Approaches for the measurement of solvent exposure in proteins by <Superscript>19</Superscript>F NMR

Fluorine NMR is a useful tool to probe protein folding, conformation and local topology owing to the sensitivity of the chemical shift to the local electrostatic environment. As an example we make use of ¹⁹F NMR and 3-fluorotyrosine to evaluate the conformation and topology of the tyrosine residues (Tyr-99 and Tyr-138) within the EF-hand motif of the C-terminal domain of calmodulin (CaM) in both the calcium-loaded and calcium-free states. We critically compare approaches to assess topology and solvent exposure via solvent isotope shifts, ¹⁹F spin–lattice relaxation rates, ¹H–¹⁹F nuclear Overhauser effects, and paramagnetic shifts and relaxation rates from dissolved oxygen. Both the solvent isotope shifts and paramagnetic shifts from dissolved oxygen sensitively reflect solvent exposed surface areas.     

Optimizing <Superscript>19</Superscript>F NMR protein spectroscopy by fractional biosynthetic labeling

In protein NMR experiments which employ nonnative labeling, incomplete enrichment is often associated with inhomogeneous line broadening due to the presence of multiple labeled species. We investigate the merits of fractional enrichment strategies using a monofluorinated phenylalanine species, where resolution is dramatically improved over that achieved by complete enrichment. In NMR studies of calmodulin, a 148 residue calcium binding protein, ¹⁹F and ¹H-¹⁵N HSQC spectra reveal a significant extent of line broadening and the appearance of minor conformers in the presence of complete (>95%) 3-fluorophenylalanine labeling. The effects of varying levels of enrichment of 3-fluorophenylalanine (i.e. between 3 and >95%) were further studied by ¹⁹F and ¹H-¹⁵N HSQC spectra,¹⁵N T₁ and T₂ relaxation measurements, ¹⁹F T₂ relaxation, translational diffusion and heat denaturation experiments via circular dichroism. Our results show that while several properties, including translational diffusion and thermal stability show little variation between non-fluorinated and >95% ¹⁹F labeled samples, ¹⁹F and ¹H-¹⁵N HSQC spectra show significant improvements in line widths and resolution at or below 76% enrichment. Moreover, high levels of fluorination (>80%) appear to increase protein disorder as evidenced by backbone ¹⁵N dynamics. In this study, reasonable signal to noise can be achieved between 60–76% ¹⁹F enrichment, without any detectable perturbations from labeling.     

Cell surface involvement in cancer metastasis: an NMR study

NMR spectroscopy is one of the few techniques which has the sensitivity to detect subtle changes to the surface chemistry of cells. It has previously been demonstrated that high resolution ¹H NMR methods can distinguish tumour cells with the capacity to metastasise and this information appears to arise from a type of proteolipid in or attached to the plasma membrane. Here we report that the ¹H NMR signal, which we have used to identify metastatic cells in rat tumours, is significantly reduced in intensity after cultured cells are treated with trypsin/EDTA. The long T₂ relaxation value (⪢ 350 ms) observed in metastatic cells is absent after enzyme treatment. 2D scalar correlated NMR (COSY) spectra of these treated cells show that a cross peak normally associated with malignancy and metastatic disease is markedly reduced. These findings indicate that the plasma membrane lipid particle which generates the high resolution spectrum is directly affected by trypsin/EDTA. Alterations to the cell surface properties were also demonstrated in vivo since reduced numbers of metastases were observed in animals injected with enzyme-treated cells. The correlation between the absence of a long T₂ relaxation value and the diminished numbers of metastases in animals suggests that the plasma membrane particle is involved in the metastatic process.     

Rubredoxin as a paramagnetic relaxation-inducing probe

The paramagnetic effect due to the presence of a metal center with unpaired electrons is no longer considered a hindrance in protein NMR spectroscopy. In the present work, the paramagnetic effect due to the presence of a metal center with unpaired electrons was used to map the interface of an electron transfer complex. Desulfovibrio gigas cytochrome c₃ was chosen as target to study the effect of the paramagnetic probe, Fe-rubredoxin, which produced specific line broadening in the heme IV methyl resonances M2¹ and M18¹. The rubredoxin binding surface in the complex with cytochrome c₃ was identified in a heteronuclear 2D NMR titration. The identified heme methyls on cytochrome c₃ are involved in the binding interface of the complex, a result that is in agreement with the predicted complexes obtained by restrained molecular docking, which shows a cluster of possible solutions near heme IV. The use of a paramagnetic probe in ¹HNMR titration and the mapping of the complex interface, in combination with a molecular simulation algorithm proved to be a valuable strategy to study electron transfer complexes involving non-heme iron proteins and cytochromes.     

Solution Structure,Copper Binding and Backbone Dynamics of Recombinant Ber e 1–The Major Allergen from Brazil Nut

Background

The 2S albumin Ber e 1 is the major allergen in Brazil nuts. Previous findings indicated that the protein alone does not cause an allergenic response in mice, but the addition of components from a Brazil nut lipid fraction were required. Structural details of Ber e 1 may contribute to the understanding of the allergenic properties of the protein and its potential interaction partners.

Methodology/Principal Findings

The solution structure of recombinant Ber e 1 was solved using NMR spectroscopy and measurements of the protein back bone dynamics at a residue-specific level were extracted using ¹⁵N-spin relaxation. A hydrophobic cavity was identified in the structure of Ber e 1. Using the paramagnetic relaxation enhancement property of Cu²⁺ in conjunction with NMR, it was shown that Ber e 1 is able to specifically interact with the divalent copper ion and the binding site was modeled into the structure. The IgE binding region as well as the copper binding site show increased dynamics on both fast ps-ns timescale as well as slower µs-ms timescale.

Conclusions/Significance

The overall fold of Ber e 1 is similar to other 2S albumins, but the hydrophobic cavity resembles that of a homologous non-specific lipid transfer protein. Ber e 1 is the first 2S albumin shown to interact with Cu²⁺ ions. This Cu²⁺ binding has minimal effect on the electrostatic potential on the surface of the protein, but the charge distribution within the hydrophobic cavity is significantly altered. As the hydrophobic cavity is likely to be involved in a putative lipid interaction the Cu²⁺ can in turn affect the interaction that is essential to provoke an allergenic response.     

Site-specific protein backbone and side-chain NMR chemical shift and relaxation analysis of human vinexin SH3 domain using a genetically encoded 15N/19F-labeled unnatural amino acid

SH3 is a ubiquitous domain mediating protein-protein interactions. Recent solution NMR structural studies have shown that a proline-rich peptide is capable of binding to the human vinexin SH3 domain. Here, an orthogonal amber tRNA/tRNA synthetase pair for ¹⁵N/¹⁹F-trifluoromethyl-phenylalanine (¹⁵N/¹⁹F-tfmF) has been applied to achieve site-specific labeling of SH3 at three different sites. One-dimensional solution NMR spectra of backbone amide (¹⁵N)¹H and side-chain ¹⁹F were obtained for SH3 with three different site-specific labels. Site-specific backbone amide (¹⁵N)¹H and side-chain ¹⁹F chemical shift and relaxation analysis of SH3 in the absence or presence of a peptide ligand demonstrated different internal motions upon ligand binding at the three different sites. This site-specific NMR analysis might be very useful for studying large-sized proteins or protein complexes.     

Structural Studies of Bcl-xL/ligand Complexes using 19F NMR

Fluorine atoms are often incorporated into drug molecules as part of the lead optimization process in order to improve affinity or modify undesirable metabolic and pharmacokinetic profiles. From an NMR perspective, the abundance of fluorinated drug leads provides an exploitable niche for structural studies using ¹⁹F NMR in the drug discovery process. As ¹⁹F has no interfering background signal from biological sources, ¹⁹F NMR studies of fluorinated drugs bound to their protein receptors can yield easily interpretable and unambiguous structural constraints. ¹⁹F can also be selectively incorporated into proteins to obtain additional constraints for structural studies. Despite these advantages, ¹⁹F NMR has rarely been exploited for structural studies due to its broad lines in macromolecules and their ligand complexes, leading to weak signals in ¹H/¹⁹F heteronuclear NOE experiments. Here we demonstrate several different experimental strategies that use ¹⁹F NMR to obtain ligand–protein structural constraints for ligands bound to the anti-apoptotic protein Bcl-xL, a drug target for anti-cancer therapy. These examples indicate the applicability of these methods to typical structural problems encountered in the drug development process.     

15N relaxation study of the cold shock protein CspB at various solvent viscosities

For a detailed NMR study of the dynamics of the cold shock protein CspB from Bacillus subtilis, we determined ¹⁵N transverse and longitudinal relaxation rates and heteronuclear nuclear Overhauser effects at different solvent viscosities. Up to a relative viscosity of 2, which is equivalent to 27% ethylene glycol (EG), the overall correlation time follows the linear Stokes-Einstein equation. At a relative viscosity of 6 (70% EG) the correlation time deviates from linearity by 30%, indicating that CspB tumbles at a higher rate as expected from the solvent viscosity probably due to a preferential binding of water molecules at the protein surface. The corresponding hydrodynamic radii, determined by NMR diffusion experiments, show no variation with viscosity. The amplitudes of intramolecular motions on a sub-nanosecond time scale revealed by an extended Lipari–Szabo analysis were mainly independent of the solvent viscosity. The lower limit of the NMR `observation window' for the internal correlation time shifts above 0.5 ns at 70% EG, which is directly reflected in the experimentally derived internal correlation times. Chemical exchange contributions to the transverse relaxation rates derived from the Lipari-Szabo approach coincide with the experimentally determined values from the transverse ¹H-¹⁵N dipolar/¹⁵N chemical shift anisotropy relaxation interference. These contributions originate from fast protein folding reactions on a millisecond timescale, which get retarded at increased solvent viscosities.     

CPMG relaxation dispersion NMR experiments measuring glycine 1Hα and 13Cα chemical shifts in the ‘invisible’ excited states of proteins

Carr-Purcell-Meiboom-Gill (CPMG) relaxation dispersion NMR experiments are extremely powerful for characterizing millisecond time-scale conformational exchange processes in biomolecules. A large number of such CPMG experiments have now emerged for measuring protein backbone chemical shifts of sparsely populated (>0.5%), excited state conformers that cannot be directly detected in NMR spectra and that are invisible to most other biophysical methods as well. A notable deficiency is, however, the absence of CPMG experiments for measurement of ¹H^α and ¹³C^α chemical shifts of glycine residues in the excited state that reflects the fact that in this case the ¹H^α, ¹³C^α spins form a three-spin system that is more complex than the AX ¹H^α–¹³C^α spin systems in the other amino acids. Here pulse sequences for recording ¹H^α and ¹³C^α CPMG relaxation dispersion profiles derived from glycine residues are presented that provide information from which ¹H^α, ¹³C^α chemical shifts can be obtained. The utility of these experiments is demonstrated by an application to a mutant of T4 lysozyme that undergoes a millisecond time-scale exchange process facilitating the binding of hydrophobic ligands to an internal cavity in the protein.     

19F NMR relaxation studies on 5-fluorotryptophan- and tetradeutero-5-fluorotryptophan-labeled E. coli glucose/galactose receptor

Summary ¹⁹F NMR relaxation studies have been carried out on a fluorotryptophan-labeled E. coli periplasmic glucose/galactose receptor (GGR). The protein was derived from E. coli grown on a medium containing a 50:50 mixture of 5-fluorotryptophan and [2,4,6,7-²H₄]-5-fluorotryptophan. As a result of the large -isotope shift, the two labels give rise to separate resonances, allowing relaxation contributions of the substituted indole protons to be selectively monitored. Spin-lattice relaxation rates were determined at field strengths of 11.75 T and 8.5 T, and the results were analyzed using a model-free formalism. In order to evaluate the contributions of chemical shift anisotropy to the observed relaxation parameters, solid-state NMR studies were performed on [2,4,6,7-²H₄]-5-fluorotryptophan. Analysis of the observed ¹⁹F powder pattern lineshape resulted in anisotropy and asymmetry parameters of =–93.5 ppm and =0.24. Theoretical analyses of the relaxation parameters are consistent with internal motion of the fluorotryptophan residues characterized by order parameters S² of 1, and by correlation times for internal motion 10^-11 s. Simultaneous least squares fitting of the spin-lattice relaxation and line-width data with ⁱ set at 10 ps yielded a molecular correlation time of 20 ns for the glucose-complexed GGR, and a mean order parameter S²=0.89 for fluorotryptophan residues 183, 127, 133, and 195. By contrast, the calculated order parameter for FTrp²⁸⁴, located on the surface of the protein, was 0.77. Significant differences among the spin-lattice relaxation rates of the five fluorotryptophan residues of glucose-complexed GGR were also observed, with the order of relaxation rates given by: R _inf1F ^sup183 >R _inf1F ^sup127 R _inf1F ^sup133 R _inf1F ^sup195 >R _inf1F ^sup284 . Although such differences may reflect motional variations among these residues, the effects are largely predicted by differences in the distribution of nearby hydrogen nuclei, derived from crystal structure data. In the absence of glucose, spin-lattice relaxation rates for fluorotryptophan residues 183, 127, 133, and 195 were found to decrease by a mean of 13%, while the value for residue 284 exhibits an increase of similar magnitude relative to the liganded molecule. These changes are interpreted in terms of a slower overall correlation time for molecular motion, as well as a change in the internal mobility of FTrp²⁸⁴, located in the hinge region of the receptor.Abbreviations FTrp D,L-5-fluorotryptophan - GGR glucose/galactose receptor protein - R_1F spin-lattice relaxation rate of fluorine - R_1F(H) spinlattice relaxation rate of the fluorine nuclei in normal (nondeuterated) fluorotryptophan residues - R_1F(D) spin-lattice relaxation rate of the fluorine in [2,4,6,7-²H₄]-5-fluorotryptophan To whom correspondence should be addressed.     

Erv1 and Cytochrome c Mediate Rapid Electron Transfer via A Collision-Type Interaction

Being essential for oxidative protein folding in the mitochondrial intermembrane space, the mitochondrial disulfide relay relies on the electron transfer (ET) from the sulfhydryl oxidase Erv1 to cytochrome c (Cc). Using solution NMR spectroscopy, we demonstrate that while the yeast Cc-Erv1 system is functionally active, no observable binding of the protein partners takes place. The transient interaction between Erv1 and Cc can be rationalized by molecular modeling, suggesting that a large surface area of Erv1 can sustain a fast ET to Cc via a collision-type mechanism, without the need for a canonical protein complex formation. We suggest that, by preventing the direct ET to molecular oxygen (O₂), the collision-type Cc-Erv1 interaction plays a role in protecting the organism against reactive oxygen species.     

Conformation of pseudoazurin in the 152 kDa electron transfer complex with nitrite reductase determined by paramagnetic NMR

Copper-containing nitrite reductase is able to catalyze the reduction of nitrite with a turnover rate of several hundreds per second. Electrons for the reaction are donated by the electron transfer protein pseudoazurin. The process of protein complex formation, electron transfer and dissociation must occur on the millisecond timescale to enable the fast turnover of the enzyme. The structure of this transient protein complex has been studied using paramagnetic NMR spectroscopy. Gadolinium complexes were attached specifically through two engineered Cys residues on three sites on the surface of nitrite reductase, causing strong distance-dependent relaxation effects on the residues of pseudoazurin. Docking of the two proteins based on these NMR-derived distance restraints and the chemical shift perturbation data shows convergence to a cluster of structures with an average root-mean-square deviation of 1.5 Å. The binding interface consists of polar and non-polar residues surrounded by charges. The interprotein distance between the two type-1 copper sites is 15.5(± 0.5) Å, enabling fast interprotein electron transfer. The NMR-based lower limit estimate of 600 s⁻¹ for the dissociation rate constant and the fast electron transfer are consistent with the transient nature of the complex.     

NMR exchange broadening arising from specific low affinity protein self-association: Analysis of nitrogen-15 nuclear relaxation for rat CD2 domain 1

Nuclear spin relaxation monitored by heteronuclear NMR provides a useful method to probe the overall and internal molecular motion for biological macromolecules over a variety of time scales. Nitrogen-15 NMR relaxation parameters have been recorded for the N-terminal domain of the rat T-cell antigen CD2 (CD2d1) in a dilution series from 1.20 mM to 40 M (pH 6.0, 25 °C). The data have been analysed within the framework of the model- free formalism of Lipari and Szabo to understand the molecular origin of severely enhanced transverse relaxation rates found for certain residues. These data revealed a strong dependence of the derived molecular correlation time _c upon the CD2d1 protein concentration. Moreover, a number of amide NH resonances exhibited exchange broadening and chemical shifts both strongly dependent on protein concentration. These amide groups cluster on the major -sheet surface of CD2d1 that coincides with a major lattice contact in the X-ray structure of the intact ectodomain of rat CD2. The complete set of relaxation data fit well to an equilibrium monomer–dimer exchange model, yielding estimates of exchange rate constants (k_ON=5000 M^-1 s^-1; k_OFF=7 s^-1) and a dissociation constant (K_D 3–6 mM) that is consistent with the difficulty in detecting the weak interactions for this molecule by alternative biophysical methods. The self-association of CD2d1 is essentially invariant to changes in buffer composition and ionic strength and the associated relaxation phenomena cannot be explained as a result of neglecting anisotropic rotational diffusion in the analysis. These observations highlight the necessity to consider low affinity protein self-association interactions as a source of residue specific exchange phenomena in NMR spectra of macromolecular biomolecules, before the assignment of more elaborate intramolecular conformational mechanisms.     

Advances in the study of GPCRs by 19F NMR

Crystallography and cryo-electron microscopy have advanced atomic resolution perspectives of inactive and active states of G protein-coupled receptors (GPCRs), alone and in complex with G proteins or arrestin. ¹⁹F NMR can play a role in ascertaining activation mechanisms and understanding the complete energy landscape associated with signal transduction. Fluorinated reporters are introduced biosynthetically via fluorinated amino acid analogs or chemically, via thiol-specific fluorinated reporters. The chemical shift sensitivity of these reporters makes it possible to discern details of conformational ensembles. In addition to spectroscopic details, paramagnetic species can be incorporated through orthogonal techniques to obtain distance information on fluorinated reporters, while T₂-and T₁-based relaxation experiments provide details on exchange kinetics in addition to fluctuations within a given state.     

Mapping the ligand binding site at protein side-chains in protein-ligand complexes through NOE difference spectroscopy

This report describes a novel NMR approach for mapping the interaction surface between an unlabeled ligand and a ¹³C,¹⁵N-labeled protein. The method relies on the spin inversion properties of the dipolar relaxation pathways and records the differential relaxation of two spin modes, where ligand and protein ¹H magnetizations are aligned either in a parallel or anti-parallel manner. Selective inversion of protein protons is achieved in a straightforward manner by exploiting the one-bond heteronuclear scalar couplings (¹J_CH, ¹J_NH). Suppression of indirect relaxation pathways mediated by bulk water or rapidly exchanging protons is achieved by selective inversion of the water signal in the middle of the NOESY mixing period. The method does not require deuteration of the protein or well separated spectral regions for the protein and the ligand, respectively. Additionally, in contrast to previous methods, the new experiment identifies side-chain enzyme ligand interactions along the intermolecular binding interface. The method is demonstrated with an application to the B₁₂-binding subunit of glutamate mutase from Clostridium tetanomorphum for which NMR chemical shift changes upon B₁₂-nucleotide loop binding and a high-resolution solution structure are available.     

Dynamic conformational equilibria in the physiological function of the Bombyx mori pheromone-binding protein

The Bombyx mori pheromone-binding protein (BmorPBP) undergoes a pH-dependent conformational transition from a form at basic pH, which contains an open cavity suitable for ligand binding (BmorPBP^B), to a form at pH 4.5, where this cavity is occupied by an additional helix (BmorPBP^A). This helix α7 is formed by the C-terminal dodecapeptide 131-142, which is flexibly disordered on the protein surface in BmorPBP^B and in its complex with the pheromone bombykol. Previous work showed that the ligand-binding cavity cannot accommodate both bombykol and helix α7. Here we further investigated mechanistic aspects of the physiologically crucial ejection of the ligand at lower pH values by solution NMR studies of the variant protein BmorPBP(1-128), where the C-terminal helix-forming tetradecapeptide is removed. The NMR structure of the truncated protein at pH 6.5 corresponds closely to BmorPBP^B. At pH 4.5, BmorPBP(1-128) maintains a B-type structure that is in a slow equilibrium, on the NMR chemical shift timescale, with a low-pH conformation for which a discrete set of ¹⁵N-¹H correlation peaks is NMR unobservable. The full NMR spectrum was recovered upon readjusting the pH of the protein solution to 6.5. These data reveal dual roles for the C-terminal tetradecapeptide of BmorPBP in the mechanism of reversible pheromone binding and transport, where it governs dynamic equilibria between two locally different protein conformations at acidic pH and competes with the ligand for binding to the interior cavity.     

Sensitivity enhancement in NMR of macromolecules by application of optimal control theory

NMR of macromolecules is limited by large transverse relaxation rates. In practice, this results in low efficiency of coherence transfer steps in multidimensional NMR experiments, leading to poor sensitivity and long acquisition times. The efficiency of coherence transfer can be maximized by design of relaxation optimized pulse sequences using tools from optimal control theory. In this paper, we demonstrate that this approach can be adopted for studies of large biological systems, such as the 800 kDa chaperone GroEL. For this system, the ¹H–¹⁵N coherence transfer module presented here yields an average sensitivity enhancement of 20–25% for cross-correlated relaxation induced polarization transfer (CRIPT) experiments.Supplementary material to this paper is available in electronic form at http://dx.doi.org/10.1007/s10858-005-3592-0     

Expression of deuterium-isotope-labelled protein in the yeast Pichia pastoris for NMR studies

Deuterium isotope labelling is important for NMR studies of large proteins and complexes. Many eukaryotic proteins are difficult to express in bacteria, but can be efficiently produced in the methylotrophic yeast Pichia pastoris. In order to facilitate NMR studies of the malaria parasite merozoite surface protein-1 (MSP1) complex and its interactions with antibodies, we have investigated production of the MSP1-19 protein in P. pastoris grown in deuterated media. The resulting deuteration patterns were analyzed by NMR and mass spectrometry. We have compared growth characteristics and levels of heterologous protein expression in cells adapted to growth in deuterated media (95% D₂O), compared with expression in non-adapted cells. We have also compared the relative deuteration levels and the distribution pattern of residual protiation in protein from cells grown either in 95% D₂O medium with protiated methanol as carbon source, or in 95% D₂O medium containing deuterated methanol. A high level of uniform C deuteration was demonstrated, and the consequent reduction of backbone amide signal linewidths in [¹H/¹⁵N]-correlation experiments was measured. Residual protiation at different positions in various amino acid residues, including the distribution of methyl isotopomers, was also investigated. The deuteration procedures examined here should facilitate economical expression of ²H/¹³C/¹⁵N-labelled protein samples for NMR studies of the structure and interactions of large proteins and protein complexes.     

Chemical shift as a probe of molecular interfaces: NMR studies of DNA binding by the three amino-terminal zinc finger domains from transcription factor IIIA

We report the NMR resonance assignments for a macromolecular protein/DNA complex containing the three amino-terminal zinc fingers (92 amino acid residues) of Xenopus laevis TFIIIA (termed zf1-3) bound to the physiological DNA target (15 base pairs), and for the free DNA. Comparisons are made of the chemical shifts of protein backbone¹ H^N, ¹⁵N,¹³ C and¹³ C and DNA base and sugar protons of the free and bound species. Chemical shift changes are analyzed in the context of the structures of the zf1-3/DNA complex to assess the utility of chemical shift change as a probe of molecular interfaces. Chemical shift perturbations that occur upon binding in the zf1-3/DNA complex do not correspond directly to the structural interface, but rather arise from a number of direct and indirect structural and dynamic effects.     

Viability of Cururbita pepo pollen: biophysical and structural data

During ageing of the short-lived pollen grains of Cucurbita pepo L., water loss was examined in relation to viability using biophysical (¹H-nuclear magnetic resonance, NMR) and cytological methods (fluorochromatic reaction test, freezefracture and scanning electron microscopy). A semi-logarithmic representation of the pollen weight loss demonstrated the complexity of the dehydration process. A the study of proton loss using ¹H-NMR indicated that two major releases water of had taken place, each with different flux rates. Pulse ¹H-NMR experiments showed the occurrene of non-exponential signal decay as a function of time, indicating the existence of different fractions of water in a pollen grain sample. These fractions leave the pollen grain at different times during pollen dehydration, and one of them (that of the so-called vital water) can be related to pollen viability. The quantity of protons giving a signal during pulse ¹H-NMR experiments was very low when the pollen grains were judged to be dead according to the fluorochromatic test. Freeze-fracture replicas of these dead pollen grains (less than 25% water content) showed that the plasma membrane had become detached from the intine surface; this ultrastructural feature might therefore be involved in the loss of pollen viability.Abbreviations A initial amplitude of the NMR signal - A₂ quantity of water charcterized by T_2-2 - A₅ quantity of water characterized by T_2–5 - FCR fluorochromatic reaction - NMR nuclear magnetic resonance - T₂ transverse relaxation time - T_2-2 T₂ measured with 2 ms between each pulse of radiofrequency - T_2–5 T₂ measured with 5 ms between each pulse of radiofrequency