TY - JOUR A1 - Fabian, H. A1 - Gast, Klaus A1 - Filimonov, Vladimir V. A1 - Zamyatkin, D. F. A1 - Rogov, V. V. T1 - Thermal unfolding of two designed monomeric lambda Cro repressor variants N2 - The thermal unfolding of the wild-type lambda Cro repressor and of two designed variants, Cro K56-[DGEVK] and Cro K56-[DGEVK] Q16L, was studied by Fourier transform infrared spectroscopy and dynamic light scattering. The engineered Cro K56-[DGEVK] monomer has five additional amino acids inserted after position 56 of the wild-type sequence, while the K56-[DGEVK] Q16L variant differs only in one position (Gln-16 to Leu substitution) from the Cro K56-[DGEVK] sequence. The temperature dependence of selected protein backbone infrared `marker' bands revealed that Cro K56- [DGEVK] is slightly more stable than the wild-type protein, while the replacement of Gln-16 by Leu increases the thermal transition temperature by similar to 20 degrees C. Moreover, thermal unfolding of the two Cro variants was found to proceed through equilibrium unfolding intermediates and to involve the formation of oligomers. The first thermal transition of Cro K56-[DGEVK] involves the melting of major parts of its native secondary structure and is accompanied by the formation of dinners and non-native beta-sheet structures. These structures unfold during a second transition at higher temperatures, accompanied by the dissociation of the dimers. In contrast to the Cro K56-[DGEVK] protein, the intermediate state of the Cro K56-[DGEVK] Q16L variant is less well defined, and involves the formation of oligomers of different size. (c) 2005 Elsevier B.V. All rights reserved Y1 - 2005 SN - 0924-2031 ER - TY - JOUR A1 - Modler, Andreas Johannes A1 - Fabian, H. A1 - Sokolowski, F. A1 - Lutsch, G. A1 - Gast, Klaus A1 - Damaschun, Gregor T1 - Polymerization of proteins into amyloid protofibrils shares common critical oligomeric states but differs in the mechanisms of their formation N2 - Amyloid protofibril formation of phosphoglycerate kinase (PGK) and Syrian hamster prion protein (SHaPrP(90- 232)) were investigated by static and dynamic light scattering, size exclusion chromatography and electron microscopy. Changes in secondary structure were monitored by Fourier transform infrared spectroscopy and by circular dichroism. Protofibril formation of the two proteins is found to be a two-stage process. At the beginning, an ensemble of critical oligomers is built lip. These critical oligomeric states possess a predominant beta-sheet structure and do not interact considerably with monomers. Initial oligomerization and transition to beta-sheet structure are coupled events differing in their details for both proteins. Intermediate oligomeric states (dimers, trimers, etc.) are populated in case of PGK, whereas SHaPrP(90-232) behaves according to oil apparent two-state reaction between monomers and octamers rich in beta- structure with a reaction order varying between 2 and 4. All oligomers coalesce to PGK protofibrils in the second stage, while SHaPrP(90-232) protofibrils are only formed by a subpopulation. The rates of both growth stages can be tuned in case of PGK by different salts preserving the underlying generalized diffusion-collision mechanism. The different kinetics of the early misfolding and oligomerization events of the two proteins argue against a common mechanism of protofibril formation. A classification scheme for misassembly, mechanisms of proteins based on energy landscapes is presented. It includes scenarios of downhill polymerization to which protofibril formation of PGK and SHaPrP(90-232) belong Y1 - 2004 ER -