Urea’s Action on Hydrophobic Interactions

Zangi, Ronen; Zhou, Ruhong; Berne, B. J.

doi:10.1021/ja807887g

Cited by 306 publications

(370 citation statements)

References 55 publications

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“…The enthalpic factor results from a decreased H-bonding ability of water, whereas the entropic factor stems from the crowding effect of TMAO; both act to destabilize the unfolded state ensemble. Because the tripeptide used in the current study is relatively small, it is possible to use molecular dynamics simulations (68,74,75), in conjunction with vibrational frequency calculations (76), to directly calculate the FFCFs of the nitrile probe under different cosolvent conditions and to provide further molecular insights. We hope that the current study will inspire new computational efforts in this regard.…”

Section: Discussionmentioning

confidence: 99%

Microscopic insights into the protein-stabilizing effect of trimethylamine N-oxide (TMAO)

Pazos

Gai

2014

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

227

237

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Although it is widely known that trimethylamine N-oxide (TMAO), an osmolyte used by nature, stabilizes the folded state of proteins, the underlying mechanism of action is not entirely understood. To gain further insight into this important biological phenomenon, we use the C≡N stretching vibration of an unnatural amino acid, p-cyano-phenylalanine, to directly probe how TMAO affects the hydration and conformational dynamics of a model peptide and a small protein. By assessing how the lineshape and spectral diffusion properties of this vibration change with cosolvent conditions, we are able to show that TMAO achieves its protein-stabilizing ability through the combination of (at least) two mechanisms: (i) It decreases the hydrogen bonding ability of water and hence the stability of the unfolded state, and (ii) it acts as a molecular crowder, as suggested by a recent computational study, that can increase the stability of the folded state via the excluded volume effect.N ature employs a variety of small organic molecules to cope with osmotic stress. Trimethylamine N-oxide (TMAO) is one such naturally occurring osmolyte that protects intracellular components against disruptive stress conditions (1). In particular, previous studies have shown that TMAO is able to enhance protein stability and to counteract the denaturing effect of urea (2, 3). TMAO (Fig. 1, Inset) adopts a skewed tetrahedral structure with a charged oxygen capable of accepting hydrogen bonds (H bonds) and three hydrophobic (methyl) groups. This amphiphilic structural arrangement makes TMAO a rather special cosolvent, because it can form H bonds with water, self-associate in a manner similar to surfactants, and show preferential interactions with or exclusion (4-12) from certain protein functional groups (13-23). Indeed, these molecular properties of TMAO have been used, either individually or in combination, to rationalize its biological activities. For example, a prevailing view about TMAO is that its osmotic and protective role is caused by the molecule's tendency to be preferentially depleted from protein surfaces, as suggested by physicochemical measurements (24-28). This thermodynamic picture, as described by Bolen and coworkers (29), implies that the protein is preferentially hydrated. Although this notion is consistent with TMAO's being a protecting osmolyte, to the best of our knowledge no experimental studies have been carried out to directly examine the effect of TMAO on protein hydration dynamics, an aspect that is also important to protein function. Herein, we use twodimensional infrared (2D IR) spectroscopy and a site-specific IR probe to explore this critical issue and gain insight toward achieving a microscopic understanding of the molecular mechanism of the protecting action of TMAO.2D IR spectroscopy is capable of assessing the frequencyfrequency correlation function (FFCF) of a given IR probe, which reports on the underlying dynamics of events that lead to fluctuations of its vibrational frequency (30). For an IR probe that is able ...

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Section: Discussionmentioning

confidence: 99%

Microscopic insights into the protein-stabilizing effect of trimethylamine N-oxide (TMAO)

Pazos

Gai

2014

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

227

237

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“…The second view is based on the direct interaction of urea with the protein. Most studies are based on model compounds and theoretical and modeling approaches, such as molecular dynamics (29)(30)(31)(32)(33)(34)(35).…”

Section: Significancementioning

confidence: 99%

A hypothesis to reconcile the physical and chemical unfolding of proteins

Oliveira

Silva

2015

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

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High pressure (HP) or urea is commonly used to disturb folding species. Pressure favors the reversible unfolding of proteins by causing changes in the volumetric properties of the protein-solvent system. However, no mechanistic model has fully elucidated the effects of urea on structure unfolding, even though proteinurea interactions are considered to be crucial. Here, we provide NMR spectroscopy and 3D reconstructions from X-ray scattering to develop the "push-and-pull" hypothesis, which helps to explain the initial mechanism of chemical unfolding in light of the physical events triggered by HP. In studying MpNep2 from Moniliophthora perniciosa, we tracked two cooperative units using HP-NMR as MpNep2 moved uphill in the energy landscape; this process contrasts with the overall structural unfolding that occurs upon reaching a threshold concentration of urea. At subdenaturing concentrations of urea, we were able to trap a state in which urea is preferentially bound to the protein (as determined by NMR intensities and chemical shifts); this state is still folded and not additionally exposed to solvent [fluorescence and small-angle X-ray scattering (SAXS)]. This state has a higher susceptibility to pressure denaturation (lower p 1/2 and larger ΔV u ); thus, urea and HP share concomitant effects of urea binding and pulling and water-inducing pushing, respectively. These observations explain the differences between the molecular mechanisms that control the physical and chemical unfolding of proteins, thus opening up new possibilities for the study of protein folding and providing an interpretation of the nature of cooperativity in the folding and unfolding processes.protein folding | hydrostatic pressure | urea | NMR | SAXS

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“…In fact, we have added up to 20 wt% of urea and not only was no phase separation observed but also the cellulose dissolution and rheology properties were improved. As mentioned above, we believe that urea is weakening the hydrophobic interactions (in a similar way as it does during protein unfolding) increasing cellulose solubility and preventing the hydrophobic regions of cellulose to come together to form a gelled network (Zangi et al 2009). …”

Section: Tuning the Solvent Quality: Role Of Salt Urea And Cyclodextmentioning

confidence: 84%

Probing cellulose amphiphilicity

Medronho

Duarte

Alves

et al. 2015

Nordic Pulp &Amp; Paper Research Journal

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SUMMARY: Cellulose dissolution and regeneration is an increasingly active research field due to the direct relevance for numerous production processes and applications. The problem is not trivial since cellulose solvents are of remarkably different nature and thus the understanding of the subtle balance between the different interactions involved becomes difficult but crucial. There is a current discussion in literature on the balance between hydrogen bonding and hydrophobic interactions in controlling the solution behavior of cellulose. This treatise attempts to review recent work highlighting the marked amphiphilic characteristics of cellulose and role of hydrophobic interactions in dissolution and regeneration. Additionally, a few examples of our own research are discussed focusing on the role of different additives in cellulose solubility. The data does support the amphiphilic behavior of cellulose, which clearly should not be neglected when developing new solvents and strategies for cellulose dissolution and regeneration. ADDRESSES OF THE AUTHORS

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Urea’s Action on Hydrophobic Interactions

Cited by 306 publications

References 55 publications

Microscopic insights into the protein-stabilizing effect of trimethylamine N-oxide (TMAO)

Microscopic insights into the protein-stabilizing effect of trimethylamine N-oxide (TMAO)

A hypothesis to reconcile the physical and chemical unfolding of proteins

Probing cellulose amphiphilicity

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