1975
DOI: 10.1073/pnas.72.7.2667
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Protein-water interaction studied by solvent 1H, 2H, and 17O magnetic relaxation.

Abstract: Previous studies of the magnetic field de- Solvent proton relaxation in protein solutions can be accounted for reasonably well within the framework of a simple model of water exchange between the bulk solvent, in which the protons are assumed not to interact with the solute, and regions on or near the protein where the rotational motion of the protein molecules is conveyed to the water molecules. If it is assumed that the water molecules in the latter region attach rigidly to the protein, then one can readily … Show more

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Cited by 103 publications
(73 citation statements)
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“…The size of the magnetization components obtained from the decompositions was independent of frequency and similar to the size of the corresponding fraction determined in the 2DTE experiment at 40 MHz (Table I). In part, the proton 1/T1 dispersion of the Li-component in N-HEWL and the deuteron 1/T1 dispersion of the Li-component in D-HEWL have been reported in the literature [21,33]. The measurements in the literature extend to lower frequencies, whereas our measurements include data at higher frequencies.…”
Section: Table Icontrasting
confidence: 50%
See 1 more Smart Citation
“…The size of the magnetization components obtained from the decompositions was independent of frequency and similar to the size of the corresponding fraction determined in the 2DTE experiment at 40 MHz (Table I). In part, the proton 1/T1 dispersion of the Li-component in N-HEWL and the deuteron 1/T1 dispersion of the Li-component in D-HEWL have been reported in the literature [21,33]. The measurements in the literature extend to lower frequencies, whereas our measurements include data at higher frequencies.…”
Section: Table Icontrasting
confidence: 50%
“…In addition, exchange of labile protein hydrogens may play an important role [29]. However, it has been shown [33] that in lysozyme solution, at pH 7, labile protein hydrogens do not make any measurable contribution to solvent proton relaxation rates, and this effect is assumed negligible in the present study.…”
Section: T1 Dispersionmentioning
confidence: 80%
“…This removes the internal inconsistencies that led some authors (Koenig et al, 1975;Bryant, 1988;Koenig & Brown, 1991) to reject a simple fast-exchange model. Furthermore, the hitherto controversial mechanism whereby the protein rotational motion is conveyed to the water molecules (Bryant, 1988) is now identified as the exchange, on the time-scale 10 −8 to 10 −6 second (for 17 O relaxation and small proteins), of highly ordered internal water molecules.…”
Section: Concluding Discussionmentioning
confidence: 99%
“…12 It is estimated that a threshold level of hydration (less than 0.4 grams of water per gram of protein) is required to fully activate the dynamics and function of globular proteins. [13][14][15] The most direct evidence for the importance of water in protein structure and function is that in the absence of water, proteins cannot diffuse and become non-functional. Lack of motion and function have been observed when proteins are transferred to organic solvents 16 and dehydration studies show that at least a monolayer of water molecules is required for the protein to be fully functional.…”
Section: Introductionmentioning
confidence: 99%