2.1. Sedimentation-velocity analytical ultracentrifugation (SV)

Analytical ultracentrifugation (AUC) is a classical and first-principle-based technique for characterizing macromolecules and nanoparticles in solution, and has a long history of applications to biological macromolecules and their reversible interactions (Schachman, 1959). The basic objective of the analytical ultracentrifuge is to monitor and interpret the evolution of the macromolecular concentration profiles after the application of a centrifugal field. For a basic introductory review and practical protocols, see, for example, Lebowitz et al. (2002) and Zhao, Brautigam et al. (2013). Sedimentation velocity (SV) and sedimentation equilibrium (SE) are the two standard experimental designs in AUC, with SV focusing on the sedimentation process while SE examines the final equilibrium distribution. For protein studies, the combination of these two methods can provide powerful information of protein size, size distribution and purity, hydrodynamic shape and affinity for binding other macromolecules (Zhao, Brautigam et al., 2013). AUC can be used to study a wide range of particle sizes from 100 to 10⁸ g mol⁻¹. Currently, three types of optical systems are available for AUC: the conventional absorbance spectrophotometer, the Rayleigh interferometer and the recently commercially introduced fluorescence-detection system (FDS). With different optical detection systems and different experimental approaches, AUC offers a remarkably broad dynamic range for investigating protein interactions with equilibrium dissociation constants (K_d) from picomolar to millimolar (Chaudhry et al., 2009; Rowe, 2011; Zhao et al., 2014). The application of AUC to protein binding studies allows determination of the stoichiometry and the affinity of protein complex formation, including both self-association and hetero-association.

SV, in particular, is highly advantageous in the study of protein interactions, mainly because the strong size-dependent sedimentation process leads to high hydrodynamic resolution, which is usually far superior to diffusion-based methods such as dynamic light scattering or size-exclusion chromatography. Furthermore, in the standard experimental design of SV, despite their higher sedimentation velocity the protein complexes will remain in a bath of their slower sedimenting constituent components, such that dissociating complexes can re-associate during the sedimentation process in a way that reflects their equilibrium and kinetic properties. In recent years, it has undergone substantial improvements in instrumentation, theory and computational data analysis, which have benefited numerous protein studies for deciphering the composition of protein complexes, binding mechanisms and specificity (Schuck, 2013). Here, we focus on some of the most recent developments in SV relevant to protein interaction studies.

2.1.1. Diffusion-deconvoluted and spectrally deconvoluted sedimentation coefficient distributions c(s) and c_k(s)

One of the most valuable aspects of SV is the great hydrodynamic resolution and sensitivity that can be applied to determine the number, the size and the hydrodynamic shape of co-existing protein complexes. A critical advance in SV was made in the 1990s with the ability for routine efficient numerical solution of the master equation of sedimentation and diffusion fluxes in the sector-shaped solution column: the Lamm equation (Lamm, 1929; Schuck, 1998; Brown & Schuck, 2007). This provides a model for the temporal and spatial evolution of the concentration of a single non-interacting particle χ₁(r, t) and opened the door to the direct modeling of the observed sedimentation boundaries a(r, t).

The extension of this to the description of a coupled sedimentation of a kinetically interacting system has been developed (Schuck, 1998, 2003; Stafford & Sherwood, 2004; Dam et al., 2005). In principle, it can provide binding constants, the sedimentation coefficients (s-values) of all species and – under highly favorable conditions of reaction kinetics on the same timescale as the sedimentation experiment, i.e. with complex lifetimes of approximately 1 h – estimates for the kinetic rate constants for chemical interconversion. While conceptually very powerful, it has the important drawback of requiring highly pure sample and prior knowledge of (or a hypothesis on) the complexes formed (Brautigam, 2011; Zhao et al., 2011; Zhao, Brautigam et al., 2013).

A more widely applicable approach, which is usually the first step in modern data analysis, is the combination of single-species Lamm equation solutions χ₁(s, r, t) into sedimentation-coefficient distributions c(s). It is defined by the integral

that is fitted directly to the set of observed boundary profiles. It is important to take precautions against overfitting through the use of maximum entropy or Tikhonov regularization (Schuck, 2000), which may be tailored to specific prior knowledge (Brown et al., 2007). Similar to the deconvolution of point-spread functions in optical imaging, c(s) results in diffusion-deconvoluted sedimentation-coefficient distributions.

In most common cases, the biological sample solution is composed of an ensemble of molecules with various sizes. Such polydispersity is challenging in many biophysical methods. However, the c(s) analysis can detect and account for this: the high hydrodynamic resolution and sensitivity to trace components allow unrelated sedimenting species to be excluded from further analysis and therefore prevent inconsistencies in GMMA arising from different sensitivity to impurities. For sufficiently long-lived complexes, c(s) can resolve the number of co-existing complexes and determine the molecular weight and s-value (i.e. a molecular shape function). For short-lived complexes, c(s) provides a platform for efficient further thermodynamic analysis (see below).

The stoichiometry of multi-component complexes can be directly resolved from sedimentation velocity data with multiple signals, if it is possible to exploit different spectral signatures of different components. For example, the spectral difference could be owing to different aromatic amino-acid contents causing differences in the extinction coefficients at 280 or 250 nm, or in combination with refractive-index signals, or using chromophoric labels in the visible-light region. We can take advantage of such differences in the multi-signal sedimentation coefficient distribution c_k(s),

(where ∊_k,λ represents the extinction coefficient of component k at wavelength λ and d is the optical path length), which simultaneously fits the data a_λ(r, t) acquired at the different signals and spectrally convolutes component contributions (Balbo et al., 2005). The integration of c_k(s) reports the concentration of components co-sedimenting in a certain peak. Details for the application of this multi-signal SV (MSSV) approach and requirements for spectral resolution can be found in Padrick & Brautigam (2011), Brautigam et al. (2013) and Zhao, Brautigam et al. (2013).

The importance of MSSV in the context of protein interaction analysis is its capability to directly reveal the size and the composition of protein complexes, which can be invaluable prior information when modeling binding isotherms observed with other methods (Fig. 1), especially for multi-component systems. This unique advantage has been demonstrated in various multi-component protein systems (Houtman et al., 2006; Brautigam et al., 2009; Barda-Saad et al., 2010; Padrick et al., 2011; May et al., 2014).

Figure 1 Example of the MSSV analysis of MHC class I (blue) binding to HHV-7 U21 (red) forming mixed 4:2 complexes (May et al., 2014). The insets show raw boundary profiles from the Rayleigh interference optical system (left) and absorbance system at 280 nm (right). No chromophoric label was required for the spectral decomposition owing to the difference in content of aromatic amino acids in the two proteins.

2.1.3. Fluorescence-detected sedimentation velocity (FDS-SV)

While traditionally AUC is constrained to the analysis of moderate to weak interactions with K_d values in the micromolar to millimolar range, based on the required optical detection by absorbance or interferometry, fluorescence detection can extend the dynamic range to nanomolar or even picomolar concentrations (Crepeau et al., 1976; Schmidt et al., 1990; Schmidt & Riesner, 1992; MacGregor et al., 2004). The fluorescence-detection system (FDS) resembles a moveable confocal microscope featuring a focal point that scans radially through the solution column (Fig. 2). A design by Laue and coworkers (MacGregor et al., 2004) has recently become commercially available from AVIV Biomedical Inc. (Lakewood, New Jersey, USA).

Figure 2 Schematic representation of the scanning setup of the FDS optics for AUC (MacGregor et al., 2004). This figure was taken from Zhao, Casillas et al. (2013).

Currently, excitation is restricted to 488 nm and emission is acquired in a wavelength band from 505 to 565 nm. This provides optimal sensitivity for GFP and FITC-related dyes, but owing to the exquisite sensitivity of the commercial system detection of some red fluorophores is also possible (unpublished observation). Initially, the majority of applications of FDS-SV were of a qualitative rather than a quantitative nature (Kroe & Laue, 2009; Kingsbury & Laue, 2011), but the analysis of FDS-SV data has undergone rapid development (Bailey et al., 2009; Lyons et al., 2013; Zhao, Casillas et al., 2013; Zhao, Lomash et al., 2013; Zhao et al., 2014). In particular, we have recently shown that, after accounting for some characteristic data features including spatial and temporal changes in the signal magnification, highly quantitative fits can be achieved with signal-to-noise ratios rivaling that of the best traditional optical system (Zhao, Casillas et al., 2013). Furthermore, when fully exploiting the very large statistics of data points that can be acquired in FDS-SV, and when using an inert carrier protein to block surface adsorption (after appropriate controls), it is possible to measure sedimentation coefficients of protein complexes at low picomolar EGFP concentrations, which opens this method up to the study of ultrahigh affinities with subnanomolar equilibrium constants (Zhao et al., 2014; Fig. 3). In the context of GMMA, this brings the sensitivity of SV-AUC onto a par with (and even exceeding) that of SPR and ITC.

Figure 3 High-affinity interaction of an EGFP and GFP monoclonal antibody (Zhao et al., 2014): (a) c(s) distributions from FDS-SV data; (b) sw isotherms (symbols) and best-fit model (lines) at different macromolecular concentrations, leading to a microscopic binding constant of 20 pM.

2.2. Isothermal titration microcalorimetry (ITC)

ITC has served as a key technique for quantifying binding affinity and stoichiometry of protein interactions. It is based on the direct measurement of the reaction heat during a titration series of injections of a reactant into a thermally isolated vessel containing reaction partner(s). From the shape of the resulting isotherm of observed heats, the change of enthalpy, ΔH, the equilibrium constant can be determined and, traditionally, an `n' value reflecting the reaction stoichiometry and active concentration errors. Numerous ITC applications have been accomplished in various systems with a range of K_d between 1 nM and 100 µM (Wiseman et al., 1989). In order to expand the accessible affinity range, various approaches have been developed using displacement or competition strategies (Sigurskjold, 2000; Velazquez Campoy & Freire, 2006; Krainer et al., 2012). The required three-component binding models have been implemented as part of the ITC model set in SEDPHAT. In the context of multi-site interactions and GMMA, one unique feature of ITC is its suitability for detecting cooperativity in binding, because we observe both changes in enthalpy (ΔΔH) and free energy (ΔΔG) (Bains & Freire, 1991; Houtman et al., 2007).

2.2.2. Integration with peak-shape analysis and error estimates

Over the last decades, significant improvements in the instrumentation of ITC have allowed smaller sample volumes and more sensitive detection. However, baseline assignment for the power traces followed by peak integration to determine the heat of each injection is a nontrivial first step in the ITC analysis, and is often one of the limiting factors for data interpretation. This has a particularly pronounced impact on the binding processes associated with smaller heats, and is exacerbated for smaller volume instruments. Since the manufacturer-provided automated integration algorithm cannot adapt well to the stochastic nature of the baseline drift and its adventitious jumps, it has previously been regarded the state-of-the-art strategy to manually adjust the baseline assignment (Velazquez Campoy & Freire, 2006). Clearly this is unsatisfactory, since it is subjective and potentially associated with bias. (This may not always be obvious since the assigned baseline is usually subtracted out in the final thermogram plots.)

In order to develop an objective approach for ITC peak integration, we introduced a new method implemented in the New Integrator of Thermograms Produced by Isothermal Calorimetry (NITPIC; Keller et al., 2012). Conceptually, this approach is based on the recognition that the peak shapes from all injections are similar (although not identical) to each other, such that regularization by truncated singular value decomposition can be used to distinguish baseline from injection heats (Keller et al., 2012). This approach is particularly robust with regard to adventitious baseline jumps. The algorithm is self-adjusting to the noise in the baseline and usually runs fully automatically. Some algorithmic adjustments are possible, for example, in rare cases, to set overall threshold levels or to adapt criteria to nonstandard isotherms, but by design no adjustment to individual injections is possible (nor is it necessary). As illustrated in Fig. 4, it greatly outperforms the standard integration routines currently provided by the instrument manufacturers.

Figure 4 Titration isotherm from data after automated thermogram processing using MicroCal Origin (blue circles) or NITPIC (red squares and error bars) and fit (red line) to a 1:1 binding model of a NITPIC isotherm (from Keller et al., 2012). The left inset shows the thermogram. The right insets illustrate the principle of baseline interpolation for three different injections as highlighted in red in the thermogram plot.

In addition to the isotherm of reaction heats, NITPIC determines error bars associated with the calculated heat of each injection on the basis of the baseline noise in the power trace surrounding the injection. This is important as it leads to proper statistical weighting in the isotherm analysis. For example, this allows realistic analysis of the statistical accuracy of binding parameters where very few data points are in the transition to saturation. This region of the data governs the estimate of the binding constant and will be sparsely sampled for high-affinity systems (high `c'-value conditions), and may therefore be sensitive to variable uncertainties of individual injection heats. Also, proper error estimates are of particular importance for the global ITC analysis when data with different loading concentrations in the reaction vessel (different `c' values) are analyzed jointly, which produce very dissimilar statistical errors.

2.3. Surface plasmon resonance surface binding (SPR)

Optical biosensing has become a popular technique for studying protein interactions with the introduction of a commercial SPR biosensor (Löfås et al., 1991). In the most commonly used flow design, a protein is immobilized on a polymeric support at the sensor surface and its binding partner (or reaction mixture) is flowed across the sensor surface at various concentrations while monitoring the accumulation of surface-bound material optically via the solution refractive-index changes in the evanescent field of light in total internal reflection (Schuck, 1997). Analogous to the potential impact of the covalent attachment of extrinsic fluorophores to proteins in fluorescence techniques (including FDS-SV; Zhao, Lomash et al., 2013), covalent attachment of the protein to the surface and the proximity of the surface can lead to alterations in its binding properties. Whether or not the surface binding parameters are identical to those in solution is strongly dependent on the particular proteins under study, and examples of both are common (Schuck et al., 1998).

The SPR biosensing data could directly offer kinetic information on the binding; however, very frequently the kinetics of surface binding significantly deviate from the expected pseudo-first-order theoretical model. This can be attributed to mass-transport limitation and/or variations of the physicochemical microenvironment of the sensor surface causing heterogeneity of the surface binding sites (Schuck & Zhao, 2010; Zhao et al., 2012). To account for these issues from surface binding, a transformation of surface-binding progress data into a space of two-dimensional rate-constant distributions has been developed and implemented in the free software EVILFIT (Svitel et al., 2007; Schuck & Zhao, 2010). EVILFIT typically leads to excellent fits of the raw data and the most populated or putatively native interactions represented in the major peaks to be focused on (Fig. 5). Tikhonov and Bayesian regularization allow the user to probe the information content of the SPR data.

Figure 5 Example of SRP data analysis with a surface site distribution in EVILFIT (Zhao et al., 2012). (a) Binding data (blue to green) and best fit (red lines) from the distribution model of an experiment of β2-microglobulin (1.0, 5.0, 10, 50 and 100 nM) binding to a CM5 sensor chip with anti-β2-microglobulin-biotin immobilized; (b) best-fit affinity and kinetic rate constant distribution from global fit of all data in (a).

In the context of GMMA these surface-induced artifacts of impaired binding sites pose a significant difficulty. Therefore, although SEDPHAT does allow the incorporation of steady-state surface-binding isotherms, in order to probe true solution interactions it is advantageous to conduct solution competition experiments, conceptually just like the competition experiments between labeled and unlabeled macromolecules in fluorescence approaches. We can exploit the SPR surface solely as a measure of the free binding partner in solution, which can be empirically calibrated through an initial series of surface-binding experiments. This is followed by experiments in which reaction mixtures are injected, which, dependent on the solution interaction, deplete the concentration of free surface-binding partner. Such a surface-competition isotherm is the preferred approach for SPR analysis in SEDPHAT in the context of global analysis. Indeed, global analysis of direct and competition isotherms can be performed to reveal differences between surface and solution binding (Schuck et al., 1998).

A strength of the SPR analysis is its application to high-affinity interactions with K_d in the nanomolar range. However, a disadvantage that is important to keep in mind is that multivalent surface binding cannot be studied reliably, and the method is limited in the presence of self-associations. Furthermore, control experiments are essential for all solution components other than the specific binding partner to ensure that they do not bind to the surface.

3.1. Basic principle of GMMA

The goal of GMMA is to exploit synergies of the different biophysical techniques. The first step in the analysis of an interacting system is the definition of the thermodynamic states, i.e. the number and stoichiometry of complexes. In our experience, SV and MSSV often provide unique opportunities as they deliberately depart from the premise of a binding model upfront. If the binding scheme cannot be identified directly, it may be assessed later by evaluating the implications of different structurally motivated hypothetical models on the quality of fit of the binding data, with GMMA offering the most stringent criteria.

The premise of GMMA is that the combination of data sets from different techniques that exploit different observables for monitoring the same binding process can break the parameter correlation which exists in a single-method analysis, and thereby increases precision and opens up more complex multi-site and multi-component systems for study (Fig. 6). As an illustration of this principle, we applied GMMA to the two-site interaction of α-chymotrypsin binding soybean trypsin inhibitor (Fig. 7; Zhao & Schuck, 2012). Of the ITC, SPR, SV and fluorescence anisotropy methods applied, no single one was able to resolve the binding energies and enthalpies of the two sites, and the individual best-fit values were very different. Yet, in combination in GMMA they determined all of the binding parameters very well, as shown by the shapes of the error contours of the individual and GMMA analyses (Fig. 8). Remarkably, even though only ITC reports binding enthalpy changes and only SV reports sedimentation coefficients, these parameters of the 1:1 and 2:1 complexes were significantly better determined by GMMA than by the combination of ITC or SV alone or by single-method global analysis (Zhao & Schuck, 2012).

Figure 6 Venn diagram of different biophysical methods that can contribute to GMMA in SEDPHAT. Hierarchy of parameters: macromolecular binding parameters that are central TO the model for each data type, such as Kd, ΔG and ΔΔG, are indicated in bold red; macromolecular parameters that serve as observables in each technique, such as mass in AUC and SPR, translational frictional coefficient in SV and DLS, spectroscopic changes upon binding in fluorescence or other spectroscopy and rotational diffusion coefficient in fluorescence anisotropy, are indicated in bold black. In ITC, the enthalpic changes (ΔH and ΔΔH) as binding parameters are directly probed calorimetrically. Finally, in most methods there are technical and `nuisance' parameters that are usually unrelated to the molecules under study, such as baseline offsets and sample dimensions (meniscus and/or bottom in SV), but also incompetent fractions, as indicated in grey. Some of these local parameters may be constrained to be the same in a subset of experiments, such as concentration errors. A given model is projected into each of the data spaces, optimizing the local and nuisance parameters, compared with the experimental data, and a global measure for the goodness of fit is calculated, which is then optimized by nonlinear regression.

Figure 7 Screenshot of GMMA fit of 11 data sets from four biophysical methods of binding between α-chymotrypsin and soybean trypsin inhibitor from Zhao & Schuck (2012). Top row, left to right: SPR competition experiment, four ITC titrations, sw isotherm from a dilution series in SV. Bottom row, left to right: sfast and effective particle boundary amplitudes from the dilution series in SV, sw and boundary fractions from a titration series in SV and steady-state fluorescence anisotropy competition titration.

Figure 8 Parameter correlations between K1 and K2 for different experiments: (a) SPR alone (top left in Fig. 7), (b) a single ITC experiment (top second from right in Fig. 7), (c) a dilution series in SV (top right and first and second lower left in Fig. 7) and (d) GMMA jointly of the same data sets.

Modeling each technique involves global parameters {p_glob}, which are dependent on the macromolecular interacting system, as well as local parameters {p_loc}, which may be macromolecular properties that are only important in a subset of experiments (such as extinction coefficients or frictional coefficients) or technical `nuisance' parameters such as instrumental baselines etc. SEDPHAT `projects' an inter­action model into the different data spaces, determines the local root-mean-square deviation and χ² of the fit and calculates from this a weighted overall χ² as

(where f_e,i, y_e,i and σ_e,i are the model, data and standard deviation for data point i of experiment e out of a total of N_e data points in a total of E experimental data sets, with a statistical weighting factor w_e for each experiment). The object-oriented internal structure of SEDPHAT will automatically add and dynamically optimize the necessary local parameters for each data type when experimental data are added, without requiring any user intervention or data-specific or system-specific programming. Nonlinear regression then globally optimizes χ²_r,glob of the fit, adjusting the parameters (optionally with user-provided constraints or links between parameters) offering simplex, Marquardt–Levenberg and simulated-annealing algorithms.

3.2. Statistical analysis functions

Standard statistical analysis functions are available in SEDPHAT to probe parameter errors and correlations in any fit, including cross-correlation parameters from the covariance matrix, contours of the error surface and its projections with F-statistics and Monte-Carlo analysis. For example, the reduction in parameter correlation between the K_d of the first and second binding site achieved through GMMA is visualized in Fig. 8 with two-dimensional projections of the error surface, which can be computed and displayed in SEDPHAT.

Specific for GMMA, we have introduced a statistical weight (w_e in equation 3) to account for very dissimilar sized data sets and to ensure that all experiments can make statistical contributions to the global fit (Zhao & Schuck, 2012). Dependent on differences in the various techniques regarding the potential impact of systematic errors, this parameter can be adjusted by the user. A tool to scan the parameter errors as a function of the set of weights {w_e} can alert as to whether any of the GMMA results is sensitive to this choice, and can report the overall largest confidence interval for all parameters (Zhao & Schuck, 2012). Furthermore, a statistical test based on cross-validation and F-statistics was implemented to flag data sets that do not seem to be mutually consistent, for example owing to possible differences from experimental imperfections or the influence of systematic errors. Finally, it is instructive to inspect which experiments carry significant information on each parameter. These functions are available in the Statistics menu of SEDPHAT, with the option to subgroup experimental data sets for the purpose of their statistical analysis.

3.3. Experimental design for GMMA using simulation tools

It can be a nontrivial question what experiments should be performed for optimally probing binding equilibria when various methods are available. This is true, in particular, for multi-component and multi-site systems and in the context of GMMA. To facilitate experimental planning, we have implemented new simulation functions in SEDPHAT that can generate series of experimental data sets in silico that can be added to a GMMA. In conjunction with the statistical analysis functions of SEDPHAT, the user may probe which set of experiments and, for each technique, which experimental design would be most informative, given a certain hypothesis for the nature of the interactions and estimates of the likely binding constants. This may also reveal whether certain types of experiments would be worth conducting on the basis of their added information content, or whether it is possible to fully characterize a certain interacting system at all with the methods at hand and given the likely errors of data acquisition.

To construct such a simulation in SEDPHAT, first the interaction model must be selected and global binding parameter estimates must be entered. The simulation functions can then be invoked to generate data sets of type SE, SV, SV isotherms, ITC, SPR, competition SPR, fluorescence anisotropy, general linear spectroscopy (such as steady-state fluorescence quenching) or any type of isotherms (for example chemical shift from NMR data and data of microscale thermophoresis). Likely values for local parameters specific to the particular technique must be provided (such as characteristic signal increments and/or ancillary experimental parameters). In order to help to create the most informative isotherms in the concentration space, the user is then brought to a two-dimensional map of either predicted total signal (for the given technique) or the fractional signal contributions of different complexes formed, or their fractional population as a function of total component concentrations (Fig. 9). Optionally, the field of view of this interaction map can be cropped to reflect feasible regions on the basis of maximal available stock concentrations and/or on the basis of minimal signals or maximal desired signals (such as OD limits in absorbance detection). Furthermore, the isotherm plots can be switched into a differential mode highlighting the regions of greatest sensitivity to changes in certain parameters. After visually discerning suitable isotherm trajectories from within any of these plots (which are presumably those that show characteristic changes along the trajectory, but this is to be assessed by statistical analysis and is likely to be dependent on the GMMA context), the user can draw a line with the mouse in the map and receive the desired number of log-equidistant mixture concentrations that probe this isotherm. For convenience, the user can obtain recipes to produce a certain volume of these mixtures from the previously given stock concentrations.

Figure 9 An example of detailed experimental planning for SV of a 2:1 binding system in SEDPHAT. (a) Parameter space of sw isotherms for the given binding system as functions of macromolecular concentration for species A (abscissa) and B (ordinate), both in logarithmic units, and with the color temperature indicating the theoretical sw values for given hypothesized binding constants, cropped to conditions where the total signal is between user-set parameters and experimentally feasible based on given stock concentrations. (b, c) Relative contribution of the AB and ABB complex, respectively, to the total signal. In all plots, a graphically user-generated trajectory (black line with points) is shown, which automatically generates the sample-preparation plan in (d).

Constraining the concentration-dependent map of signal (or complex species) to feasible mixtures based on given component stock concentrations can highlight, for example, how high the stock concentrations should be to generate sufficient information and how much total volume would be required. With the caveat that the interaction parameters of the underlying simulations are hypothetical, these simulation tools can guide protein preparation and link it to experimental information content. Similarly, such simulations may reveal which signal-to-noise ratio would be required with a certain technique to be informative in the context of GMMA.