Engineering metal ion coordination to regulate amyloid fibril assembly and toxicity
Protein and peptide assembly into amyloid has been implicated in functions that range from beneficial epigenetic controls to pathological etiologies. However, the exact structures of the assemblies that regulate biological activity remain poorly defined. We have previously used Zn 2؉ to modulate the assembly kinetics and morphology of congeners of the amyloid  peptide (A) associated with Alzheimer's disease. We now reveal a correlation among A-Cu 2؉ coordination, peptide self-assembly, and neuronal viability. By using the central segment of A, HHQKLVFFA or A(13-21), which contains residues H13 and H14 implicated in A-metal ion binding, we show that Cu 2؉ forms complexes with A(13-21) and its K16A mutant and that the complexes, which do not selfassemble into fibrils, have structures similar to those found for the human prion protein, PrP. N-terminal acetylation and H14A substitution, Ac-A(13-21)H14A, alters metal coordination, allowing Cu 2؉ to accelerate assembly into neurotoxic fibrils. These results establish that the N-terminal region of A can access different metal-ion-coordination environments and that different complexes can lead to profound changes in A self-assembly kinetics, morphology, and toxicity. Related metal-ion coordination may be critical to the etiology of other neurodegenerative diseases.copper-binding ͉ neurotoxicity ͉ self-assembly P rotein intermolecular assembly, especially formation of amyloid fibrillar structures, is correlated with a variety of human neurodegenerative diseases, including Alzheimer's, Parkinson's, Huntington's, and Creutzfeldt-Jakob diseases (1). More recently, amyloid has been tied to many nonpathological functional roles. For example, formation and self-perpetuation of amyloids in Saccharomyces cerevisiae regulate diverse yeast phenotypic expression as a positive response to environmental fluctuations (2), and amyloid may be involved in long-term memory and synapse maintenance in the marine snail, Aplysia (3, 4). Many proteins, including archetypical globular proteins such as myoglobin, can also form amyloid fibrils, suggesting that amyloidogenesis may be an intrinsic property of any ␣-amino acid polymer (5). Accordingly, these highly ordered paracrystalline protein self-assemblies have now been recognized as useful for nanostructure fabrication and biotechnology (6-8). Fully capturing these technological opportunities and understanding the biological roles of amyloid will depend on further definition of the organized structure and assembly pathway.Increasing evidence now implicates transition metal ions, including Zn 2ϩ , Cu 2ϩ , and Fe 3ϩ , as contributors both to amyloid  (A) assembly in vitro and to the neuropathology of Alzheimer's disease, AD (9). The obligatory region of metal ion (Zn 2ϩ /Cu 2ϩ ) binding of A has been mapped to the N terminus, amino acids 1-28 (10-16). In its soluble nonamyloid conformation, the peptide contains multiple intramolecular binding sites for Zn 2ϩ and Cu 2ϩ (9, 17), and intermolecular Zn 2ϩ binding can promote A aggrega...
A carbinolamine (1-aminoethan-1-ol-2-yl) structure for the product radical in the CoII product radical pair catalytic intermediate state in coenzyme B12 (adenosylcobalamin)-dependent ethanolamine deaminase from Salmonella typhimurium has been determined by using isotope labeling and techniques of electron paramagnetic resonance (EPR) spectroscopy. The presence of nitrogen is detected from the difference in the EPR line shapes of the product radicals that are cryotrapped during steady-state turnover on either 14N- or 15N-labeled aminoethanol substrate. Three-pulse electron spin-echo envelope modulation (ESEEM) spectroscopy of the product radical labeled with 2H reveals two types of beta-2H hyperfine couplings. A structural model is proposed in which the two beta-2H couplings arise from two C1-C2 product radical rotamer states. The sum of the dihedral angles between the C2 p-orbital axis and C1-Hbeta bonds is 120 degrees , which indicates sp3-hybridization at C1. This confirms the C1 carbinolamine structure. The identification of the carbinolamine product radical indicates that the radical rearrangement in ethanolamine deaminase deviates from the solution elimination reaction pathway and proceeds by migration of the amine from C2 of the substrate radical to C1 of the product radical.
Prolactin, a lactogenic hormone, binds to two prolactin receptors sequentially, the first receptor binding at site 1 of the hormone followed by the second receptor binding at site 2. We have investigated the mechanism by which human prolactin (hPRL) binds the extracellular domain of the human prolactin receptor (hPRLbp) using surface plasmon resonance (SPR) technology. We have covalently coupled hPRL to the SPR chip surface via coupling chemistries that reside in and block either site 1 or site 2. Equilibrium binding experiments using saturating hPRLbp concentrations show that site 2 receptor binding is dependent on site 1 receptor occupancy. In contrast, site 1 binding is independent of site 2 occupancy. Thus, sites 1 and 2 are functionally coupled, site 1 binding inducing the functional organization of site 2. Site 2 of hPRL does not have a measurable binding affinity prior to hPRLbp binding at site 1. After site 1 receptor binding, site 2 affinity is increased to values approaching that of site 1. Corruption of either site 1 or site 2 by mutagenesis is consistent with a functional coupling of sites 1 and 2. Fluorescence resonance energy transfer (FRET) experiments indicate that receptor binding at site 1 induces a conformation change in the hormone. These data support an "induced-fit" model for prolactin receptor binding where binding of the first receptor to hPRL induces a conformation change in the hormone creating the second receptor-binding site.
The protein chemical, kinetic, and electron paramagnetic resonance (EPR) and electron spin-echo envelope modulation (ESEEM) spectroscopic properties of ethanolamine ammonia-lyase (EAL) from Salmonella typhimurium with site-directed mutations in a conserved arginine residue (R160) of the active site containing EutB protein subunit have been characterized. R160 was predicted by a comparative model of EutB to play a critical role in protein structure and catalysis [Sun, L., and Warncke, K. (2006) Proteins: Struct., Funct., Bioinf. 64, 308-319]. R160I and R160E mutants fail to assemble into an EAL oligomer that can be isolated by the standard enzyme purification procedure. The R160K and R160A mutants assemble, but R160A EAL is catalytically inactive and reacts with substrates to form magnetically isolated Co(II) and unidentified radical species. R160A EAL activity is resurrected by externally added guanidinium to 2.3% of wild-type EAL. R160K EAL displays catalytic turnover of aminoethanol, with a 180-fold lower value of k(cat)/ K(M) relative to wild-type enzyme. R160K EAL also forms Co(II)-substrate radical pair intermediate states during turnover on aminoethanol and (S)-2-aminopropanol substrates. Simulations of the X-band EPR spectra show that the Co(II)-substrate radical pair separation distances are increased by 2.1 +/- 1.0 A in R160K EAL relative to wild-type EAL, which corresponds to the predicted 1.6 A change in arginine versus lysine side chain length. 14N ESEEM from a hyperfine-coupled protein nitrogen in wild type is absent in R160K EAL, which indicates that a guanidinium 14N of R160 interacts directly with the substrate radical through a hydrogen bond. ESEEM of the 2H-labeled substrate radical states in wild-type and R160K EAL shows that the native separation distances among the substrate C1 and C2, and coenzyme C5' reactant centers, are conserved in the mutant protein. The EPR and ESEEM measurements evince a protein-mediated force on the C5'-methyl center that is directed toward the reacting substrate species during the hydrogen atom transfer and radical rearrangement reactions. The results indicate that the positive charge at the residue 160 side chain terminus is required for proper folding of EutB, assembly of a stable EAL oligomer, and catalysis in the assembled oligomer.
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