Solid-state NMR is a powerful tool for quantifying chemical composition and structure in complex assemblies and even whole cells. We employed N{P} REDOR NMR to obtain atomic-level distance propensities in intact 15N-labeled E. coli ribosomes. The experimental REDOR dephasing of shift-resolved lysyl amine nitrogens by phosphorus was comparable to that expected from a calculation of N-P distances involving the lysines included in the crystal structure coordinates. Among the nitrogen contributions to the REDOR spectra, the strongest dephasing emerged from the dipolar couplings to phosphorus involving nitrogen peaks ascribed primarily to rRNA, and the weakest dephasing arose from protein amide nitrogens. This approach is applicable to any macromolecular system and provides quantitative comparisons of distance proximities between shift-resolved nuclei of one type and heteronuclear dephasing spins. Enhanced molecular specificity could be achieved through the use of spectroscopic filters or specific labeling. Furthermore, ribosome 13C and 15N CPMAS spectra were compared with those of whole cells from which the ribosomes were isolated. Whole-cell signatures of ribosomes were identified and should be of value in comparing overall cellular ribosome content in whole-cell samples.
Solid-state class="Chemical">NMR is a powerful tool for quaclass="Chemical">ntifyiclass="Chemical">ng chemical compositioclass="Chemical">n aclass="Chemical">nd structure iclass="Chemical">n complex assemblies aclass="Chemical">nd eveclass="Chemical">n whole cells. We employed class="Chemical">n class="Chemical">N{P} REDOR NMR to obtain atomic-level distance propensities in intact 15N-labeled E. coli ribosomes. The experimental REDOR dephasing of shift-resolved lysyl aminenitrogens by phosphorus was comparable to that expected from a calculation of N-P distances involving the lysines included in the crystal structure coordinates. Among the nitrogen contributions to the REDOR spectra, the strongest dephasing emerged from the dipolar couplings to phosphorus involving nitrogen peaks ascribed primarily to rRNA, and the weakest dephasing arose from protein amidenitrogens. This approach is applicable to any macromolecular system and provides quantitative comparisons of distance proximities between shift-resolved nuclei of one type and heteronuclear dephasing spins. Enhanced molecular specificity could be achieved through the use of spectroscopic filters or specific labeling. Furthermore, ribosome 13C and 15N CPMAS spectra were compared with those of whole cells from which the ribosomes were isolated. Whole-cell signatures of ribosomes were identified and should be of value in comparing overall cellular ribosome content in whole-cell samples.
Authors: B T Wimberly; D E Brodersen; W M Clemons; R J Morgan-Warren; A P Carter; C Vonrhein; T Hartsch; V Ramakrishnan Journal: Nature Date: 2000-09-21 Impact factor: 49.962
Authors: Zheng Liu; Cristina Gutierrez-Vargas; Jia Wei; Robert A Grassucci; Ming Sun; Noel Espina; Susan Madison-Antenucci; Liang Tong; Joachim Frank Journal: Protein Sci Date: 2016-10-26 Impact factor: 6.725
Authors: Andrea Bertarello; Pierrick Berruyer; Markus Artelsmair; Charles S Elmore; Sepideh Heydarkhan-Hagvall; Markus Schade; Elisabetta Chiarparin; Staffan Schantz; Lyndon Emsley Journal: J Am Chem Soc Date: 2022-04-06 Impact factor: 16.383