2.1. Sample quality

Given the paramount importance of sample preparation and characterization for biomolecular structure modelling using SAS data, sample quality must continue to be emphasized. A SAS profile can be measured from any sample and, unlike crystallography and NMR where there are both quantitative standards and internal controls for assessing sample and data quality, a SAS profile by itself does not provide sufficient information for such assessment. Fundamental to the successful interpretation of a biomolecular SAS experiment in terms of structural models is that the scattering data are demonstrated to be from a highly purified solution of monodisperse particles in the dilute solution regime. This means that the SAS data are free of contributions from contaminants and the effects of nonspecific aggregation or inter-particle distance correlations. To avoid these systematic biases, well characterized solutions of high purity must be measured, yielding SAS profiles that encode information regarding biomolecular structure (the form factor). Additionally, as coherent scattering that encodes the desired structural information for a biomolecule in solution is inherently weak (e.g. ∼1 in 10⁶ incident photons are scattered from a 1 mg ml⁻¹ solution of a 15 kDa protein; Stuhrmann, 1980), accurately and precisely scaled measurements, with respect to incident radiation, of solvent plus biomolecule and precisely matched solvents also are essential. As described in the following sections, an inaccurate solvent subtraction from the solvent plus the biomolecule of interest will affect important validation parameters and structural interpretation.

Traditionally, solution SAS data for structural evaluation and modelling have been collected at multiple concentrations of the particle of interest to evaluate and eliminate concentration-dependent contributions to the scattering through the strategic choice of solvent conditions or extrapolation to infinite dilution. The molecular mass (M) or volume (V) of the scattering particle then can be estimated from the zero-angle scattering, I(0). The calculation of M or V from I(0) requires accurate concentrations of the sample constituents to be determined, which can be challenging. While UV-based determination of concentration can be difficult for some systems (for example proteins with few aromatics or with solvents containing UV-absorbing components), concentration can often be determined to better than 10% accuracy (Gasteiger et al., 2005). Agreement of the I(0)-based estimate of M with that determined from the chemical composition of the scattering particle is important in validating that the measured SAS profile corresponds to the form factor of the particle of interest, is free of nonspecific associations and is in the dilute solution regime. When determining M from chemical composition it is important to include not only the protein or nucleic acid sequence, but also purification tags if still present, plus any cofactors, modifications or bound ligands, and in the case of SANS the isotopic composition. There may be situations where the determination of M from I(0) differs from that calculated from the composition. For example, DNA and RNA as polyanions can attract a diffuse ion atmosphere where neutralizing counterions are localized near their surface and will contribute significantly to the scattering. These effects on particle scattering can be difficult to quantify a priori. In such cases, there should be some discussion dedicated to explaining any major discrepancies from the expected M.

In the case of folded structures, and providing that solvent subtraction is accurate, one can use the complementary method for estimating M using the scattering invariant (Q_i; Porod, 1951) and its relationship to the scattering particle volume (Debye et al., 1957; Porod, 1951). In the case of unfolded or very flexible systems, the Kratky plot (Kratky, 1982) can provide evidence for the flexibility. Solvent-blank mismatch with the sample will introduce errors that will confound these analyses as they depend on an accurate representation of the scattering at high angles. For proteins, the high-angle data are orders of magnitude less intense than the lowest angle data, and are only a few parts per thousand above the solvent scattering. For SANS data, contributions to the background from incoherent scattering can also prove problematic as the incoherent scattering cross-section of ¹H is 10–20 times the total scattering cross-sections of other nuclei present in a biomolecule (Jacrot, 1976). As a result, solvent subtractions for SANS data with significant ¹H often include adjustments by an ad hoc addition or subtraction of a constant to force the scattering at high angles to approximately zero. The need for this adjustment can be minimized by using a final dialysate as the solvent blank from dialysis that has been maintained in a closed environment to avoid differential ¹H–²H exchange and calibrating sample and solvent transmissions against pure ¹H₂O and ²H₂O.

Developments of inline purification of samples using size-exclusion chromatography (SEC) at synchrotron SAXS beamlines (see, for example, Brennich et al., 2017; David & Pérez, 2009; Graewert et al., 2015; Mathew et al., 2004) and at SANS beamlines (Jordan et al., 2016) is becoming increasingly popular. These SEC–SAS measurements involve the collection of SAS data as the solution elutes from the SEC column, and thus enable the separation of components of mixtures and polydisperse solutions. In the case of membrane proteins, this allows the separation of encapsulated proteins from empty detergent micelles or nanodiscs (Berthaud et al., 2012). This combined SEC–SAS approach has been extremely successful at synchrotron SAXS facilities and has opened up studies of systems that were previously impossible owing to time-dependent aggregation. A drawback to the approach is the necessary dilution of the sample on the SEC column. Additionally, as the fluid in the centre of the tubing linking the SEC column to the SAXS cell flows faster than that at the edges of the tube (Poiseuille flow), the SEC peak will broaden before measurement. Depending on the path length between the measurement cell/capillary and the end of the column, this broadening can be quite significant. Excessive path lengths will not only degrade the resolution of the eluted peaks, but the UV-absorbance measurements of the eluent may not correlate with the SAS measurement frame, which limits the ability to determine sample concentrations. Monitoring UV absorbance immediately prior to SAS measurements with minimal intervening path length and volume, or ultimately with coincident measurement, facilitates increased accuracy in the estimation of M or V from I(0).

Excellent descriptions for the preparation of high-quality samples and well matched solvent blanks for SAXS and SANS experiments have recently appeared in Nature Protocols (Jeffries et al., 2016; Skou et al., 2014). Together, these papers provide important and comprehensive practical advice for the preparation of samples for a SAS experiment that demonstrably meet the stringent requirements for obtaining SAS data suitable for structural analysis. Table 1 summarizes our recommended reporting guidelines for sample details.

2.2. Data acquisition and reduction

In the case of isotropic solution scattering, data reduction refers to the process of converting counts on a detector to the one-dimensional scattered intensity profile arising from the sample, with associated errors, as I(q) versus q (where q = 4πsinθ/λ, 2θ is the scattering angle and λ is the wavelength of the radiation). To obtain the SAS profile relating to the structure of the particle of interest, the data-reduction software must take into account detector sensitivity and non­linearity, sample transmission, incident intensity and accurate and precise subtraction of solvent scattering. Dilute solution measurement places severe requirements on normalizing scattering intensity measurements, which today can be better than 0.1% and fully satisfactory. All of these procedures are described in detail in Svergun et al. (2013).

The data-reduction process may also require addressing potential instrumental `smearing' effects on the SAS profile (see chapter 4 of Glatter & Kratky, 1982). The theory guiding the interpretation of SAS data in terms of structure generally assumes an effective point source and a single wavelength. The instrument setup used for a SAS experiment may be an excellent approximation to a point source, or may differ significantly from it and thus require corrections to be made to data or to model scattering profiles for comparison with the experiment. The wavelength resolution (Δλ/λ) for SAXS (whether synchrotron or laboratory-based) is generally a good approximation to a single wavelength, while for SANS it can be of the order of 10–15% in order to optimize the neutron flux on the sample (for examples, see https://www.ill.eu/instruments-support/instruments-groups/groups/lss/more/world-directory-of-sans-instruments/). Beam size and shape also play a key role in data smearing. Modern synchrotron beams and most laboratory-based instruments have sufficiently small beam dimensions (in the range of tenths of a millimetre to millimetres at the detector) such that smearing effects can be safely ignored for most applications. Neutron beam dimensions can be as large as 100 mm at the detector and thus can cause significant instrumental smearing. Some laboratory-based SAXS instruments use line-focused sources to increase the X-ray flux on the sample. These types of instruments, which were first implemented by Otto Kratky (see chapter 3 of Glatter & Kratky, 1982), have since been further developed for laboratory-based SAS applications (see, for example, Bergmann et al., 2000) and data treatments must deal with significant instrumental smearing effects. Data `desmearing' can be performed using the ratio of points in the smeared-model and unsmeared-model I(q) profiles calculated using Fourier and/or linear regularization techniques, such as the indirect Fourier transform of a P(r) model if the particle maximum dimension (d_max) is well determined. Alternatively, iterative methods can be used, although these typically amplify statistical errors (see Vad & Sager, 2011 and references therein). However, the preferred approach is to smear the model I(q) profile analytically using the measured beam profile for direct comparison with experimental data.

During data reduction, the SAS intensity data also should be placed on an absolute scale in units of cm⁻¹ by comparison with the incident beam flux or the scattering from pure H₂O (Orthaber et al., 2000; Jacrot & Zaccai, 1981). Pure H₂O is a readily accessible, universal standard whose scattering has been well characterized over a wide range of temperatures. Secondary standards are also available, such as glassy carbon (see the new NIST Standard Reference Material 3600; https://www-s.nist.gov/srmors/view_detail.cfm?srm=3600; Allen et al., 2017). Absolute scaling enables the direct comparison of SAS data from different instruments, including X-ray and neutron sources, without arbitrary scaling and also enables the determination of M or V from I(0) without reference to the scattering from a reference protein. In the case of SANS, it has been routine to place the data on an absolute scale. The more common practice for SAXS experimenters has been to provide data on an arbitrary relative scale, which we do not recommend for reasons that will be addressed further below.

Owing to the tremendous variety of SAS instrumentation, the typical SAS user will need beamline scientists or instrument manufacturers to provide many of the instrument and data-acquisition parameters and references that we recommend to be reported regarding data acquisition and reduction (a summary is given in Table 2). We therefore encourage instrument scientists to collect and provide these parameters and references to users in an easy-to-access form at the time of data collection.

2.3. Data presentation, analysis and validation

In order for a reader to be able to assess the quality of SAS data and their suitability for structural modelling, it is necessary that the data be presented in a clear, well described manner along with the parameters and analyses that support the conclusion that the SAS profile represents the shape of the particle of interest or, in the case of flexible systems, the population-weighted average SAS profile for the ensemble of conformations present.

Because I(q) decreases by several orders of magnitude over the measured q range, data should be presented as log I(q) versus q and/or log I(q) versus log q. The former provides a clear representation of the data over the entire q range, while the latter will have a near-zero slope at low q if the minimum measured q value meets the requirement of being sufficiently small to ensure adequate characterization of the largest particles present. A linear Guinier plot [ln I(q) versus q²; Guinier, 1939] is a necessary but not sufficient demonstration that a solution contains monodisperse particles of the same size. The upper limit of the q range for the linear Guinier approximation varies depending on the particle shape and homogeneity. For a sphere of uniform scattering density, Guinier showed that the limit is qR_g < 1.3, while for extended shapes and/or inhomogeneous particles this limit can be <1.0 (Feigin & Svergun, 1987). Assessment of the appropriate Guinier limit will be aided by complementary analyses for particle shape, such as P(r) (see below). The lower q limit for the Guinier analysis should be the lowest, reliably measured q value. For a particle with maximum dimensions d_max, the minimum q value measured should be at most ∼π/d_max for accurate assessment of the particle size and shape (Moore, 1980), and as a general principle it is important to measure below this limit to have an assurance that there are no larger particles present. It has been common practice to truncate data at low q when there are small amounts of large M impurities, aggregation or polydispersity present resulting in some upturn of the Guinier plot. This practice is not to be encouraged, but in the event that it is performed it must be reported and justified. Truncating the most obviously affected lower q data in the Guinier plot will not completely eliminate the effects of the contaminant and will thus have an effect on the derived structural parameters that must be acknowledged and quantified to the extent possible [for example, by indicating the impacts on I(0) and R_g]. The best practice would be to also display the truncated data points, for example as empty symbols, with filled symbols representing data points included in the linear fit so that the reader can fully appreciate the potential effect of truncation. For Guinier fits, a quality-of-fit parameter such as the Pearson residual (R) or coefficient of correlation (R²) for a linear fit is widely understood and thus is most useful to report.

The Fourier transform of the scattering profile yields P(r) versus r, the scattering contrast-weighted distribution of distances r between atoms, and is generally computed as the indirect Fourier transform of I(q) (Glatter, 1977). By its definition, P(r) is equal to zero for r values exceeding the maximum particle size d_max. Agreement between the P(r) and Guinier-determined R_g and I(0) values is a good measure of the self-consistency of the SAS profile, as P(r) is calculated using a larger portion of the measured q range. This said, it is not correct to simply choose a d_max that provides a solution that agrees with the Guinier R_g. Rather, the P(r) solution must be independently optimized with the understanding that d_max is an input parameter to the indirect transform selected by the user based on the observed fit of the regularized I(q) corresponding to a given P(r) and how P(r) approaches zero at r = 0 and d_max. The d_max value as independently assessed from the P(r) transform should be consistent with, but not guided by, the known dimensions of the system from complementary techniques. There is an inherent uncertainty in d_max that is difficult to quantify in a rigorous and consistent way. Furthermore, automated routines for calculating P(r) can provide mathematically optimized solutions that are quite unphysical, leading to erroneous d_max selection, and hence need to be treated with great caution. The stability of the P(r) fit needs to be carefully assessed by examining a range of d_max values and the effects of choosing different q ranges. The indirect Fourier transform methods for calculating P(r) include a smoothing parameter that is a complicating factor in assessing the quality of the fit for a given solution. A simple χ² test is straightforward to calculate, although it does have limitations, as will be discussed below (§2.4). Another approach used by the popular program GNOM for calculating P(r) is to use a quality-of-fit assessment (referred to as the `total estimate' ) that is based on χ<sup>2</sup> combined with a number of `perceptual criteria' (Svergun, 1992).

The molecular mass M in daltons for a scattering particle is readily calculated as

where I(0) is on an absolute scale in units of cm⁻¹, N_A is Avogadro's number, C is the concentration of the scattering particle in g ml⁻¹ and Δρ_M is the scattering mass contrast, which can be calculated as , where is the average scattering-length density difference between the particle and its solvent in cm⁻² (or cm cm⁻³, scattering length/unit volume) and is its partial specific volume in cm³ g⁻¹ (Orthaber et al., 2000). and are both related to the molecular volume and can be readily estimated for X-rays and neutrons from the chemical and isotopic composition of the particle and its solvent. For X-rays, Δρ_M is sometimes calculated as , where ρ_p is the number of electrons per mass of dry volume, ρ_s is the electron density of the solvent and r₀ is the scattering length of an electron in cm (2.8179 × 10⁻¹³ cm; Mylonas & Svergun, 2007). There are several web-based tools for the calculation of these parameters from the chemical and isotopic composition. Values for and from the chemical composition of solvent and solute for SAXS and SANS can be obtained using the Contrast model of MULCh (https://smb-research.smb.usyd.edu.au/NCVWeb/index.jsp); the web version of US-SOMO (https://somo.chem.utk.edu/somo/) will calculate and other molecular properties from the sequence. A biomolecular scattering-length density () calculator for proteins and polynucleotides with different levels of deuteration is also available at https://psldc.isis.rl.ac.uk/Psldc/. These calculations are based on the volumes of the constituent chemical groups and generally provide accurate values of for proteins with M > 20 kDa, where the effects of hydration and variations in amino-acid packing have little impact on calculations. For an easy-to-use protocol for the calculation of M, see Box 2 in Jeffries et al. (2016).

Historically, proteins have been used as a calibration standard for estimating M. From (1) it can be seen that if the product of and is assumed to be the same for all proteins, the mass is proportional to I(0) normalized by the protein concentration in (w/v) units (Mylonas & Svergun, 2007). However, the simplest implementation of this ratio method is not readily applicable to polynucleotides or protein–polynucleotide complexes. Also, for proteins experimentally determined values of vary by as much as 10%. For a typical folded and hydrated protein, is in the range 0.70–0.74 cm³ g⁻¹ (Harpaz et al., 1994), and hydration, flexibility or modifications such as glycosylation can affect the value. The value of also can vary, especially in the case of bound metal ligands, for example. Additionally, it is the case that most readily available inexpensive protein standards have some tendency for time-induced and/or radiation-induced aggregation or degradation, which introduces further systematic error in the assessed M value. Nevertheless, it can be useful in practice to measure a known protein standard (such as lysozyme, bovine serum albumin or glucose isomerase) as a check of the overall experimental setup. However, we do not recommend dependence on this approach for the evaluation of M in favour of absolute scaling of the SAS data and using (1), as this method is subject to fewer errors.

The total scattered intensity [calculated as the integral from zero to infinity of q²I(q)] is referred to as the Porod invariant Q_i, which, for uniform scattering density particles with a well defined boundary, depends only on the volume of the scattering particle and not its form (Porod, 1951). The particle volume or Porod volume, V_P, is then calculated as

As Q_i is an integral from zero to infinity and data are only measured for a finite q range, in practice the integral is generally estimated using a smoothed, regularized scattering profile obtained from P(r) [for example as in the method of Fischer et al. (2010) and in the current implementation of GNOM (Petoukhov et al., 2012)]. The GNOM implementation includes a correction to force the high-q data to obey the expected q⁻⁴ dependence for a uniform scattering density particle with a well defined boundary (i.e. a globular, folded biomolecule; Porod, 1951). By interrogating a large set of theoretical scattering profiles calculated from coordinates of proteins in the Protein Data Bank (PDB; Berman et al., 2000), Fischer and coworkers determined empirical correction factors for estimating Q_i for scattering data acquired over specific measured q ranges. Rambo and Tainer defined a new invariant that does not depend upon the q⁻⁴ assumption and thus is applicable to both folded, globular molecules and flexible systems, the latter of which have a shallower q⁻³ or q⁻² dependence (Rambo & Tainer, 2013b). This invariant can be used to calculate a volume of correlation, V_c. Any one or all of these methods can be used to estimate the volume of the scattering particle, which can then be related to M, keeping in mind that they all are highly dependent on accurate background subtraction. A useful rule of thumb for the ratio V_P/M is ∼1.45–1.50. Agreement of this estimate with that derived using (1) and with the expected value from the chemical composition of the particle of interest (full sequences, including tags, bound ligands and modifications) is a primary validation parameter that demonstrates that the scattering particle is a monodisperse, folded macromolecule or macromolecular complex, and that the SAS data are suitable for quantitative structural interpretation and three-dimensional modelling.

In the case of SANS with contrast-variation data, I(0) and R_g values vary with contrast and hence should be reported for each contrast point measured. The M or V estimate from I(0) should also be determined for each contrast point to identify potential ²H₂O-induced aggregation effects [from (1), for a constant M and , I(0) ∝ ]. In addition, the Stuhrmann plot (R_g² versus 1/Δρ; Koch & Stuhrmann, 1979) is valuable to show as it provides information on internal scattering density variations within the scattering particle. For a particle composed of discrete components with distinct mean scattering densities (for example a protein plus polynucleotide, or ²H-labelled and unlabelled proteins) a combination of the Stuhrmann analysis and application of the parallel axis theorem (Engelman & Moore, 1975) will provide information on the disposition of components, the R_g values of each component and the R_g value for the total particle at infinite contrast (i.e. where internal scattering density fluctuations are negligible; Whitten et al., 2008). With sufficient measurements in the contrast series it is possible to extract the scattering profiles for individual components along with a cross-term that encodes information on the dispositions of the components. The MULCh suite of programs (ModULes for the analysis of Contrast variation data; available for download and as a web-based tool at https://smb-research.smb.usyd.edu.au/NCVWeb/index.jsp; Whitten et al., 2008) was designed to aid in planning a SANS contrast-variation experiment by providing the dependence of I(0) on contrast for given deuteration levels in biomolecular components and solvent (Contrast module), for Stuhrmann and parallel axis theorem analysis (Rg module), and for extraction of the scattering profiles of individual components of a complex and their cross-term (Compost module).

The above q⁻⁴ approximation for the decay of high-q data is a reasonable approximation for most folded proteins, but not for unfolded proteins, where for a fully random-coil chain the dependence is q⁻² (Debye, 1947). The asymptotic behaviour of the high-q data thus can distinguish between folded, partly flexible and unfolded structures. Where flexibility is a possibility, its qualitative evaluation can be made using Kratky [q²I(q) versus q; see chapter 11 of Glatter & Kratky, 1982] and Porod–Debye [q⁴I(q) versus q⁴; Debye et al., 1957] plots of the data (recently reviewed in Rambo & Tainer, 2011), provided that background subtractions are accurate. The dimensionless Kratky plot [(qR_g)²I(q)/I(0) versus qR_g] is most useful to distinguish between different degrees of folding. Proteins containing folded domains display a bell-shaped curve, with a maximum of about 1.1 at around qR_g = 1.75. With increasing elongation and degree of unfolding, the maximum shifts to the upper right and the upward slope of the right side of the curve increases (Durand et al., 2010; Bizien et al., 2016).

Presentation of the data, analysis and validation parameters as recommended in the summary in Table 3 will aid both the experimenter and the reader in evaluating data quality, the validity of the analysis and the suitability of the data for structural modelling. The recommendations include depositing the data in a publically available archive.

Table 3 Summary of guidelines for data presentation, analysis and validation Difference scattering profiles [(particle + solvent) − (solvent scattering)] corresponding to the particle form factor deposited in a publicly available archive or made available as supplementary material and presented as a plot of log I(q) versus q or log I(q) versus log q along with a Guinier plot with the following.  (i) Intensities on an absolute scale in units of cm−1 with propagated standard errors (σ). Note: for Guinier plots [ln I(q) versus q2] a first-order approximation to the error in ln I(q) is σI(q)/I(q).  (ii) For multiple curves on the same plot, data can be offset for clarity with the offsets given in the figure caption.  (iii) For SANS contrast-variation experiments, data from all contrast points.  (iv) Guinier Rg and I(0) values with errors, a quality-of-fit parameter (such as a coefficient of correlation R2) with the q or qRg range specified and linear fits displayed with qmin < q ≃ π/dmax. Any data from the measurement range that was truncated should be displayed and identified by the use of a symbols that distinguish them from data points included in the linear fit. P(r) versus r with associated Rg and I(0) (with errors) and dmax values is essential for SAXS data and is advised for SANS data [especially at solvent match points for complexes of components with distinct scattering densities where interpretation of P(r) will be the most intuitive as the scattering object has an approximately uniform scattering density]. M or V estimates, preferably from multiple methods; for example, methods based on I(0) in addition to VP or Vc. For I(0)-based methods, values and uncertainties in the calculated or experimentally determined concentration and parameters used, such as , and solvent and particle scattering-length densities, along with the methods of calculation or measurement. Where applied, the magnitude of corrections for solvent subtraction applied to the data as a potential warning that something is not correct if unduly large (say 1% percent of the solvent scattering level). Where relevant, the method of data desmearing to correct for beam geometry and/or polychromaticity and the original smeared data be made available. For a concentration series, note if no change in Rg or I(0)/C is observed with increasing concentration [C in (w/v)] and for best practice report M estimates at each concentrations or provide a plot of I(0)/C versus C. A dimensionless Kratky plot as a check on the degree of folding and/or flexibility in the scattering particle. Kratky and/or Porod–Debye plots might alternatively be used to assess potential flexibility. For SEC–SAS data a plot of I(0) and Rg as a function of measurement time or measurement frame, and correlated UV traces if used for estimating C, including the leading and trailing edge of elution peaks. An I(0)/A280 or I(0)/C plot as a function of time is also useful. For more complex cases, deconvolution of multiple species in the SEC profile may be needed, for example using the HPLC–SAXS module of US-SUMO (https://www.somo.uthscsa.edu/). Description of the data processing used to obtain the final data set for analysis and modelling [including data reduction to I(q) versus q, solvent subtraction, merging of multiple data sets, extrapolation to infinite dilution etc.]. For merged or extrapolated data sets, the original measurements should be available along with the precise protocol used for processing. For contrast-variation experiments the nature and number of contrast points with a plot of normalized ± [I(0)/C]1/2 versus solvent scattering density identifying the total particle solvent match point along with transmissions at each contrast with controls for pure 1H2O and 2H2O for calibration. For contrast-variation experiments on assemblies of components with different mean scattering densities, the M or V estimates from I(0) for each contrast point, Stuhrmann plots and derived Rg values for individual components and whole particle at infinite contrast and extracted component scattering functions (including cross-term) are all desirable. Software used for data processing and analysis [e.g. Rg, VP and P(r)] including version numbers.

2.4. Structure modelling

Having obtained accurate and sufficiently precise data as I(q) versus q for the system of interest, provided evidence that the scattering profile is free of nonspecific aggregation or interparticle interference effects, that it yields the expected M or V value, and having assessed the potential flexibility of the system, a three-dimensional modelling strategy can be selected. This strategy may include ab initio shape or bead modelling and/or atomistic modelling using domains or subunits of known structure, usually derived from crystallo­graphy or NMR experiments and potentially additional experimental restraints. The model is optimized such that a penalty function is minimized that includes the fit to the scattering data (i.e. χ²) and any other penalties related to restraints on the model (e.g. compactness, connectedness, distance restraints etc.).

As solution scattering data reduce to one-dimensional profiles, there are a number of issues regarding the representation and precision of derived three-dimensional models (Schneidman-Duhovny et al., 2012). In the case of data that can be adequately fitted by a single average three-dimensional model (either shape or atomistic representations), an evaluation of the inherent ambiguity in the modelling solution is required. Here, a question to answer is whether a single best-fit model or class of very similar models uniquely fits the data, or whether multiple classes of models exist that fit the data equally well. AMBIMETER is a recently released program that provides an a priori assessment as to whether the spherically averaged single-particle scattering can be fitted by a single relatively well-defined shape, or whether it is consistent with multiple shapes (Petoukhov & Svergun, 2015). It is common practice to run multiple independent model optimizations with SAS data and to use a cluster analysis to compare models in terms of their shape or, in the case of atomistic models, relative positions and orientations of domains or subunits and contacts between the different components. Providing that conformational space has been adequately sampled, the number of clusters that fit the data provides an estimate of the ambiguity in the model solution. Spatial restraints from complementary experiments (for example symmetry, domain structures from NMR or crystallography, distances or orientational restraints from chemical cross-linking, NMR, Förster resonance energy transfer, sequence conservation or co-variation) can be imposed as part of any modelling strategy to increase the resolution of the model representation and its precision (Schneidman-Duhovny et al., 2012; Rambo & Tainer, 2013a). An outstanding question in ongoing research with regard to hybrid atomistic modelling is whether the conformational search space is adequately sampled and how this can be achieved.

Symmetry assumptions in bead or shape modelling can highly influence the resulting models, and thus if symmetry is imposed to generate a model that is to be used, it is advisable to compare the result obtained in the absence of symmetry restraints. In the event that the imposition of symmetry results in a shape that is radically different to shapes derived without the symmetry assumption, the symmetry assumption may be incorrect.

If monodispersity in solution cannot be achieved or guaranteed, the measured scattering intensity reflects the spherical average over all K species present. Assuming non-interacting particles, the scattering intensity is then a linear combination of the scattering of the species I_k(q) multiplied by their respective number density n_k,

Depending on the number of components in the solution, there are various approaches to data analysis. In the case of mixtures with a limited number of components whose individual scattering intensities are known, the population fractions may be estimated from (3) (for example using the program OLIGOMER; Konarev et al., 2003). For systems with unknown structure existing in a stable equilibrium, for example a monomer and dimer with known association and disassociation constants, three-dimensional structural analysis is possible. This can be performed ab initio or using rigid-body modelling (for example with GASBORMX or SASREFMX; Petoukhov et al., 2013). The reporting guidelines for using these programs are similar to the monodisperse case but with the extra parameter of the fraction of each species in solution, and typically multiple curves are recorded for analysis (e.g. a concentration series).

Perhaps the most complicated mixtures are flexible systems containing multiple conformers, for example multidomain proteins with flexible linkers or hinges. For such systems, the number of terms in (3) can be astronomically high. These systems may still be characterized with multistate or ensemble methods where a large population of potential conformations is generated and substates or sub-ensembles that describe the observed scattering data based on a priori information are selected (Tria et al., 2015; Berlin et al., 2013; Schneidman-Duhovny et al., 2016; Perkins et al., 2016; Kikhney & Svergun, 2015; Terakawa et al., 2014; Pelikan et al., 2009; Yang et al., 2010; Bernadó et al., 2007). As the number of degrees of freedom in ensemble modelling is so much larger than when optimizing a single average model, the danger of overfitting and over-interpretation is significantly amplified. Satisfactory solution of the problem of multistate/ensemble modelling thus depends greatly on the application of restraints from complementary experiments or bioinformatics to limit the conformational space that must be sampled. While many programs for multistate/ensemble modelling produce representative structures to describe the range of states within the population, these representative structures are generally neither accurate nor precise in their detail and primarily aid in providing a visual, qualitative description of the nature of representative states. On the other hand, the distribution of R_g values for the optimized ensemble is generally quite robust, providing a quantitative measure of the extent of structural flexibility (Bernadó et al., 2008; Carter et al., 2015). In cases where the conformational space is sufficiently restrained and exhaustively sampled, it may be practical to evaluate the ambiguity and precision of the multistate/ensemble models. For example, consider a system where the data are explained by `open' and `closed' structural states. A cluster analysis on the opened and closed states may reveal little variability in the closed state, and thus low ambiguity and higher precision, while the open structure may show larger variation and consequently high ambiguity and low precision (see, for example, Fig. 3J in Carter et al., 2015).

For atomistic representations, the protocol used to include contributions to the scattering data from the hydration layer is important. These effects are quite significant for SAXS and for SANS from samples with high levels of D₂O (Kim & Gabel, 2015; Zhang et al., 2012; Svergun et al., 1998; Perkins, 1986). They become especially significant and important to report in the co-refinement of SAXS/NMR data for solution structure determination (Grishaev et al., 2010).

The most commonly used parameter for evaluating the discrepancy between the scattering profile computed from a model and the measured scattering profile is the global fit parameter χ², which is defined most simply as

where N is the number of points in the scattering profile, I_exp(q) is the experimental scattering profile, I_mod(q) is the computed scattering profile based on the three-dimensional model, c is a multiplicative scaling parameter that is used to minimize χ², and σ(q) is the standard error for each measured data point. From (4) we see that χ² will be smaller for data with poor statistics and conversely larger for data with vanishingly small statistical errors. Thus, while relative χ² values are most valuable in comparing two models against the same data set, absolute values can be less useful in comparing fits to two independent data sets.

Scattering data are acquired as the sum of events on a detector. A model that fits the data within its error estimates will have a χ² value close to 1, providing that the random statistical errors are propagated correctly and there are no systematic errors. Overestimation or underestimation of the statistical errors and potential contributions from systematic errors have led to reported χ² values ranging from a few tenths to quite large values (>5), and yet the fits to the data may be good, even excellent, or claimed to be good based on a `by-eye' evaluation of a presented plot (see, for example, Supplementary Fig. 2 in Appolaire et al., 2014). Generally, SAS intensity decreases rapidly and by orders of magnitude over the measured q range, and depending upon how the data are presented, regions of significant misfitting of the scattering profile may not be apparent. Also, as χ² is a global fit parameter, it is important to present the data and model fit so that systematic deviations that may be present in specific q regimes are evident, for example in the mid-q regime most highly influenced by domain positioning and orientation where SAS data are often most helpful in SAXS/NMR structure refinement (Grishaev et al., 2008). A straightforward and intuitive approach to demonstrating the quality of a model fit over the entire measured or modelled q range of a SAS profile that takes into account relative errors across the measured q range is an error-weighted residual difference plot of [I_exp(q) − cI_mod(q)]/σ(q) versus q, as is nicely demonstrated in Figs. 3, 4 and 5 of Carter et al. (2015). The error weighting of this difference plot aids in visualization by preventing the plot from being dominated by regions of weaker scattering and poor statistics. This plot presents the fit in the noisy high-q regions without losing information in the low- to mid-q regions that contain the shape information that can be most important for biomolecular SAS modelling. If the deviations from the model are only evident in the high-q regime, it might be indicative of an error in solvent subtraction or unaccounted-for disorder.

Different modelling programs use various adjustable parameters in their procedures to minimize χ² and these are valuable to consider (e.g. for CRYSOL the parameters Vol, Dro and Ra specify the excluded volume, scattering density contrast in the hydration layer and atomic group radius, respectively, and there is also an optional adjustable constant term to account for possible errors in the solvent subtraction; for FoXS the parameters c₁ and c₂ are used to adjust excluded volume and hydration-layer density to account for the hydration layer). Understanding these parameters is necessary to ensure that they represent realistic assumptions given the physics of the system. Here, it should be noted that not only do different modelling programs use different adjustable parameters, they sometimes evolve over time in ways that can affect the absolute value of χ²; for example, a later version may incorporate an adjustable constant subtraction/addition for optimization which can significantly affect χ².

The different detector characteristics, protocols for error propagation, details of the modelling algorithm and nature of the adjustable parameters renders comparisons of published χ² values from different experiments and different modelling calculations performed at different points in time essentially meaningless. Alternative statistics have been proposed, including a Pearson correlation-based method (dos Reis et al., 2011) and a measurement of the volatility of the ratio between experiment and fit (Hura et al., 2013). Rambo and Tainer proposed the use of a resampling-based adaptation of the reduced χ² test and defined a χ²_free with the aim of reducing the chance of model misidentification in noisy data and avoiding overfitting (Rambo & Tainer, 2013b). The χ²_free parameter, however, does not solve problems relating to inaccurate error propagation. A recently proposed alternative to χ² that is independent of the amplitude of the statistical errors considers only the statistical likelihood of a run of consecutive points lying systematically above or below the profile generated from the fitted model (Franke et al., 2015). The method has proven to be useful for comparing synchrotron SAXS data frames to detect subtle radiation damage or for selecting SEC–SAXS data frames for averaging and subsequent analysis. As implemented in ATSAS, a two-dimensional correlation map (CORMAP) is generated that usefully highlights patterns of systematic deviation. A score (P-value) is assigned relating to the statistical probability of the longest run of points that lie consistently above or below the model. While CORMAP does not require knowledge of errors, if the random errors are very small and because the model curve is smooth, a constant sign of difference can easily be observed over a long q range, resulting in very small P-values. In such cases of data with high statistical precision, χ² would also be expected to be greater than 1 owing to systematic deviations between the experimental data and model curve.

The above issues and limitations noted, χ² nonetheless remains an accepted and necessary parameter to report as most modelling protocols minimize χ² one way or another. However, reporting a combination of χ² values with comments on the confidence level with which a global minimum was identified along with a clear graphical representation of deviations between the model and the experimental data in the form of a residual plot is essential.

Assessing the precision, or variability among all sufficiently well scoring models, is important for SAS-derived models. Recently, a tool has been developed that uses the Fourier shell correlation criterion widely employed in electron-microscopy model assessment to evaluate the variability among ab initio shape models to provide an assessment of the model precision in terms of a resolution (Tuukkanen et al., 2016). The method (SASRES) is implemented in the bead-modelling tools of the ATSAS package (Petoukhov et al., 2012). A clear benefit of this tool is that it will discourage the over-interpretation of surface bumps and valleys in these models.

For a given optimized atomistic model, accuracy will vary substantially for different regions depending on the contributing data. For example, the linker sequences between structured domains from crystallography or NMR that are modelled only by optimizing the fit to the SAS data will not be accurate at the level of coordinate positions. Likewise, interfaces that are not defined experimentally by crystallography or NMR are likely not to be accurate. The disposition of the domains may be relatively well defined; that is, accurate within limits that can be placed on the spatial and orientational parameters (Kim & Gabel, 2015; Gabel, 2012). The accuracy will depend on the asymmetry of the structure shape and whether there were additional contacts from experiment or bioinformatics analysis used as restraints. Their precision can be estimated from the variability of equally scored models providing that conformational space was exhaustively sampled. It is thus important in reporting atomistic models to clearly identify the sources of the components of the model; where there is high-resolution information, its accuracy and precision, the basis for building regions of unknown structure and how the conformational search space was restrained to enable adequate sampling. Table 4 summarizes the recommended reporting guidelines for structural modelling.