals used in these experiments contains 2 M ammonium sulfate and there are approximately 25 sulfate molecules bound at various surface sites in each structure, the sulfonic acid-containing fragments as well as the M-1 fragment (the anion) do not bind at these sulfate-binding sites. A total of 88 fragment-binding events (73%) occur at one of the previously identified binding sites, namely the three active sites (including the NAD binding pocket), or any of the three additional CoA binding sites or in associated pockets near the bound CoA or NAD⁺ molecules (Table 5). Of these 88, only two binding events occur at a crystal contact (fragment M-80, bound at subsite H0). 33 individual fragments (27%) bind at previously unidentified binding sites scattered over the surface of the tetramer (Fig. 2); 12 of these sites are at crystal contacts. 41 fragment-binding events occur at the ECH active site (Table 5), which is the maximum number of hits at a single binding pocket, indicating that this is the fragment-binding `hotspot' of MtTFE.

Figure 2 The 121 binding events on the surface of the TFE tetramer. The same view and coloring scheme are used as in Fig. 1. The two α-subunits are colored wheat and green and the β2 thiolase dimer subunits are colored cyan and yellow. The ECH, HAD and KAT active sites are identified as ECH(CoA) (with a thin arrow), HAD(NAD+) and KAT(CoA). The vertical arrow visualizes the twofold axis of the α2β2 tetramer. The ECH active site of the left α-subunit (wheat) is behind and the ECH active site of the right α-subunit (green) is at the front, showing the fragments bound in its substrate-binding tunnel. The surface has been made transparent, so that binding events that are hidden behind the surface are still visible. The labels CoA-A, CoA-B and CoA-C identify the additional CoA binding sites.

It is noteworthy that in some structures blobs of positive difference electron density could not be assigned to the soaked fragments and in these cases the densities have been left unmodelled. This may be, for example, because of partial disorder of the bound fragment. One fragment (M-72) was observed in its unmodified monomeric form (see, for example, Table 2), but the electron-density map also showed it to be present in a dimeric form (Supplementary Fig. S1) as well in modified monomeric and dimeric forms. The modification of the monomeric form was modeled as a partially disordered glycerol adduct, although the precise nature of the modification is not known. This modification was also observed for one binding event of the dimeric form. In two binding events this dimeric form had reacted with a histidine side chain of the enzyme. The modified histidine side chain is observed in both copies of the N-terminal His tag of the α-chain, at His(−9), and its binding site is at the exit of the substrate-binding tunnel of the ECH active site. The structures of the modeled derivatives of M-72 are in agreement with the known structural properties of this boron compound (Diaz & Yudin, 2017). The occurrence of the monomeric and dimeric forms of M-72 in the stock solution was verified by mass spectrometry (see Section 2). The bound unmodified M-72 molecules and the modified M-72 derivatives included in the final structure have a good fit to the electron-density map, with RSCC values of 0.81 or higher. None of the experiments with the other compounds resulted in a covalent modification of MtTFE. For one other fragment (M-10), the electron-density maps also suggested that the fragment was modified in two binding events, being a dimeric form (Supplementary Fig. S1).

3.2. The fragment-binding events that are mapped to the 15 subsites

Previous crystallographic binding studies of MtTFE with CoA identified the ECH, HAD and KAT active sites, as well as three additional CoA binding sites referred to as the CoA-A(HAD/KAT), CoA-B(ECH2) and CoA-C(ECH/HAD) binding sites based on their location on the surface of the MtTFE tetramer (Dalwani et al., 2021; Table 4, Fig. 1). Each of these six sites occurs in pairs, as the asymmetric unit of this crystal form is the α₂β₂ tetramer, in which a local twofold axis (Fig. 1) relates the two αβ dimers to each other. Many binding sites of the fragments overlap with these CoA binding regions, but also identify binding pockets near these CoA binding sites; for example, regions where the acyl tail of the acyl-CoA substrate molecules could bind, as discussed further below. The binding pockets at the active sites for the acyl tail of the acyl-CoA substrates have been predicted in previous studies (Dalwani et al., 2021).

The substrates of MtTFE are large molecules (molecular mass of >900 Da), larger than the bound fragments, and therefore each of the active-site CoA binding pockets are described in terms of smaller subsites from the pantetheine region (site-1), via the catalytic site (site-2), to the acyl-tail region (site-3), as defined in Table 4: (i) three subsites at the ECH active site (E1, E2 and E3), (ii) four subsites at the HAD active site [H0 (the NAD binding pocket), H1, H2 and H3] and (iii) three subsites at the KAT active site (K1, K2 and K3).

The CoA-C(ECH/HAD) additional CoA binding site and its nearby regions are also divided into three subsites (I1, I2 and I3, as defined in Table 4). Only a few fragments are bound at the other two additional CoA binding sites and therefore these sites are referred to as the C1 and C2 sites for the CoA-A(HAD/KAT) and CoA-B(ECH2) sites, respectively. In this way, 88 fragment-binding events are mapped to these 15 subsites (Table 5). In addition, 33 other binding events are observed at binding sites scattered over the surface of the MtTFE tetramer (Fig. 2, Table 5). In the next sections, the fragment binding in the three active sites is discussed and the binding events at the three additional CoA binding sites are subsequently described.

3.3. Fragment binding at the three active sites includes the proposed CoA acyl-tail binding pockets

Previous crystallographic binding experiments of seven MtTFE active-site point-mutated variants with 2E-enoyl-CoA substrates did not yield structures of complexes of MtTFE with bound acyl-CoA substrate/intermediate molecules, but instead resulted in CoA-bound structures (Dalwani et al., 2021). Thus, although these previous studies identify the binding sites for the CoA moiety of the acyl-CoA substrate at each of the active sites, as well as the binding of CoA at three additional sites, these studies did not provide experimental evidence for the mode of binding of the acyl-tail part of the acyl-CoA substrate in any of the active sites. However, in addition to fragment binding being observed at the CoA binding sites, the current fragment-screening experiments also resulted in MtTFE structures in which fragments are bound at the predicted acyl-tail binding pockets of each of the active sites, referred to in Table 4 as E3, H3 and K3, as discussed further in the next sections. A similar overlap of the binding sites for fragments and fatty acids has also been described in recent crystallographic binding studies of serum albumins with ketoprofen (Anderson, 2022; Czub et al., 2022) using a fragment with similar properties as used in these MtTFE studies (ketoprofen has a negative charge and two aromatic rings).

3.4. The ECH active-site binding pocket

A majority of the fragments (12 out of 16 fragments, 41 binding events) bind in the ECH active site, making it the fragment-binding hotspot of our fragment-screening experiments (Fig. 3, Table 5). These fragments are bound at multiple sites across the entire ECH active site. The mode of binding of fragment M-83 in the ECH active site is shown in Fig. 4. Its sulfonate group binds in the active site, near the catalytic glutamates Gluα119 and Gluα141 (Supplementary Fig. S2). A similar mode of binding is observed for fragment B-H11, which interacts with these two catalytic glutamates using its hydroxyl group. The seven fragments M-10, M-49, M-76, M-79, M-80, M-92 and M-109 share a common substructure of a sulfonic acid functional group connected to an aromatic ring. The sulfonate groups of these seven fragments bind in the same region of the ECH catalytic site, but the aromatic group is bound in two different ways, such that for M-10, M-49, M-76, M-79 and M-109 it overlaps with the mode of binding of the pantetheine moiety of the substrate, whereas for M-80 and M-92 it points towards the E3 region. Altogether, the bound fragment molecules cover the entire ECH active site from the pantetheine binding site through the acyl-tail binding tunnel to the exit of this tunnel (Fig. 3). The bound fragment molecules thereby also overlap nicely with the predicted mode of binding of the acyl tail of 2E-decenoyl-CoA from previous modeling experiments (Dalwani et al., 2021), as shown in Fig. 4 using the bound M-83 fragments as an example. It is noteworthy that none of the fragments bind at the binding pocket for the adenine moiety of CoA.

Figure 3 Fragment-binding events at the ECH active site. View into the ECH acyl-tail binding tunnel. The C-terminal helix of the crotonase fold (helix H10) covers the ECH active site. Also included are CoA as bound to the ECH active site [magenta, labeled CoA(ECH)], as well as the CoA bound in the CoA-C(ECH/HAD) site [magenta, labeled CoA(CoA-C)]. The bound fragments cover the active-site pocket (E1, E2 and E3) and extend to the exit of the ECH acyl-tail binding tunnel.

Figure 4 The acyl-tail binding pocket of the ECH (a), HAD (b) and KAT (c) active sites. The mode of binding of fragment M-83 (cyan) to the subsites is shown, together with the superimposed mode of binding of the acyl-CoA substrate (magenta), as predicted by model building (Dalwani et al., 2021). The predicted mode of binding of the acyl tail of the substrates overlaps with the fragments bound at regions E2 and E3 (residues A811 and A812), at H2 and H3 (residues A813 and A809) and at K2 and K3 (residue C508) of the three active sites. The omit mFo − DFc difference maps of these residues are shown in Table 2. Interactions of these fragments with active-site residues are visualized in Supplementary Fig. S2.

3.5. The HAD active-site binding pocket

The substrate-binding groove of the HAD active site consists of the C domain (the NAD binding domain) and the D/E domains of the α subunit. The C domain is known to exhibit conformational flexibility with respect to the D/E domains such that it can exist in `open' and `closed' conformations. The fully closed conformation, competent for catalysis, is only captured in the structure of the complex of the homologous monofunctional human HAD with NAD⁺ and acetoacetyl-CoA (Barycki et al., 2000). In the available structures of MtTFE, the substrate-binding groove of the HAD active site is always seen in its open conformation and domain C has high conformational flexibility (Dalwani et al., 2021). Except for capturing NAD⁺ binding in the NAD binding pocket (subsite H0) of the HAD active site (Dalwani et al., 2021), all previous crystallographic MtTFE binding experiments failed to capture any ligand binding in the 3S-hydroxyacyl-CoA binding pocket of the HAD active site (i.e. subsites H1, H2 and H3). In the current fragment-binding studies six fragments bind in the substrate-binding pocket and two fragments bind in the NAD binding pocket: M-1 and M-80 (Table 5). The M-1 binding event (of the hexafluoro­phosphate anion) is in the pocket which binds the adenine ring of NAD. The M-80 binding event is near a crystal-contact region and the mode of binding of the M-80 fragment is also stabilized by crystal contacts. The six fragments that bind in the substrate-binding pocket are B-E1, M-1, M-53, M-76, M-83 and M-109. Fragments B-E1 and M-83 form hydrogen bonds either to Serα512 or to both Serα441 and Serα512, both of which point into the catalytic site. These fragments also make weak interactions with the side chain of the catalytic Hisα462. The mode of binding of fragment M-83 is shown in Fig. 4 and Supplementary Fig. S2. Fewer fragments bind here compared with the ECH active site, but binding is observed in the same subsites as seen for the ECH active site, and the mode of binding of these fragment molecules also overlaps with the predicted mode of binding of 3-ketodecanoyl-CoA (Dalwani et al., 2021). None of the bound fragments induces conformational changes that capture a closed conformation of the MtTFE HAD active site. Thus, in all structures of MtTFE reported thus far the C domain of the HAD active site is always seen in its open conformation

3.6. The KAT active-site binding pocket

The acyl-tail binding pocket of the KAT active site is the least accessible of the three active sites of MtTFE. The lowest number of fragments bind at the KAT active site (three out of 16 fragments bind in this active site and there are six binding events; Table 5). Each of these bound fragments (B-E1, M-1 and M-83) binds in the KAT acyl-tail binding tunnel, beyond the CoA sulfhydryl group (Fig. 4). B-E1 and M-83 interact weakly with the side chain of the catalytic cysteine Cysβ92. The R-SO₂-R and R-SO₂-OH moieties of B-E1 and M-83, respectively, bind at the same site, forming a hydrogen bond to the side chain of Glnβ149, as visualized in Supplementary Fig. S2 for the M-83 fragment. The five-membered ring of fragment B-E1 points away from the acyl-tail binding tunnel towards the KAT225 loop of the thiolase β-subunit (contacting the Leuβ228 side chain) and the H9A helix of the α-subunit (in particular Proα243). Leuβ228 and Proα243 line the groove between the I2 site and the K2 site. M-1 (the hexafluorophosphate anion) binds in the acyl-tail binding tunnel, displacing the side chain of Metβ134, which has moved. The bound fragment M-83 overlaps with the mode of binding of the acyl tail of 3-ketodecanoyl-CoA, as predicted from previous modeling experiments (Dalwani et al., 2021) and shown in Fig. 4.

3.7. The fragment-binding events identify the CoA-C(ECH/HAD) site as a possible functional transient binding site

The reaction intermediates of MtTFE are polar negatively charged derivatives of CoA. Analysis of the surface features of MtTFE shows that its three active sites are separated by a surface path which is devoid of negatively charged residues (Fig. 5, Supplementary Fig. S3 and Supplementary Movie S1), and it has been proposed that this path could be used to transiently anchor the reaction intermediates, allowing them to crawl between the active sites, thus enabling substrate channeling (Venkatesan & Wierenga, 2013). Crystallographic binding studies with CoA have identified three additional CoA binding sites (Dalwani et al., 2021), which to some extent overlap with this surface path. A comparison of the CoA–protein interactions of CoA bound at these additional binding sites versus the CoA–protein interactions of CoA bound in the active sites shows that on average the total number of atom–atom interactions per bound CoA (23.3 versus 27.5) and the total number of hydrogen-bond interactions (3.2 versus 8.5) are significantly lower for CoA bound in the additional binding sites compared with CoA bound in the active-site binding pockets (Supplementary Table S5). This is of particular interest for the CoA-C(ECH/HAD) binding site, which is located between the ECH, HAD and KAT active sites and which has been proposed to be part of the surface path relevant for substrate channeling (Dalwani et al., 2021). At this binding site the CoA is bound in an extended conformation and the interactions between the bound CoA and the protein are much weaker than at the active sites (Supplementary Table S5). The location of this site and the weak CoA–protein interactions indicate that of the three additional CoA binding sites, the CoA-C(ECH/HAD) site could be a functional transient binding site for reaction intermediates.

Figure 5 Properties of the protein surface of the possible substrate-channeling path between the three active sites of MtTFE. The image shows the color-coded molecular surface of the CoA-C(ECH/HAD) region, near the interface of chain A (α subunit) and chain D (β subunit) of the CoA-C structure (PDB entry 7o4t), color-coded such that the blue and red colors identify surface regions with positive and negative electrostatic potential, respectively. Neutral regions have a white color. The active sites are identified as CoA(ECH) (with an arrow), NAD+(HAD) (of the α subunit) and CoA(KAT) (of the β subunit). The CoA molecule bound at the CoA-C(ECH/HAD) site (I2) at the center of the surface between the three active sites is also included. I1, H1 and I3 identify the binding regions extending from I2 towards the ECH, HAD and KAT active sites, respectively. Also shown is CoA bound in the CoA-B(ECH2) site. A stereo figure is shown in Supplementary Fig. S3 and a video (Supplementary Movie S1) is also provided. The fragments included in the image are indicated in the inset, which schematically visualizes the locations of the I1, I2 and I3 sites with respect to the three catalytic sites in the same view as used for the molecular-surface image.

The fragment-screening experiments identify multiple binding sites which overlap with the additional CoA binding sites. Seven out of 16 fragments (23 binding events) bind overlapping with at least one of the three additional CoA binding sites (Table 5). A single fragment (B-51) binds at the CoA-A(HAD/KAT) binding site (two binding events), one fragment (M-53) binds at the CoA-B(ECH2) binding site (one binding event) and five fragments (B-E1, M-1, M-49, M-53 and M-72) bind at the CoA-C(ECH/HAD) binding site (I2; 13 binding events). Clearly, the CoA-C(ECH/HAD) binding site is a favorable binding site for these fragments. Furthermore, near the CoA-C(ECH/HAD) site, fragments B-H11 and M-72 bind at subsite I1, which perfectly bridges the gap between the bound CoA at the ECH active site and the CoA-C(ECH/HAD) binding site. In addition, fragments M-76 and M-83 bind at H1 (the binding region of the pantetheine moiety of the HAD active site, which is close to I2) and fragments M-53 and M-72 bind at subsite I3, which extends beyond the CoA-C S atom towards the KAT active site. Fig. 5 shows the binding sites of these fragments in this region. The omit mF_o − DF_c difference maps of B-E1 (bound at I2), B-H11 (bound at I1), M-76 (bound at H1) and M-72 (bound at I3) are shown in Table 3. The 23 binding events at the H1, I1, I2 and I3 sites are defined by interactions with the α-subunit, except for the binding event of M-53 at the I3 subsite, which also involves interactions with the β-subunit (with βLeu231). Fig. 5 also provides a schematic visualization of the I1, H1 and I3 binding sites near the CoA-C(ECH/HAD) site (I2) with respect to the ECH, HAD and KAT active sites. The negatively charged functional group of fragment M-83 overlaps with the negatively charged pyrophosphate moiety of the CoA molecule bound at this site. Each of the fragments that bind in the CoA-C(ECH/HAD) binding region also binds to at least one of the three active sites (Table 5).

The proposed I3 binding groove between the CoA-C(ECH/HAD) site and the KAT active site is lined by residues α240–α250 of the α subunit (in particular Ileα241, helix H9A) and by residues Pheβ225-Glu-Gly-Leu-Ala-Ala-Leuβ231 just before the Lα5 helix of the thiolase subunit (in particular Leuβ231). The latter region, referred to as the KAT225 loop, is built as a high-B-factor loop in the unliganded structure of MtTFE (PDB entry 7o4q), but it adopts a helical conformation in the structures with CoA bound (for example, PDB entry 7o4t). This loop is an extension of the adenine binding loop (Harijan et al., 2023), which has a conserved sequence fingerprint [Leu(β221)-Lys-Pro-Ala-Phe] that shapes the CoA binding pocket. In particular, Leuβ221 (pointing to the adenine ring) and Pheβ225 (pointing to the methyl groups of the pantetheine moiety), as well as Proβ223, are conserved in sequence alignments (Venkatesan & Wierenga, 2013; Harijan et al., 2023). In some structures of the fragment complexes the KAT225 loop is disordered, in some structures it is built in a helical conformation (for example in the structure of the M-72 complex) and in some structures it is built in a loop conformation, such as for example in the structure of the M-53 complex. The binding pocket of one of the bound fragment M-53 molecules is shaped by the side chains of Ileα241 and Leuβ231. Further studies are required to understand the functional relevance of the different conformations of the KAT225 loop region.

3.8. The proposed substrate-channeling path identified by the fragment-binding events

As outlined above, in addition to identifying the CoA-C(ECH/HAD) site as a potential transient binding site (the I2 site) for reaction intermediates, these crystallographic fragment-screening experiments also identify subsites I1, H1 and I3, which are binding pockets that extend from the I2 CoA-C(ECH/HAD) binding site to the ECH, HAD and KAT catalytic sites, respectively. The crystallographic fragment-screening experiments therefore suggest a substrate-channeling path that could be used for the surface crawling of negatively charged reaction intermediates between the three active sites. The proposed path subsequently consists of the following binding sites: ECH (catalytic site) → I1 → I2 → H1 → HAD (catalytic site) → H1 → I2 → I3 → KAT (catalytic site). The distances from the ECH and HAD active sites to the I2 site are approximately 21 and 12 Å, respectively, and the corresponding distance from the KAT active site is approximately 44 Å, when considering the distances between the bridging pyrophosphate O atoms of the CoA molecules bound at these sites. The path is identified by the fragments B-E1, B-H11, M-1, M-49, M-53 and M-72, in addition to the CoA-C(ECH/HAD) molecule (Table 5, Fig. 5, Supplementary Fig. S3). Supplementary Movie S1 visualizes the results of these fragment-binding experiments, highlighting the proposed substrate-channeling path between the active sites, by showing the fragments as bound at sites along this surface path of MtTFE. The fragments M-1, M-49, M-53 and M-72 are negatively charged, like the MtTFE reaction intermediates. This path can be described as consisting of neutral residues, being lined by the side chains of positively charged residues (Lys/Arg; Fig. 5). Positively charged residues of the protein surface have been proposed to be important for steering the diffusion of negatively charged ligands for substrate channeling of the TS-DHFR bifunctional enzyme (Anderson, 2017; Metzger et al., 2014) as well as in other biological systems (Zheng et al., 2019). Other properties, such as disfavoring the binding of water molecules, referred to as `dewetting' (Hilario et al., 2016), have been described for the substrate-channeling path of the enzyme tryptophan synthase, in which a neutral indole molecule channels through a tunnel between its two active sites.