The cellular environment determines the structure and function of proteins. Marginal changes of the environment can severely affect the energy landscape of protein folding. However, despite the important role of chaperones on protein folding, less is known about chaperonal modulation of protein aggregation and fibrillation considering different classes of chaperones. We find that the pharmacological chaperone O4, the chemical chaperone proline as well as the protein chaperone serum amyloid P component (SAP) are inhibitors of the type 2 diabetes mellitus-related aggregation process of islet amyloid polypeptide (IAPP). By applying biophysical methods such as thioflavin T fluorescence spectroscopy, fluorescence anisotropy, total reflection Fourier-transform infrared spectroscopy, circular dichroism spectroscopy and atomic force microscopy we analyse and compare their inhibition mechanism. We demonstrate that the fibrillation reaction of human IAPP is strongly inhibited by formation of globular, amorphous assemblies by both, the pharmacological and the protein chaperones. We studied the inhibition mechanism under cell-like conditions by using the artificial crowding agents Ficoll 70 and sucrose. Under such conditions the suppressive effect of proline was decreased, whereas the pharmacological chaperone remains active.
In vivo studies have shown that the cytoskeleton of cells is very sensitive to changes in temperature and pressure. In particular, actin filaments get depolymerized when pressure is increased up to several hundred bars, conditions that are easily encountered in the deep sea. We quantitatively evaluate the effects of temperature, pressure, and osmolytes on the kinetics of the polymerization reaction of actin by high-pressure stopped-flow experiments in combination with fluorescence detection and an integrative stochastic simulation of the polymerization process. We show that the compatible osmolyte trimethylamine-N-oxide is not only able to compensate for the strongly retarding effect of chaotropic agents, such as urea, on actin polymerization, it is also able to largely offset the deteriorating effect of pressure on actin polymerization, thereby allowing biological cells to better cope with extreme environmental conditions.
Owing to the presence of various types of osmolytes in the cellular environment, this study focuses on the impact of stabilizing (TMAO and betaine) as well as destabilizing (urea) cosolvents on the aggregation and fibrillation reaction of the highly amyloidogenic islet amyloid polypeptide (IAPP). IAPP is associated with type-2 diabetes mellitus and is responsible for the disease accompanying β-cell membrane permeabilization and final β-cell loss. To reveal the impact of the cosolvents on the aggregation kinetics, conformational and morphological changes upon IAPP fibrillation, Thioflavin T fluorescence spectroscopy, atomic force microscopy and attenuated total reflection Fourier-transform infrared spectroscopy were applied. For TMAO, and less pronounced for betaine, a decrease of the growth rate of fibrils is observed, whereas the lag phase remains essentially unchanged, indicating the ability of the compatible solutes to stabilize large oligomeric and protofibrillar structures and therefore hamper fibril elongation. Conversely, urea displays concentration-dependent prolongation of the lag phase, indicating stabilization of IAPP in its unfolded monomeric state, hence leading to retardation of IAPP nuclei formation. Mixtures of urea with TMAO, and to a lesser extent with betaine, exhibit a counteractive effect. TMAO is able to fully compensate the prolonged lag phase induced by urea. This strongly matches the findings of a counteraction of TMAO and urea in protein folding and unfolding experiments. The data also reveal that the influence of these cosolvents is only on the aggregation kinetics without markedly changing the final IAPP fibrillar morphology, i.e., the solution structure and cosolvent composition essentially affect the kinetics of the fibrillation process only.
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