Simultaneous measurement of intra- and intermolecular NOEs in differentially labeled protein-ligand complexes*

A new NOE strategy is presented that allows the simultaneous observation of intermolecular and intramolecular NOEs between an unlabeled ligand and a ¹³C,¹⁵N-labeled protein. The method uses an adiabatic ¹³C inversion pulse optimized to an empirically observed relationship between ¹ J _CH and carbon chemical shift to selectively invert the protein protons (attached to ¹³C). Two NOESY data sets are recorded where the intermolecular and intramolecular NOESY cross peaks have either equal or opposite signs, respectively. Addition and subtraction yield two NOESY spectra which contain either NOEs within the labeled protein (or unlabeled ligand) or along the binding interface. The method is demonstrated with an application to the B₁₂-binding subunit of Glutamate Mutase from Clostridium tetanomorphum complexed with the B₁₂-nucleotide loop moiety of the natural cofactor adenosylcobalamin (Coenzyme B₁₂).     

Off-resonance rotating-frame relaxation dispersion experiment for 13C in aromatic side chains using L-optimized TROSY-selection

Protein dynamics on the microsecond–millisecond time scales often play a critical role in biological function. NMR relaxation dispersion experiments are powerful approaches for investigating biologically relevant dynamics with site-specific resolution, as shown by a growing number of publications on enzyme catalysis, protein folding, ligand binding, and allostery. To date, the majority of studies has probed the backbone amides or side-chain methyl groups, while experiments targeting other sites have been used more sparingly. Aromatic side chains are useful probes of protein dynamics, because they are over-represented in protein binding interfaces, have important catalytic roles in enzymes, and form a sizable part of the protein interior. Here we present an off-resonance R _1ρ experiment for measuring microsecond to millisecond conformational exchange of aromatic side chains in selectively ¹³C labeled proteins by means of longitudinal- and transverse-relaxation optimization. Using selective excitation and inversion of the narrow component of the ¹³C doublet, the experiment achieves significant sensitivity enhancement in terms of both signal intensity and the fractional contribution from exchange to transverse relaxation; additional signal enhancement is achieved by optimizing the longitudinal relaxation recovery of the covalently attached ¹H spins. We validated the L-TROSY-selected R _1ρ experiment by measuring exchange parameters for Y23 in bovine pancreatic trypsin inhibitor at a temperature of 328 K, where the ring flip is in the fast exchange regime with a mean waiting time between flips of 320 μs. The determined chemical shift difference matches perfectly with that measured from the NMR spectrum at lower temperatures, where separate peaks are observed for the two sites. We further show that potentially complicating effects of strong scalar coupling between protons (Weininger et al. in J Phys Chem B 117: 9241–9247, 2013b) can be accounted for using a simple expression, and provide recommendations for data acquisition when the studied system exhibits this behavior. The present method extends the repertoire of relaxation methods tailored for aromatic side chains by enabling studies of faster processes and improved control over artifacts due to strong coupling.     

Carcinogen-Nucleic Acid Interactions: Equilibrium Binding Studies of Aflatoxins B1 and B2 with DNA and the Oligodeoxynucleotide d(ATGCAT)2

Abstract

Equilibrium binding is believed to play an important role in directing the subsequent covalent attachment of many carcinogens to DNA. We have utilized UV spectroscopy to examine the non-covalent interactions of aflatoxin B₁ and B₂ with calf thymus DNA, poly(dAdT):poly(dAdT), and poly(dGdC):poly(dGdC), and have utilized NMR spectroscopy to examine non-covalent interactions of aflatoxin B₂ with the oligodeoxynucleotide d(ATGCAT)₂. UV-VIS binding isotherms suggest a greater binding affinity for calf thymus DNA and poly(dAdT):poly(dAdT) than for poly(dGdC):poly(dGdC). Scatchard analysis of aflatoxin B₁ binding to calf thymus DNA in 0.1 M NaCl buffer indicates that binding of the carcinogen at levels of bound aflatoxin ? 1 carcinogen per 200 base pairs occurs with positive cooperativity. The cooperative binding effect is dependent on the ionic strength of the medium; when the NaCl concentration is reduced to 0.01 M, positive cooperativity is observed at carcinogen levels ? 1 carcinogen per 500 base pairs. The Scatchard data may be fit using a “two-site” binding model [L.S. Rosenberg, M J. Carvlin, and T.R. Krugh, Biochemistry 25, 1002–1008 (1986)]. This model assumes two independent sets of binding sites on the DNA lattice, one a high affinity site which binds the carcinogen with positive cooperativity, the second consisting of lower affinity binding sites to which non-specific binding occurs. NMR analysis of aflatoxin B₂ binding to d(ATGCAT)₂ indicates that the aflatoxin B₂/oligodeoxynucleotide complex is in fast exchange on the NMR time scale. Upfield chemical shifts of 0.1–0.5 ppm are observed for the aflatoxin B₂ 4-OCH₃, H5, and H6a protons. Much smaller chemical shift changes ? 0.06 ppm) are observed for the oligodeoxynucleotide protons. The greatest effect for the oligodeoxynucleotide protons is observed for the adenine H2 protons, located in the minor groove. Nonselective T₁ experiments demonstrate a 15–25 % decrease in the relaxation time for the adenine H2 protons when aflatoxin B₂ is added to the solution. This result suggests that aflatoxin B₂ protons in the bound state may be in close proximity to these protons, providing a source of dipolar relaxation. Further experiments are in progress to probe the nature of the aflatoxin B₁ and B₂ complexes with polymeric DNA and oligodeoxynucleotides, and to establish the relationship between the non-covalent DNA-carcinogen complexes observed in these experiments, and covalent aflatoxin B₁,-guanine N7 DNA adducts.     

Identification of platination sites on human serum transferrin using 13C and 15N NMR spectroscopy

 Reactions between various apo and metal-bound forms of human serum transferrin (80 kDa) and the recombinant N-lobe (40 kDa) with [Pt(en)Cl₂] or cis-[PtCl₂(NH₃)₂] have been investigated in solution via observation of [¹H,¹⁵N] NMR resonances of the Pt complexes, [¹H,¹³C] resonances of the eCH₃ groups of the protein methionine residues, and by chromatographic analysis of single-site methionine mutants. For the whole protein, the preferred Pt binding site appears to be Met256. Additional binding occurs at the other surface-exposed methionine (Met499), which is platinated at a slower rate than Met256. In contrast, binding of similar Pt compounds to the N-lobe of the protein occurs at Met313, rather than Met256. Met313 is buried in the interlobe contact region of intact transferrin. After loss of one chloride ligand from Pt and binding to methionine sulfur of the N-lobe, chelate-ring closure appears to occur with binding to a deprotonated backbone amide nitrogen, and the loss of the other chloride ligand. Such chelate-ring closure was not observed during reactions of the whole protein, even after several days. Received: 5 May 1999 / Accepted: 26 July 1999     

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.     

Probing protein-peptide binding surfaces using charged stable free radicals and transverse paramagnetic relaxation enhancement (PRE)

Nitroxide species, which have an unpaired electron localized on a nitrogen atom, can be useful as NMR probes to identify areas of the surface of a protein involved in the formation of a complex. The proximity of an electron spin leads to higher NMR relaxation rates for protein nuclei. If a protein–ligand complex is formed the radical is excluded from certain sites on the protein surface, protecting them from relaxation effects. We show here that charged nitroxide species can be helpful for identifying regions of the surface of the ⁴F1⁵F1 module pair from human fibronectin involved in peptide binding.Supplementary material to this paper is available in electronic form at http://dx.doi.org/10.1007/s10858-004-7912-6     

Paramagnetic 1H NMR spectroscopy of the reduced, unbound Photosystem I subunit PsaC: sequence-specific assignment of contact-shifted resonances and identification of mixed-and equal-valence Fe-Fe pairs in [4Fe-4S] centers FA − and FB −

A and F_B. The g-tensor orientation of F_A ⁻ and F_B ⁻ is believed to be correlated to the preferential localization of the mixed-valence and equal-valence (ferrous) iron pairs in each [4Fe-4S]⁺ cluster. The preferential position of the mixed-valence and equal-valence pairs, in turn, can be inferred from the study of the temperature dependence of contact-shifted resonances by ¹H NMR spectroscopy. For this, a sequence-specific assignment of these signals is required. The ¹H NMR spectrum of reduced, unbound PsaC from Synechococcus sp. PCC 7002 at 280.4 K in 99% D₂O solution shows 18 hyperfine-shifted resonances. The non-solvent-exchangeable, hyperfine-shifted resonances of reduced PsaC are clearly identified as belonging to the cysteines coordinating the clusters F_A ⁻ and F_B ⁻ by their downfield chemical shifts, by their temperature dependencies, and by their short T ₁ relaxation times. The usual fast method of assigning the ¹H NMR spectra of reduced [4Fe-4S] proteins through magnetization transfer from the oxidized to the reduced state was not feasible in the case of reduced PsaC. Therefore, a de novo self-consistent sequence-specific assignment of the hyperfine-shifted resonances was obtained based on dipolar connectivities from 1D NOE difference spectra and on longitudinal relaxation times using the X-ray structure of Clostridium acidi urici 2[4Fe-4S] cluster ferredoxin at 0.94 Å resolution as a model. The results clearly show the same sequence-specific distribution of Curie and anti-Curie cysteines for unbound, reduced PsaC as established for other [4Fe-4S]-containing proteins; therefore, the mixed-valence and equal-valence (ferrous) Fe-Fe pairs in F_A ⁻ and F_B ⁻ have the same preferential positions relative to the protein. The analysis reveals that the magnetic properties of the two [4Fe-4S] clusters are essentially indistinguishable in unbound PsaC, in contrast to the PsaC that is bound as a component of the PS I complex. Received: 1 February 2000 / Accepted: 20 March 2000     

An NMR Study of the Spatial Structure and Intramolecular Dynamics of Modified Analogues of Steroid Hormones

Special features of the use of homo- and heteronuclear correlation methods of NMR in one and two dimensions for studying the spatial structure and intramolecular dynamics of modified analogues of steroid hormones (MASH) are considered. The application of these methods to the assignment of resonances in the high-field ¹H NMR region and to the determination of the most stereospecifically important parameters, such as the vicinal constants of spin–spin coupling (³ J _H–H) and nuclear Overhauser effects (NOE), are discussed using the example of NMR studies of some estrogens and androgens at 300 MHz and on the basis of literature data. The most efficient combination of the methods and the necessary modification of each of them may be chosen considering the spectral and relaxation parameters of MASH in liquid medium, including the anisotropy of the overall diffusive motion. The characteristics of MASH are the wide use of correlations through long-range couplings (COSY-45 and DQF-COSY), the application of the ^4,5 J _H–H constants for the determination of spatial structure, and the advantage of heteronuclear HSQC methods with and without ¹³C decoupling over the corresponding HMQC methods in both resolution and sensitivity. In the conformationally rigid MASH molecules, the anisotropy of the MASH diffusive motion in liquid adversely affects the determination of interproton distances by the calibrating processing method for the NOE difference and NOESY spectra: it results in both overestimated and underestimated distance values depending on the polar angle ratios of the reference and the determined distances. Under certain conditions, conformationally mobile MASH demonstrate the additional contribution of the scalar relaxation mechanism between the indirectly (scalarly) bound protons. This mechanism is responsible for the underestimated values of NOE and the corresponding errors in the distance determination.     

Nuclear magnetic resonance‐based determination of dioxygen binding sites in protein cavities

The location and ligand accessibility of internal cavities in cysteine‐free wild‐type T4 lysozyme was investigated using O₂ gas‐pressure NMR spectroscopy and molecular dynamics (MD) simulation. Upon increasing the concentration of dissolved O₂ in solvent to 8.9 mM, O₂‐induced paramagnetic relaxation enhancements (PREs) to the backbone amide and side chain methyl protons were observed, specifically around two cavities in the C‐terminal domain. To determine the number of O₂ binding sites and their atomic coordinates from the 1/r⁶ distance dependence of the PREs, we established an analytical procedure using Akaike's Information Criterion, in combination with a grid‐search. Two O₂‐accessible sites were identified in internal cavities: One site was consistent with the xenon‐binding site in the protein in crystal, and the other site was established to be a novel ligand‐binding site. MD simulations performed at 10 and 100 mM O₂ revealed dioxygen ingress and egress as well as rotational and translational motions of O₂ in the cavities. It is therefore suggested that conformational fluctuations within the ground‐state ensemble transiently develop channels for O₂ association with the internal protein cavities.     

Investigation of exchange couplings in [Fe3S4]+ clusters by electron spin-lattice relaxation

3 S₄]⁺, S=1/2, composed of three, antiferromagnetically coupled high-spin ferric ions) by continuous wave (CW) and pulsed EPR techniques: Azotobacter vinelandii ferredoxin I, Desulfovibrio gigas ferredoxin II, and the 3Fe forms of Pyrococcus furiosus ferredoxin and aconitase. The 35 GHz (Q-band) CW EPR signals are simulated to yield experimental g tensors, which either had not been reported, or had been reported only at X-band microwave frequency. Pulsed X- and Q-band EPR techniques are used to determine electron spin-lattice (T ₁, longitudinal) relaxation times at several positions on the samples' EPR envelope over the temperature range 2–4.2 K. The T ₁ values vary sharply across the EPR envelope, a reflection of the fact that the envelope results from a distribution in cluster properties, as seen earlier as a distribution in g ₃ values and in ⁵⁷ Fe hyperfine interactions, as detected by electron nuclear double resonance spectroscopy. The temperature dependence of 1/T ₁ is analyzed in terms of the Orbach mechanism, with relaxation dominated by resonant two-phonon transitions to a doublet excited state at ∼20 cm⁻¹ above the doublet ground state for all four of these 3Fe proteins. The experimental EPR data are combined with previously reported ⁵⁷Fe hyperfine data to determine electronic spin exchange-coupling within the clusters, following the model of Kent et al. Their model defines the coupling parameters as follows: J ₁₃=J, J ₁₂=J(1+ε′), J ₂₃=J(1+ε), where J _ij is the isotropic exchange coupling between ferric ions i and j, and ε and ε′ are measures of coupling inequivalence. We have extended their theory to include the effects of ε′≠0 and thus derived an exact expression for the energy of the doublet excited state for any ε, ε′. This excited state energy corresponds roughly to ε J and is in the range 5–10 cm⁻¹ for each of these four 3Fe proteins. This magnitude of the product ε J, determined by our time-domain relaxation studies in the temperature range 2–4 K, is the same as that obtained from three other distinct types of study: CW EPR studies of spin relaxation in the range 5.5–50 K, NMR studies in the range 293–303 K, and static susceptibility measurements in the range 1.8–200 K. We suggest that an apparent disagreement as to the individual values of J and ε be resolved in favor of the values obtained by susceptibility and NMR (J≳200 cm⁻¹ and ε≳0.02 cm⁻¹ ), as opposed to a smaller J and larger ε as suggested in CW EPR studies. However, we note that this resolution casts doubt on the accepted theoretical model for describing the distribution in magnetic properties of 3Fe clusters. Received: 23 December 1999 / Accepted: 8 March 2000     

TROSY NMR with partially deuterated proteins

TROSY-type optimization of liquid-state NMR experiments is based on the preservation of unique coherence transfer pathways with distinct transverse relaxation properties. The broadband decoupling of the ¹H spins interchanges the TROSY and anti-TROSY magnetization transfer pathways and thus is not used in TROSY-type triple resonance experiments or is replaced with narrowband selective decoupling. To achieve the full advantage of TROSY, the uniform deuteration of proteins is usually required. Here we propose a new and general method for ¹H broadband decoupling in TROSY NMR, which does not compromise the relaxation optimization in the ¹⁵N–¹H moieties, but uniformly and efficiently refocuses the ¹ J _CH scalar coupling evolution in the ¹³C–¹H moieties. Combined with the conventional ²H decoupling, this method enables obtaining high sensitivity TROSY-type triple resonance spectra with partially deuterated or fully protonated ¹³C,¹⁵N labeled proteins.     

Structure and magnetic properties of a tetranuclear Cu4O4 open-cubane in [Cu(L)]4·4H2O with L = (E)-N′-(2-oxy-3-methoxybenzylidene)benzohydrazide

The in-situ formed hydrazone Schiff base ligand (E)-N′-(2-oxy-3-methoxybenzylidene)benzohydrazide (L²⁻) reacts with copper(II) acetate to a tetranuclear open cubane [Cu(L)]₄ complex which crystallizes as two symmetry-independent (Z′ = 2) S₄-symmetrical molecules in different twofold special positions with a homodromic water tetramer. The two independent (A and B) open- or pseudo-cubanes with Cu₄O₄ cores of 4 + 2 class (Ruiz classification) each have three different magnetic exchange pathways leading to an overall antiferromagnetic coupling with J_1B = J_2B = −17.2 cm⁻¹, J_1A = −36.7 cm⁻¹, J_2A = −159 cm⁻¹, J_3A = J_3B = 33.5 cm⁻¹, g = 2.40 and ρ = 0.0687. The magnetic properties have been analysed using the H = −Σ_i,jJ_ij(S_iS_j) spin Hamiltonian.     

Off-resonance rotating-frame amide proton spin relaxation experiments measuring microsecond chemical exchange in proteins

NMR spin relaxation in the rotating frame (R_1ρ) is a unique method for atomic-resolution characterization of conformational (chemical) exchange processes occurring on the microsecond time scale. Here, we use amide ¹H off-resonance R_1ρ relaxation experiments to determine exchange parameters for processes that are significantly faster than those that can be probed using ¹⁵N or ¹³C relaxation. The new pulse sequence is validated using the E140Q mutant of the C-terminal domain of calmodulin, which exhibits significant conformational exchange contributions to the transverse relaxation rates. The ¹H off-resonance R_1ρ data sample the entire relaxation dispersion profiles for the large majority of residues in this protein, which exchanges between conformations with a time constant of approximately 20 μs. This is in contrast to the case for ¹⁵N, where additional laboratory-frame relaxation data are required to determine the exchange parameters reliably. Experiments were performed on uniformly ¹⁵N-enriched samples that were either highly enriched in ²H or fully protonated. In the latter case, dipolar cross-relaxation with aliphatic protons were effectively decoupled to first order using a selective inversion pulse. Deuterated and protonated samples gave the same results, within experimental errors. The use of deuterated samples increases the sensitivity towards exchange contributions to the ¹H transverse relaxation rates, since dipolar relaxation is greatly reduced. The exchange correlation times determined from the present ¹H off-resonance R_1ρ experiments are in excellent agreement with those determined previously using a combination of ¹⁵N laboratory-frame and off-resonance R_1ρ relaxation data, with average values of and 21 ± 3 μs, respectively.     

Pulsed NMR studies on Na + binding to simple carbohydrates

Pulsed NMR spectroscopy has been used to study Na⁺ binding to several simple carbohydrates in aqueous solution. Changes in the ²³Na spin-lattice relaxation time (T₁) were monitored to indicate complex formation between sodium ions and a ligand. It was found that Na⁺ interacts with these hydroxy-compounds in a manner similar to other metal cations, but very weakly. Among the sugars investigated, $\text{c i s}$-inositol forms the strongest complexes with the stability constant about 1.2 M^?1 (if 1:1 complexes are assumed). A qualitative study of competition between Na⁺ and Ca²⁺ was done, indicating that both cations have the same binding sites.     

1H NMR relaxation investigation of acetylcholinesterase inhibitors from huperzine A and derivative

The binding properties of huperzine A (1) with Torpediniforms Nacline acetylcholinesterase (TnAChE) were investigated by (1)H NMR methods. The noselective, selective and double-selective spin-lattice relaxation rates were acquired in absent and present of TnAChE at a ratio [ligand]/[protein]=1:0.005. The selective relaxation rates shown protons of 1 had dipole-dipole interaction with protein active site protons. The motional correlation time of bound ligand was calculated by double-selective relaxation rate at 1 tau(2,3)=40.5 ns at 298 K, which showed 1 had high affinity with TnAChE. The experiments give a possible method to use TnAChE to locate the new huperzine A derivatives as AChE inhibitors.     

The use of TROSY for detection and suppression of conformational exchange NMR line broadening in biological macromolecules

The interference between conformational exchange-induced time-dependent variations of chemical shifts in a pair of scalar coupled ¹H and ¹⁵N spins is used to construct novel TROSY-type NMR experiments to suppress NMR signal loss in [¹⁵N,¹H]-correlation spectra of a 14-mer DNA duplex free in solution and complexed with the Antp homeodomain. An analysis of double- and zero-quantum relaxation rates of base ¹H–¹⁵N moieties showed that for certain residues the contribution of conformational exchange-induced transverse relaxation might represent a dominant relaxation mechanism, which, in turn, can be effectively suppressed by TROSY. The use of the new TROSY method for exchange-induced transverse relaxation optimization is illustrated with two new experiments, 2D ^h1 J _HN,^h2 J _NN-quantitative [¹⁵N,¹H]-TROSY to measure ^h1 J _HN and ^h2 J _NN scalar coupling constants across hydrogen bonds in nucleic acids, and 2D (^h2 J _NN+^h1 J _NH)-correlation-[¹⁵N,¹H]-TROSY to correlate ¹H^N chemical shifts of bases with the chemical shifts of the tertiary ¹⁵N spins across hydrogen bonds using the sum of the trans-hydrogen bond coupling constants in nucleic acids.     

F nuclear magnetic resonance screening of glucokinase activators

Human hexokinase enzyme IV (EC 2.7.1.1) catalyzes the phosphorylation of glucose and regulates the level of glucose. This enzyme exhibits strong positive cooperativity due to an allosteric transition between an inactive form and a closed active form. This form can be stabilized by activators and, thus, can increase its turnover by a kinetic memory effect characterized by a slow decay to the inactive state. The structural details of this kinetic allostery are known. Several synthetic activators have been reported. We present a preliminary nuclear magnetic resonance (NMR) screening of a chemical library in search of molecules with some affinity for glucokinase (GK). The library, composed of eight molecules with known activity as well as molecules that display no interaction, has been tested using the FAXS (fluorine chemical shift anisotropy and exchange for screening) method, based on monitoring the R₂ relaxation of the ¹⁹F spin. To ensure a valid interaction measurement, the enzyme was placed in the presence of glucose and magnesium. The binding signal of one known fluorinated ligand was measured by determining the displacement of the known ligand. This simple measure of the ¹⁹F signal intensity after an 80-ms spin echo correlates nicely with the EC₅₀, opening a route for NMR screening of GK activators.     

Nitroxide spin labels as EPR reporters of the relaxation and magnetic properties of the heme–copper site in cytochrome bo 3, E. coli

A nitroxide spin label (SL) has been used to probe the electron spin relaxation times and the magnetic states of the oxygen-binding heme–copper dinuclear site in Escherichia coli cytochrome bo _3, a quinol oxidase (QO), in different oxidation states. The spin lattice relaxation times, T ₁, of the SL are enhanced by the paramagnetic metal sites in QO and hence show a strong dependence on the oxidation state of the latter. A new, general form of equations and a computer simulation program have been developed for the calculation of relaxation enhancement by an arbitrary fast relaxing spin system of S ≥ 1/2. This has allowed us to obtain an accurate estimate of the transverse relaxation time, T ₂, of the dinuclear coupled pair Fe(III)–Cu_B(II) in the oxidized form of QO that is too short to measure directly. In the case of the F′ state, the relaxation properties of the heme–copper center have been shown to be consistent with a ferryl [Fe(IV)=O] heme and Cu_B(II) coupled by approximately 1.5–3 cm⁻¹ to a radical. The magnitude suggests that the coupling arises from a radical form of the covalently linked tyrosine–histidine ligand to Cu(II) with unpaired spin density primarily on the tyrosine component. This work demonstrates that nitroxide SLs are potentially valuable tools to probe both the relaxation and the magnetic properties of multinuclear high-spin paramagnetic active sites in proteins that are otherwise not accessible from direct EPR measurements.     

Interaction of a <Emphasis Type="Italic">Salmonella enteritidis</Emphasis> O-antigen octasaccharide with the phage P22 tailspike protein by NMR spectroscopy and docking studies

The tailspike protein P22 recognizes an octasaccharide derived from the O-antigen polysaccharide of Salmonella enteritidis in a shallow groove and molecular docking successfully identifies this binding region on the protein surface. Analysis by 2D ¹H,¹H-T-ROESY and transferred NOESY NMR experiments indicate that the bound octasaccharide ligand has a conformation similar to that observed in solution. The results from a saturation transfer difference NMR experiment show that a large number of protons in the octasaccharide are in close contact with the protein as a result of binding. A comparison of the crystal structure of the complex and a molecular dynamics simulation of the octasaccharide with explicit water molecules suggest that only minor conformational changes are needed upon binding to the tailspike protein.     

Programming xenon diffusion in maltose-binding protein

Protein interiors contain void space that can bind small gas molecules. Determination of gas pathways and kinetics in proteins has been an intriguing and challenging task. Here, we combined computational methods and the hyperpolarized xenon-129 chemical exchange saturation transfer (hyper-CEST) NMR technique to investigate xenon (Xe) exchange kinetics in maltose-binding protein (MBP). A salt bridge ～9 Å from the Xe-binding site formed upon maltose binding and slowed the Xe exchange rate, leading to a hyper-CEST ¹²⁹Xe signal from maltose-bound MBP. Xe dissociation occurred faster than dissociation of the salt bridge, as shown by ¹³C NMR spectroscopy and variable-B₁ hyper-CEST experiments. “Xe flooding” molecular dynamics simulations identified a surface hydrophobic site, V23, that has good Xe binding affinity. Mutations at this site confirmed its role as a secondary exchange pathway in modulating Xe diffusion. This shows the possibility for site-specifically controlling xenon protein-solvent exchange. Analysis of the available MBP structures suggests a biological role of MBP’s large hydrophobic cavity to accommodate structural changes associated with ligand binding and protein-protein interactions.