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The Role of Trehalose for the Stabilization of Proteins

Christoffer Olsson (Institutionen för fysik, Kondenserade materiens fysik (Chalmers)) ; Helén Jansson (Institutionen för bygg- och miljöteknik, Byggnadsteknologi) ; Jan Swenson (Institutionen för fysik, Kondenserade materiens fysik (Chalmers))
Journal of Physical Chemistry B (1520-6106). Vol. 120 (2016), 20, p. 4723-4731.
[Artikel, refereegranskad vetenskaplig]

Understanding of how the stabilization mechanism of trehalose operates on biological molecules against different types of environmental stress could prove to gain great advancements in many different types of conservation techniques, such as cryopreservation or freeze-drying. Many theories exist that aim to explain why trehalose possesses an extraordinary ability to stabilize biomolecules. However, all of them just explain parts of its mechanism and a comprehensive picture is still lacking. In this study, we have used differential scanning calorimetry (DSC) and viscometry measurements to determine how the glass transition temperature T-g, the protein denaturation temperature T-den, and the dynamic viscosity depend on both the trehalose and the protein concentration in myoglobin-trehalose-water systems. The aim has been to determine whether these physical properties are related and to gain indirect structural insights from the limits of water crystallization at different concentration ratios. The results show that for systems without partial crystallization of water the addition of protein increases T-g, most likely due to the fact that the protein adsorbs water and thereby reduces. the water content in the trehalose-water matrix. Furthermore, these systems are generally decreasing in T-den, with an increasing protein concentration, and thereby also an increasing viscosity, showing that the dynamics of the trehalose-water matrix and the stability of the native structure of the protein are not necessarily coupled. We also infer, by analyzing the maximum amount of water for which ice formation is avoided, that the preferential hydration model is consistent with our experimental data.

Denna post skapades 2016-07-06. Senast ändrad 2017-10-03.
CPL Pubid: 239050


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Institutioner (Chalmers)

Institutionen för fysik, Kondenserade materiens fysik (Chalmers)
Institutionen för bygg- och miljöteknik, Byggnadsteknologi (2005-2017)


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Chalmers infrastruktur