Macromolecular crowding ought to stabilize folded forms of proteins, through an excluded volume effect. This explanation has been questioned and observed effects attributed to weak interactions with other cell components. Here we show conclusively that protein stability is affected by volume exclusion and that the effect is more pronounced when the crowder’s size is closer to that of the protein under study. Accurate evaluation of the volume exclusion effect is made possible by the choice of yeast frataxin, a protein that undergoes cold denaturation above zero degrees, because the unfolded form at low temperature is more expanded than the corresponding one at high temperature. To achieve optimum sensitivity to changes in stability we introduce an empirical parameter derived from the stability curve. The large effect of PEG 20 on cold denaturation can be explained by a change in water activity, according to Privalov’s interpretation of cold denaturation.
The stability of proteins is generally assessed in dilute solutions that, in addition to the molecule under study, contain only few other molecular species, such as those of a buffer, whose interaction with the protein is diffusion limited. However, cellular fluids contain high concentrations of macromolecules. For instance, it has been claimed that the cytoplasm of Escherichia coli contains several macromolecules with a global concentration from 0.20 to 0.40 g ml−1 corresponding to up to 40% of a cell’s volume1.
The influence of crowding on protein stability has been the subject of heated controversies during the past few years, also in connection with its possible relevance for the function of proteins in vivo2. Overall, experimental evidence suggests that excluded volume effects induced by the presence of macromolecules are modest2,3. Some authors have drawn attention to the predominant influence of weak interactions as opposed to purely entropic effects4. Other authors have hypothesized but not firmly proven that the volume change associated with the transition from folded to unfolded species is much smaller than generally assumed2. A conclusive assessment of the effect of crowding on protein stability is hampered by various difficulties. A crucial problem comes from the uncertainty on the choice of the most suitable crowder, given the variety of crowders potentially available, and on which concentration to use. The range of crowder concentration existing in living cells is rather large and ill defined1; thus, it is not uncommon to find studies on crowding at concentrations lower than 10% or as large as 40%. Some studies have been performed using low molecular weight crowders whose effect can hardly be defined as crowding as it is better described as solvent perturbation5,6. Other authors have made use of artificial crowders such as dextran7,8,9, Ficoll10,11,12, polyethylene glycol (PEG)9,13 or different proteins14,15 that could potentially mimic the cellular environment. The role of soft interactions, evidenced by Pielak and co-workers4,14, is probably crucial inside cells, but the use of proteins as crowders may mask the true contribution of volume exclusion, the possible relationship between the dimensions of the protein under study and those of crowders and indirect effects mediated by water activity16. We focused on synthetic crowders, taking extra care to ascertain whether they interact with our protein before assessing their role in volume exclusion.
The relevance of the relative dimensions of crowder and protein was only preliminarily analysed by Minton17 in one of the early papers on crowding in the extreme case of a solute of small molecular weight in the presence of macromolecular crowders. More recently, Hoffman et al.18 reconsidered the question in the case of the kinetics of protein–protein interactions but no firmly established experimental answer on the influence on protein stability exists.
Another crucial point that makes so difficult to assess the influence of crowders on protein stability is the choice of the parameter to measure stability. It is common practice to use only the midpoint of the thermal unfolding curve (Tm). This parameter is not very sensitive and, even worse, it can be completely misleading (vide infra). Here, we addressed these compelling questions by undertaking the first detailed study of the influence of crowding on the stability of yeast frataxin (Yfh1), a natural protein that undergoes cold denaturation above water freezing10. Szyperski et al.19 have demonstrated that whenever cold and heat denaturation can be observed for the same protein, a single fit of the thermogram allows accurate determination of the heat capacity difference between the native and denatured states (ΔCp) and hence of the whole stability curve of the protein20. While for most proteins the cold denaturation temperature (Tc) is well below water freezing, Yfh1 is an ideal system for the characterization of the cold denatured species and of the factors influencing protein thermal stability, offering the chance of using it as a tool to study protein stability in a variety of environments21,22,23. The great asset of this tool is that a substantial population of the unfolded species is at equilibrium with the folded species at all accessible temperatures24. In addition, the nature of the unfolded species changes with temperature, from a strongly hydrated form at lower temperatures to a weakly hydrated one at high temperature22. Such a situation can be compared with the setup of a sensitive electronic device, say a kind of Wheatstone Bridge25 for protein stability, because tiny environmental variations will be detected and enhanced as a perturbation of the equilibrium.
We tested some of the most commonly used artificial crowders, that is, PEG 20, dextran 40, Ficoll 70 and Ficoll 400, to cover a wide range of molecular weights (20–400 kDa). The influence of each of these crowders was studied over a range of concentrations consistent with the composition of cellular fluids. We developed an ad hoc empirical approach to define a single parameter that describes thermal stability of a protein on the basis of its stability curve. We show that this parameter is helpful in describing the effect of macromolecular crowding.
Overall, our results indicate that the most effective crowders are those whose molecular weight is closest to that of the protein under study. Careful spectroscopic investigations show that all of the synthetic crowders employed have negligible interactions with Yfh1, excluding a sizeable contribution of weak nonspecific interactions. The asymmetry of the influence of crowders on high and low temperature unfolding is consistent with a more expanded nature of the low temperature unfolded state22,26, but the unique behaviour of PEG can only be explained by a strong decrease of the water ability to solvate hydrophobic protein side chains.
Relative size is crucial
The crowders were chosen, among other reasons, to represent a range of different sizes, starting from one comparable to that of the protein up to much larger ones. The radius of gyration of the folded state of Yfh1 has been previously estimated at 2.1 nm, typical for a globular protein of 13.8 kDa molecular weight23. The dimensions of Yfh1 in the unfolded states have been measured by Aznauryan et al.26 by single-molecule spectroscopy. These authors have shown that the radius of gyration of this protein, at the lowest accessible temperature, when it is a cold unfolded species, is ca. 3.3 nm. As temperature is raised from 273 K to ∼320 K, the radius of gyration of Yhf1 decreases to 2.7 nm corresponding to a continuous collapse of the unfolded chain with increasing temperature, followed by a slight reexpansion at temperatures above 320 K26.
It is important to bear in mind that relative dimensions of the protein under study and crowders are not related to their molecular weights in a simple, linear way. It has been shown that synthetic crowders may have distinctly different volumes at different concentrations. In the case of several PEG polymers, Kozer et al.27 have shown that although in the dilute regime, the polymers behave as highly solvated spheres, at higher concentrations they begin to interpenetrate one another. Thus, a synthetic crowder, such as PEG or Ficoll, mimics some properties of the medium in a eukaryotic cell. The relevant net result, in our study, is that the space occupancy of the crowder at high concentrations may be even greater than predicted by its intrinsic volume.
The influence of PEG 20, dextran 40, Ficoll 70 and Ficoll 400 at concentrations ranging from 0 up to 20% (w/v) was investigated in the temperature range 2–70 °C.
To assess the secondary structure content of Yfh1 in the presence of different crowders at varying concentrations, and thus measure the relative populations of folded and unfolded species, we recorded thermograms, that is, thermal denaturation curves obtained from solutions of 10 μM Yfh1, by following the circular dichroism (CD) intensity at 220 nm as a function of temperature in the temperature range 2 to 70 °C and in the presence of varying concentrations of crowders (Fig. 1, upper panels). All curves show an increase of the CD signal at 220 nm as a function of increasing crowder concentration, in agreement with an increase in the population of the folded species, accompanied by a moderate increase of the high temperature melting points (Tm) and a more pronounced decrease of the cold denaturation temperatures (Tc). Altogether, these data suggest a substantial increase in the thermal stability of Yfh1 induced by increasing concentrations of the crowders, with significant differences, particularly as far as the concentration dependence is concerned.
Volume exclusion crucially affects cold denaturation
A deeper analysis of the influence on stability of different crowders, as yielded by the stability curves corresponding to thermal unfolding curves, is required because the population of the folded form of Yfh1 at room temperature is <100% (ref. 28).
With the assumption of a two-state equilibrium between folded and unfolded forms, the population of the folded species at any temperature, fF(T), is a function of ΔG0(T), the Gibbs free energy for unfolding, that is shown as modified Gibbs–Helmholtz in equation (1).
Fitting of the CD thermal unfolding curves yields stability curves (Fig. 1, lower panels), from which it is possible to retrieve thermodynamic data (Table 1). The most striking result is the difference induced by increasing amounts of crowders in the high and low temperature transitions. The maximum increase in the values of Tm is similar for all crowders, 12 K for PEG 20, 13 K for dextran 40 and 10 K for both Ficolls, whereas the corresponding decrease of the values of Tc ranges from ca. 44 K for PEG 20, 18 K for dextran 40 to 17 K for both Ficolls. Thus, if we assume that changes in Tc and Tm may be taken as bona fide assessments of thermal stability, for the same crowder, we must conclude that we observe a marked increase in stability at low temperature but a smaller increase in stability at high temperature.
Protein–crowder interactions are negligible
A possible explanation for this asymmetric effect of crowders is the presence of weak interactions of synthetic crowders with Yfh1. To minimize this risk, we had deliberately excluded proteins as crowders since they seem to be particularly prone to interactions14,29. However, the ‘neutrality’ of various synthetic crowders, after initial enthusiasm, has also been challenged to different degrees30,31,32,33.
We thus checked neutrality with respect to soft interactions with our protein by CD and nuclear magnetic resonance (NMR). Far-ultraviolet CD spectra of Yfh1 were recorded at 25 °C in the absence and presence of 5% w/v of each crowder, that is, a concentration that should have minimal volume exclusion effect. The spectra are very similar, although with some sign of increased secondary structure content for the solutions containing either PEG 20 or dextran 40 (Supplementary Fig. 1). The increment of secondary structure content might be due to incipient volume exclusion effects rather than to soft interactions. To settle the issue we compared NMR 15N heteronuclear single-quantum correlated (HSQC)spectra of Yfh1 in 10 mM HEPES and in 5% w/v solutions of representative crowders since NMR is more sensitive than CD to even slight changes of the chemical environment and can thus also reveal local weak interactions (Fig. 2). As a rule of thumb, observation of chemical shift perturbations (CSPs) in NMR spectra does not necessarily indicate significant conformational changes but the absence of CSP is proof of the lack of conformational changes.
Only few peaks show minor (<0.03 p.p.m. in the proton dimension) CSP, therefore ruling out the possibility that the crowders used here significantly alter the architecture of Yfh1. The only apparent exception is that it is possible to observe, in the centre of the spectra, a decrease in the intensity of some (sharp) peaks, typical of the unfolded species of Yfh1. Their intensity is so low that the corresponding peaks of Yfh1 in the buffer solution become dominant, bursting out from the background. This may reflect a small shift of the equilibrium in favour of the folded species that can already be observed at the concentration of 5% w/v, presumably as the precocious manifestation of a volume exclusion effect (vide infra). The choice of showing spectra at 5% crowder concentration is based on the fact that, in doing so, we can disentangle effects arising from soft interactions and viscosity from those arising from volume exclusion effects, because it can be assumed that a 5% concentration is not sufficient to cause volume exclusion effects, whereas higher concentrations of crowders can strongly decrease the quality of NMR spectra owing to the increase of viscosity. Nonetheless, after observing larger effects for PEG 20, we extended the NMR study in the range 5 to 20% PEG 20. The spectra up to 10% concentration are of good quality, although with incipient broadening, due to the considerable increase in viscosity.
In the superposition of the spectrum in buffer with that in the presence of 10% PEG 20 (Fig. 3a) the chemical shift changes are essentially identical to those observed in the 5% comparison (Fig. 2c). The main difference is that a few peaks of the folded species are apparently absent. This observation is the incipient manifestation of the broadening induced by the increase in viscosity as the amount of crowder is increased; the weakest and broadest peaks are the first to be influenced. The increase in viscosity does hardly influence CD spectra but affects NMR spectra, owing to the slowing down of tumbling motions. The broadening of the peaks of the globular part of the folded species becomes extreme in the 20% spectrum, to the point that the only observable peaks are those of the intrinsically disordered N-terminus. This behaviour is very interesting since it closely parallels what we had previously observed by in-cell NMR (Fig. 3c)34. We can thus conclude that the disappearance of the NMR spectrum of the folded species in cell, as well as in our in vitro experiment, must be attributed mainly to the increase in viscosity and the ensuing reduction of tumbling, without a sizeable contribution of weak interactions. This is per se an important conclusion.
Defining protein stability by Tm has clear limits
Protein stability is difficult to define using a single parameter, to the point that, in extreme cases, it may appear as an elusive concept. As pointed out by Pucci et al.35 thermal stability ought to be split between ‘thermodynamic stability’, that is, the folding free energy ΔG, and ‘thermal resistance’, that is, the melting temperature (Tm). It is common place to assume that the variation of melting temperature (ΔTm) can be used as a faithful measure of stability, implying proportionality with the change in thermodynamic stability (ΔΔG). Becktel and Schellman20 in their exhaustive analysis of the protein stability curve showed that when the change in free energy is small and the melting temperatures are not too close to the temperature of maximum stability (TS), it is possible to relate the change in Tm to the value of the perturbation free energy at the melting temperature. The relationship between changes in melting temperature and changes in free energy is linear only if we can make the assumption that the portions of the two stability curves chosen to measure the temperature increment (ΔT) behave as parallel straight lines (Supplementary Fig. 2) crossing the abscissa (T). In actual cases this is often not true: a common cause of failure stems from the simultaneous change of the enthalpy of folding and of heat content (ΔCp). Any change in curvature (−ΔCp/T) will make the two portions not parallel. For instance, as shown by McCrary et al.36 in the comparison between thermophilic Sac7d and mesophilic Metmyoglobin, the two indicators yield an oxymoronic description of thermal stability: Sac7d appears to be a protein of lower thermodynamic stability, although with higher thermal resistance. It is clear, from Fig. 4a, calculated from the thermodynamic data of McCrary et al.36, that Sac7d, the protein from a thermophilic organism, has a large increase in the Tm with a concomitant lowering of ΔGS, the free energy difference at the temperature of maximum stability (TS). It is also possible to have an increase in ΔGS, with little increase or even a decrease in Tm. The comparison of the stability curve of lysozyme in buffer alone and in buffer with the 5% v/v addition of propanol, calculated from the thermodynamic parameters of Velicelebi and Sturtevant37, is shown in Fig. 4b. It is clear that the very small decrease of Tm upon addition of propanol is not paralleled by a decrease in ΔGS (thermodynamic stability). On the contrary, there is a large increase of ΔGS. These contradictory results prompted us to look for a single parameter to express stability.
A sensitive empiric parameter to describe stability
We propose the use of a single parameter to gauge thermal stability: the area of the stability curve between the two unfolding temperatures. To compare areas we can take the integral of the equation of the stability curve (1) and calculate its value between Tc and Tm.
The integral of equation (1) is given by:
It is easy to grasp that this parameter is an assessment of the global thermodynamic stability within the entire temperature range of protein stability, rather than at a single temperature.
In the case of the comparison between a protein from a mesophilic organism (Metmyoglobin) with a thermophilic one (Sac7d)36 the large decrease in ΔHm is paralleled by an increase of both Tm (of 11 K) and of the integral of the stability curve (I), as shown in Table 2.
Thus, we have no paradox: two parameters, Tm and I, point to greater thermal stability. In the case of the addition of propanol to the lysozyme solution the small decrease of Tm is accompanied by an increase in ΔGS of 30% but also by a much larger increase in the integral. It is fair to say that the large increase of I hints at a great thermal stabilization in spite of the small decrease of Tm. Table 2 summarizes the values of the integral of the stability curve (I) between Tc and Tm for the examples of Fig. 4a,b, alongside the relevant thermodynamic parameters.
An interesting application of the new parameter is shown in Fig. 4c,d. Luke et al.38 tried to correlate Tm and ΔGu values for some hyperthermostable proteins. The correlation is approximately linear, but only if values for mesophilic counterparts are included in the same graph. If one plots only values for hyperthermostable proteins the graph looks like that of Fig. 4c. It is far from linear and it is difficult to fit any curve. However, if relative areas are used instead (Fig. 4d), relative values of the integral (I/Io) correlate fairly well with Tm and all values fall to an exponential curve.
We have also used the new parameter to analyse our data on the stabilizing influence of alcohols21 and found that it allows a much easier interpretation of the results (Supplementary Figs 3 and 4). Accordingly, we can use it to assess the influence of crowding on protein stability.
Using the relative increments of the area of the stability curves not only clarifies the meaning of the disparity observed between high (Tm) and low transition points (Tc) but also gives us new insights into the influence of different crowders. The comparison of the changes of Tm (Fig. 5a) and of Tc (Fig. 5b) illustrates why the use of this type of parameter may yield ambiguous results.
The two graphs of Fig. 5a,b offer contradictory views on the influence of crowders on the stability of Yfh1. Judging from high temperature unfolding, all crowders have apparently similar moderate influence on the stability of the protein. Conversely, judging from low temperature unfolding, it appears that all Tcs decrease more and those influenced by PEG 20 correspond to a very pronounced stabilizing effect on the protein. In Fig. 5c, we report the dependence of the areas of the stability curves of Yfh1 under the influence of different crowders. The areas are normalized with respect to the area of the stability curve of Yfh1 in buffer. The use of this single parameter offers an unambiguous interpretation. The dependence of the two smaller crowders is qualitatively different from those of crowders whose volume is much larger than that of Yfh1. The increase in protein stability indicated by the increase of relative areas under the influence of PEG 20 is so large as to hint at the concurrence of different causes.
Molecular crowding has recently come in the spotlights because of its essential role in the cell and biological fluids.
Several authors have remarked that experimental findings on the stabilization induced by crowders appear far smaller than those predicted by theoretical calculations2,3. This discrepancy might be attributed in part to a basic overestimation of the volume increase upon denaturation2 but also to the relative insensitivity of melting point (Tm) to detect changes in stability. Depending on the combination of thermodynamic parameters, it may happen that the value of Tm increases very little or even decreases, whereas thermodynamic stability increases21,24,36. To circumvent this difficulty we used a different single parameter, defined as the area of the stability curve to gauge protein stability that can be used in cases when cold and heat denaturation can be detected. This new parameter is very sensitive to even small changes in global protein stability. Using it we were able to determine unequivocally that volume exclusion plays an important role in the absence of weak interactions between the crowders and the protein. We studied the influence, on the stability of Yfh1, of different macromolecular crowders at concentrations ranging between 5 and 20% w/v. This comparison highlights the importance of the relative dimensions of the protein under study and of the crowders. Crowders whose molecular weight is closer to that of the protein under study appear to be more effective than larger crowders.
A very important result emerging from our study is that the influence of crowders on high and low temperature unfolding is dramatically different. The possibility of observing cold denaturation reveals that low temperature unfolding is much more sensitive to the presence of macromolecules that affect volume availability. The most likely interpretation of this marked asymmetry is that the volume of the low temperature unfolded species is larger than that at high temperature. This interpretation is consistent with our previous observations on the difference between the two unfolded states22,23, mainly based on a strong hydration of the low temperature species that leads to a more expanded state. This finding was later confirmed by a direct FRET measurement26.
The influence of PEG 20 on cold denaturation of Yfh1 is so larger than those of the other crowders that it cannot be attributed solely to the larger volume of the low temperature unfolded species. Having ruled out a direct interaction of PEG 20 with our protein, the most likely cause of the marked asymmetry observed between low and high temperature behaviour of Yfh1 in the presence of PEG must be sought in the indirect effect on water activity. The ability of PEG polymers to lower water activity is routinely exploited in protein crystallization39,40. Its asymmetric effect on cold and hot denaturation is consistent with the mechanism of cold denaturation based on preferential hydration of the hydrophobic groups of the protein core41.
It is fair to ask whether the behaviour of Yfh1 is idiosyncratic. How general are our findings? Is the dependence of stability on crowder’s relative size a unique property of this protein or a general property of many if not all proteins? Can we extrapolate it to other proteins? The answer is yes, with the proviso that it is generally difficult to observe the influence on low temperature unfolded species directly, simply because cold denaturation transition occurs, for most proteins, at too low a temperature to allow direct observation. However, although it is not generally possible to observe the low temperature transition, it is often possible to measure ΔCp accurately from calorimetric measurements. Thus, we can take advantage of the full stability curve and of the related integral parameter. It remains to be seen whether the low temperature unfolded species is more expanded than the high temperature one in all proteins. It is quite possible that the volume change upon unfolding, both at high and low temperature, can vary widely among different proteins2.
It is important to emphasize that the analysis of the influence of crowders on Yfh1 was greatly facilitated by gauging stability with the aid of the integral of the stability curve. We can thus conclude that our study sets a clear answer on the question of the influence of volume exclusion, also in relation with the optimal size of a crowder and demonstrates that the use of integrals of the stability curve is a very useful addition to the parameters commonly employed to describe the thermal stability of proteins.
Yfh1 was expressed in E. coli and purified as described by He et al.42 Purity of the recombinant proteins was checked by SDS–polyacrylamide gel electrophoresis after each step of the purification.
All crowding agents, PEG 20, dextran 40, Ficoll 70 and Ficoll 400 were purchased from Sigma Aldrich. Concentrated solutions to be used as mother solutions to prepare samples at different crowder concentrations were examined for their potential influence on the final ionic strength and pH.
Yfh1, cloned in pET21a vectors, was transformed in BL21(DE3) E. coli cells and selected for transformation in ampicillin plates, according to previously published protocols42. As previously described34, single colonies were grown overnight at 37 °C in 3 ml of Luria Broth medium and 2 ml of the cultures were used to inoculate 100 ml of fresh medium. When the cells reached the desired optical density, they were collected by centrifugation at 3,600 g for 15 min at room temperature. The pellet was then resuspended in 100 ml of 15N enriched minimal medium, incubated in a rotary shaker at 37 °C for 10 min and induced with isopropylthiogalactoside (0.5 mM).
The final pellet was resuspended in 500 ml of M9 medium mixed with 50 ml of D2O, before transferring it into standard 5 mm NMR tubes using a Pasteur pipette and used immediately for NMR experiments.
NMR spectra were recorded on a Bruker AVANCE operating at 600 MHz 1H frequency. Measurements were carried out using a 15 N uniformly labelled protein at a concentration of 70 μM in a 20 mM HEPES buffer at pH 7.0 and in the same buffer supplemented with 5% of PEG 20, dextran 40, Ficoll 70 or Ficoll 400. Water suppression was achieved by the WATERGATE pulse-sequence43, HSQC spectrum experiments were used as described by Bax et al.44 The spectra were processed using the NMRPipe program45. Baseline correction was applied when necessary.
Far-ultraviolet CD measurements
Samples were prepared using a Yfh1 concentration of 10 μM in a 10 mM HEPES buffer at pH 7.0 and with varying concentrations of PEG 20, dextran 40, Ficoll 70 or Ficoll 400. Baseline correction was obtained by subtraction of the appropriate buffer spectrum. Thermal unfolding curves were obtained by monitoring the ellipticity at 220 nm using a Jasco J-815 CD spectropolarimeter equipped with a Jasco CDF-4265/15 Peltier unit. The 1 mm path length cells (Hellma) were used and a heating rate of 2 °C min−1 in the temperature range 2–70 °C.
Equations to describe stability
To have an accurate insight into protein stability, it is desirable to be able to measure its whole stability curve. This curve is the plot of ΔG, the difference of free energy between the folded and unfolded species, as calculated from a modified Gibbs–Helmholtz equation (1) in which the reference temperature is the midpoint of the high temperature transition (Tm), as a function of temperature. For most proteins, fitting thermograms based on spectroscopic measurements, for example, CD and NMR spectroscopies, yields accurate vales for Tm and ΔHm. However, these fits are totally insensitive to the value of ΔCp, unless it is possible to observe two unfolding transitions, that is, cold denaturation and heat denaturation. The occurrence of cold denaturation is obvious from the stability curve of any protein20. The bell-shaped form of the curve implies that destabilization of the folded species happens at the two zero points of ΔG, as the temperature varies from room temperature in either direction, that is, to higher or lower temperatures. All thermodynamic parameters can then be extracted from a plot of ΔG against temperature, by means of an original fitting program46. The calculation of errors on the parameters is based on the fitting procedure. The errors in ΔCp and other parameters are modest because the temperature dependence of ΔG is quite sensitive to the value of ΔCp (proportional to the curvature of the stability curve).
The data that support the findings of this study are available from the corresponding author on reasonable request.
How to cite this article: Alfano, C. et al. An optimized strategy to measure protein stability highlights differences between cold and hot unfolded states. Nat. Commun. 8, 15428 doi: 10.1038/ncomms15428 (2017).
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Zimmerman, S. B. & Trach, S. O. Estimation of macromolecule concentrations and excluded volume effects for the cytoplasm of Escherichia coli. J. Mol. Biol. 222, 599–620 (1991).
Politou, A. & Temussi, P. A. Revisiting a dogma: the effect of volume exclusion in molecular crowding. Curr. Opin. Struct. Biol. 30, 1–6 (2015).
Hong, J. & Gierasch, L. M. Macromolecular crowding remodels the energy landscape of a protein by favoring a more compact unfolded state. J. Am. Chem. Soc. 132, 10445–10452 (2010).
Smith, A. E., Zhang, Z., Pielak, G. J. & Li, C. NMR studies of protein folding and binding in cells and cell-like environments. Curr. Opin. Struct. Biol. 30, 7–16 (2015).
Oshima, H. & Kinoshita, M. Effects of sugars on the thermal stability of a protein. J. Chem. Phys. 138, 245101 (2013).
Spiga, E., Abriata, L. A., Piazza, F. & Dal Peraro, M. Dissecting the effects of concentrated carbohydrate solutions on protein diffusion, hydration, and internal dynamics. J Phys. Chem. B 118, 5310–5321 (2014).
Christiansen, A. & Wittung-Stafshede, P. Quantification of excluded volume effects on the folding landscape of Pseudomonas aeruginosa apoazurin in vitro. Biophys. J. 105, 1689–1699 (2013).
Adén, J. & Wittung-Stafshede, P. Folding of an unfolded protein by macromolecular crowding in vitro. Biochemistry 53, 2271–2277 (2014).
Senske, M. et al. Protein stabilization by macromolecular crowding through enthalpy rather than entropy. J. Am. Chem. Soc. 136, 9036–9041 (2014).
Sanfelice, D. et al. The effect of crowding and confinement: a comparison of Yfh1 stability in different environments. Phys. Biol. 10, 045002 (2013).
Mittal, S. & Singh, L. R. Denatured state structural property determines protein stabilization by macromolecular crowding: a thermodynamic and structural approach. PLoS ONE 8, e78936 (2013).
Sotomayor-Pérez, A. C., Subrini, O., Hessel, A., Ladant, D. & Chenal, A. Molecular crowding stabilizes both the intrinsically disordered calcium-free state and the folded calcium-bound state of a repeat in toxin (RTX) protein. J. Am. Chem. Soc. 135, 11929–11934 (2013).
Mukherjee, S. K., Gautam, S., Biswas, S., Kundu, J. & Chowdhury, P. K. Do macromolecular crowding agents exert only an excluded volume effect? A protein solvation study. J. Phys. Chem. B. 119, 14145–14156 (2015).
Wang, Y., Sarkar, M., Smith, A. E., Krois, A. S. & Pielak, G. J. Macromolecular crowding and protein stability. J. Am. Chem. Soc. 134, 16614–16618 (2012).
Martorell, G., Adrover, M., Kelly, G., Temussi, P. A. & Pastore, A. A natural and readily available crowding agent: NMR studies of proteins in hen egg white. Proteins 79, 1408–1415 (2011).
Graziano, G. On the mechanism of cold denaturation. Phys. Chem. Chem. Phys. 16, 21755–21767 (2014).
Minton, A. P. The influence of macromolecular crowding and macromolecular confinement on biochemical reactions in physiological media. J Biol Chem. 276, 10577–10580 (2001).
Hoffman, L. et al. Relative cosolute size influences the kinetics of protein-protein interactions. Biophys. J. 109, 510–520 (2015).
Szyperski, T., Mills, J. L., Perl, D. & Balbach, J. Combined NMR-observation of cold denaturation in supercooled water and heat denaturation enables accurate measurement of ΔCp of protein unfolding. Eur. Biophys. J. 35, 363–366 (2006).
Becktel, W. J. & Schellman, J. A. Protein stability curves. Biopolymers 26, 1859–1877 (1987).
Martin, S. R., Esposito, V., De Los Rios, P., Pastore, A. & Temussi, P. A. Cold denaturation of yeast frataxin offers the clue to understand the effect of alcohols on protein stability. J. Am. Chem. Soc. 130, 9963–9970 (2008).
Adrover, M., Esposito, V., Martorell, G., Pastore, A. & Temussi, P. A. Understanding cold denaturation: the case study of Yfh1. J. Am. Chem. Soc. 132, 16240–16246 (2010).
Adrover, M. et al. The role of hydration in protein stability: comparison of the cold and heat unfolded states of Yfh1. J. Mol. Biol. 417, 413–424 (2012).
Sanfelice, D. et al. Yeast frataxin is stabilized by low salt concentrations: cold denaturation disentangles ionic strength effects from specific interactions. PLoS ONE 9, e95801 (2014).
Ekelof, S. The genesis of the Wheatstone bridge. Eng. Sci. Educ. J. 10, 37–40 (2001).
Aznauryan, M., Nettels, D., Holla, A., Hofmann, H. & Schuler, B. Single-molecule spectroscopy of cold denaturation and the temperature-induced collapse of unfolded proteins. J. Am. Chem. Soc. 135, 14040–14043 (2013).
Kozer, N., Kuttner, Y. Y., Haran, G. & Schreiber, G. Protein-protein association in polymer solutions: from dilute to semidilute to concentrated. Biophys. J. 92, 2139–2149 (2007).
Pastore, A. et al. Unbiased cold denaturation: low- and high-temperature unfolding of yeast frataxin under physiological conditions. J. Am. Chem. Soc. 129, 5374–5375 (2007).
Sarkar, M., Lu, J. & Pielak, G. J. Protein crowder charge and protein stability. Biochemistry 53, 1601–1606 (2014).
Crowley, P. B., Brett, K. & Muldoon, J. NMR spectroscopy reveals cytochrome c-poly(ethylene glycol) interactions. ChemBioChem. 9, 685–688 (2008).
Jiao, M., Li, H. T., Chen, J., Minton, A. P. & Liang, Y. Attractive protein-polymer interactions markedly alter the effect of macromolecular crowding on protein association equilibria. Biophys. J. 99, 914–923 (2010).
Paredes, J. M. et al. Photophysics of the interaction between a fluorescein derivative and Ficoll. J. Phys. Chem. A 115, 13242–13250 (2011).
Sukenik, S., Sapir, L., Gilman-Politi, R. & Harries, D. Diversity in the mechanisms of cosolute action on biomolecular processes. Faraday Discuss 160, 225–237 (2013).
Popovic, M. et al. Selective observation of the disordered import signal of a globular protein by in-cell NMR: the example of frataxins. Protein Sci. 24, 996–1003 (2015).
Pucci, F., Dhanani, M., Dehouck, Y. & Rooman, M. Protein thermostability prediction within homologous families using temperature-dependent statistical potentials. PLoS ONE 9, e91659 (2014).
McCrary, B. S., Edmondson, S. P. & Shriver, J. W. Hyperthermophile protein folding thermodynamics: differential scanning calorimetry and chemical denaturation of Sac7d. J. Mol. Biol. 264, 784–805 (1996).
Velicelebi, G. & Sturtevant, J. M. Thermodynamics of the denaturation of lysozyme in alcohol--water mixtures. Biochemistry 18, 1180–1186 (1979).
Luke, K. A., Higgins, C. L. & Wittung-Stafshede, P. Thermodynamic stability and folding of proteins from hyperthermophilic organisms. FEBS J. 274, 4023–4033 (2007).
McPherson, A. Jr Crystallization of proteins from polyethylene glycol. J. Biol. Chem. 251, 6300–6303 (1976).
Stiebler, R., Hoang, A. N., Egan, T. J., Wright, D. W. & Oliveira, M. F. Increase on the initial soluble heme levels in acidic conditions is an important mechanism for spontaneous heme crystallization in vitro. PLoS ONE 5, e12694 (2010).
Privalov, P. L. Cold denaturation of proteins. Crit. Rev. Biochem. Mol. Biol. 25, 281–305 (1990).
He, Y. et al. Yeast frataxin solution structure, iron binding, and ferrochelatase interaction. Biochemistry 43, 16254–16262 (2004).
Piotto, M., Saudek, V. & Sklenár, V. Gradient-tailored excitation for single-quantum NMR spectroscopy of aqueous solutions. J. Biomol. NMR 2, 661–665 (1992).
Bax, A., Ikura, M., Kay, L. E., Torchia, D. A. & Tschudin, R. Comparison of different modes of two-dimensional reverse correlation NMR for the study of proteins. J. Magn. Reson. 86, 304–318 (1990).
Delaglio, F. et al. NMRPipe: a multidimensional spectral processing system based on UNIX pipes. J. Biomol. NMR 6, 277–293 (1995).
Masino, L., Martin, S. R. & Bayley, P. M. Ligand binding and thermodynamic stability of a multidomain protein, calmodulin. Protein Sci. 9, 1519–1529 (2000).
The work was supported by MRC (U117584256).
The authors declare no competing financial interests.
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Alfano, C., Sanfelice, D., Martin, S. et al. An optimized strategy to measure protein stability highlights differences between cold and hot unfolded states. Nat Commun 8, 15428 (2017). https://doi.org/10.1038/ncomms15428
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