Solvent exposure of Tyr10 as a probe of structural differences between monomeric and aggregated forms of the amyloid-ß peptide.

Aggregation of amyloid-ß (Aß) peptides is a characteristic pathological feature of Alzheimer's disease. We have exploited the relationship between solvent exposure and intrinsic fluorescence of a single tyrosine residue, Tyr10, in the Aß sequence to probe structural features of the monomeric, oligomeric and fibrillar forms of the 42-residue Aß1-42. By monitoring the quenching of Tyr10 fluorescence upon addition of water-soluble acrylamide, we show that in Aß1-42 oligomers this residue is solvent-exposed to a similar extent to that found in the unfolded monomer. By contrast, Tyr10 is significantly shielded from acrylamide quenching in Aß1-42 fibrils, consistent with its proximity to the fibrillar cross-ß core. Furthermore, circular dichroism measurements reveal that Aß1-42 oligomers have a considerably lower ß-sheet content than the Aß1-42 fibrils, indicative of a less ordered molecular arrangement in the former. Taken together these findings suggest significant differences in the structural assembly of oligomers and fibrils that are consistent with differences in their biological effects.

Fluorescence spectroscopy of soluble E. coli SPase I Δ2-75 reveals conformational changes in response to ligand binding.

The bacterial Sec pathway is responsible for the translocation of secretory preproteins. During the later stages of transport, the membrane-embedded signal peptidase I (SPase I) cleaves the signal peptide from a preprotein. We used tryptophan fluorescence spectroscopy of a soluble, catalytically active E. coli SPase I Δ2-75 enzyme to study its dynamic conformational changes while in solution and when interacting with lipids and signal peptides. We generated four single Trp SPase I Δ2-75 mutants, W261, W284, W300, and W310. Based on fluorescence quenching experiments, W300 and W310 were found to be more solvent accessible than W261 and W284 in the absence of ligands. W300 and W310 inserted into lipids, consistent with their location at the enzyme's proposed membrane-interface region, while the solvent accessibilities of W261, W284, and W300 were modified in the presence of signal peptide, suggesting propagation of structural changes beyond the active site in response to peptide binding. The signal peptide binding affinity for the enzyme was measured via FRET experiments and the Kd determined to be 4.4 µM. The location of the peptide with respect to the enzyme was also established; this positioning is crucial for the peptide to gain access to the enzyme active site as it emerges from the translocon into the membrane bilayer. These studies reveal enzymatic structural changes required for preprotein proteolysis as it interacts with its two key partners, the signal peptide and membrane phospholipids.

Spectroscopic Studies of Asparaginyl-tRNA Synthetase from Entamoeba histolytica.

BACKGROUND: Aminoacyl-tRNA synthetases play an important role in catalyzing the first step in protein synthesis by attaching the appropriate amino acid to its cognate tRNA which then transported to the growing polypeptide chain. Asparaginyl-tRNA Synthetase (AsnRS) from Brugia malayi, Leishmania major, Thermus thermophilus, Trypanosoma brucei have been shown to play an important role in survival and pathogenesis. Entamoeba histolytica (Ehis) is an anaerobic eukaryotic pathogen that infects the large intestines of humans. It is a major cause of dysentery and has the potential to cause life-threatening abscesses in the liver and other organs making it the second leading cause of parasitic death after malaria. Ehis-AsnRS has not been studied in detail, except the crystal structure determined at 3 Å resolution showing that it is primarily α-helical and dimeric. It is a homodimer, with each 52 kDa monomer consisting of 451 amino acids. It has a relatively short N-terminal as compared to its human and yeast counterparts. OBJECTIVE: Our study focusses to understand certain structural characteristics of Ehis-AsnRS using biophysical tools to decipher the thermodynamics of unfolding and its binding properties. METHODS: Ehis-AsnRS was cloned and expressed in E. coli BL21DE3 cells. Protein purification was performed using Ni-NTA affinity chromatography, following which the protein was used for biophysical studies. Various techniques such as steady-state fluorescence, quenching, circular dichroism, differential scanning fluorimetry, isothermal calorimetry and fluorescence lifetime studies were employed for the conformational characterization of Ehis-AsnRS. Protein concentration for far-UV and near-UV circular dichroism experiments was 8 µM and 20 µM respectively, while 4 µM protein was used for the rest of the experiments. RESULTS: The present study revealed that Ehis-AsnRS undergoes unfolding when subjected to increasing concentration of GdnHCl and the process is reversible. With increasing temperature, it retains its structural compactness up to 45ºC before it unfolds. Steady-state fluorescence, circular dichroism and hydrophobic dye binding experiments cumulatively suggest that Ehis-AsnRS undergoes a two-state transition during unfolding. Shifting of the transition mid-point with increasing protein concentration further illustrate that dissociation and unfolding processes are coupled indicating the absence of any detectable folded monomer. CONCLUSION: This article indicates that GdnHCl induced denaturation of Ehis-AsnRS is a two - state process and does not involve any intermediate; unfolding occurs directly from native dimer to unfolded monomer. The solvent exposure of the tryptophan residues is biphasic, indicating selective quenching. Ehis-AsnRS also exhibits a structural as well as functional stability over a wide range of pH.