One of the most intriguing disease-related mutations in human prion protein (PrP) is the Tyr to Stop codon substitution at position 145. This mutation results in a Gerstmann-Straussler-Scheinkerlike disease with extensive PrP amyloid deposits in the brain. Here, we provide evidence for a spontaneous conversion of the recombinant polypeptide corresponding to the Y145Stop variant (huPrP23-144) from a monomeric unordered state to a fibrillar form. This conversion is characterized by a protein concentration-dependent lag phase and has characteristics of a nucleation-dependent polymerization. Atomic force microscopy shows that huPrP23-144 fibrils are characterized by an apparent periodicity along the long axis, with an average period of 20 nm. Fourier-transform infrared spectra indicate that the conversion is associated with formation of -sheet structure. However, the infrared bands for huPrP23-144 are quite different from those for a synthetic peptide PrP106 -126, suggesting conformational non-equivalence of -structures in the disease-associated Y145Stop variant and a frequently used short model peptide. To identify the region that is critical for the self-seeded assembly of huPrP23-144 amyloid, experiments were performed by using the recombinant polypeptides corresponding to prion protein fragments 23-114, 23-124, 23-134, 23-137, 23-139, and 23-141. Importantly, none of the fragments ending before residue 139 showed a propensity for conformational conversion to amyloid fibrils, indicating that residues within the 138 -141 region are essential for this conversion.
It is believed that the critical step in the pathogenesis of transmissible spongiform encephalopathies is a transition of prion protein (PrP) from an alpha-helical conformation, PrP(C), to a beta-sheet-rich form, PrP(Sc). Native prion protein contains a single disulfide bond linking Cys residues at positions 179 and 214. To elucidate the role of this bridge in the stability and folding of the protein, we studied the reduced form of the recombinant human PrP as well as the variant of PrP in which cysteines were replaced with alanine residues. At neutral pH, the reduced prion protein and the Cys-free mutant were insoluble and formed amorphous aggregates. However, the proteins could be refolded in a monomeric form under the conditions of mildly acidic pH. Spectroscopic experiments indicate that the monomeric Cys-free and reduced PrP have molten globule-like properties, i.e. they are characterized by compromised tertiary interactions, an increased exposure of hydrophobic surfaces, lack of cooperative unfolding transition in urea, and partial loss of native (alpha-helical) secondary structure. In the presence of sodium chloride, these partially unfolded proteins undergo a transition to a beta-sheet-rich structure. However, this transition is invariably associated with protein oligomerization. The present data argue against the notion that reduced prion protein can exist in a stable monomeric form that is rich in beta-sheet structure.
Methylmalonyl-CoA mutase is an adenosylcobalamindependent enzyme that catalyzes the 1,2 rearrangement of methylmalonyl-CoA to succinyl-CoA. This reaction results in the interchange of a carbonyl-CoA group and a hydrogen atom on vicinal carbons. The crystal structure of the enzyme reveals the presence of an aromatic cluster of residues in the active site that includes His-244, Tyr-243, and Tyr-89 in the large subunit. Of these, His-244 is within hydrogen bonding distance to the carbonyl oxygen of the carbonyl-CoA moiety of the substrate. The location of these aromatic residues suggests a possible role for them in catalysis either in radical stabilization and/or by direct participation in one or more steps in the reaction. The mechanism by which the initially formed substrate radical isomerizes to the product radical during the rearrangement of methylmalonyl-CoA to succinyl-CoA is unknown. Ab initio molecular orbital theory calculations predict that partial proton transfer can contribute significantly to the lowering of the barrier for the rearrangement reaction. In this study, we report the kinetic characterization of the H244G mutant, which results in an acute sensitivity of the enzyme to oxygen, indicating the important role of this residue in radical stabilization. Mutation of His-244 leads to an ϳ300-fold lowering in the catalytic efficiency of the enzyme and loss of one of the two titratable pK a values that govern the activity of the wild type enzyme. These data suggest that protonation of His-244 increases the reaction rate in wild type enzyme and provides experimental support for ab initio molecular orbital theory calculations that predict rate enhancement of the rearrangement reaction by the interaction of the migrating group with a general acid. However, the magnitude of the rate enhancement is significantly lower than that predicted by the theoretical studies.
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