Thermodynamic stability measurements on multimeric proteins using a new H/D exchange- and matrix-assisted laser desorption/ionization (MALDI) mass spectrometry-based method

We recently reported on a new H/D exchange- and matrix-assisted laser desorption/ionization (MALDI) mass spectrometry-based technique, termed SUPREX, that removes several important limitations associated with measuring the thermodynamic stability of proteins. In contrast to conventional spectroscopy-based techniques for characterizing the equilibrium unfolding behavior of proteins, SUPREX is amenable to the thermodynamic analysis of both purified and unpurified proteins using mg to ng quantities of material. Here we report on the application of SUPREX to the analysis of multimeric protein systems. Included in this work are the SUPREX results we obtained in studies on six model multimeric proteins including the GCN4p1 dimer, the coil-V(a)L(d) trimer, the 4-oxalocrotonate tautomerase (4-OT) hexamer, the Trp repressor (TrpR) dimer, the Arc repressor (ArcR) dimer, and an ArcR mutant (the (DOA20)ArcR) dimer which contained two destabilizing mutations including an Asp to Ala mutation at position 20 and an amide to ester bond mutation between amino acid (aa) residues 19 and 20. As part of the work described here, we present a new method for the analysis of SUPREX data that is generally applicable to both monomeric and multimeric protein systems. Our results on the model proteins in this study indicate that this new method can be used to determine folding free energies for proteins with the accuracy and precision of conventional spectroscopy-based methods.     

Shape of the free energy barriers for protein folding probed by multiple perturbation analysis

The characterization of the free energy barriers has been a major goal in studies on the mechanism of protein folding. Testing the effect of mutations or denaturants on protein folding reactions revealed that transition state movement is rare, suggesting that folding barriers are robust and narrow maxima on the free energy landscape. Here we demonstrate that the application of multiple perturbations allows the observation of small transition state movements that escape detection in single perturbation experiments. We used tendamistat as a model protein to test the broadness of the free energy barriers. Tendamistat folds over two consecutive transition states and through a high-energy intermediate. Measuring the combined effect of temperature and denaturant on the position of the transition state in the wild-type protein and in several mutants revealed that the early transition state shows significant transition state movement. Its accessible surface area state becomes more native-like with destabilization of the native state by temperature. To the same extent, the entropy of the early transition state becomes more native-like with increasing denaturant concentration, in accordance with Hammond behavior. The position of the late transition state, in contrast, is much less sensitive to the applied perturbations. These results suggest that the barriers in protein folding become increasingly narrow as the folding polypeptide chain approaches the native state.     

Unification of the folding mechanisms of non-two-state and two-state proteins

We have collected the kinetic folding data for non-two-state and two-state globular proteins reported in the literature, and investigated the relationships between the folding kinetics and the native three-dimensional structure of these proteins. The rate constants of formation of both the intermediate and the native state of non-two-state folders were found to be significantly correlated with protein chain length and native backbone topology, which is represented by the absolute contact order and sequence-distant native pairs. The folding rate of two-state folders, which is known to be correlated with the native backbone topology, apparently does not correlate significantly with protein chain length. On the basis of a comparison of the folding rates of the non-two-state and two-state folders, it was found that they are similarly dependent on the parameters that reflect the native backbone topology. This suggests that the mechanisms behind non-two-state and two-state folding are essentially identical. The present results lead us to propose a unified mechanism of protein folding, in which folding occurs in a hierarchical manner, reflecting the hierarchy of the native three-dimensional structure, as embodied in the case of non-two-state folding with an accumulation of the intermediate. Apparently, two-state folding is merely a simplified version of hierarchical folding caused either by an alteration in the rate-limiting step of folding or by destabilization of the intermediate.     

Beta-sheet proteins with nearly identical structures have different folding intermediates

The folding mechanisms of two proteins in the family of intracellular lipid binding proteins, ileal lipid binding protein (ILBP) and intestinal fatty acid binding protein (IFABP), were examined. The structures of these all-beta-proteins are very similar, with 123 of the 127 amino acids of ILBP having backbone and C(beta) conformations nearly identical to those of 123 of the 131 residues of IFABP. Despite this structural similarity, the sequences of these proteins have diverged, with 23% sequence identity and an additional 16% sequence similarity. The folding process was completely reversible, and no significant concentrations of intermediates were observed by circular dichroism or fluorescence at equilibrium for either protein. ILBP was less stable than IFABP with a midpoint of 2. 9 M urea compared to 4.0 M urea for IFABP. Stopped-flow kinetic studies showed that both the folding and unfolding of these proteins were not monophasic, suggesting that either multiple paths or intermediate states were present during these processes. Proline isomerization is unlikely to be the cause of the multiphasic kinetics. ILBP had an intermediate state with molten globule-like spectral properties, whereas IFABP had an intermediate state with little if any secondary structure during folding and unfolding. Double-jump experiments showed that these intermediates appear to be on the folding path for each protein. The folding mechanisms of these proteins were markedly different, suggesting that the different sequences of these two proteins dictate different paths through the folding landscape to the same final structure.     

The folding pathway of barnase: the rate-limiting transition state and a hidden intermediate under native conditions

The nature of the rate-limiting transition state at zero denaturant (TS(1)) and whether there are hidden intermediates are the two major unsolved problems in defining the folding pathway of barnase. In earlier studies, it was shown that TS(1) has small phi values throughout the structure of the protein, suggesting that the transition state has either a defined partially folded secondary structure with all side chains significantly exposed or numerous different partially unfolded structures with similar stability. To distinguish the two possibilities, we studied the effect of Gly mutations on the folding rate of barnase to investigate the secondary structure formation in the transition state. Two mutations in the same region of a beta-strand decreased the folding rate by 20- and 50-fold, respectively, suggesting that the secondary structures in this region are dominantly formed in the rate-limiting transition state. We also performed native-state hydrogen exchange experiments on barnase at pD 5.0 and 25 degrees C and identified a partially unfolded state. The structure of the intermediate was investigated using protein engineering and NMR. The results suggest that the intermediate has an omega loop unfolded. This intermediate is more folded than the rate-limiting transition state previously characterized at high denaturant concentrations (TS(2)). Therefore, it exists after TS(2) in folding. Consistent with this conclusion, the intermediate folds with the same rate and denaturant dependence as the wild-type protein, but unfolds faster with less dependence on the denaturant concentration. These and other results in the literature suggest that barnase folds through partially unfolded intermediates that exist after the rate-limiting step. Such folding behavior is similar to those of cytochrome c and Rd-apocyt b(562). Together, we suggest that other small apparently two-state proteins may also fold through hidden intermediates.     

Using an E. coli Type 1 secretion system to secrete the mammalian, intracellular protein IFABP in its active form

A biotechnological production of proteins through protein secretion systems might be superior to the conventional cytoplasmic production, because of the absence of large amounts of proteases present in the extracellular space and the ease of purification or downstream processing. However, secretion of proteins is still a trial-and-error approach and many proteins fail to be secreted. Recently, a study of a Type 1 secretion system revealed that the folding rate of the passenger protein dictates secretion efficiency. Here, the well-known MalE failed to be secreted when fused to a C-terminal fragment of the natural substrate haemolysin A. In contrast, slow-folding mutants of MalE were secreted in high yields. However, MalE is a bacterial protein that is targeted to the periplasmic space of E. coli and possesses the intrinsic capability to cross a membrane. Therefore, we applied the same approach for another eukaryotic protein that resides in the cytoplasm. As an example, we chose the intestinal fatty acid binding protein (IFABP) and highlight the universal potential of this Type 1 secretion system to secrete proteins with slow-folding kinetics (here the G121V mutant). Finally, a one-step purification protocol was established yielding 1mg of pure IFABP G121V per liter culture supernatant. Moreover, secreted IFABP G121V was shown to reach a folded state, which is biologically active.     

Formation of on- and off-pathway intermediates in the folding kinetics of Azotobacter vinelandii apoflavodoxin

The folding kinetics of the 179-residue Azotobacter vinelandii apoflavodoxin, which has an alpha-beta parallel topology, have been followed by stopped-flow experiments monitored by fluorescence intensity and anisotropy. Single-jump and interrupted refolding experiments show that the refolding kinetics involve four processes yielding native molecules. Interrupted unfolding experiments show that the two slowest folding processes are due to Xaa-Pro peptide bond isomerization in unfolded apoflavodoxin. The denaturant dependence of the folding kinetics is complex. Under strongly unfolding conditions (>2.5 M GuHCl), single exponential kinetics are observed. The slope of the chevron plot changes between 3 and 5 M denaturant, and no additional unfolding process is observed. This reveals the presence of two consecutive transition states on a linear pathway that surround a high-energy on-pathway intermediate. Under refolding conditions, two processes are observed for the folding of apoflavodoxin molecules with native Xaa-Pro peptide bond conformations, which implies the population of an intermediate. The slowest of these two processes becomes faster with increasing denaturant concentration, meaning that an unfolding step is rate-limiting for folding of the majority of apoflavodoxin molecules. It is shown that the intermediate that populates during refolding is off-pathway. The experimental data obtained on apoflavodoxin folding are consistent with the linear folding mechanism I(off) <==> U <==> I(on) <== > N, the off-pathway intermediate being the molten globule one that also populates during equilibrium denaturation of apoflavodoxin. The presence of such on-pathway and off-pathway intermediates in the folding kinetics of alpha-beta parallel proteins is apparently governed by protein topology.     

Accuracy and precision of a new H/D exchange- and mass spectrometry-based technique for measuring the thermodynamic properties of protein-peptide complexes

A new H/D exchange- and MALDI mass spectrometry-based technique, termed SUPREX, was used to characterize the thermodynamic properties of a series of model protein-peptide complexes of the Abelson tyrosine kinase SH3 domain (abl-SH3) and the S-Protein (S-Pro). The SUPREX technique was employed to evaluate the folding free energies (DeltaG(f) values) of each model protein in the absence and in the presence of a series of different peptide ligands. Ultimately, these SUPREX-derived DeltaG(f) values were used to calculate dissociation constants (K(d) values) for each of the nine protein-peptide complexes in this study. As part of this work, we describe a new data collection and analysis method that allows the accurate and precise determination of protein folding m-values in the SUPREX experiment. The m-values that we determined for the abl-SH3 domain and the S-Pro system were in good agreement with those determined by conventional techniques. Our results also indicate that the SUPREX-derived K(d) values for the protein-peptide complexes in this work were in reasonably good agreement with those determined by conventional techniques.     

Slow folding of a three-helix protein via a compact intermediate

The KIX domain of CREB binding protein (CBP) forms a small three-helix bundle which folds autonomously. Previous equilibrium unfolding experiments led to the suggestion that folding may not be strictly two-state. To investigate the folding mechanism in more detail, the folding kinetics of KIX have been studied by urea jump fluorescence-detected stopped-flow experiments. Clear evidence for an intermediate is obtained from the plot of the natural log of the observed rate constant versus denaturant concentration, the chevron plot, and from analysis of the initial fluorescence amplitudes of the stopped-flow experiments. The chevron plot exhibits a change in shape, rollover, at low denaturant concentrations, characteristic of the formation of an intermediate. The kinetic data can be fit to a three-state model involving a compact intermediate. An on-pathway model predicts that the position of the intermediate lies close to the native state. The folding rate in the absence of denaturant is 260 s(-)(1) at pH 7.5 and 25 degrees C. This is significantly slower than the rates of other helical proteins similar in size. The slow folding may be due to the necessity of forming a buried polar interaction in the native state. The potential functional significance of the folding intermediate is discussed.     

Distinguishing between two-state and three-state models for ubiquitin folding

Conflicting results exist regarding whether the folding of mammalian ubiquitin at 25 degrees C is a simple, two-state kinetic process or a more complex, three-state process with a defined kinetic intermediate. We have measured folding rate constants up to about 1000 s(-1) using conventional rapid mixing methods in single-jump, double-jump, and continuous-flow modes. The linear dependence of folding rates on denaturant concentration and the lack of an unaccounted "burst-phase" change for the fluorescence signal indicate that a two-state folding model is adequate to describe the folding pathway. This behavior also is seen for folding in the presence of the stabilizing additives 0.23 M sodium sulfate and 1 M sodium chloride. These results stress the need for caution in interpreting deviations from ideal two-state "chevron" behavior when folding is heterogeneous or folding rate constants are near the detection limit.     

Slow motion analysis of protein folding intermediates within wet silica gels

Resolving the complete folding pathway of a protein is a major challenge to conventional experimental methods because of the rapidity and complexity of folding. Here, we show that entrapment of the protein cytochrome c in wet, optically transparent, porous silica gel matrices has enabled a dramatic expansion, to days or weeks, of the folding time, allowing direct observation of the entire folding pathway using a combination of three spectroscopic techniques, far-ultraviolet circular dichroism, tryptophan fluorescence, and Soret absorption spectroscopy. During refolding in silica gels, collapse and helix formation occur in a stepwise manner, as observed in aqueous solution. Analysis of kinetics and transient spectra indeed reveals a sequence of four distinct intermediates with progressively increasing degrees of folding, two of which closely resemble those previously characterized in solution, namely, the early collapsed and the molten globule intermediates. The other two are the precollapsed and pre-molten globule intermediates that may escape detection by conventional kinetic methods. Interestingly, varying the strength of the gel network has a dramatic effect on the folding time, but no significant effect on the structural features of each folding intermediate, indicating that the interaction between the protein and gel matrix has no measurable effect on the folding pathway. These results better define the major pathway of cytochrome c folding. In addition, in this paper we present the results of the application of this method to a simple, apparent two-state folder ubiquitin, helping to interpret the results for cytochrome c.     

Protein misfolding: optional barriers, misfolded intermediates, and pathway heterogeneity

To investigate the character and role of misfolded intermediates in protein folding, a recombinant cytochrome c without the normally blocking histidine to heme misligation was studied. Folding remains heterogeneous as in the wild-type protein. Half of the population folds relatively rapidly to the native state in a two-state manner. The other half collapses (fluorescence quenching) and forms a full complement of helix (CD) with the same rate and denaturant dependence as the fast folding fraction but then is blocked and reaches the native structure (695nm absorbance) much more slowly. The factors that transiently block folding are not intrinsic to the folding process but depend on ambient conditions, including protein aggregation (f(concentration)), N terminus to heme misligation (f(pH)), and proline mis-isomerization (f(U state equilibration time)). The misfolded intermediate populated by the slowly folding fraction was characterized by hydrogen exchange pulse labeling. It is very advanced with all of the native-like elements fairly stably formed but not the final Met80-S to heme iron ligation, similar to a previously studied molten globule form induced by low pH. To complete final native state acquisition, some small back unfolding is required (error repair) but the misfolded intermediate does not revisit the U state before proceeding to N. These properties show that the intermediate is a normal on-pathway form that contains, in addition, adventitious misfolding errors that transiently block its forward progress. Related observations for other proteins (partially misfolded intermediates, pathway heterogeneity) might be similarly explained in terms of the optional insertion of error-dependent barriers into a classical folding pathway.     

A common folding mechanism in the cytochrome c family

Of the globular proteins, cytochrome c (cyt c) has been used extensively as a model system for folding studies. Here we analyse the folding pathway of different cyt c proteins from prokaryotes and eukaryotes, and attempt to single out general correlations between structural determinants and folding mechanisms. Recent studies provide evidence that the folding pathway of several cyt c proteins involves the formation of a partially structured intermediate. Using state-of-the-art kinetic analysis on published data, we show that such a folding intermediate is an obligatory on-pathway species that might represent either a defined local minimum in the reaction coordinate or an unstable high-energy state. Available data also indicate that some essential structural features of the folding intermediate and transition states are highly conserved across this protein family. Thus, cyt c proteins share a consensus folding mechanism in spite of large differences in physico-chemical properties and thermodynamic stability. This novel outlook on the folding of cyt c can shed light on much published data and might offer a general scheme by which to plan new experiments.     

Simulation and experiment conspire to reveal cryptic intermediates and a slide from the nucleation-condensation to framework mechanism of folding

There is a change from three-state to two-state kinetics of folding across the homeodomain superfamily of proteins as the mechanism slides from framework to nucleation-condensation. The tendency for framework folding in this family correlates with inherent helical propensity. The cellular myeloblastis protein (c-Myb) falls in the mechanistic transition region. An earlier, preliminary report of protein engineering experiments and molecular dynamics simulations (MD) showed that the folding mechanism for this protein has aspects of both the nucleation-condensation and framework models. In the more in-depth analysis of the MD trajectories presented here, we find that folding may be attributed to both of these mechanisms in different regions of the protein. The folding of the loop, middle helix, and turn is best described by nucleation-condensation, whereas folding of the N and C-terminal helices may be described by the framework model. Experimentally, c-Myb folds by apparent two-state kinetics, but the MD simulations predict that the kinetics hide a high-energy intermediate. We stabilized this hypothetical folding intermediate by deleting a residue (P174) in the loop between its second and third helices, and the mutant intermediate is long-lived in the simulations. Equilibrium and kinetic experiments demonstrate that folding of the DeltaP174 mutant is indeed three-state. The presence and shape of the intermediate observed in the simulations were confirmed by small angle X-ray scattering experiments.     

Exploring the cytochrome c folding mechanism: cytochrome c552 from thermus thermophilus folds through an on-pathway intermediate

Understanding the role of partially folded intermediate states in the folding mechanism of a protein is a crucial yet very difficult problem. We exploited a kinetic approach to demonstrate that a transient intermediate of a thermostable member of the widely studied cytochrome c family (cytochrome c552 from Thermus thermophilus) is indeed on-pathway. This is the first clear indication of an obligatory intermediate in the folding mechanism of a cytochrome c. The fluorescence properties of this intermediate demonstrate that the relative position of the heme and of the only tryptophan residue cannot correspond to their native orientation. Based on an analysis of the three-dimensional structure of cytochrome c552, we propose an interpretation of the data which explains the residual fluorescence of the intermediate and is consistent with the established role played by some conserved interhelical interactions in the folding of other members of this family. A limited set of topologically conserved contacts may guide the folding of evolutionary distant cytochromes c through the same partially structured state, which, however, can play different kinetic roles, acting either as an intermediate or a transition state.     

Folding mechanism of three structurally similar β-sheet proteins

The folding mechanism of cellular retinoic acid binding protein I (CRABP I), cellular retinol binding protein II (CRBP II), and intestinal fatty acid binding protein (IFABP) were investigated to determine if proteins with similar native structures have similar folding mechanisms. These mostly β-sheet proteins have very similar structures, despite having as little as 33% sequence similarity. The reversible urea denaturation of these proteins was characterized at equilibrium by circular dichroism and fluorescence. The data were best fit by a two-state model for each of these proteins, suggesting that no significant population of folding intermediates were present at equilibrium. The native states were of similar stability with free energies (linearly extrapolated to 0 M urea, ΔG) of 6.5, 8.3, and 5.5 kcal/mole for CRABP I, CRBP II, and IFABP, respectively. The kinetics of the folding and unfolding processes for these proteins was monitored by stopped-flow CD and fluorescence. Intermediates were observed during both the folding and unfolding of all of these proteins. However, the overall rates of folding and unfolding differed by nearly three orders of magnitude. Further, the spectroscopic properties of the intermediate states were different for each protein, suggesting that different amounts of secondary and/or tertiary structure were associated with each intermediate state for each protein. These data show that the folding path for proteins in the same structural family can be quite different, and provide evidence for different folding landscapes for these sequences. Proteins 33:107–118, 1998. © 1998 Wiley-Liss, Inc.     

Apparent Debye-Huckel electrostatic effects in the folding of a simple, single domain protein

We have monitored the effects of salts and denaturants on the folding of the simple, two-state protein FynSH3. As predicted by Debye-Huckel limiting law, both the stability and (log) folding rate of FynSH3 increase nearly perfectly linearly (r(2)> 0.99) with the square root of ionic strength upon increasing concentrations of the relatively nonchaotropic salt sodium chloride. The stability of FynSH3 is also linear in square root ionic strength when the relatively nonchaotropic salts sodium bromide, potassium bromide, and potassium chloride are employed. Comparison of the kinetic and equilibrium effects of sodium chloride suggests that the electrostatic interactions formed in the folding transition state are approximately 50% as destabilizing as those formed in the native state, presumably reflecting the more compact nature of the latter. In contrast, the relationship between concentration and folding kinetics is more complex when the highly chaotropic salt guanidine hydrochloride (GuHCl) is employed. At moderate to high GuHCl concentrations the net effect of the linear, presumably chaotrope-induced deceleration and the presumed, square root-dependent ionic strength-induced acceleration is well approximated as linear, thus accounting for the observation of "chevron behavior" (log folding rate linear in denaturant concentration) typically reported for the folding of single domain proteins. At very low GuHCl concentrations, however, significant kinetic rollover is observed. This rollover is reasonably well fitted as a sum of a linear, presumably chaotropic effect and a square root-dependent, presumably electrostatic effect. These results thus not only provide insight into the nature of the folding transition state but also suggest that caution is in order when extrapolating GuHCl-based chevrons to estimate folding rates in the absence of denaturant and in interpreting deviations from chevron linearity as evidence for non-two-state kinetics.     

The kinetic pathway of folding of barnase

To search for folding intermediates, we have examined the folding and unfolding kinetics of wild-type barnase and four representative mutants under a wide range of conditions that span two-state and multi-state kinetics. The choice of mutants and conditions provided in-built controls for artifacts that might distort the interpretation of kinetics, such as the non-linearity of kinetic and equilibrium data with concentration of denaturant. We measured unfolding rate constants over a complete range of denaturant concentration by using by 1H/2H-exchange kinetics under conditions that favour folding, conventional stopped-flow methods at higher denaturant concentrations and continuous flow. Under conditions that favour multi-state kinetics, plots of the rate constants for unfolding against denaturant concentration fitted quantitatively to the equation for three-state kinetics, with a sigmoid component for a change of rate determining step, as did the refolding kinetics. The position of the transition state on the reaction pathway, as measured by solvent exposure (the Tanford beta value) also moved with denaturant concentration, fitting quantitatively to the same equations with a change of rate determining step. The sigmoid behaviour disappeared under conditions that favoured two-state kinetics. Those data combined with direct structural observations and simulation support a minimal reaction pathway for the folding of barnase that involves two detectable folding intermediates. The first intermediate, I(1), is the denatured state under physiological conditions, D(Phys), which has native-like topology, is lower in energy than the random-flight denatured state U and is suggested by molecular dynamics simulation of unfolding to be on-pathway. The second intermediate, I(2), is high energy, and is proven by the change in rate determining step in the unfolding kinetics to be on-pathway. The change in rate determining step in unfolding with structure or environment reflects the change in partitioning of this intermediate to products or starting materials.     

SUPREX (Stability of Unpurified Proteins from Rates of H/D Exchange) analysis of the thermodynamics of synergistic anion binding by ferric-binding protein (FbpA), a bacterial transferrin

SUPREX (stability of unpurified proteins from rates of H/D exchange) is a H/D exchange- and matrix-assisted laser desorption/ionization (MALDI)-based technique for characterizing the equilibrium unfolding/refolding properties of proteins and protein-ligand complexes. Here, we describe the application of SUPREX to the thermodynamic analysis of synergistic anion binding to iron-loaded ferric-binding protein (Fe(3+)FbpA-X, X = synergistic anion). The in vivo function of FbpA is to transport unchelated Fe(3+) across the periplasmic space of certain Gram-negative bacteria, a process that requires simultaneous binding of a synergistic anion. Our results indicate that Fe(3+)FbpA-X is not a so-called "ideal" protein system for SUPREX analyses because it does not exhibit two-state folding properties and it does not exhibit EX2 H/D exchange behavior. However, despite these nonideal properties of the Fe(3+)FbpA-X protein-folding/unfolding reaction, we demonstrate that the SUPREX technique is still amenable to the quantitative thermodynamic analysis of synergistic anion binding to Fe(3+)FbpA. As part of this work, the SUPREX technique was used to evaluate the DeltaDeltaG(f) values of four synergistic anion-containing complexes of Fe(3+)FbpA (i.e., Fe(3+)FbpA-PO(4), Fe(3+)FbpA-citrate, Fe(3+)FbpA-AsO(4), and Fe(3+)FbpA-SO(4)). The DeltaDeltaG(f) value obtained for Fe(3+)FbpA-citrate relative to Fe(3+)FbpA-PO(4) (1.45 +/- 0.44 kcal/mol), is in good agreement with that reported previously (1.98 kcal/mol). The value obtained for Fe(3+)FbpA-AsO(4) (0.58 +/- 0.45 kcal/mol) was also consistent with that reported previously (0.68 kcal/mol), but the measurement error is very close to the magnitude of the value. This work (i) demonstrates the utility of the SUPREX method for studying anion binding by FbpA, (ii) provides the first evaluation of a DeltaDeltaG(f) value for Fe(3+)FbpA-SO(4), -1.43 +/- 0.17 kcal/mol, and (iii) helps substantiate our hypothesis that the synergistic anion plays a role in controlling the lability of iron bound to FbpA in the transport process.     

Ex vivo analysis of synergistic anion binding to FbpA in Gram-negative bacteria

Ferric binding protein, FbpA, is a member of the transferrin superfamily whose function is to move an essential nutrient, iron, across the periplasm and into the cytosol through formation of a ternary complex containing Fe (3+) and a synergistic anion, X. Here we utilize SUPREX ( stability of unpurified proteins from rates of H/D exchange) to determine the identification and distribution of the synergistic anion in FeFbpA-X species in periplasmic preparations from Gram-negative bacteria. SUPREX is a mass spectrometry-based technique uniquely suited for thermodynamic analyses of protein-ligand complexes in complex biological mixtures such as periplasmic preparations. Model binary mixtures of FeFbpA-Cit and FeFbpA-PO 4 were initially characterized by SUPREX due to the likely presence of citrate and phosphate ions in the periplasm. Ex vivo SUPREX analyses were performed on FeFbpA-X species overexpressed in an Escherichia coli cell line and on endogenous FeFbpA-X species in Neisseria gonorrheae. Detected in the E. coli periplasmic extract were two distinct populations of FbpA, including one in which the protein was unliganded (i.e., apoFbpA) and one in which the protein was bound to iron and the synergistic anion, phosphate (i.e., FeFbpA-PO 4). FeFbpA-PO 4 was the only population of FbpA molecules detected in the N. gonorrheae periplasmic extract. This work provides the first determination of the identity of the in vivo anion bound to FeFbpA-X in the periplasm and substantiates the hypothesis that the synergistic anion plays a structural and functional role in FbpA-mediated transport of iron across the periplasm and into the cytosol.