2.1. Quantifying the difference between scattering curves by volatility ratios

According to Shannon channel information theory, any SAXS profile can be captured by a small number of independent parameters. Similarly, one can also summarize the difference between any two scattering profiles I(q) and J(q) by changes in related structural parameters such as the radius of gyration R_g, Porod volume V_P and volume of correlation V_c (Rambo & Tainer, 2013a). Alternatively, explicit difference measures such as linearity of fit, χ_lin. (Chen et al., 2018), and volatility ratio V_R (Hura et al., 2013) can be computed. Each of these quantities smoothly captures the net change in scattering profiles due to changes in the underlying populations of the bound and unbound receptor. In particular, V_R quantifies SAXS differences by computing the ratio of intensities between the two curves and summing the scalar changes of mean ratios between adjacent Shannon channels in q-space. To give an analogy, the V_R metric is sourced from the field of economics where it describes which of two stock prices has exhibited more rapid fluctuations over a period of time.

A modified definition of V_R is presented below, adapted for ligand-based screening. For a given set of titrations conducted at the same receptor concentration and beamline session, a reference profile J(q) is defined by averaging all buffer-subtracted scattering profiles measured on the apo protein. The geometrically normalized ratio R(q) between J(q) and I(q) at each titration point is evaluated, ignoring any points where I(q) < 0 or J(q) < 0:

Figs. 1(c) and 1(d) illustrate the I(q) and R(q) series of two ligand titrations Arg:HisBP and Orn:HisBP, defining J(q) as the respective apo intensities. Here, N_q defines the total number of raw measurements over scattering angles q, such that N_q is much greater than the number of associated independent Shannon channels N_S. An optional fitting constant c is applied to take into account variations in buffer scattering that arise from unbound ligands and counterions, while preserving the symmetry property V_R.

To account for the oversampling of SAXS profiles relative to the Shannon information content, R(q) is divided along q into N_S channels of width Δq = π/D_max, resulting in M channels and M(q) points within each complete channel. A fixed D_max is chosen based on the largest observed particle size across the titration. Applying geometric means again produces a mean ratio R_i for each channel [Fig. 1(e)],

In practice, the usable q-range is rarely an integer multiple of Shannon channels. A weight factor w_i is thus applied, defined to be 1 for all channels except for the partial bin at the highest q, where the number of raw measurements in the channel N_q,channel may be less than M_q. V_R is defined as the sum of scalar differences between consecutive R_i,

In this study, V_R is numerically minimized over the constant parameter c by Powell minimization (Powell, 1964), with its initial value set to zero.

3.1. Sample preparation

The E. coli HisBP gene (Uniprot entry P0AEU0, residues 23–260) was cloned into pET-M11 plasmids containing kanamycin resistance, T7-lac promoter and an N-terminal His₆ tag with a TEV cleavage site. The pETMSCIII plasmids for GlnBP (Uniprot entry P0AEQ3, residues 23–248) and DEBP (Uniprot entry P37902, residues 28–302) were generously provided by Professor Colin Jackson, containing ampicillin resistance and N-terminal His₆ tags.

The production and purification of GlnBP and DEBP follow that of previous protocols (Clifton & Jackson, 2016). We summarize this below with slight modifications for HisBP. After plasmid amplification in E. coli DH5α cells, protein expression was carried out in E. coli BL21(DE3) cells. Expression cultures were grown in LB medium at 37°C supplemented with either 100 µg ml⁻¹ ampicillin (GlnBP/DEBP) or 50 µg ml⁻¹ kanamycin (HisBP). For NMR experiments, LB medium was replaced by ¹⁵N-labelled M9 minimal medium. Once OD₆₀₀ exceeded 0.6, cultures were induced with 1 mM isopropyl β-D-1-thiogalactopyranoside for 4 h. Cells were spun-down, resuspended in loading buffer (500 mM NaCl, 20 mM imidazole and 20 mM NaH₂PO₄ pH 7.4), lysed by sonication, then filtered before conducting His₆-tag-based purification by Ni-nitrilotriacetic acid affinity (Ni-NTA) chromatography. After initial loading and washing, on-column refolding was conducted via a decreasing urea gradient from 8 M to 0 M to remove bound endogenous ligands, then eluted in buffer (500 mM NaCl, 300 mM imidazole and 20 mM NaH₂PO₄ pH 7.4). HisBP was further exchanged back into the loading buffer, cleaved overnight via addition of TEV protease, then re-loaded onto a second Ni-NTA column to separate the similar-sized N-terminal tags. All PBPs were finally subjected to size-exclusion chromatography (SEC) in the final buffer used for all experimental measurements (100 mM NaCl, 0.5 mM TCEP and 20 mM NaH₂PO₄ pH 7.4), except for NMR meaurements where samples were diluted by the addition of 9% D₂O.

3.2. SAXS measurements

Candidate ligands for each protein were selected on the basis of known affinities in the literature and chemical similarity. Titrations were conducted at fixed protein concentrations to exclude signal-to-noise factors. An initial mass concentration of 2.0 or 4.0 mg ml⁻¹ was employed in prospective experiments, then scaled to 2.0, 1.0, 0.5 and 0.25 mg ml⁻¹ in later concentration-variation studies. Twelve-point titrations were prepared at ligand-protein ratios 0.0, 0.2, 0.6, 0.8, 0.9, 1.0, 1.1, 1.2, 1.5, 2.0, 4.0 and 10.0 to cover a theoretical K_D sensitivity within two orders of magnitude of the fixed protein concentration employed, assuming ∼5% random error (Fig. S1 of the supporting information). A total of eight beamline experiments were conducted, using the automated sample changing environments available on site, operated in constant-flow mode: three times at ESRF BM29, three at DESY P12, once at Australian Synchrotron SAXS/WAXS and once at Diamond B21. Of the above, one prospective session at ESRF and two at DESY were dedicated to identifying a suitable set of PBP interactions and optimizing protocols. Their preliminary results have been excluded from this report. Furthermore, experiments at ESRF BM29 and Diamond B21 were carried out on site, while the DESY P12 experiment was carried out by mail-in. For these measurements, samples were prepared by pipetting ligand–protein mixtures onto 96-well plates prior to transport. As for the Australian Synchrotron measurements, apo–HisBP was lyophilized in its final buffer and reconstituted on site using pure H₂O and then mixed with the ligands in 96-well plates. The measurement parameters for each site are catalogued in Table 1. For brevity, we report six representative scattering curves for HisBP, GlnBP and DEBP in their free and native ligand-bound forms in Table S5 of the supporting information following community guidelines (Trewhella et al., 2017).

3.3. Automated analysis pipeline

The SAXScreen workflow was utilized for the semi-automated prediction of binding curves from scattering intensities (Chen et al., 2018), whose methodology we reproduce here with modifications for quantitative prediction. Buffer-subtracted intensities provided from respective synchrotron pipelines were used as starting points for analysis. DATGNOM (Franke et al., 2017) was used to determine the maximum molecular extent, D_max, for each PBP, which ranges from 5.6 to 8.2 nm depending on the protein size and ligand binding (cf. Table  S5). The average values for apo–HisBP, GlnBP and DEBP were determined to be 5.9 ± 0.1, 6.4 ± 0.3 and 8.2 ± 0.2 nm, respectively. Thus, an intermediate value of 7.2 nm was fixed for all computations involving D_max including V_R.

ATSAS AUTORG (Petoukhov et al., 2007) was utilized to algorithmically compute scattering angle regions obeying the Guinier approximation (Fig. S2). This was used to assist in locating data points affected by sample handling errors or measurement failures, along with detectable aggregation. The ideal minimum angle after removal of parasitic scattering is 0.1–0.15 nm⁻¹, although a more conservative cutoff was used to collectively eliminate residual aggregation. The maximum usable q was determined by visual inspection of noise. The final ranges used across all HisBP beamline sessions were: 0.2–2.0 nm⁻¹ at 20 µM and below, 0.25–2.5 nm⁻¹ at 40 µM, and 0.3–3 nm⁻¹ above 80 µM. The q-ranges for DEBP and GlnBP were set to 0.1–2.8 nm⁻¹.

We considered the data-cleaning algorithms provided by SAXS Merge to further exclude user bias (Spill et al., 2014), but did not use this in the final analysis. A common scattering reference is created per HisBP concentration and per beamline experiment by averaging apo protein replicates after discarding outliers. This reference is used for both V_R and χ_lin computations. Other metrics have been computed as previously reported (Chen et al., 2018).

To fit binding curves against metrics, we consider all titrations conducted per protein concentration per beamline experiment as a single set, after removing data points resulting from aggregation, preparation errors or measurement errors. For a given metric X, model curves are constructed using the following free parameters: the expected value for the apo receptor X_apo, a set of values for each receptor–ligand X_holo(L) and a set of ligand affinities log₁₀K_D(L). As the majority of metrics vary pseudo-linearly with population changes (Fig. 2), we adopt the following linear model for simplicity,

The set of model curves together with equation (3) were fitted against observed data using a Powell minimization algorithm (Powell, 1964). Since the two-state binding curve at constant [R] cannot effectively discriminate between K_D values much larger or smaller than [R], fitted K_D values are limited to within four orders of magnitude of the receptor concentration (cf. Fig. S1). Two uncertainty estimation methods were implemented to define error bars in K_D. For metrics possessing measurement uncertainty (χ_lin, R_g and V_c), 1000 replicates were produced by adding Gaussian noise with σ equal to the measurement uncertainty. Error bars indicate σ of logK_D from the ensemble of replicate predictions. For metrics where uncertainty was not computed (V_R and V_P), the uncertainty was estimated by single-point removal, where K_D was recomputed after removal of each titration point. The σ of the resulting replicates are taken as the σ of logK_D. To eliminate cases where the fitting process fails due to ill-constrained parameters, replicates were discarded if the fitted apo–holo differences were >3σ from the mean value of all replicates.

Figure 2 Theoretical modelling of the changes in structural parameters as a function of the mixtures of two conformers. (a) Theoretical SAXS profiles of three ligand-triggered population transitions, following open versus closed leucine-binding protein (LBP), T versus R states of aspartate carbamoyltransferase (ATCase) and dimeric versus hexameric forms of human ribonucleotide reductase (hRNR). Profiles were computed by CRYSOL based on crystal structure coordinates, see the main text for details. (b) Corresponding structural parameters computed from a mixture of two conformations for VR, Rg and Vc. VR values were calculated over 0–2 nm−1 for LBP and ATCase, and over 0–1 nm−1 for hRNR.

3.4. Isothermal calorimetry

All ITC measurements were conducted on a Malvern MicroCal PEAQ ITC at 20°C with stirring at 200 rev min⁻¹ using the same buffer as in SAXS measurements. The cell was initially loaded with 200 µl of 20 µM protein with an initial ligand concentration of 200 µM in the syringe to quantify His:HisBP binding. This was further adjusted in subsequent runs to resolve weaker interactions as necessary. ITC titration curves for all experiments are shown in Fig. S3 along with the concentrations used.

3.5. NMR

All NMR experiments have been carried out at 298 K on an 800 MHz Bruker Avance III NMR spectrometer equipped with a cryogenic probehead. Titrations of HisBP against His and Arg were measured via recording ¹H–¹⁵N HSQC spectra at discrete ligand:protein ratios of 0.0, 0.1, 0.2, 0.3, 0.4, 0.6, 0.8, 0.9, 1.0, 1.1, 1.2 and 1.5 for His; and 0.0, 0.1, 0.2, 0.3, 0.4, 0.6, 0.8, 0.9, 1.0, 1.1, 1.2, 1.5, 1.8 and 2.1 for Arg, respectively. Data were processed with NMRpipe (Delaglio et al., 1995), analyzed using NMRFAM-Sparky (Lee et al., 2015) and visualized with Python modules nmrglue and matplotlib (Helmus & Jaroniec, 2013; Hunter, 2007).

Backbone assignments of apo- and His-bound HisBP have been derived from BMRB entries 19242 and 19245 (Chu et al., 2013). The assignment of Arg-bound HisBP is produced by extending the apo-HisBP assignment along titrations, leaving sites in slow exchange unassigned. For affinity computations based on chemical shift perturbations, ¹H and ¹⁵N shifts have been combined to a composite shift δ = [(δ_H)² + (0.2δ_N)²]^1/2. The derivation of an overall dissociation constant from chemical shift perturbations follows the work by Williamson (2013), where the shift in peak position is used to derive free and bound populations without considering peak intensities. The effect of site-specific exchange rates upon peak positions is taken into account (London, 1993). We discarded residues with either insignificant shifts at saturation (δ < 0.05) or which were in slow exchange such that peak positions alone were no longer informative. This resulted in 110 sites included in the fitting process. The binding interaction is modelled with site-specific bound-state CSP, site-specific bound-state lifetimes τ and a single overall K_D. This translates to 221 degrees of freedom, fitted to 1468 target CSP values.

3.6. Software and data availability

The SAXScreen software has been previously published at https://www.github.com/zharmad/SAXScreen and has been updated to include V_R computations. The dataset of the 1D sample and buffer scattering intensities for each beamline has been made available on Zenodo and accessible via https://dx.doi.org/10.5281/zenodo.3355877. Representative scattering datasets have been deposited at SASBDB (Valentini et al., 2015), encompassing HisBP, DEBP and GlnBP in their unbound states and bound to eponymous cognate ligands (SASBDB identifiers: SASDFD8, SASDFE8, SASDFF8, SASDFG8, SASDFH8 and SASDFJ8).

4.1. Theoretical modelling

To enumerate the relationship between the populations of two-state mixtures and the metrics computed from their composite scattering profiles, theoretical modelling was conducted to simulate three ligand-triggered structural transitions, utilizing six atomic coordinates from the PDB: the closure of leucine-binding protein (LBP) upon ligand capture by 1usg and 1usi (Magnusson et al., 2004), the product-regulated switching between a low activity T-state and a high-activity R-state of aspartate carbamoyltransferase (ATCase) by 1za1 and 7at1 (Wang et al., 2005; Gouaux et al., 1990), and the assembly of dimeric versus hexameric states of human ribonucleotide reductase (hRNR) by 3hnc and 6aui (Fairman et al., 2011; Brignole et al., 2018). Fig. 2 demonstrates that, assuming ligand contributions have been subtracted, the change in population produces quasi-linear changes in the structural metrics. The effective R_g versus population curve is strongly non-linear for the dimer–hexamer transition of hRNR due to the non-monodispersity of intermediate mixtures. In contrast, V_R and V_c deviate by <3% from linear regression fits across all three theoretical titrations. This suggests that populations can be directly estimated from a linear fit to parameter changes. A more accurate polynomial fit appears to be non-trivial to devise, as the curvature depends on the scattering molecules.

4.2. HisBP screening at Diamond B21

The 26 kDa HisBP possesses four known amino acid ligands with K_D ranging from 64 nM to 72 µM: histidine, arginine, lysine and ornithine (Table 2). Titrations against each ligand were performed at 10, 20, 40 and 80 µM at a total photon dose of 10¹⁴ to evaluate the impact of receptor concentrations on screening performance (Fig. 3). First, both the signal-to-noise ratio (S/N) and usable q-range were found to be dependent on the receptor concentration employed, as would be expected when the total dose is held constant. In the case of HisBP, dropping concentrations from 40 µM to 20 µM leads to loss of detectable intensity changes above q > 2  nm⁻¹ (cf. Fig. S4). However, their effects upon structural parameters are different: the comparative parameters V_R and χ_lin decrease in magnitude with decreasing concentration, but their uncertainties remain constant. Even at the minimum 10 µM HisBP, V_R binding curves could still be resolved. In contrast, the structural parameters V_c and R_g increase in uncertainty with decreasing concentration. This increase in uncertainty is larger than the total observed change caused by ligand binding at 10 and 20 µM, although the size of the errors is likely to be over-estimated.

Figure 3 Detailed analysis of HisBP ligand screening at Diamond B21 at four concentrations between 10 and 80 µM. Colours represent HisBP titrated against four ligands: His (black), Arg (blue), Lys (violet) and Orn (red). (a) R(q) plotted over the q-range included in the analysis. (b) Computed VR curves. (c) Computed χlin curves. (d) Computed Vc curves. (e) Computed Rg curves.

4.3. Replication with varying photon doses

The accuracy of the above metrics and final uncertainties are affected by the S/N of the measured SAXS profiles. Thus, replicate HisBP screening trials were carried out at three other beamlines, ESRF BM29, DESY P12 and Australian Synchrotron SAXS/WAXS, so as to gather sufficient data for an analysis based on photon exposure. The summary results of these replicated screening trials are shown in Fig. 4 and Table 2, including again HisBP titrations at multiple protein concentrations. For completeness, the binding curves for all parameters and all beamlines are included in Figs. S5–S7.

Figure 4 Replicate VR titration curves of HisBP against four ligands: His (black), Arg (blue), Lys (violet) and Orn (red). Data collected at various total doses: (a) 1.6 × 1014 photons at Diamond, N = 192; (b) 2.6 × 1013 photons at DESY, N = 172; (c) 2.6 × 1013 photons at Australian Synchrotron, N = 144; and (d) 3 × 1012 photons at ESRF, N = 144. The HisBP concentrations used within each experiment are labelled on respective plots. Note that the maximum q-range measured in (d) was 2.8 nm−1, which affected the VR.

We first observe that the total photon dose imposes a minimum viable concentration: although 10¹⁴ photons (Diamond) proves sufficient to permit screening at 10 µM protein (0.26 mg ml⁻¹), the use of 10¹²–10¹³ photons at other beamlines resulted in insufficient S/N at this concentration to resolve scattering changes above the noise. In particular, the inter-sample variations increase with a decreasing photon dose. This implies that binding can only be detected in practice if it exerts a V_R change of >0.1 within the usable q-range. The Australian Synchrotron replicate additionally exhibits smoother fits relative to the DESY replicate at the same total dose. This can probably be explained by the division of the total dose into fewer frames at the former, since S/N scales proportionally with photon counts per frame but only as a square root of the number of frames. However, the division of photon exposure should also be balanced with the potential need to remove later frames due to cumulative radiation damage. Dosage comparisons between beamlines are also subject to differences in measuring environment, camera size and other factors influencing the raw counts seen by the detector.

Further analysis of the scattering parameters also suggests a dependence of the maximum V_R upon ligand identity. The magnitude of the change in V_R for the native His ligand is consistently but marginally larger than that observed for other binding ligands. This difference is more visible with χ_lin binding curves (Fig. S5), further suggesting structural differences between native and non-native complexes. This was confirmed by NMR chemical shift perturbations of HisPB:His and Arg:HisBP, where the two interactions share some but not all contacts (Figs. S8–S10). In particular, the signals from numerous locations around the active site of Arg:HisBP differ from those of His:HisBP, suggesting that the larger Arg side chain enforces an alternate arrangement of the complex.

4.4. Dissociation constants from SAXS titrations

Dissociation constants (K_D) were computed from V_R curves by assuming that these accurately represent underlying population changes (Table 2), with equivalent calculations via other metrics included in Tables S1–S4. Of the Diamond B21 results, the 20 µM titrations appear to be the most consistent with reference values derived from ITC. The largest deviations occur when the target K_D falls outside two orders of magnitude of receptor concentration (Fig. 5), or falls below the minimum viable screening concentration. Specifically, the pairing of micromolar [HisBP] required for SAXS and nanomolar His:HisBP K_D results in a dependence of fitted K_D values upon [HisBP], which is echoed to a lesser extent by Arg:HisBP. This disparity between SAXS- and ITC-based K_D appears to be mitigated with higher photon doses, such that the 10¹⁴ photon dosage utilized at Diamond reliably produced lower nanomolar predictions for His:HisBP. Other residual variations between beamlines arise from sample handling limitations. AUTORG analysis of Guinier regimes (Fig. S2) identified a systematic residual aggregation resulting from lyophilization and on-site reconstitution protocols, which affected the Australian Synchrotron measurement. Sporadic sample handling errors and measurement failures also reduced the number of titration points used to determine binding. Notwithstanding these complications, K_D predictions from V_R appear to be superior in accuracy to those based on other parameters, which sometimes failed to achieve qualitative ranking (Tables S1–S4). In summary, these results suggest that a viable screening setup for a system comparable to HisBP in terms of size and magnitude of structural change can be screened at 20 µM using 10¹³–10¹⁴ photons to achieve acceptable resolution between nanomolar and micromolar binding.

Figure 5 Computed KD from VR curves in Fig. 4, plotted as a function of receptor concentration [HisBP] and total photon dose. Colours represent replicates at different total doses: (black) 2.6 × 1013 photons at DESY, (blue) 3 × 1012 photons at ESRF, (red) 2.6 × 1013photons at Australian Synchrotron and (violet) 1.6 × 1014 photons at Diamond. Reference values from ITC are shown as dashed grey lines with error bars at the plot edges. Low confidence limits imposed by constant-receptor titrations are represented by light-yellow regions where KD lies outside one or two orders of magnitude of [HisBP]. For comparison, equivalent plots using other metrics are shown in Figs. S11–S13.

4.5. Prospective screening of GlnBP and DEBP

In general, the minimum S/N required to conduct screening depends on the magnitude of the structural changes of a system relative to its physical size. This is relevant to PBPs as they can exhibit a solution equilibrium between open and closed conformations, regardless of ligand binding (Feng et al., 2016). Thus, the ability for bound ligands to alter the conformational equilibrium affects the minimum viable concentration and total dose. To illustrate the dependence of screening performance on scattering magnitude, prospective screening trials of glutamine-binding protein (GlnBP) and aspartate/glutamate-binding protein (DEBP) are presented. These together with HisBP represent three scenarios: GlnBP exhibits a marginal shift in open–closed equilibria upon ligand binding, DEBP switches from an open-dominated to closed-dominated state, whereas HisBP presented above shifts from an open–closed mixture to a closed-dominated bound complex. This is reflected in the sharp contrast in the net R_g decrease between the three PBPs (Table 3).

Fig. 6 summarizes GlnBP and DEBP screening conducted at 2 mg ml⁻¹ and 10¹² photons. The small net change of conformations caused by Gln:GlnBP binding translates to miniscule 10% changes in intensities below q < 1.5 nm⁻¹. This in turn produces poorly defined V_R curves with ΔV_R values of 0.09 versus residuals of ∼0.03. The poor S/N strongly limits resolvable K_D such that only qualitative binding can be deduced (Table 2). Notably, the Arg:GlnBP interaction can be detected thermodynamically in ITC, but not structurally in SAXS. This may be due to the Arg side chain stabilizing a complex with dimensions very similar to the average apo distribution. In the same vein, while DEBP experiences a larger compaction on ligand binding relative to HisBP, the compaction is smaller relative to the larger size of DEBP. Thus its ΔV_R is only 0.16 compared with 0.4–0.5 seen for HisBP. Curiously, the SAXS titrations also suggest an unexpected binding between Asn:DEBP and Gln:DEBP. Here, one notes that selectivity of Asp:DEBP versus Glu:DEBP is 1:10 in ITC but 1:400 in SAXS while ΔV_R is comparable. This suggests that the Asp:DEBP complex is similar in conformation but less stable than the Glu:DEBP complex. The above analyses illustrate a potential application for SAXS to disambiguate ligand targets on the basis of their structural mechanisms.

Figure 6 Summary of SAXS-based screening performance on GlnBP and DEBP. (a) Ratio curves of R(q) for the titration between GlnBP and DEBP with its cognate ligands Gln and Glu, respectively. (b) VR curves for the prospective screening trial of GlnBP with native and other amino acid targets. (c) VR curves for the prospective screening trial of DEBP with native and other amino acid targets. For comparison, equivalent curves using other metrics are shown in Fig. S14.