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Substantial Progress on Structural Biology Study for Rabbit Prion Protein
Update time: 2010-08-17
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Order parameters S2 for (A) RaPrPC-(121-228) and (B) the S173N variant. (Image by SIMM )
Research group lead by Prof. Hai Dong Lin from SIMM recently detected the backbone dynamics of structured C-terminal domains-(121-228) of the recombinant protein RaPrPC-(91-228) and its S173N variant by determined the solution structures. The result was published in J. Biol. Chem. On July 16, 2010.

Rabbits are one of the few mammalian species that appear to be resistant to transmissible spongiform encephalopathies (TSEs) due to the structural characteristics of the rabbit prion protein (RaPrPC) itself. In contrast to many other mammalian PrPCs, loop 165-172 that connects β-sheet-2 and α-helix-2 is well-defined in RaPrPC. For the first time, order parameters S2 are obtained for residues in this loop region, indicating that loop 165-172 of RaPrPC is highly ordered. Compared with the wild-type RaPrPC, less hydrogen bonds form in the S173N variant. The NMR dynamics analysis reveals a distinct increase in the structural flexibility of loop 165-172 and helix-3 after the S173N substitution, implying that the S173N substitution disturbs the long-range interaction of loop 165-172 with helix-3, which further leads to a marked decrease in the global conformational stability. Significantly, RaPrPC possesses a unique charge distribution, carrying a continuous area of positive charges on the surface, which is distinguished from other PrPCs. The S173N substitution causes visible changes of the charge distribution around the recognition sites for the hypothetical protein X. Our results suggest that the ordered loop 165-172 and its interaction with helix-3, together with the unique distribution of surface electrostatic potential, significantly contribute to the unique biological functions and biochemical characteristics of RaPrPC.

 
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