Protein Dynamics in Organic Media at Varying Water Activity Studied by Molecular Dynamics Simulation

Wedberg, Rasmus; Abildskov, Jens; Peters, Günther H.J.

doi:10.1021/jp211054u

Cited by 70 publications

(98 citation statements)

References 93 publications

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“…The same question may be asked in the cases where water is replaced by organic solvents (Soares et al, 2003;Chen et al, 2008;Wedberg et al, 2012;Klibanov, 2010). Van der Waals interactions still operate, and dipolar interactions will increase in strength as water is removed.…”

Section: Discussionmentioning

confidence: 99%

“…An important family of experimental tools for studying proteins and protein-protein interactions consists of matrix-assisted laser desorption/ionization (MALDI), time-of-flight mass spectrometry (TOF) and electrospray (Smith et al, 1990;Robinson et al, 2007;Wyttenbach and Bowers, 2007;Breuker and McLafferty, 2008;Benesch and Robinson, 2009;Liu et al, 2009;Liu and Schey, 2008;Barrera et al, 2008). Many proteins, and many protein-protein complexes, retain their structural integrity in vacuo, at least for a sufficiently long time, for many of their essential structural features to be retained and be capable of study in intimate detail (Patriksson et al, 2007;Meyer et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

“…For this work, our guiding principles were to provide insights into protein hydration and dehydration in the light of an abundance of excellent published work (Smith et al, 1990;Robinson et al, 2007;Wyttenbach and Bowers, 2007;Breuker and McLafferty, 2008;Benesch and Robinson, 2009;Liu et al, 2009;Liu and Schey, 2008;Barrera et al, 2008) but in particular by the large-scale systematic experimental study of protein hydration (Chen et al, 2008). In that seminal work, distinction was made between three categories of water molecules: individual water molecules hydrogen-bonded to donor/acceptor atoms on the surface or in crevices, bound waters immediately surrounding these, and remaining crystal waters (meaning water molecules located in the crystal structure) surrounding the former which have the normal attributes of bulk water.…”

Section: Introductionmentioning

confidence: 99%

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The fate of proteins in outer space

Seddon

Bywater

2015

International Journal of Astrobiology

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It is well established that any properly conducted biophysical studies of proteins must take appropriate account of solvent. For water-soluble proteins it has been an article of faith that water is largely responsible for stabilizing the fold, a notion that has recently come under increasing scrutiny. Further, there are some instances when proteins are studied experimentally in the absence of solvent, as in matrix-assisted laser desorption/ionization or electrospray mass spectrometry, for example, or in organic solvents for protein engineering purposes. Apart from these considerations, there is considerable speculation as to whether there is life on planets other than Earth, where conditions including the presence of water (both in liquid or vapor form and indeed ice), temperature and pressure may be vastly different from those prevailing on Earth. Mars, for example, has only 0.6% of Earth's mean atmospheric pressure which presents profound problems to protein structures, as this paper and a large corpus of experimental work demonstrate. Similar objections will most likely apply in the case of most exoplanets and other bodies such as comets whose chemistry and climate are still largely unknown.This poses the question, how do proteins survive in these different environments? In order to cast some light on these issues we have conducted a series of molecular dynamics simulations on protein dehydration under a variety of conditions. We find that, while proteins undergoing dehydration can retain their integrity for a short duration they ultimately become disordered, and we further show that the disordering can be retarded if superficial water is kept in place on the surface. These findings are compared with other published results on protein solvation in an astrobiological and astrochemical setting. Inter alia, our results suggest that there are limits as to what to expect in terms of the existence of possible extraterrestrial forms as well to what can be achieved in experimental investigations on living systems despatched from Earth. This finding may appear to undermine currently held hopes that life will be found on nearby planets, but it is important to be aware that the presence of ice and water are by themselves not sufficient; there has to be an atmosphere which includes water vapor at a sufficiently high partial pressure for proteins to be active. A possible scenario in which there has been a history of adequate water vapor pressure which allowed organisms to prepare for a future dessicated state by forming suitable protective capsules cannot of course be ruled out.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

The fate of proteins in outer space

Seddon

Bywater

2015

International Journal of Astrobiology

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“…Recently, we have explored different approaches to this property via MD simulation (Wedberg, Abildskov, and Peters 2012). Two main strategies to study how protein properties depend on water activity are termed "real-time" control and "a posteriori" analysis.…”

Section: Enzyme Solutionsmentioning

confidence: 99%

- Global and Local Properties of Mixtures: An Expanded Paradigm for the Study of Mixtures

2016

Fluctuation Theory of Solutions

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“…It has been reported that motions of surface residues are linked to the stability of lipase in polar solvents (methanol, acetonitrile, DMSO and dimethylformamide) [17], [42] and [43]. It is also known that polar solvents, as dehydrating agents, are able to bind to the surface residues of enzyme (lipase, protease and -12 -other enzymes), perturbing the essential layer of water that provides enzyme with conformational flexibility needed for catalysis and thus decreasing the enzymatic activity [40], [44], [45], [46], [47], [48], and [49]. Therefore, the capacity of lipases to tolerate polar solvents could be improved by introducing more intra-protein interactions on the flexible surface region or reducing the interactions between polar solvent molecules and enzyme surface residues.…”

Section: Computational Prediction Of a Stabilizing Mutation For Tllmentioning

confidence: 99%

New insights into the molecular mechanism of methanol-induced inactivation ofThermomyces lanuginosuslipase: a molecular dynamics simulation study

Tong

Busk

Lange

et al. 2015

Molecular Simulation

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Methanol intolerance of lipase is a major limitation in lipase-catalyzed methanolysis reactions.In this study, to understand the molecular mechanism of methanol-induced inactivation of lipases, we performed molecular dynamics (MD) simulations of Thermomyces lanuginosus lipase (TLL) in water and methanol and compared the observed structural and dynamic properties. The solvent accessibility analysis showed that in methanol, polar residues tended to be buried away from the solvent while non-polar residues tended to be more solventexposed in comparison to those in water. Moreover, we observed that in methanol, the van der Waals packing of the core residues in two hydrophobic regions of TLL became weak.

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Protein Dynamics in Organic Media at Varying Water Activity Studied by Molecular Dynamics Simulation

Cited by 70 publications

References 93 publications

The fate of proteins in outer space

The fate of proteins in outer space

- Global and Local Properties of Mixtures: An Expanded Paradigm for the Study of Mixtures

New insights into the molecular mechanism of methanol-induced inactivation ofThermomyces lanuginosuslipase: a molecular dynamics simulation study

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