¹⁷O NMR spectroscopy as a tool to study hydrogen bonding of cholesterol in lipid bilayers

Abstract: Solid state NMR of 17O enriched cholesterol in bilayers reveals the chemical shift depends on extent of hydrogen bonding.

“…In general, the values of jC Q ( 17 O)j found in a-D-glucose are about 8-10 MHz with h Q close to 1. These parameters are similar to those previously reported for protected carbohydrate compounds, 25 D-glucosamine, 26 and several other related functional groups such as hemiacetal/hemiketal, 51,52 gem-diol, 53 hydroxyl, 54 and phenolic groups. [55][56][57] Because the six oxygen-containing functional groups in a-Dglucose are very similar, their 17 O isotropic chemical shis, d iso ( 17 O), are found within a small range of 60 ppm.…”

“…The interplay between the two NMR tensors is responsible for the observed field dependence of the static 17 O NMR spectra. From an analysis of these static powder line shapes, we were able to obtain the principal components of the 17 O CS tensor and their relative orientations with respect to the 17 glucosamine, 26 and several other related functional groups such as hemiacetal/hemiketal, 51,52 gem-diol, 53 hydroxyl, 54 and phenolic groups. [55][56][57] Because the six oxygen-containing functional groups in α-D-glucose are very similar, their 17 O isotropic chemical shifts, δ iso ( 17 O), are found within a small range of 60 ppm.…”

Solid-state ¹⁷O NMR study of α-d-glucose: exploring new frontiers in isotopic labeling, sensitivity enhancement, and NMR crystallography

“…In general, the values of jC Q ( 17 O)j found in a-D-glucose are about 8-10 MHz with h Q close to 1. These parameters are similar to those previously reported for protected carbohydrate compounds, 25 D-glucosamine, 26 and several other related functional groups such as hemiacetal/hemiketal, 51,52 gem-diol, 53 hydroxyl, 54 and phenolic groups. [55][56][57] Because the six oxygen-containing functional groups in a-Dglucose are very similar, their 17 O isotropic chemical shis, d iso ( 17 O), are found within a small range of 60 ppm.…”

“…The interplay between the two NMR tensors is responsible for the observed field dependence of the static 17 O NMR spectra. From an analysis of these static powder line shapes, we were able to obtain the principal components of the 17 O CS tensor and their relative orientations with respect to the 17 glucosamine, 26 and several other related functional groups such as hemiacetal/hemiketal, 51,52 gem-diol, 53 hydroxyl, 54 and phenolic groups. [55][56][57] Because the six oxygen-containing functional groups in α-D-glucose are very similar, their 17 O isotropic chemical shifts, δ iso ( 17 O), are found within a small range of 60 ppm.…”

Solid-state ¹⁷O NMR study of α-d-glucose: exploring new frontiers in isotopic labeling, sensitivity enhancement, and NMR crystallography

“…One key approach for detection of water in biological systems has been the use of 17 O-enriched water in conjunction with magnetic resonance spectroscopy. 16 − 21 Among these methods, electron paramagnetic resonance (EPR) can take advantage of high selectivity, as it detects nuclei only in the ligand sphere ( r ≲ 1.5 nm) 22 of paramagnetic centers.…”

“…Of particular interest is water involvement in electron transfer processes, − its action as a proton wire − or its role in proton-coupled electron transfer (PCET). − The identification of internal water in proteins can be achieved by X-ray diffraction. − However, the crystallization of transient protein complexes is difficult. One key approach for detection of water in biological systems has been the use of 17 O-enriched water in conjunction with magnetic resonance spectroscopy. − Among these methods, electron paramagnetic resonance (EPR) can take advantage of high selectivity, as it detects nuclei only in the ligand sphere ( r ≲ 1.5 nm) of paramagnetic centers.…”

Detection of Water Molecules on the Radical Transfer Pathway of Ribonucleotide Reductase by ¹⁷O Electron–Nuclear Double Resonance Spectroscopy

“…Cholesterol is an unsaturated alcohol belonging to the steroid family of compounds [ 1 , 2 ], whose amphiphilic character, imparted by the hydroxyl group (OH), helps to regulate the membrane fluidity of cells [ 3 , 4 ]. It does so by forming hydrogen bonds with water molecules and other lipid components of the cell membrane [ 5 , 6 ]. In the human body, cholesterol is biosynthesized in the liver and is required for the formation of vitamin D and steroid hormones [ 7 , 8 , 9 ].…”

Presence of Cholesterol in Non-Animal Organisms: Identification and Quantification of Cholesterol in Crude Seed Oil from Perilla frutescens and Dehydrated Pyropia tenera