4.1.1. Chain L of the Escherichia coli respiratory complex I

Some of the most challenging tests were derived from the structure of conformation 2 of the E. coli respiratory complex I: PDB entry 7nyu, EMDB entry EMD-12654 (Kolata & Efremov, 2021). Not only is the overall resolution relatively low for ab initio modeling at 3.8 Å, but the local resolution varies widely, with the map quality dropping dramatically for parts of the membrane domain furthest from the peripheral domain. The poorest local resolution, estimated by the original authors to be in the range 9–11 Å, is for chain L. The map quality improves for the neighboring chain M and even more for the next neighbor, chain N. Since chains L, M and N are homologous, with about 26% pairwise sequence identity, it is possible to obtain nonrandom but suboptimal mismatched placements of the models for these chains.

A global search using chain L of PDB entry 3rko (Efremov & Sazanov, 2011) as a model for the corresponding chain of PDB entry 7nyu failed to find the correct placement; instead, two incorrect placements were found superimposed on chains M and N. An attempt to dock chain M of PDB entry 3rko succeeded, but the search also yielded an additional incorrect placement superimposed on the more well ordered map region for chain N. We wished to see whether the emplace_local program could be used to match the models of chains L, M and N to their correct sites in the reconstruction, in particular chain L, which failed in the global search. Table 1 shows the results of local searches pairing each of these models with the three map regions, all carried out at the nominal resolution of 3.8 Å. Note that each of the searches took from 25 to 45 s (using a Linux workstation with a 3.8 GHz Intel Core i7-9800X CPU with eight cores but running primarily on a single thread), whether carried out from the standalone Phenix program or the ChimeraX plugin. By comparison, the unsuccessful global search for chain L took 616 s on the same computer (Millán et al., 2023). In each case, a search with the model matched to the map region succeeded. However, searches for the mismatched model in the poorest, chain L, map region failed. Searches for the mismatched model in the intermediate-quality chain M region detected part of the map sphere coming from the better-ordered chain N region; as a result, the final rigid-body refinements were no longer centered on the original map region (Table 1a). Carrying out the searches at lower resolution might have been expected to reduce the sensitivity to the local map quality. However, when the set of searches was repeated using data limited to either 5, 7 or 9 Å, the same calculations failed, with one set of exceptions: using data to between 5 and 9 Å resolution, the chain L model could successfully be docked into the chain M map region.

To obtain docking scores for the desired mismatched pairs, rigid-body refinements were carried out in em_placement, starting from a superposition on the target chain from PDB entry 7nyu. The results are shown in Table 1(b), with the entries flagged for cases where emplace_local failed to yield the desired solution. Likelihood is based on the consistency of a model with a set of data, so it can be used to choose among competing hypotheses for the same data (columns in Table 1b) but not among different data sets for the same hypothesis (rows in Table 1b). With this in mind, it is clear that the model of chain N is the most consistent with the data obtained from the chain N region of the cryo-EM maps, even though non­random scores are obtained for the other models. In contrast, the model of chain L gives the highest score for docking in the chain N region of the map, an intermediate score for docking in the chain M region and the lowest score for docking in its own region. This does not imply that chain L should really be placed in the chain N position, but just arises because the full map has higher signal to noise in the chain N region, enough to overcome the deficiencies of the chain L model in the overall score.

Fig. 2(a) shows the result of docking chain L of PDB entry 3rko into the chain L region of the target map. The poor quality of the fit to the map is in accordance with a value for the LLG that is close to the level required for confidence. Fig. 2(b) shows the good superposition of the docked model on the deposited structure in PDB entry 7nyu, along with the deposited reconstruction. We note that the initial fit to this map (Kolata & Efremov, 2021) used models derived from PDB entries 3rko (Efremov & Sazanov, 2011) and 4hea (Baradaran et al., 2013), both of which show the same relationship among the components of the membrane arm seen in PDB entry 7nyu. In addition, the authors reported carrying out focused refinement, although the resulting map was not deposited.

Figure 2 Model derived from chain L (magenta) of PDB entry 3rko, docked into the region of the map corresponding to chain L of PDB entry 7nyu (EMDB entry EMD-12654). Chain M of PDB entry 7nyu is shown in light blue. (a) The map is computed using the Fourier coefficients arising from analysis of the local map volume (Millán et al., 2023). (b) Chain L of PDB entry 7nyu is shown in light green, and the map is the full map from EMDB entry EMD-12654.

4.1.2. AlphaFold model of a megabody bound to the GABA receptor

The structure of the pentameric human γ-aminobutyric acid (GABA) receptor bound to a megabody (PDB entry 7a5v, EMDB entry EMD-11657) was determined at a high overall resolution of 1.7 Å (Nakane et al., 2020), and models of the GABA receptor monomers are placed easily. However, the local order of each megabody bound to the periphery of the pentamer is significantly worse than that of each GABA receptor monomer, dropping to a local resolution of about 3 Å at the periphery as judged by phenix.local_resolution. To prepare a search model for the megabody (for which there is no independent structure), its structure was predicted using the community ColabFold version (Mirdita et al., 2022) of AlphaFold (Jumper et al., 2021), and the model was processed through phenix.process_predicted_model to remove very low-confidence residues and downweight the lower-confidence remaining residues (Oeffner et al., 2022). The overall reconstruction has fivefold symmetry, but only two of the five copies were placed in the global search. We note that this search took more than 30 min, longer than any of the other global search test cases (Millán et al., 2023).

We wished to understand why the global search failed to find all five copies and to explore whether emplace_local would be an effective alternative to the global em_placement search in similar situations. In this particular case, missing copies can easily be generated by applying the fivefold symmetry to one or other of the two placements, but in the general case the symmetry may be inexact or unknown. Local searches centered at each of the five megabody positions gave similar results (Table 2): each search took about 55 s, correctly placing a copy of the megabody with an LLG score above 500. In each case, the correct orientation was the top hit in the rotation search of around six trial orientations. When run from the ChimeraX interface with the symmetry option enabled, the solutions were correctly expanded over the fivefold symmetry.

Table 2 Results of emplace_local searches for megabody in complex with GABA receptor Megabody copy Sphere shift† (Å) Rotation eLLG‡ Top rotation LLG§ Correct rotation LLG¶ Correct RFZ∥ Final LLG Run time (s) 1 0 54.7 −13.4 (4) −13.4 (1) 5.63 805 58.4 2 0 55.5 −15.3 (11) −15.3 (1) 5.24 536 54.7 3 0 54.6 −11.9 (3) −11.9 (1) 5.90 540 56.6 4 0 54.8 −12.6 (6) −12.6 (1) 5.62 523 56.3 5 0 54.5 −12.1 (5) −12.1 (1) 5.80 533 55.9 1 −9 68.1 −38.6 (55) — (—) — 14 182.8 1 −6 64.7 −32.4 (37) −38.3 (16) 3.57 548 99.5 1 −3 60.7 −27.4 (33) −27.4 (1) 4.52 547 57.9 1 +3 51.5 5.8 (1) 5.8 (1) 7.57 505 56.3 1 +6 51.3 18.6 (1) 18.6 (1) 8.81 505 55.4 1 +9 53.6 31.7 (1) 31.7 (1) 9.89 505 54.7 †Shift of the search sphere relative to the fivefold rotation axis. ‡Expected log-likelihood-gain (eLLG) score for the rotation search (Read et al., 2023). §Top log-likelihood-gain score from the rotation search (number of accepted orientations in parentheses). ¶Log-likelihood-gain score for correct orientation (position in search list in parentheses). ∥Rotation-function Z-score for the correct orientation.

Varying the center of the search sphere had a substantial effect on the efficiency of the search. Since the megabody on the periphery is less well ordered than the GABA receptor in the center of the reconstruction, it seemed reasonable to consider that varying the search center could alter the degree to which the GABA receptor component contributed to the search volume, adding strong signal that could not be explained by the megabody model and thus contributing to noise in the search. Moreover, when noise from the unexplained signal extends to higher resolution than the target signal, the likelihood target is mis-calibrated to expect more signal and less noise at high resolution. This reasoning accounts very well for what was observed when the search sphere for the first copy of the megabody was systematically moved nearer and farther from the fivefold symmetry axis, thereby including more or less of the GABA receptor density, respectively. The search sphere was moved in 3 Å steps from 9 Å nearer to 9 Å farther. The range of tested positions for the search sphere is illustrated in Fig. 3, with Fig. 3(a) showing how much of the GABA receptor structure was contained within the sphere when it was 9 Å closer to the fivefold symmetry axis and Fig. 3(b) showing how little of it was contained when the sphere was 9 Å farther from the axis. With a sphere radius of 25.7 Å, two spheres offset by as much as 9 Å still share 74% of the same volume. Nonetheless, when the search sphere was shifted 9 Å closer to the rotation axis (−9 Å) the search failed because the correct orientation was not found in the default rotation search. When the search sphere was moved farther from the rotation axis, the search succeeded and the statistics (clarity of rotation search, run time) continued to improve as the search sphere was shifted outwards to include less overlap with the GABA receptor region of the map (Table 2). The expected log-likelihood-gain (eLLG) score increases as the search sphere moves closer to the rotation axis, because there is more ordered density to contribute to the signal that is detected in the eLLG calculation. However, because the most well ordered density largely arises from parts of the map that are not explained by the megabody model, it actually contributes additional noise to the search, leading to lower and even negative rotation LLG values for the spheres closest to the rotation axis. Note that negative LLG values for both rotation and translation searches arise when the model predicts the data less well than expected from the presumed quality of the model and data. The variation in the final LLG score for the successful searches for the first copy of the megabody was unexpected but arises from a stochastic difference of one grid spacing in the centers chosen for the spheres used for the final rigid-body refinement; the lower scores correspond to grid centers that are slightly nearer the fivefold axis.

Figure 3 Range of placements of the search sphere when searching for the megabody component. The GABA receptor structure is shown in blue and the megabody is in magenta. (a) Sphere center placed 9 Å closer to the fivefold symmetry axis than the center of the correctly placed megabody component, substantially overlapping the GABA receptor component. (b) Sphere center placed 9 Å farther from the axis, minimally overlapping the GABA receptor component.

The sensitivity of the rotation search to the presence of more strongly ordered density from the GABA component explains the limited success of the global search. In the global search, the reconstruction was covered by six overlapping spheres with radii of 58.2 Å, which did not follow the fivefold symmetry. These spheres are likely to overlap significantly with the GABA component. In addition, because the expected LLG for the rotation search scales inversely with the sphere volume (Read et al., 2023), only about 1/12 of the signal expected for the local search sphere would be expected in the subvolumes for the global search.

4.1.3. Constant region of F_ab bound to α3β4 ganglionic nicotinic receptor

The structure of the α3β4 ganglionic nicotinic receptor bound to the ligand AT-1001 and to the F_ab fragment from a monoclonal antibody (PDB entry 6pv8, EMDB entry EMD-20488) was determined by cryo-EM at a resolution of 3.87 Å (Gharpure et al., 2019). Copies of the F_ab fragment bind to the two α3 subunits in the heteropentamer. In the published structure, only the variable domains directly contacting the receptor were fitted, because the map quality is poor for the constant domains (Fig. 4a). As judged using phenix.local_resolution, the local resolution is about 5.0–5.5 Å in this region. Unfortunately, the box chosen for the map deposition has a boundary very near to the constant domains. This makes it difficult to extract appropriately sized spheres of density for the docking algorithm; the map analysis assumes that the solvent region has the same noise distribution as the protein region, so it is not appropriate to pad the input map with zeros.

Figure 4 Searching for the Fab constant domains in the complex with the α3β4 ganglionic nicotinic receptor (EMDB entry EMD-20488). (a) The published structure is shown in the deposited map. The modeled part of the Fab fragments consists of the variable domains of the heavy chain (light orange) and the variable domains of the light chain (light green). The map is of much poorer quality for the constant domains of these chains, at the bottom of the image. (b) The search sphere, corresponding to the uninterpreted map region in the lower right panel (a), is indicated by the yellow sphere. (c) The placed model for the constant domain from chain D of PDB entry 4wfe is shown as a blue cartoon, while the model derived from chain H of PDB entry 3mxv is shown in pink.

We wished to see whether models of the constant domains could be docked, either with the global em_placement search or with emplace_local. In the published structure, the initial model for the variable domain of the light chain was derived from PDB entry 4wfe (Brohawn et al., 2014) and the variable domain of the heavy chain from PDB entry 3mxv (Maun et al., 2010). Our models of the corresponding constant domains were derived from the same PDB entries. Although there are two independent copies of the F_ab bound, only that interacting with the α3 subunit in chain D of PDB entry 6pv8 is sufficiently far from the edge of the deposited reconstruction.

Global docking trials of the constant domains with em_placement failed for reasons similar to those encountered in the previous two test cases: strong noise from better-ordered parts of the map that contained other components misled the search algorithm. When docking the constant domain from the light-chain model (chain D of PDB entry 4wfe) in the global search, three potential solutions were found with LLG values varying from 35 to 70. The solutions are nonrandom, but they incorrectly superimpose β-structure from the constant domain on β-structure from the better-ordered components. Docking the constant domain from the heavy-chain model (derived from chain H of PDB entry 3mxv) gave similar incorrect results, with LLG values varying from 23 to 58 for five potential solutions, which are all incorrect but nonrandom.

In contrast, local docking with emplace_local succeeded when care was taken to avoid searching in the part of the map occupied by the variable domains. This was easiest to achieve with the interactive ChimeraX interface. Fig. 4(b) shows the positioning of the search sphere in ChimeraX to avoid the part of the map accounted for by the variable domains of the relevant copy of the F_ab (interacting with the α3 subunit in chain D of PDB entry 6pv8), while Fig. 4(c) shows the result of searching within this volume for the two constant-domain models. The light-chain constant-domain model gave an LLG score of 159 and a map correlation of 0.473, while the heavy-chain constant-domain model yielded an LLG of 135 and a map correlation of 0.481.

4.2.1. Chain L of the E. coli respiratory complex I

As noted above, the local map resolution around chain L is estimated by the original authors to be about 9–11 Å, although the nominal (best) resolution for the whole reconstruction is 3.8 Å. In addition, the signal to noise for this map is highly anisotropic; the authors noted substantial orientation bias in the particles (Kolata & Efremov, 2021). We ran a series of local docking tests using either half-maps or the full map, and varying the nominal resolution limit (Table 3). If half-maps were used, the docking searches were successful for all resolution limits tested, from 3.8 to 13 Å. However, when the full map was used the docking searches failed for resolution limits better than 7 Å (i.e. when the resolution was indicated to be better than it actually is), confirming that the method using a single full map is indeed more sensitive to the choice of resolution limit. The full-map docking calculation at higher resolution limits was drawn into fitting the better-ordered map features of chain M.

Ideally, a proper calibration of the error model in the likelihood target, based on the statistical analysis of half-maps, should account for the lack of information in higher resolution Fourier terms than the local resolution, effectively ignoring them. However, we see that the inclusion of high-resolution data degrades the performance of the docking algorithm in this case, even when half-maps are used, indicating that there is still room for improvement in the algorithms estimating the signal and noise contributions.

4.2.2. AlphaFold model of megabody bound to GABA receptor

In this case, the imposition of fivefold symmetry on the reconstruction has helped to ensure that there is little anisotropy in the signal or noise. As a result, the approximation used for the full-map searches is more appropriate than in the other test cases and the success rates are very similar (Table 3). In fact, searches imposing a resolution limit of 9 Å fail with the half maps but succeed with the full map, although the separation between the correct score and the top incorrect score is relatively small.

4.2.3. Constant region of F_ab bound to α3β4 ganglionic nicotinic receptor

This test case is complicated by the fact that the deposited reconstruction has been truncated close to the unmodelled domains. The heavy-chain constant domain from the F_ab bound to chain D is furthest from the map boundary, so the model derived from chain H of PDB entry 3mxv was used for the full map docking comparisons.

Both sets of searches, using half-maps or full maps, succeed over the full range of resolution limits tested, from 3.87 to 13.0 Å. However, the half-map searches yield less ambiguous answers and, although the full-map search at 13.0 Å resolution succeeds, there is very little distinction between the correct placement and the top incorrect solution.

Note that for all test cases the single-map protocol is up to twice as fast when it succeeds, because it does not require the likelihood-based estimation of signal and noise parameters. In addition, in a variety of tests for cases with better signal strength, the single-map protocol was found to be robust and efficient (results not shown).

4.3.1. Chain L of the E. coli respiratory complex I

Using the command fitmap #2 in #1 search 1000 radius 20.5, where the trimmed model from chain L of PDB entry 3rko was display item 2 and the deposited map was display item 1, the correct placement (with an average map value score of 1.444) was found in ten of the 1000 trials, taking a total of 44.6 s. If either the search model was moved closer to the position of chain M in the deposited structure or the search radius was increased to 80 Å, the fitmap algorithm was led to find an incorrect superposition on chain M with a higher score of 1.796, similar to the single full-map search with emplace_local when run at resolutions higher than 7 Å.

The fitmap procedure in ChimeraX also succeeded when a resolution keyword was given to activate the map-to-map fit, for a range of resolutions between 3.8 and 9.0 Å. Run times were considerably longer than the comparable runs using the emplace_local procedure (Table 3), taking from 46.2 s at 9.0 Å to 186 s at 3.8 Å. When a resolution of 11.0 Å was chosen for fitmap, the correct placement was second in the list of possibilities, with a score of 0.599 compared with 0.602 for the highest incorrect result. By comparison, emplace_local succeeded at resolutions as low as 13.0 Å using either the full map or half-maps (Table 3).

4.3.2. AlphaFold model of megabody bound to GABA receptor

Three sets of 1000 search trials were carried out using the fitmap command with a radius of 24.0 Å, each taking about 43 s. In one of these sets the correct placement with an average map value score of 0.027 was found twice, but in the other two sets of trials the search failed, yielding a top score of 0.015. A larger-scale search found the correct solution in five of 5000 trials, taking 211 s. To be confident of finding the correct solution in the random search for this problem, we conclude that several thousand trials would indeed be required. By comparison, the successful searches using the deterministic emplace_local algorithm took about 55 s (Table 2).

The map-to-map option was somewhat more successful, giving 3–8 solutions per 1000 trials when the resolution was specified in the range 1.7–5.5 Å (taking 85.2–157 s), but failing or yielding only a single solution when the resolution was set lower. In contrast, emplace_local succeeded when using half-maps with the resolution specified between 1.7 and 7.0 Å and with just the single full map at resolutions as low as 9.0 Å, with each of these calculations taking less than a minute (Table 3).

4.3.3. Constant region of F_ab bound to α3β4 ganglionic nicotinic receptor

The ChimeraX fitmap command was tested for docking the same copy of the heavy-chain constant domain (derived from chain H of PDB entry 3mxv) as the full map in emplace_local tests. A default search with 1000 trials and a radius of 22.7 Å ran in 34.4 s; the correct solution was found eight times with a score of 0.00805, but an incorrect solution (superimposed on the light chain) had the slightly higher score of 0.00820. The map-in-map option was again more successful, with the top-scoring solution being correct for resolutions of 3.87–9.0 Å, taking from 35 to 58 s. With a resolution of 11.0 Å, the correct solution (found five times) was third in the list with a score of 0.734, compared with 0.756 for the top solution. At 13.0 Å the correct solution was not found, even with as many as 10 000 trials.