Chemistry Reference
In-Depth Information
73. Damberg P, Jarvet J, Gr
aslund A (2005) Limited variations in 15N CSA magnitudes and
orientations in ubiquitin are revealed by joint analysis of longitudinal and transverse NMR
relaxation. J Am Chem Soc 127:1995-2005
74. Hansen DF, Yang D, Feng H, Zhou Z, Wiesner S, Bai Y, Kay LE (2007) An exchange-free
measure of 15N transverse relaxation: an NMR spectroscopy application to the study of
a folding intermediate with pervasive chemical exchange. J Am Chem Soc 129:11468-11478
75. Hansen DF, Feng H, Zhou Z, Bai Y, Kay LE (2009) Selective characterization of microsec-
ond motions in proteins by NMR relaxation. J Am Chem Soc 131:16257-16265
76. Jeener J, Meier BH, Bachmann P, Ernst RR (1979) Investigation of exchange processes by
two-dimensional NMR spectroscopy. J Chem Phys 71:4546-4553
77. Sahu D, Clore GM, Iwahara J (2007) TROSY-based z-exchange spectroscopy: application to
the determination of the activation energy for intermolecular protein translocation between
specific sites on different DNA molecules. J Am Chem Soc 129:13232-13237
78. Li Y, Palmer AG (2009) TROSY-selected ZZ-exchange experiment for characterizing slow
chemical exchange in large proteins. J Biomol NMR 45:357-360
79. Robson SA, Peterson R, Bouchard LS, Villareal VA, Clubb RT (2010) A heteronuclear zero
quantum coherence Nz-exchange experiment that resolves resonance overlap and its applica-
tion to measure the rates of heme binding to the IsdC protein. J Am Chem Soc 132:9522-9523
80. Fite W II, Redfield AG (1967) Nuclear spin relaxation in superconduting mixed-state
vanadium. Phys Rev 162:358-367
81. Koenig SH, Schillinger WE (1969) Nuclear magnetic relaxation dispersion in protein
solutions. J Biol Chem 244:3283-3289
82. Kimmich R (1979) Field cycling in NMR relaxation spectroscopy: applications in biological,
chemical and polymer physics. Bull Magn Reson 1:195-218
83. Noack F (1986) NMR field-cycling spectroscopy: principles and applications. Prog NMR
Spectrosc 18:171-276
84. Bertini I, Briganti F, Xia ZC, Luchinat C (1993) Nuclear magnetic relaxation dispersion
studies of hexaaquo Mn(II) ions in water-glycerol mixtures. J Magn Reson A 101:198-201
85. Hodges MW, Cafiso DS, Polnaszek CF, Lester CC, Bryant RG (1997) Water translational
motion at the bilayer interface: an NMR relaxation dispersion measurement. Biophys J 75:
2575-2579
86. Koenig SH, Brown RD (1990) Field-cycling relaxometry of protein solutions and tissue:
implications for MRI. Prog NMR Spectrosc 22:487-567
87. Halle B, Denisov VP (1995) A new view of water dynamics in immobilized proteins. Biophys
J 69:242-249
88. Roberts MF, Redfield AG (2004) Phospholipid bilayer surface configuration probed quanti-
tatively by P-31 field-cycling NMR. Proc Natl Acad Sci USA 101:17066-17071
89. Kimmich R, Anoardo E (2004) Field-cycling NMR relaxometry. Prog NMR Spectrosc 44:
257-320
90. Diakova G, Goddard YA, Korb JP, Bryant RG (2010) Water and backbone dynamics in
a hydrated protein. Biophys J 98:138-146
91. Wagner S, Dinesen TRJ, Rayner T, Bryant RG (1999) High-resolution magnetic relaxation
dispersion measurements of solute spin probes using a dual-magnet system. J Magn Reson
140:172-178
92. Redfield AG (2003) Shuttling device for high-resolution measurements of relaxation and
related phenomena in solution at low field, using a shared commercial 500 MHz NMR
instrument. Magn Reson Chem 41:753-768
93. Victor K, Kavolius V, Bryant RG (2004) Magnetic relaxation dispersion probe. J Magn
Reson 171:253-257
94. McConnell HM (1958) Reaction rates by nuclear magnetic resonance. J Chem Phys 28:
430-431
€
