Protein (19)F NMR in Escherichia coli.

Although overexpression and (15)N enrichment facilitate the observation of resonances from disordered proteins in Escherichia coli, (15)N enrichment alone is insufficient for detecting most globular proteins. Here, we explain this dichotomy and overcome the problem while extending the capability of in-cell NMR by using (19)F-labeled proteins. Resonances from small (approximately 10 kDa) globular proteins containing the amino acid analogue 3-fluoro-tyrosine can be observed in cells, but for larger proteins the (19)F resonances are broadened beyond detection. Incorporating the amino acid analogue trifluoromethyl-L-phenylalanine allows larger proteins (up to 100 kDa) to be observed in cells. We also show that site-specific structural and dynamic information about both globular and disordered proteins can be obtained inside cells by using (19)F NMR.

19F NMR studies of alpha-synuclein conformation and fibrillation.

Fibrils of the intrinsically disordered protein alpha-synuclein are hallmarks of Parkinson's disease. The fluorescent dye thioflavin T is often used to characterize fibrillation, but this assay may not provide quantitative information about structure and mechanism. To gain such information, we incorporated the 19F-labeled amino acid, 3-fluorotyrosine, into recombinant human alpha-synuclein at its endogenous tyrosine residues. Tyrosine 39 is in the positively charged N-terminal region of this 140-residue protein. The other three tyrosines, 125, 133, and 136, are near the C-terminus. 19F nuclear magnetic resonance spectroscopy was used to study several properties of labeled alpha-synuclein, including its conformation, conformational changes induced by urea, spermine, and sodium dodecyl sulfate (SDS), its interaction with SDS micelles, and the kinetics of fibril formation. The results show that the tyrosines are in disordered regions but that there is some structure near position 39 that is disrupted by urea. SDS binding alters the conformation near position 39, but the C-terminal tyrosines are disordered under all conditions. The NMR data also indicate that SDS-micelle-bound alpha-synuclein and the free protein exchange on the 10 ms time scale. Studies of fibrillation show the utility of 19F-labeled NMR. The data indicate that fibrillation is not accompanied by the formation of large quantities of low molecular weight intermediates. Although dye binding and 19F NMR data show that 1 mM SDS and 1 mM spermine accelerate aggregation compared to buffer alone, only the NMR data indicate that the species formed in SDS are smaller than those formed in buffer or buffer plus spermine. We conclude that 19F NMR spectroscopy is useful for obtaining residue-level, quantitative information about the structure, binding, and aggregation of alpha-synuclein.

Alpha-Synuclein conformation affects its tyrosine-dependent oxidative aggregation.

Oxidative stress and aggregation of the protein alpha-synuclein are thought to be key factors in Parkinson's disease. Previous work shows that cytochrome c with H(2)O(2) causes tyrosine-dependent in vitro peroxidative aggregation of proteins, including alpha-synuclein. Here, we examine the role of each of alpha-synuclein's four tyrosine residues and how the protein's conformation affects covalent oxidative aggregation. When alpha-synuclein adopts a collapsed conformation, tyrosine 39 is essential for wild-type-like covalent aggregation. This lone N-terminal tyrosine, however, is not required for wild-type-like covalent aggregation in the presence of a denaturant or when alpha-synuclein is present in noncovalent fibrils. We also show that preformed oxidative aggregates are not incorporated into noncovalent fibrils. These data provide insight into how dityrosine may be formed in Lewy bodies seen in Parkinson's disease.