Balance of enthalpy and entropy in depletion forces

Sukenik, Shahar; Sapir, Liel; Harries, Daniel

doi:10.1016/j.cocis.2013.10.002

Cited by 90 publications

(115 citation statements)

References 72 publications

(87 reference statements)

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“…The implications of these enthalpic changes for the mechanism of osmolyte stabilization were pointed out by Politi and Harries (37): There must be other intermolecular forces acting in addition to steric crowding. Sukenik et al categorized possible mechanisms based on the measured sign and relative magnitudes of enthalpic and entropic contributions (38). Senske et al did a similar classification of possible mechanisms for protein stabilization based on observed changes in enthalpy of unfolding and melting temperature T m (which depends also on entropy) (39).…”

Section: Discussionmentioning

confidence: 99%

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Analysis of the size dependence of macromolecular crowding shows that smaller is better

Sharp

2015

Proc. Natl. Acad. Sci. U.S.A.

139

129

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The aqueous milieu inside cells contains as much as 30-40% dissolved protein and RNA by volume. This large concentration of macromolecules is expected to cause significant deviations from solution ideality. In vivo biochemical reaction rates and equilibria might differ significantly from those measured in the majority of in vitro experiments that are performed at much lower macromolecule concentrations. Consequently crowding, a nonspecific phenomenon believed to arise from the large excluded volume of these macromolecules, has been studied extensively by experimental and theoretical methods. However, the relevant theory has not been applied consistently. When the steric effects of macromolecular crowders and small molecules like water and ions are treated on an equal footing, the effect of the macromolecules is opposite to that commonly believed. Large molecules are less effective at crowding than water and ions. There is also a surprisingly weak dependence on crowder size. Molecules of medium size, ∼5 Å radius, have the same effect as much larger macromolecules like proteins and RNA. These results require a reassessment of observed high-concentration effects and of strategies to mimic in vivo conditions with in vitro experiments. T he milieu inside cells contains a large amount of solutes that include small ions, metabolites, and macromolecules. Typical protein/RNA concentrations range from 300 mg/mL to 400 mg/mL or about 30-40% by weight. These are 10-fold or more higher than the macromolecular concentrations usually encountered in in vitro measurements and could lead to significant nonideality in solution behavior. The possibility that in vivo biochemical reaction rates and equilibria might be quite different from measured values due to this nonideality has stimulated considerable research. Macromolecular crowding in particular has stimulated a large number of studies, which have been extensively reviewed (1-5). Crowding has been variously described as physical occupation of volume by the macromolecules, which is then unavailable to other molecules, as an excluded volume effect, as a nonspecific effect due to steric repulsion, and as eliminating positions at which the protein can be placed (2, 5, 6). The other contribution to nonideality is from interactions between various solution components, either attractive or repulsive-repulsive interactions distinct from the van der Waals core repulsion or steric factor underlying crowding. We know very little about the contribution of intersolute interactions to nonideality in vivo. Crowding has been more extensively studied because the steric or excluded volume of a macromolecule is a welldefined property, it is always present, and its qualitative effect on biochemical reactions seems obvious (2). However, as I demonstrate in this paper, the effect of crowding macromolecules on a biochemical reaction is not obvious, the relevant theory has not been consistently applied, and indeed the effect is opposite to that commonly believed.Analyses of the effect of crowding mac...

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Section: Discussionmentioning

confidence: 99%

“…The second difficulty is that observed effects of osmolytes and crowders on protein binding and folding often have significant enthalpic contributions (23,(37)(38)(39). Excluded volume effects are entropic, whether treated by the mean-field AO, scaled particle, or HS mixture models.…”

Section: Discussionmentioning

confidence: 99%

Analysis of the size dependence of macromolecular crowding shows that smaller is better

Sharp

2015

Proc. Natl. Acad. Sci. U.S.A.

139

129

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“…We found that the relative fibril elongation rate in our simulations with 40 Å crowders has a value that is similar to the relative fibril elongation rate for insulin fibrils in the presence of 200 kDa dextran. Our relative fibril elongation rates for Ab (16)(17)(18)(19)(20)(21)(22) with 20 Å crowders are equivalent to those obtained for bovine insulin and insulin B-chain with 200 kDa dextran, and our relative fibril elongation rates for Ab (16)(17)(18)(19)(20)(21)(22) with 5 Å crowders are equivalent to those obtained for human a-synuclein and hen egg white lysozyme with 200 kDa dextran.…”

Section: Introductionmentioning

confidence: 72%

“…Experiments have been conducted to examine how attractive molecules, including osmolytes (14)(15)(16)(17)(18)(19)(20), saccharides (21), small-molecule inhibitors (22)(23)(24), and quantum dots (25), affect protein aggregation. Among these experimental studies, the most relevant to our work involved the addition of osmolytes to a system of proteins, because they employed concentrations and size scales similar to those used in our simulations.…”

Section: Introductionmentioning

confidence: 99%

“…More specifically, we applied discontinuous molecular dynamics (DMD) combined with the PRIME20 force field to a system comprised of 192 Ab (16)(17)(18)(19)(20)(21)(22) peptides and hard-sphere crowders with diameters D ¼ 5 Å , 20 Å , and 40 Å at crowder volume fractions f ¼ 0.00 and 0.10 starting from a random configuration. The major findings of that study were that 1) the addition of crowders to a system of peptides increases the rates of oligomerization and fibrillization, with higher volume fractions and smaller crowders providing the largest enhancement effects, and 2) the aggregation mechanism changes from a relatively slow-nucleated polymerization mechanism to a relatively fast-nucleated conformational conversion mechanism as the crowder volume fraction increases or the crowder diameter decreases.…”

Section: Introductionmentioning

confidence: 99%

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Effects of Hydrophobic Macromolecular Crowders on Amyloid β (16–22) Aggregation

Latshaw

Hall

2015

Biophysical Journal

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In Alzheimer's disease (AD), the amyloid β (Aβ) peptide aggregates in the brain to form progressively larger oligomers, fibrils, and plaques. The aggregation process is strongly influenced by the presence of other macromolecular species, called crowders, that can exert forces on the proteins. One very common attribute of macromolecular crowders is their hydrophobicity. We examined the effect of hydrophobic crowders on protein aggregation by using discontinuous molecular dynamics (DMD) simulations in combination with an intermediate resolution protein model, PRIME20. The systems considered contained 48 Aβ (16-22) peptides and crowders with diameters of 5 Å, 20 Å, and 40 Å, represented by hard spheres or spheres with square-well/square-shoulder interactions, at a crowder volume fraction of ϕ = 0.10. Results show that low levels of crowder hydrophobicity are capable of increasing the fibrillation lag time and high levels of crowder hydrophobicity can fully prevent the formation of fibrils. The types of structures that remain during the final stages of the simulations are summarized in a global phase diagram that shows fibril, disordered oligomer, or β-sheet phases in the space spanned by crowder size and crowder hydrophobicity. In particular, at high levels of hydrophobicity, simulations with 5 Å crowders result in only disordered oligomers and simulations with 40 Å crowders result in only β-sheets. The presence of hydrophobic crowders reduces the antiparallel β-sheet content of fibrils, whereas hard sphere crowders increase it. Finally, strong hydrophobic crowders alter the secondary structure of the Aβ (16-22) monomers, bending them into a shape that is incapable of forming ordered β-sheets or fibrils. These results qualitatively agree with previous theoretical and experimental work.

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Cosolvent and Crowding Effects on the Temperature‐ and Pressure‐Dependent Dissociation Process of the α/β‐Tubulin Heterodimer

et al. 2019

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Tubulin is one of the main components of the cytoskeleton of eukaryotic cells. The formation of microtubules depends strongly on environmental and solution conditions, and has been found to be among the most pressure sensitive processes in vivo. We explored the effects of different types of cosolvents, such as trimethylamine‐N‐oxide (TMAO), sucrose and urea, and crowding agents to mimic cell‐like conditions, on the temperature and pressure stability of the building block of microtubules, i. e. the α/β‐tubulin heterodimer. To this end, fluorescence and FTIR spectroscopy, differential scanning and pressure perturbation calorimetry as well as fluorescence anisotropy and correlation spectroscopies were applied. The pressure and temperature of dissociation of α/β‐tubulin as well as the underlying thermodynamic parameters upon dissociation, such as volume and enthalpy changes, have been determined for the different solution conditions. The temperature and pressure of dissociation of the α/β‐tubulin heterodimer and hence its stability increases dramatically in the presence of TMAO and the nanocrowder sucrose. We show that by adjusting the levels of compatible cosolutes and crowders, cells are able to withstand deteriorating effects of pressure even up to the kbar‐range.

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Balance of enthalpy and entropy in depletion forces

Cited by 90 publications

References 72 publications

Analysis of the size dependence of macromolecular crowding shows that smaller is better

Analysis of the size dependence of macromolecular crowding shows that smaller is better

Effects of Hydrophobic Macromolecular Crowders on Amyloid β (16–22) Aggregation

Cosolvent and Crowding Effects on the Temperature‐ and Pressure‐Dependent Dissociation Process of the α/β‐Tubulin Heterodimer

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