HCN, a triple-resonance NMR technique for selective observation of histidine and tryptophan side chains in 13C/15N-labeled proteins

Ligand- and pH-Induced Structural Transition of Gypsy Moth Lymantria dispar Pheromone-Binding Protein 1 (LdisPBP1)

Pheromone-binding proteins (PBPs) are small, water-soluble proteins found in the lymph of pheromone-sensing hairs. PBPs are essential in modulating pheromone partitioning in the lymph and at pheromone receptors of olfactory sensory neurons. The function of a PBP is associated with its ability to structurally convert between two conformations. Although mechanistic details remain unclear, it has been proposed that the structural transition between these forms is affected by two factors: pH and the presence or absence of ligand. To better understand the PBP conformational transition, the structure of the gypsy moth (Lymantria dispar) LdisPBP1 was elucidated at pH 4.5 and 35 °C using nuclear magnetic resonance spectroscopy. In addition, the effects of sample pH and binding of the species' pheromone, (+)-disparlure, (7R,8S)-epoxy-2-methyloctadecane, and its enantiomer were monitored via ¹⁵N HSQC spectroscopy. LdisPBP1 in acidic conditions has seven helices, with its C-terminal residues forming the seventh helix within the pheromone-binding pocket and its N-terminal residues disordered. Under conditions where this conformation is made favorable, free LdisPBP1 would have limited ligand binding capacity due to the seventh helix occupying the internal binding pocket. Our findings suggest that even in the presence of 4-fold ligand at acidic pH, LdisPBP1 is only ∼60% in its pheromone-bound form. Furthermore, evidence of a different LdisPBP1 form is seen at higher pH, with the transition pH between 5.6 and 6.0. This suggests that LdisPBP1 at neutral pH exists as a mixture of at least two conformations. These findings have implications concerning the PBP ligand binding and release mechanism.

Assessing the One-Bond Cα-H Spin-Spin Coupling Constants in Proteins: Pros and Cons of Different Approaches

In the present work, we explore three different approaches for the computation of the one-bond spin-spin coupling constants (SSCC) 1JCαH in proteins: density functional theory (DFT) calculations, a Karplus-like equation, and Gaussian process regression. The main motivation of this work is to select the best method for fast and accurate computation of the 1JCαH SSCC, for its use in everyday applications in protein structure validation, refinement, and/or determination. Our initial results showed a poor agreement between the DFT-computed and observed 1JCαH SSCC values. Further analysis leads us to the understanding that the model chosen for the DFT computations is inappropriate and that more complex models will require a higher, if not prohibitively, computational cost. Finally, we show that the Karplus-like equation and Gaussian Process regression provide faster and more accurate results than DFT-based calculations.

BEST and SOFAST experiments for resonance assignment of histidine and tyrosine side chains in 13C/15N labeled proteins

Aromatic amino-acid side chains are essential components for the structure and function of proteins. We present herein a set of NMR experiments for time-efficient resonance assignment of histidine and tyrosine side chains in uniformly ¹³C/¹⁵N-labeled proteins. The use of band-selective ¹³C pulses allows to deal with linear chains of coupled spins, thus avoiding signal loss that occurs in branched spin systems during coherence transfer. Furthermore, our pulse schemes make use of longitudinal ¹H relaxation enhancement, Ernst-angle excitation, and simultaneous detection of ¹H and ¹³C steady-state polarization to achieve significant signal enhancements.

Limiting Values of the one-bond C-H Spin-Spin Coupling Constants of the Imidazole Ring of Histidine at High-pH

Assessment of the relative amounts of the forms of the imidazole ring of Histidine (His), namely the protonated (H+) and the tautomeric Nε2-H and Nδ1-H forms, respectively, is a challenging task in NMR spectroscopy. Indeed, their determination by direct observation of the 15N and 13C chemical shifts or the one-bond C-H, 1JCH, Spin-Spin Coupling Constants (SSCC) requires knowledge of the "canonical" limiting values of these forms in which each one is present to the extent of 100%. In particular, at high-pH, an accurate determination of these "canonical" limiting values, at which the tautomeric forms of His coexist, is an elusive problem in NMR spectroscopy. Among different NMR-based approaches to treat this problem, we focus here on the computation, at the DFT level of theory, of the high-pH limiting value for the 1JCH SSCC of the imidazole ring of His. Solvent effects were considered by using the polarizable continuum model approach. The results of this computation suggest, first, that the value of 1JCε1H = 205 ± 1.0 Hz should be adopted as the canonical high-pH limiting value for this SSCC; second, the variation of 1JCε1H SSCC during tautomeric changes is minor, i.e., within ±1Hz; and, finally, the value of 1JCδ2H SSCC upon tautomeric changes is large (15 Hz) indicating that, at high-pH or for non-protonated His at any pH, the tautomeric fractions of the imidazole ring of His can be predicted accurately as a function of the observed value of 1JCδ2H SSCC.

pH-dependent random coil (1)H, (13)C, and (15)N chemical shifts of the ionizable amino acids: a guide for protein pK a measurements

The pK a values and charge states of ionizable residues in polypeptides and proteins are frequently determined via NMR-monitored pH titrations. To aid the interpretation of the resulting titration data, we have measured the pH-dependent chemical shifts of nearly all the (1)H, (13)C, and (15)N nuclei in the seven common ionizable amino acids (X = Asp, Glu, His, Cys, Tyr, Lys, and Arg) within the context of a blocked tripeptide, acetyl-Gly-X-Gly-amide. Alanine amide and N-acetyl alanine were used as models of the N- and C-termini, respectively. Together, this study provides an essentially complete set of pH-dependent intra-residue and nearest-neighbor reference chemical shifts to help guide protein pK a measurements. These data should also facilitate pH-dependent corrections in algorithms used to predict the chemical shifts of random coil polypeptides. In parallel, deuterium isotope shifts for the side chain (15)N nuclei of His, Lys, and Arg in their positively-charged and neutral states were also measured. Along with previously published results for Asp, Glu, Cys, and Tyr, these deuterium isotope shifts can provide complementary experimental evidence for defining the ionization states of protein residues.

Architecture of the catalytic HPN motif is conserved in all E2 conjugating enzymes

E2 conjugating enzymes are the central enzymes in the ubiquitination pathway and are responsible for the transfer of ubiquitin and ubiquitin-like proteins on to target substrates. The secondary structural elements of the catalytic domain of these enzymes is highly conserved, including the sequence conservation of a three-residue HPN (His-Pro-Asn) motif located upstream of the active-site cysteine residue used for ubiquitin conjugation. Despite the vast structural knowledge of E2 enzymes, the catalytic mechanism of these enzymes remains poorly understood, in large part due to variation in the arrangements of the residues in the HPN motif in existing E2 structures. In the present study, we used the E2 enzyme HIP2 to probe the structures of the HPN motif in several other E2 enzymes. A combination of chemical-shift analysis, determination of the histidine protonation states and amide temperature coefficients were used to determine the orientation of the histidine ring and hydrogen-bonding arrangements within the HPN motif. Unlike many three-dimensional structures, we found that a conserved hydrogen bond between the histidine imidazole ring and the asparagine backbone amide proton, a common histidine protonation state, and a common histidine orientation exists for all E2 enzymes examined. These results indicate that the histidine within the HPN motif is orientated to structurally stabilize a tight turn motif in all E2 enzymes and is not orientated to interact with the asparagine side chain as proposed in some mechanisms. These results suggest that a common catalysis mechanism probably exists for all E2 conjugating enzymes to facilitate ubiquitin transfer.

Monomeric structure of the cardioprotective chemokine SDF-1/CXCL12

The chemokine stromal cell-derived factor-1 (SDF-1/CXCL12) directs leukocyte migration, stem cell homing, and cancer metastasis through activation of CXCR4, which is also a coreceptor for T-tropic HIV-1. Recently, SDF-1 was shown to play a protective role after myocardial infarction, and the protein is a candidate for development of new anti-ischemic compounds. SDF-1 is monomeric at nanomolar concentrations but binding partners promote self-association at higher concentrations to form a typical CXC chemokine homodimer. Two NMR structures have been reported for the SDF-1 monomer, but only one matches the conformation observed in a series of dimeric crystal structures. In the other model, the C-terminal helix is tilted at an angle incompatible with SDF-1 dimerization. Using a rat heart explant model for ischemia/reperfusion injury, we found that dimeric SDF-1 exerts no cardioprotective effect, suggesting that the active species is monomeric. To resolve the discrepancy between existing models, we solved the NMR structure of the SDF-1 monomer in different solution conditions. Irrespective of pH and buffer composition, the C-terminal helix remains tilted at an angle with no evidence for the perpendicular arrangement. Furthermore, we find that phospholipid bicelles promote dimerization that necessarily shifts the helix to the perpendicular orientation, yielding dipolar couplings that are incompatible with the NOE distance constraints. We conclude that interactions with the alignment medium biased the previous structure, masking flexibility in the helix position that may be essential for the distinct functional properties of the SDF-1 monomer.

Structural and dynamic determinants of ligand binding in the ternary complex of chicken liver bile acid binding protein with two bile salts revealed by NMR

Bile acids are physiological detergents facilitating absorption, transport, and distribution of lipid-soluble vitamins and dietary fats;they also play a role as signaling molecules that activate nuclear receptors and regulate cholesterol metabolism. Bile acid circulation is mediated by bile acid binding proteins (BABPs), and a detailed structural study of the complex of BABPs with bile salts has become a key issue for the complete understanding of the role of these proteins and their involvement in cholesterol homeostasis. The solution structure here reported describes, at variance with previously determined singly ligated structures, a BABP in a ternary complex with two bile acid molecules, obtained by employing a variety of NMR experiments. Exchange processes between the two bound chenodeoxycholate molecules as well as the more superficial ligand and the free pool have been detected through ROESY and diffusion experiments. Significant backbone flexibility has been observed in regions located at the protein open end, facilitating bile salts exchange. A detailed description of the protonation states and tautomeric forms of histidines strongly supports the view that histidine protonation modulates backbone flexibility and regulates ligand binding. This structure opens the way to targeted site-directed mutagenesis and interaction studies to investigate both binding and nuclear localization mechanisms.

Solution-state molecular structure of apo and oleate-liganded liver fatty acid-binding protein

Rat liver fatty acid-binding protein (LFABP) is distinctive among intracellular lipid-binding proteins (iLBPs): more than one molecule of long-chain fatty acid and a variety of diverse ligands can be bound within its large cavity, and in vitro lipid transfer to model membranes follows a mechanism that is diffusion-controlled rather than mediated by protein-membrane collisions. Because the apoprotein has proven resistant to crystallization, nuclear magnetic resonance spectroscopy offers a unique route to functionally informative comparisons of molecular structure and dynamics for LFABP in free (apo) and liganded (holo) forms. We report herein the solution-state structures determined for apo-LFABP at pH 6.0 and for holoprotein liganded to two oleates at pH 7.0, as well as the structure of the complex including locations of the ligands. 1H, 13C, and 15N resonance assignments revealed very similar types and locations of secondary structural elements for apo- and holo-LFABP as judged from chemical shift indices. The solution-state tertiary structures of the proteins were derived with the CNS/ARIA computational protocol, using distance and angular restraints based on 1H-1H nuclear Overhauser effects (NOEs), hydrogen-bonding networks, 3J(HNHA) coupling constants, intermolecular NOEs, and residual dipolar (NH) couplings. The holo-LFABP solution-state conformation is in substantial agreement with a previously reported X-ray structure [Thompson, J., Winter, N., Terwey, D., Bratt, J., and Banaszak, L. (1997) The crystal structure of the liver fatty acid-binding protein. A complex with two bound oleates, J. Biol. Chem. 272, 7140-7150], including the typical beta-barrel capped by a helix-turn-helix portal. In the solution state, the internally bound oleate has the expected U-shaped conformation and is tethered electrostatically, but the extended portal ligand can adopt a range of conformations based on the computationally refined structures, in contrast to the single conformation observed in the crystal structure. The apo-LFABP also has a well-defined beta-barrel structural motif typical of other members of the iLBP protein family, but the portal region that is thought to facilitate ligand entry and exit exhibits conformational variability and an unusual "open cap" orientation with respect to the barrel. These structural results allow us to propose a model in which ligand binding to LFABP occurs through conformational fluctuations that adjust the helix-turn-helix motif to open or close the top of the beta-barrel, and solvent accessibility to the protein cavity favors diffusion-controlled ligand transport.

Triple-resonance methods for complete resonance assignment of aromatic protons and directly bound heteronuclei in histidine and tryptophan residues

A set of three experiments is described which correlate aromatic resonances of histidine and tryptophan residues with amide resonances in 13C/15N-labelled proteins. Provided that backbone 1H and 15N positions of the sequentially following residues are known, this results in sequence-specific assignment of histidine 1H(delta2)/13C(delta2) and 1H(epsilon1)/13C(epsilon1) as well as tryptophan 1H(delta1)/13C(delta1), 1H(zeta2)/13C(zeta2), 1H(eta2)/13C(eta2), 1H(epsilon3)/13C(epsilon3), 1H(zeta3)/13C(zeta3) and 1H(epsilon1)/15N(epsilon1) chemical shifts. In the reverse situation, these residues can be located in the 1H-(15)N correlation map to facilitate backbone assignments. It may be chosen between selective versions for either of the two amino acid types or simultaneous detection of both with complete discrimination against phenylalanine or tyrosine residues in each case. The linkages between delta-proton/carbon and the remaining aromatic as well as backbone resonances do not rely on through-space interactions, which may be ambiguous, but exclusively employ one-bond scalar couplings for magnetization transfer instead. Knowledge of these aromatic chemical shifts is the prerequisite for the analysis of NOESY spectra, the study of protein-ligand interactions involving histidine and tryptophan residues and the monitoring of imidazole protonation states during pH titrations. The new methods are demonstrated with five different proteins with molecular weights ranging from 11 to 28 kDa.

Unusual heme-histidine bond in the active site of a chaperone

The heme chaperone CcmE is essential for the delivery of heme to c-type cytochromes. It forms an unusual transient, yet covalent, bond between an essential histidine, H130, and heme. We report on the discovery of the chemical structure of this bond solved by NMR, where the heme vinyl is cross-linked at the beta carbon to the Ndelta1 of H130. As this type of heme linkage has not been described previously in any cytochrome or hemoprotein, it represents a novel type of heme-histidine complex.

Quantitative identification of the protonation state of histidines in vitro and in vivo

The C[bond]N coupling constants centered at the C(epsilon 1) and C(delta 2) carbons in histidine residues depend on the protonation state and tautomeric form of the imidazole ring, making them excellent indicators of pH or pK(a), and the ratio of the tautomeric states. In this paper, we demonstrate that the intensity ratios for the C(epsilon 1)-H and C(delta 2)-H cross-peaks measured with a constant time HSQC experiment without and with J(C[bond]N) amplitude modulation are determined by the ratios of the protonated and deprotonated forms and tautomeric states. This allows one to investigate the tautomeric state of histidines as well as their pK(a) in situations where changing the pH value by titration is difficult, for example, for in-cell NMR experiments. We apply this technique to the investigation of the bacterial protein NmerA and determine that the intracellular pH in the Escherichia coli cytoplasm is 7.1 +/- 0.1.

Identification of histidine tautomers in proteins by 2D 1H/13C(delta2) one-bond correlated NMR

If the 13Cdelta2 chemical shift of neutral ("high pH") histidine is >122 ppm, primarily Ndelta1-H tautomer (2) is indicated; if it is <122 ppm, primarily Nepsilon2-H tautomer (1) is indicated. His resonances from the catalytic triad of active serine proteases, for example, are readily distinguished from those of denatured enzyme. The 13Cdelta2 chemical shifts increased by 6.2 ppm for the catalytic histidines in both alpha-lytic protease and subtilisin BPN' in raising the pH from that of imidazolium cation to that of tautomer 2. This tautomer identification method is easy to implement, requiring only bioincorporation of [U-13C] (or the more readily available [U-13C,15N])-histidine. Standard 1H/13C correlation HMQC or HSQC NMR pulse programs then yield the 13Cdelta2 chemical shifts with the benefit of high 1H sensitivity. Because of large one-bond spin-couplings (1JCH approximately 200 Hz), the method should extend to proteins having large 1H and 13C line widths, including very high molecular weights.

Multiplicity-Selective Coherence Transfer Steps for the Design of Amino Acid-Selective Experiments-A Triple-Resonance Experiment Selective for Asn and Gln

A multiplicity-selective coherence transfer step is discussed, that can replace the normal INEPT transfer in triple-resonance experiments. Depending on the pulse sequence in which they are implemented, amino acid-selective experiments will be created. Two experiments selective for Asn and Gln are proposed. Copyright 1998 Academic Press.

The tautomeric state of histidines in myoglobin

1H-15N HMQC spectra were collected on 15N-labeled sperm whale myoglobin (Mb) to determine the tautomeric state of its histidines in the neutral form. By analyzing metaquoMb and metcyanoMb data sets collected at various pH values, cross-peaks were assigned to the imidazole rings and their patterns interpreted. Of the nine histidines not interacting with the heme in sperm whale myoglobin, it was found that seven (His-12, His-48, His-81, His-82, His-113, His-116, and His-119) are predominantly in the N epsilon2H form with varying degrees of contribution from the Ndelta1 H form. The eighth, His-24, is in the Ndelta1H state as expected from the solid state structure. 13C correlation spectra were collected to probe the state of the ninth residue (His-36). Tentative interpretation of the data through comparison with horse Mb suggested that this ring is predominantly in the Ndelta1H state. In addition, signals were observed from the histidines associated with the heme (His-64, His-93, and His-97) in the 1H-15N HMQC spectra of the metcyano form. In several cases, the tautomeric state of the imidazole ring could not be derived from inspection of the solid state structure. It was noted that hydrogen bonding of the ring was not unambiguously reflected in the nitrogen chemical shift. With the experimentally determined tautomeric state composition in solution, it will be possible to broaden the scope of other studies focused on the electrostatic contribution of histidines to the thermodynamic properties of myoglobin.