<p>The R3H domain of the human protein Sµbp-2 was produced with 5-fluoro-L-isoleucine (FIle) and 5,5-difluoro-L-isoleucine (diFIle) as probes for detection by <sup>19</sup>F-NMR spectroscopy. The fluorinated protein, produced by cell-free protein synthesis, was obtained more easily with diFIle than FIle as FIle readily hydrolysed at pH 7.5 with the release of fluoride. The <sup>19</sup>F-NMR spectra showed large chemical shift ranges but were heterogeneous. The heterogeneities arose from difficulties to fully exclude canonical isoleucine, the presence of multiple conformations and limited stability of the proteins, with the sample made with diFIle being particularly prone to precipitation. <sup>19</sup>F resonance assignments were obtained by comparison of the chemical shifts of γ<sub>1</sub>-protons with those observed in the wild-type protein. Non-uniform cross-peak intensities observed in short-delay <sup>1</sup>H,<sup>19</sup>F correlation experiments suggest incomplete averaging of <sup>3</sup><i>J</i><sub>HF</sub> couplings and therefore preferential rotamer populations of the CH<sub>2</sub>F and CHF<sub>2</sub> groups.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

19F-NMR spectroscopy of fluorinated isoleucine analogues in a protein

  • Adarshi P. Welegedara,
  • Yi Jiun Tan,
  • Matteo Borgini,
  • Peter Wipf,
  • Gottfried Otting

摘要

The R3H domain of the human protein Sµbp-2 was produced with 5-fluoro-L-isoleucine (FIle) and 5,5-difluoro-L-isoleucine (diFIle) as probes for detection by 19F-NMR spectroscopy. The fluorinated protein, produced by cell-free protein synthesis, was obtained more easily with diFIle than FIle as FIle readily hydrolysed at pH 7.5 with the release of fluoride. The 19F-NMR spectra showed large chemical shift ranges but were heterogeneous. The heterogeneities arose from difficulties to fully exclude canonical isoleucine, the presence of multiple conformations and limited stability of the proteins, with the sample made with diFIle being particularly prone to precipitation. 19F resonance assignments were obtained by comparison of the chemical shifts of γ1-protons with those observed in the wild-type protein. Non-uniform cross-peak intensities observed in short-delay 1H,19F correlation experiments suggest incomplete averaging of 3JHF couplings and therefore preferential rotamer populations of the CH2F and CHF2 groups.