The solution structures of two prophage homologues of the bacteriophage λ Ea8.5 protein reveal a newly discovered hybrid homeodomain/zinc-finger fold.

A cluster of genes in the exoxis region of bacteriophage λ are capable of inhibiting the initiation of DNA synthesis in Escherichia coli. The most indispensible gene in this region is ea8.5. Here, we report the nuclear magnetic resonance structures of two ea8.5 orthologs from enteropathogenic E. coli and Pseudomonas putida prophages. Both proteins are characterized by a fused homeodomain/zinc-finger fold that escaped detection by primary sequence search methods. While these folds are both associated with a nucleic acid binding function, the amino acid composition suggests otherwise, leading to the possibility that Ea8.5 associates with other viral and host proteins.

Lysine methylation strategies for characterizing protein conformations by NMR.

In the presence of formaldehyde and a mild reducing agent, reductive methylation is known to achieve near complete dimethylation of protein amino groups under non-denaturing conditions, in aqueous media. Amino methylation of proteins is employed in mass spectrometric, crystallographic, and NMR studies. Where biosynthetic labeling is prohibitive, amino (13)C-methylation provides an attractive option for monitoring folding, kinetics, protein-protein and protein-DNA interactions by NMR. Here, we demonstrate two improvements over traditional (13)C-reductive methylation schemes: (1) By judicious choice of stoichiometry and pH, ε-aminos can be preferentially monomethylated. Monomethyl tags are less perturbing and generally exhibit improved resolution over dimethyllysines, and (2) By use of deuterated reducing agents and (13)C-formaldehyde, amino groups can be labeled with (13)CH(2)D tags. Use of deutero-(13)C-formaldehyde affords either (13)CHD(2), or (13)CD(3) probes depending on choice of reducing agent. Making use of (13)C-(2)H scalar couplings, we demonstrate a filtering scheme that eliminates natural abundance (13)C signal.

Dioxygen transmembrane distributions and partitioning thermodynamics in lipid bilayers and micelles.

Cellular respiration, mediated by the passive diffusion of oxygen across lipid membranes, is key to many basic cellular processes. In this work, we report the detailed distribution of oxygen across lipid bilayers and examine the thermodynamics of oxygen partitioning via NMR studies of lipids in a small unilamellar vesicle (SUV) morphology. Dissolved oxygen gives rise to paramagnetic chemical shift perturbations and relaxation rate enhancements, both of which report on local oxygen concentration. From SUVs containing the phospholipid sn-2-perdeuterio-1-myristelaidoyl, 2-myristoyl-sn-glycero-3-phosphocholine (MLMPC), an analogue of 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC), we deduced the complete trans-bilayer oxygen distribution by measuring (13)C paramagnetic chemical shifts perturbations for 18 different sites on MLMPC arising from oxygen at a partial pressure of 30 bar. The overall oxygen solubility at 45 °C spans a factor of 7 between the bulk water (23.7 mM) and the bilayer center (170 mM) and is lowest in the vicinity of the phosphocholine headgroup, suggesting that oxygen diffusion across the glycerol backbone should be the rate-limiting step in diffusion-mediated passive transport of oxygen across the lipid bilayer. Lowering of the temperature from 45 to 25 °C gave rise to a slight decrease of the oxygen solubility within the hydrocarbon interior of the membrane. An analysis of the temperature dependence of the oxygen solubility profile, as measured by (1)H paramagnetic relaxation rate enhancements, reveals that oxygen partitioning into the bilayer is entropically favored (ΔS° = 54 ± 3 J K(-1) mol(-1)) and must overcome an enthalpic barrier (ΔH° = 12.0 ± 0.9 kJ mol(-1)).

Optimizing ¹9F 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 T(1) and T(2) relaxation measurements, ¹9F T(2) 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.

Approaches to the assignment of (19)F resonances from 3-fluorophenylalanine labeled calmodulin using solution state NMR.

Traditional single site replacement mutations (in this case, phenylalanine to tyrosine) were compared with methods which exclusively employ (15)N and (19)F-edited two- and three-dimensional NMR experiments for purposes of assigning (19)F NMR resonances from calmodulin (CaM), biosynthetically labeled with 3-fluorophenylalanine (3-FPhe). The global substitution of 3-FPhe for native phenylalanine was tolerated in CaM as evidenced by a comparison of (1)H-(15)N HSQC spectra and calcium binding assays in the presence and absence of 3-FPhe. The (19)F NMR spectrum reveals six resolved resonances, one of which integrates to three 3-FPhe species, making for a total of eight fluorophenylalanines. Single phenylalanine to tyrosine mutants of five phenylalanine positions resulted in (19)F NMR spectra with significant chemical shift perturbations of the remaining resonances, and provided only a single definitive assignment. Although (1)H-(19)F heteronucleclear NOEs proved weak, (19)F-edited (1)H-(1)H NOESY connectivities were relatively easy to establish by making use of the (3)J(FH) coupling between the fluorine nucleus and the adjacent fluorophenylalanine delta proton. (19)F-edited NOESY connectivities between the delta protons and alpha and beta nuclei in addition to (15)N-edited (1)H, (1)H NOESY crosspeaks proved sufficient to assign 4 of 8 (19)F resonances. Controlled cleavage of the protein into two fragments using trypsin, and a repetition of the above 2D and 3D techniques resulted in unambiguous assignments of all 8 (19)F NMR resonances. Our studies suggest that (19)F-edited NOESY NMR spectra are generally adequate for complete assignment without the need to resort to mutational analysis.

Approaches for the measurement of solvent exposure in proteins by 19F 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 (19)F 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, (19)F spin-lattice relaxation rates, (1)H-(19)F 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.

The measurement of immersion depth and topology of membrane proteins by solution state NMR.

An important component of the study of membrane proteins involves the determination of details associated with protein topology - for example, the location of transmembrane residues, specifics of immersion depth, orientation of the protein in the membrane, and extent of solvent exposure for each residue. Solution state NMR is well suited to the determination of immersion depth with the use of paramagnetic additives designed to give rise to depth-specific relaxation effects or chemical shift perturbations. Such additives include spin labels designed to be "anchored" within a given region of the membrane or small freely diffusing paramagnetic species, whose partitioning properties across the water membrane interface create a gradient of paramagnetic effects which correlate with depth. This review highlights the use of oxygen and other small paramagnetic additives in studies of immersion depth and topology of membrane proteins in lipid bilayers and micelles.

19F NMR studies of solvent exposure and peptide binding to an SH3 domain.

(19)F NMR was used to study topological features of the SH3 domain of Fyn tyrosine kinase for both the free protein and a complex formed with a binding peptide. Metafluorinated tyrosine was biosynthetically incorporated into each of 5 residues of the G48M mutant of the SH3 domain (i.e. residues 8, 10, 49 and 54 in addition to a single residue in the linker region to the C-terminal polyhistidine tag). Distinct (19)F NMR resonances were observed and subsequently assigned after separately introducing single phenylalanine mutations. (19)F NMR chemical shifts were dependent on protein concentration above 0.6 mM, suggestive of dimerization via the binding site in the vicinity of the tyrosine side chains. (19)F NMR spectra of Fyn SH3 were also obtained as a function of concentration of a small peptide (2-hydroxynicotinic-NH)-Arg-Ala-Leu-Pro-Pro-Leu-Pro-diaminopropionic acid -NH(2), known to interact with the canonical polyproline II (PPII) helix binding site of the SH3 domain. Based on the (19)F chemical shifts of Tyr8, Tyr49, and Tyr54, as a function of peptide concentration, an equilibrium dissociation constant of 18 +/- 4 microM was obtained. Analysis of the line widths suggested an average exchange rate, k(ex), associated with the peptide-protein two-site exchange, of 5200 +/- 600 s(-1) at a peptide concentration where 96% of the FynSH3 protein was assumed to be bound. The extent of solvent exposure of the fluorine labels was studied by a combination of solvent isotope shifts and paramagnetic effects from dissolved oxygen. Tyr54, Tyr49, Tyr10, and Tyr8, in addition to the Tyr on the C-terminal tag, appear to be fully exposed to the solvent at the metafluoro position in the absence of binding peptide. Tyr54 and, to some extent, Tyr10 become protected from the solvent in the peptide bound state, consistent with known structural data on SH3-domain peptide complexes. These results show the potential utility of (19)F-metafluorotyrosine to probe protein-protein interactions in conjunction with paramagnetic contrast agents.

Nuclear magnetic resonance structures of the zinc finger domain of human DNA polymerase-alpha.

The carboxy terminus of the human DNA polymerase-alpha contains a zinc finger motif. Three-dimensional structures of this motif containing 38 amino acid residues, W L I C E E P T C R N R T R H L P L Q F S R T G P L C P A C M K A T L Q P E, were determined by nuclear magnetic resonance (NMR) spectroscopy. The structures reveal an alpha-helix-like domain at the amino terminus, extending 13 residues from L2 through H15 with an interruption at the sixth residue. The helix region is followed by three turns (H15-L18, T23-L26 and L26-A29), all of which involve proline. The first turn appears to be type III, judging by the dihedral angles. The second and third turns appear to be atypical. A second, shorter helix is formed at the carboxy terminus extending from C30 through L35. A fourth type III turn starting at L35 was also observed in the structure. Proline serves as the third residue of all the turns. Four cysteine residues, two located at the beginning of the helix at the N-terminus and two at the carboxy end, are coordinated to Zn(II), facilitating the formation of a loop. One of the cysteines at the carboxy terminus is part of the atypical turn, while the other is the part of the short helix. These structural features are consistent with the circular dichroism (CD) measurements which indicate the presence of 45% helix, 11% beta turns and 19% non-ordered secondary structures. The zinc finger motif described here is different from those observed for C(4), C(2)H(2), and C(2)HC modules reported in the literature. In particular, polymerase-alpha structures exhibit helix-turn-helix motif while most zinc finger proteins show anti-parallel sheet and helix. Several residues capable of binding DNA, T, R, N, and H are located in the helical region. These structural features imply that the zinc finger motif is most likely involved in binding DNA prior to replication, presumably through the helical region. These results are discussed in the context of other eukaryotic and prokaryotic DNA polymerases belonging to the polymerase B family.

Discovery and biological evaluation of a new family of potent modulators of multidrug resistance: reversal of multidrug resistance of mouse lymphoma cells by new natural jatrophane diterpenoids isolated from Euphorbia species.

The effects of 15 jatrophane diterpene polyesters (1-3 and 5-16) isolated from lipophilic extracts of Euphorbia serrulata, E. esula, E. salicifolia, and E. peplus (Euphorbiaceae) on the reversion of multidrug resistance of mouse lymphoma cells were examined. The structures of five new compounds (1-5) were elucidated by spectroscopic methods, including HRFABMS, ESIMS, (1)H-(1)H homonuclear and (1)H-(13)C heteronuclear correlations, long-range correlation spectra, and NOESY experiments. The stereochemistry and absolute configuration of one compound (3) were determined by X-ray crystallography. The structure-activity relationship is discussed.

Unwinding of DNA polymerases by the antitumor drug, cis-diamminedichloroplatinum(II).

The helix-turn-helix motifs of the DNA binding domains of human polymerase-alpha and polymerase-kappa are dramatically perturbed upon binding to cisplatin with concomitant release of zinc.

Oxygen as a paramagnetic probe of clustering and solvent exposure in folded and unfolded states of an SH3 domain.

The N-terminal SH3 domain of the Drosophila modular protein Drk undergoes slow exchange between a folded (Fexch) and highly populated unfolded (Uexch) state under nondenaturing buffer conditions, enabling both Fexch and Uexch states to be simultaneously monitored. The addition of dissolved oxygen, equilibrated to a partial pressure of either 30 atm or 60 atm, provides the means to study solvent exposure with atomic resolution via 13C NMR paramagnetic shifts in 1H,13C HSQC (heteronuclear single quantum coherence) spectra. Absolute differences in these paramagnetic shifts between the Fexch and Uexch states allow the discrimination of regions of the protein which undergo change in solvent exposure upon unfolding. Contact with dissolved oxygen for both the Fexch and Uexch states could also be assessed through 13C paramagnetic shifts which were normalized based on the corresponding paramagnetic shifts seen in the free amino acids. In the Fexch state, the 13C nuclei belonging to the hydrophobic core of the protein exhibited very weak normalized paramagnetic shifts while those with greater solvent accessible surface area exhibited significantly larger normalized shifts. The Uexch state displayed less varied 13C paramagnetic shifts although distinct regions of protection from solvent exposure could be identified by a lack of such shifts. These regions, which included Phe9, Thr12, Ala13, Lys21, Thr22, Ile24, Ile27, and Arg38, overlapped with those found to have residual nativelike and non-native structures in previous studies and in some cases provided novel information. Thus, the paramagnetic shifts from dissolved oxygen are highly useful in the study of a transient structure or clustering in disordered systems, where conventional NMR measurements (couplings, chemical shift deviations from random coil values, and NOEs) may give little information.

Current applications of bicelles in NMR studies of membrane-associated amphiphiles and proteins.

This review covers current trends in studies of membrane amphiphiles and membrane proteins using both fast tumbling bicelles and magnetically aligned bicelle media for both solution state and solid state NMR. The fast tumbling bicelles provide a versatile biologically mimetic membrane model, which in many cases is preferable to micelles, both because of the range of lipids and amphiphiles that may be combined and because radius of curvature effects and strain effects common with micelles may be avoided. Drug and small molecule binding and partitioning studies should benefit from their application in fast tumbling bicelles, tailored to mimic specific membranes. A wide range of topology and immersion depth studies have been shown to be effective in fast tumbling bicelles, while residual dipolar couplings add another dimension to structure refinement possibilities, particularly for situations in which the peptide is uniformly labeled with 15N and 13C. Solid state NMR studies of polytopic transmembrane proteins demonstrate that it is possible to express, purify, and reconstitute membrane proteins, ranging in size from single transmembrane domains to seven-transmembrane GPCRs, into bicelles. The line widths and quality of the resulting 15NH dipole-15N chemical shift spectra demonstrate that there are no insurmountable obstacles to the study of large membrane proteins in magnetically aligned media.

Tryptophan solvent exposure in folded and unfolded states of an SH3 domain by 19F and 1H NMR.

The isolated N-terminal SH3 domain of the Drosophila signal transduction protein Drk (drkN SH3) is a useful model for the study of residual structure and fluctuating structure in disordered proteins since it exists in slow exchange between a folded (Fexch) and compact unfolded (Uexch) state in roughly equal proportions under nondenaturing conditions. The single tryptophan residue, Trp36, is believed to play a key role in forming a non-native hydrophobic cluster in the Uexch state, with a number of long-range nuclear Overhauser contacts (NOEs) observed primarily to the indole proton. Substitution of Trp36 for 5-fluoro-Trp36 resulted in a substantial shift in the equilibrium to favor the Fexch state. A variety of 19F NMR measurements were performed to investigate the degree of solvent exposure and hydrophobicity associated with the 5-fluoro position in both the Fexch and Uexch states. Ambient T1 measurements and H2O/D2O solvent isotope effects indicated extensive protein contacts to the 5-fluoro position in the Fexch state and greater solvent exposure in the Uexch state. This was corroborated by the measurements of paramagnetic effects (chemical shift perturbations and T1 relaxation enhancement) from dissolved oxygen at a partial pressure of 20 atm. In contrast, paramagnetic effects from dissolved oxygen revealed less solvent exposure to the indole proton of Trp36 in the Uexch state than that observed for the Fexch state, consistent with the model in which Trp36 indole belongs to a non-native cluster. Thus, although the Uexch state may be described as a dynamically interconverting ensemble of conformers, there appears to be significant asymmetry in the environment of the indole group and the six-membered ring or backbone of Trp36. This implied lack of averaging of a side chain position is in contrast to the general view of fluctuating side chains within disordered states.

Topology of an outer-membrane enzyme: Measuring oxygen and water contacts in solution NMR studies of PagP.

The topology of the bacterial outer-membrane enzyme, PagP, in dodecylphosphocholine micelles was studied by solution NMR using oxygen and water contacts as probes of hydrophobicity and topology. The effects of oxygen on amide protons were measured at an oxygen partial pressure of 20 atm through the paramagnetic contribution to the relaxation rates associated with the decay of two-spin order. A significant gradation of paramagnetic rates was observed for backbone amides belonging to the transmembrane residues. These rates were observed to depend on immersion depth, local hydrophobicity, and steric effects. Variations in the paramagnetic relaxation rates due to local hydrophobicity or steric effects could be, to some extent, averaged out by considering an azimuthally averaged quantity. This averaged paramagnetic rate was found to have a distinct maximum exactly in the middle of the transmembrane domain of PagP, assuming the immersion depth axis is tilted by 25 degrees with respect to the barrel axis. Contact between the protein surface and water was assessed by measuring the amide decay rates during water saturation. The comparison of local contrast effects from both water and oxygen allows one to distinguish among steric effects, local hydrophobicity, and immersion depth. For example, the absence of contrast effects from either water or oxygen at the periplasmic end of beta-strands B and C was consistent with protection effects arising from the association with the N-terminal alpha-helix. A parameter defined by the natural logarithm of the ratio of the normalized paramagnetic relaxation rate to the normalized amide decay rate under water saturation was found to correlate with immersion depth of the corresponding backbone amide nuclei. The results suggest that the oxygen/water contrast experiments give direct information regarding membrane protein topology and surface hydrophobicities, thereby complementing existing NMR structure studies and ESR spin-labeling studies.

A combined NMR and molecular dynamics study of the transmembrane solubility and diffusion rate profile of dioxygen in lipid bilayers.

The transmembrane profile of oxygen solubility and diffusivity in a lipid bilayer was assessed by (13)C NMR of the resident lipids (sn-2-perdeuterio-1-myristelaidoyl-2-myristoyl-sn-glycero-3-phosphocholine) in combination with molecular dynamics (MD) simulations. At an oxygen partial pressure of 50 atm, distinct chemical shift perturbations of a paramagnetic origin were observed, spanning a factor of 3.2 within the sn-1 chain and an overall factor of 10 from the headgroup to the hydrophobic interior. The distinguishing feature of the (13)C NMR shift perturbation measurements, in comparison to ESR and fluorescence quenching measurements, is that the local accessibility of oxygen is achieved for nearly all carbon atoms in a single experiment with atomic resolution and without the use of a probe molecule. MD simulations of an oxygenated and hydrated lipid bilayer provided an immersion depth distribution of all carbon nuclei, in addition to the distribution of oxygen concentration and diffusivity with immersion depth. All oxygen-induced (13)C NMR chemical shift perturbations could be reasonably approximated by simply accounting for the MD-derived immersion depth distribution of oxygen in the bilayer, appropriately averaged according to the immersion depth distribution of the (13)C nuclei. Second-order effects in the paramagnetic shift are attributed to the collisionally accessible solid angle or to the propensity of the valence electrons in the vicinity of a given nuclear spin to be polarized or delocalized by oxygen. A method is presented to measure such effects. The excellent agreement between MD and NMR provides an important cross-validation of the two techniques.

Probing the transition state ensemble of a protein folding reaction by pressure-dependent NMR relaxation dispersion.

The F61A/A90G mutant of a redesigned form of apocytochrome b562 folds by an apparent two-state mechanism. We have used the pressure dependence of 15N NMR relaxation dispersion rate profiles to study the changes in volumetric parameters that accompany the folding reaction of this protein at 45 degrees C. The experiments were performed under conditions where the folding/unfolding equilibrium could be studied at each pressure without addition of denaturants. The exquisite sensitivity of the methodology to small changes in folding/unfolding rates facilitated the use of relatively low-pressure values (between 1 and 270 bar) so that pressure-induced changes to the unfolded state ensemble could be minimized. A volume change for unfolding of -81 mL/mol is measured (at 1 bar), a factor of 1.4 larger (in absolute value) than the volume difference between the transition state ensemble (TSE) and the unfolded state. Notably, the changes in the free energy difference between folded and unfolded states and in the activation free energy for folding were not linear with pressure. Thus, the difference in the isothermal compressibility upon unfolding (-0.11 mL mol(-1) bar(-1)) and, for the first time, the compressibility of the TSE relative to the unfolded state (0.15 mL mol(-1) bar(-1)) could be calculated. The results argue for a TSE that is collapsed but loosely packed relative to the folded state and significantly hydrated, suggesting that the release of water occurs after the rate-limiting step in protein folding. The notion of a collapsed and hydrated TSE is consistent with expectations based on earlier temperature-dependent folding studies, showing that the barrier to folding at 45 degrees C is entropic (Choy, W. Y.; Zhou, Z.; Bai, Y.; Kay, L. E. J. Am. Chem. Soc. 2005, 127, 5066-5072).