Find the protein Alpha-synuclein to answer the questions. 1. What are the differ

Question

Find the protein Alpha-synuclein to answer the questions.

1. What are the different types of secondary structures in this protein?

2. Which residues are directly involved in formation of amyloid fibrils?

3. Will this protein bind metal ions? Explain.

4. Notice that 3 residues are potentially phosphorylated in this protein. Will the phosphorylation of amino acids chage the physical properties of the modifired amino acid side-chain?

5. Note the affect of mutation to amino acids 2 and 50. Explain why mutaions of either aspartic acid to alanine or histidine to alalnine, would affect the ability of this protein to bind metal ions?

6. Why would the natural variant at residue 46, result in a protein that will be more likely to bind to negaitively-charged phopholipid liposomes? (liposomes are synthetic lipid membranes used for experimental purpose).

Explanation / Answer

The E46K genetic missense mutation of the wild-type ?-synuclein protein was recently identified in a family of Spanish origin with hereditary Parkinson's disease. Detailed understanding of the structures of the monomeric E46K mutant-type ?-synuclein protein as well as the impact of the E46K missense mutation on the conformations and free energy landscapes of the wild-type ?-synuclein are required for gaining insights into the pathogenic mechanism of Parkinson's disease. In this study, we use extensive parallel tempering molecular dynamics simulations along with thermodynamic calculations to assess the secondary and tertiary structural properties as well as the conformational preferences of the monomeric wild-type and E46K mutant-type ?-synuclein proteins in an aqueous solution environment. We also present the residual secondary structure component conversion stabilities with dynamics using a theoretical strategy, which we most recently developed. To the best of our knowledge, this study presents the first detailed comparison of the structural and thermodynamic properties of the wild-type and E46K mutant-type ?-synuclein proteins in an aqueous solution environment at the atomic level with dynamics. We find that the E46K mutation results not only in local but also in long-range changes in the structural properties of the wild-type ?-synuclein protein. The mutation site shows a significant decrease in helical content as well as a large increase in ?-sheet structure formation upon E46K mutation. In addition, the ?-sheet content of the C-terminal region increases significantly in the E46K mutant-type ?S in comparison to the wild-type ?S. Our theoretical strategy developed to assess the thermodynamic preference of secondary structure transitions indicates that this shift in secondary structure is the result of a decrease in the thermodynamic preference of turn to helix conversions while the coil to ?-sheet preference increases for these residues. Long-range intramolecular protein interactions of the C-terminal with the N-terminal and NAC regions increase upon E46K mutation, resulting in more compact structures for the E46K mutant-type rather than wild-type ?S. However, the E46K mutant-type ?S structures are less stable than the wild-type ?S. Overall, our results show that the E46K mutant-type ?S has a higher propensity to aggregate than the wild-type ?S and that the N-terminal and C-terminal regions are reactive toward fibrillization and aggregation upon E46K mutation and we explain the associated reasons based on the structural properties herein. Small molecules or drugs that can block the specific residues forming abundant ?-sheet structure, which we report here, might help to reduce the reactivity of these intrinsically disordered fibrillogenic proteins toward aggregation and their toxicity.

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