Cross relaxation at the lysozyme–water interface: an NMR line-shape-relaxation correlation study

Peemoeller, H.; Kydon, D. W.; Sharp, A. R.; Schreiner, L J

doi:10.1139/p84-136

Cited by 16 publications

(15 citation statements)

References 1 publication

Supporting

Mentioning

Contrasting

Order By: Relevance

“…4). The observation of such a negative reconstructed FID, with associated T 1 shorter than the minimum T 1 found in the T 1 HH results (Table 2), provided strong evidence for magnetization exchange between a solid‐like and a liquid‐like spin reservoir (16, 25). In our cartilage samples exchange was detected between the S and L2 spin reservoirs which proceeded at a relativity high rate.…”

Section: Resultssupporting

confidence: 91%

Macromolecule and water magnetization exchange modeling in articular cartilage

et al. 2000

View full text Add to dashboard Cite

Section: Resultssupporting

confidence: 91%

Macromolecule and water magnetization exchange modeling in articular cartilage

et al. 2000

View full text Add to dashboard Cite

“…8 for k with the parameters found for the anisotropic motion model (legend to Fig. 2) and the above 01 and r, we calculate k = 44 s-' at 40 MHz and 293 K. In a two-dimensional NMR time evolution study of proton magnetization in wet HEWL at the same frequency and temperature, a value for k = (98 ± 16) s-1 was deduced (22). Although the two values of k differ by a factor of -2, the results are nevertheless encouraging.…”

Section: Resultsmentioning

confidence: 91%

“…However, it must be kept in mind that such predicted rates are to be compared with the intrinsic water proton rates Rlwi and R2wi rather than the observed relaxation rates. In a recent study of cross-relaxation effects in wet HEWL at 40 MHz (22), it was shown that at room temperature the water-HEWL cross-relaxation rate had a value of -100 s'-i. This is approximately one-sixth of the observed proton rate R2W but >10 times as large as the observed rate R,W (8).…”

Section: Resultsmentioning

confidence: 99%

Water molecule dynamics in hydrated lysozyme. A deuteron magnetic resonance study

Peemoeller¹,

Yeomans²,

Kydon³

et al. 1986

Biophysical Journal

Self Cite

View full text Add to dashboard Cite

Proton nuclear magnetic resonance relaxation investigations of water dynamics in hydrated protein powders have the serious drawback that protein-water intermolecular dipolar interactions make the unambiguous interpretation of the results difficult. To circumvent this difficulty, deuteron spin-lattice and spin-spin relaxation times in lysozyme powder hydrated with deuterium oxide were measured as a function of temperature and at two frequencies. Although the deuteron relaxation results are compatible with a water molecule dynamics model based on either a bimodal distribution of correlation times or anisotropic motion, a comparison of the present results with proton data suggests than an anisotropic motion model is more likely to provide a reasonable description of the water molecule motion. An analysis based on an anisotropic motion model that uses two correlation times to characterize the motion shows that most of the water molecules rotate about their twofold axis of symmetry at a rate that is only approximately 100 times smaller than the rate of isotropic diffusion in the bulk liquid. The reorientation of the twofold axis of symmetry itself is characterized by a correlation time of approximately 10(-7) s.

show abstract

“…Unfortunately, the observed water proton rates cannot be used directly to deduce dynamical information about the water molecules in protein solutions with absolute confidence due to possible contributions from water proton -protein proton intermolecular coupling that may produce spin-lattice relaxation and/or magnetization exchange effects [40][41][42]. In addition, exchange of labile protein hydrogens may play an important role [29].…”

Section: T1 Dispersionmentioning

confidence: 99%

Proton and Deuteron Relaxation Study of Molecular Dynamics in Lysozyme Solutions

et al. 2000

Self Cite

View full text Add to dashboard Cite

A nuclear magnetic resonance spin-lattice relaxation dispersion study of the relaxation of several magnetization components in both natural and deuterated lysozyme solutions was undertaken at 20°C. Proton and deuteron resonances were employed. The two-dimensional time evolution of the magnetization and the spin-spin relaxation were analyzed. In addition, an isotopic dilution study was performed at 5 and 30.6 MHz. The results indicate that the water proton spin-lattice relaxation rate which arises from intermolecular relaxation between the water protons and the lysozyme protons represents a relatively strong relaxation mechanism. A model for the dynamics of the water molecules, consistent with the proton and deuteron dispersions as well as with the isotopic dilution results, is presented.

show abstract

Cross relaxation at the lysozyme–water interface: an NMR line-shape-relaxation correlation study

Cited by 16 publications

References 1 publication

Macromolecule and water magnetization exchange modeling in articular cartilage

Macromolecule and water magnetization exchange modeling in articular cartilage

Water molecule dynamics in hydrated lysozyme. A deuteron magnetic resonance study

Proton and Deuteron Relaxation Study of Molecular Dynamics in Lysozyme Solutions

Contact Info

Product

Resources

About