Detailed Biophysical Characterization of the Acid-Induced PrPc to PrPβ Conversion Process

Prions are believed to spontaneously convert from a native, monomeric highly helical form (called PrPc) to a largely β-sheet-rich, multimeric and insoluble aggregate (called PrPsc). Because of its large size and insolubility, biophysical characterization of PrPsc has been difficult, and there are se...

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Veröffentlicht in:	Biochemistry (Easton) 2011-02, Vol.50 (7), p.1162-1173
Hauptverfasser:	Bjorndahl, Trent C, Zhou, Guo-Ping, Liu, Xuehui, Perez-Pineiro, Rolando, Semenchenko, Valentyna, Saleem, Fozia, Acharya, Sandipta, Bujold, Adina, Sobsey, Constance A, Wishart, David S
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creator	Bjorndahl, Trent C Zhou, Guo-Ping Liu, Xuehui Perez-Pineiro, Rolando Semenchenko, Valentyna Saleem, Fozia Acharya, Sandipta Bujold, Adina Sobsey, Constance A Wishart, David S
description	Prions are believed to spontaneously convert from a native, monomeric highly helical form (called PrPc) to a largely β-sheet-rich, multimeric and insoluble aggregate (called PrPsc). Because of its large size and insolubility, biophysical characterization of PrPsc has been difficult, and there are several contradictory or incomplete models of the PrPsc structure. A β-sheet-rich, soluble intermediate, called PrPβ, exhibits many of the same features as PrPsc and can be generated using a combination of low pH and/or mild denaturing conditions. Studies of the PrPc to PrPβ conversion process and of PrPβ folding intermediates may provide insights into the structure of PrPsc. Using a truncated, recombinant version of Syrian hamster PrPβ (shPrP(90−232)), we used NMR spectroscopy, in combination with other biophysical techniques (circular dichroism, dynamic light scattering, electron microscopy, fluorescence spectroscopy, mass spectrometry, and proteinase K digestion), to characterize the pH-driven PrPc to PrPβ conversion process in detail. Our results show that below pH 2.8 the protein oligomerizes and conversion to the β-rich structure is initiated. At pH 1.7 and above, the oligomeric protein can recover its native monomeric state through dialysis to pH 5.2. However, when conversion is completed at pH 1.0, the large oligomer “locks down” irreversibly into a stable, β-rich form. At pH values above 3.0, the protein is amenable to NMR investigation. Chemical shift perturbations, NOE, amide line width, and T 2 measurements implicate the putative “amylome motif” region, “NNQNNF” as the region most involved in the initial helix-to-β conversion phase. We also found that acid-induced PrPβ oligomers could be converted to fibrils without the use of chaotropic denaturants. The latter finding represents one of the first examples wherein physiologically accessible conditions (i.e., only low pH) were used to achieve PrP conversion and fibril formation.
doi_str_mv	10.1021/bi101435c
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Because of its large size and insolubility, biophysical characterization of PrPsc has been difficult, and there are several contradictory or incomplete models of the PrPsc structure. A β-sheet-rich, soluble intermediate, called PrPβ, exhibits many of the same features as PrPsc and can be generated using a combination of low pH and/or mild denaturing conditions. Studies of the PrPc to PrPβ conversion process and of PrPβ folding intermediates may provide insights into the structure of PrPsc. Using a truncated, recombinant version of Syrian hamster PrPβ (shPrP(90−232)), we used NMR spectroscopy, in combination with other biophysical techniques (circular dichroism, dynamic light scattering, electron microscopy, fluorescence spectroscopy, mass spectrometry, and proteinase K digestion), to characterize the pH-driven PrPc to PrPβ conversion process in detail. Our results show that below pH 2.8 the protein oligomerizes and conversion to the β-rich structure is initiated. At pH 1.7 and above, the oligomeric protein can recover its native monomeric state through dialysis to pH 5.2. However, when conversion is completed at pH 1.0, the large oligomer “locks down” irreversibly into a stable, β-rich form. At pH values above 3.0, the protein is amenable to NMR investigation. Chemical shift perturbations, NOE, amide line width, and T 2 measurements implicate the putative “amylome motif” region, “NNQNNF” as the region most involved in the initial helix-to-β conversion phase. We also found that acid-induced PrPβ oligomers could be converted to fibrils without the use of chaotropic denaturants. 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Because of its large size and insolubility, biophysical characterization of PrPsc has been difficult, and there are several contradictory or incomplete models of the PrPsc structure. A β-sheet-rich, soluble intermediate, called PrPβ, exhibits many of the same features as PrPsc and can be generated using a combination of low pH and/or mild denaturing conditions. Studies of the PrPc to PrPβ conversion process and of PrPβ folding intermediates may provide insights into the structure of PrPsc. Using a truncated, recombinant version of Syrian hamster PrPβ (shPrP(90−232)), we used NMR spectroscopy, in combination with other biophysical techniques (circular dichroism, dynamic light scattering, electron microscopy, fluorescence spectroscopy, mass spectrometry, and proteinase K digestion), to characterize the pH-driven PrPc to PrPβ conversion process in detail. Our results show that below pH 2.8 the protein oligomerizes and conversion to the β-rich structure is initiated. At pH 1.7 and above, the oligomeric protein can recover its native monomeric state through dialysis to pH 5.2. However, when conversion is completed at pH 1.0, the large oligomer “locks down” irreversibly into a stable, β-rich form. At pH values above 3.0, the protein is amenable to NMR investigation. Chemical shift perturbations, NOE, amide line width, and T 2 measurements implicate the putative “amylome motif” region, “NNQNNF” as the region most involved in the initial helix-to-β conversion phase. We also found that acid-induced PrPβ oligomers could be converted to fibrils without the use of chaotropic denaturants. 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Because of its large size and insolubility, biophysical characterization of PrPsc has been difficult, and there are several contradictory or incomplete models of the PrPsc structure. A β-sheet-rich, soluble intermediate, called PrPβ, exhibits many of the same features as PrPsc and can be generated using a combination of low pH and/or mild denaturing conditions. Studies of the PrPc to PrPβ conversion process and of PrPβ folding intermediates may provide insights into the structure of PrPsc. Using a truncated, recombinant version of Syrian hamster PrPβ (shPrP(90−232)), we used NMR spectroscopy, in combination with other biophysical techniques (circular dichroism, dynamic light scattering, electron microscopy, fluorescence spectroscopy, mass spectrometry, and proteinase K digestion), to characterize the pH-driven PrPc to PrPβ conversion process in detail. Our results show that below pH 2.8 the protein oligomerizes and conversion to the β-rich structure is initiated. At pH 1.7 and above, the oligomeric protein can recover its native monomeric state through dialysis to pH 5.2. However, when conversion is completed at pH 1.0, the large oligomer “locks down” irreversibly into a stable, β-rich form. At pH values above 3.0, the protein is amenable to NMR investigation. Chemical shift perturbations, NOE, amide line width, and T 2 measurements implicate the putative “amylome motif” region, “NNQNNF” as the region most involved in the initial helix-to-β conversion phase. We also found that acid-induced PrPβ oligomers could be converted to fibrils without the use of chaotropic denaturants. The latter finding represents one of the first examples wherein physiologically accessible conditions (i.e., only low pH) were used to achieve PrP conversion and fibril formation.</abstract><pub>American Chemical Society</pub><doi>10.1021/bi101435c</doi><tpages>12</tpages></addata></record>
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title	Detailed Biophysical Characterization of the Acid-Induced PrPc to PrPβ Conversion Process
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