The major components of neuritic plaques found in Alzheimer disease (AD) are peptides known as amyloid β‐peptides (Aβ), which derive from the proteolitic cleavage of the amyloid precursor proteins. In vitro Aβ may undergo a conformational transition from a soluble form to aggregated, fibrillary β‐sheet structures, which seem to be neurotoxic. Alternatively, it has been suggested that an α‐helical form can be involved in a process of membrane poration, which would then trigger cellular death. Conformational studies on these peptides in aqueous solution are complicated by their tendency to aggregate, and only recently NMR structures of Aβ‐(1–40) and Aβ‐(1–42) have been determined in aqueous trifluoroethanol or in SDS micelles. All these studies hint to the presence of two helical regions, connected through a flexible kink, but it proved difficult to determine the length and position of the helical stretches with accuracy and, most of all, to ascertain whether the kink region has a preferred conformation. In the search for a medium which could allow a more accurate structure determination, we performed an exhaustive solvent scan that showed a high propensity of Aβ‐(1–42) to adopt helical conformations in aqueous solutions of fluorinated alcohols. The 3D NMR structure of Aβ‐(1–42) shows two helical regions encompassing residues 8–25 and 28–38, connected by a regular type I β‐turn. The surprising similarity of this structure, as well as the sequence of the C‐terminal moiety, with those of the fusion domain of influenza hemagglutinin suggests a direct mechanism of neurotoxicity.
Current views of the role of beta-amyloid (Abeta) peptide fibrils range from regarding them as the cause of Alzheimer's pathology to having a protective function. In the last few years, it has also been suggested that soluble oligomers might be the most important toxic species. In all cases, the study of the conformational properties of Abeta peptides in soluble form constitutes a basic approach to the design of molecules with "antiamyloid" activity. We have experimentally investigated the conformational path that can lead the Abeta-(1-42) peptide from the native state, which is represented by an alpha helix embedded in the membrane, to the final state in the amyloid fibrils, which is characterized by beta-sheet structures. The conformational steps were monitored by using CD and NMR spectroscopy in media of varying polarities. This was achieved by changing the composition of water and hexafluoroisopropanol (HFIP). In the presence of HFIP, beta conformations can be observed in solutions that have very high water content (up to 99 % water; v/v). These can be turned back to alpha helices simply by adding the appropriate amount of HFIP. The transition of Abeta-(1-42) from alpha to beta conformations occurs when the amount of water is higher than 80 % (v/v). The NMR structure solved in HFIP/H2O with high water content showed that, on going from very apolar to polar environments, the long N-terminal helix is essentially retained, whereas the shorter C-terminal helix is lost. The complete conformational path was investigated in detail with the aid of molecular-dynamics simulations in explicit solvent, which led to the localization of residues that might seed beta conformations. The structures obtained might help to find regions that are more affected by environmental conditions in vivo. This could in turn aid the design of molecules able to inhibit fibril deposition or revert oligomerization processes.
Double oriented fiber spectra of syndiotactic polypropylene were obtained. It was possible to redetermine with greater accuracy the unit cell constants, which are: a = 14.50, b = 5.60, c = 7.40 A. Space group: C2221. It was proved that the chain has s(2/1)2 symmetry, corresponding to a succession of internal rotation angles A2B2A2B2. The agreement between experimental and calculated intensities on the hkl layers with l = 0, 1, 2, 3 up to the lowest observed Bragg distance (about 2 A.) is good for the packing model proposed. The structural results are briefly discussed.
Protein unfolding can be induced both by heating and by cooling from ambient temperatures. 1 Accurate analysis of heat and cold denaturation processes has the potential to unveil hitherto obscure aspects of protein stability and dynamics. 2 For instance, while heat denaturation is generally highly cooperative, cold denaturation has been suggested to occur in a noncooperative fashion. 3,4 This view has been recently supported by an NMR study of ubiquitin in reverse micelles at very low temperatures, 5 but this is still controversial since Van Horn et al., 6 on the basis of similar NMR data, and Kitahara et al., 7 by an NMR study at 2 kbar, found a simple two-state behavior for the low-temperature unfolding of ubiquitin.To reach a consensus on this debate and other general issues, it is necessary to investigate cold denaturation further. However, since the cold denaturation of most proteins occurs well below the freezing point of water, full access to the cold denatured state is normally limited for the obvious reason that water freezes at 0 °C. The most common approach to circumvent this difficulty has been to try to raise the temperature of cold denaturation using destabilizing agents such as extreme pH values, chemical denaturants, cryosolvents, or very high pressure. 7-10 Alternatively, some laboratories used proteins destabilized by a combination of point mutations and denaturing agents. 9 The main drawback of these approaches is that it is not generally easy to extrapolate results to physiological conditions. On the other hand, there are methods aimed at keeping water in a supercooled condition, but these studies have also invariably used destabilized proteins. 11,12Following a different approach, we looked for a protein whose cold denaturation could be studied without the need for destabilization in a normal buffer at physiological pH within a temperature range accessible to several techniques. Here we describe the cold and heat denaturation of yeast frataxin (Yfh1) measured both by NMR and CD spectroscopies. In a systematic study of the factors that influence the thermal stability of the frataxin fold, we had previously shown that although they share the same fold, three orthologues from E. coli (CyaY), S. cerevisiae (Yfh1) and H. sapiens (hfra), are characterized, under the same conditions, by a remarkable variation of melting temperatures. 13 Yfh1, the one with lowest heat denaturation temperature, seemed a promising candidate for cold denaturation above 0 °C. Yfh1 and 15 Nlabeled Yfh1 were expressed in E. coli as described by He et al. 14 Since variations of ionic NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscript strength lead to significant increases in the melting temperature, we restricted the present investigation to solutions of Yfh1 in salt-free buffers.We recorded 1D and 2D NMR spectra of Yfh1 either in TRIS at pH 7.0 or in HEPES at pH 7.0 in the temperature range −5 to 45 °C. Typically, 0.3-0.5 mM unlabeled or 15 N uniformly labeled protein samples were used. Thanks to t...
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