Through-space Correlation Research Articles

Mapping of the detergent-exposed surface of membrane proteins and peptides by 1H solution NMR in detergent: Application to the gramicidinA ion channel.

The present work evaluates the use of intermolecular polypeptide-detergent 1H through-space connectivities to determine the bilayer exposed-surface and the bilayer topography of membrane polypeptides solubilized in non- deuterated detergents. For this purpose, the membrane peptide gramicidin A, solubilized in non-deuterated sodium dodecylsulfate as its dimeric β6,3 helix channel conformation was used. For this peptide, a high-resolution 3D structure, as well as reasonable assumptions concerning its membrane arrangement, exist. Band-selective 2D NOESY, ROESY and 3D NOESY-NOESY experiments were used to detect detergent-polypeptide through-space correlations in the presence of an excess of the non-deuterated detergent. The observed intermolecular NOEs appear to be strongly temperature- dependent. Based on the known 3D structure of the gramicidin channel, the detergent-polypeptide through-space correlations appear to be selective for 1H located on the hydrophobic surface of gramicidin A with very few contributions from interior 1H or water-exposed 1H. It is suggested that this method can be of general use to evaluate the bilayer-exposed surface and topography of membrane peptides and small proteins.

2D CP/MAS13C Isotropic Chemical Shift Correlation Established by1H Spin Diffusion

A new 2D solid-state CP/MAS13C NMR exchange experiment for through-space isotropic chemical shift correlation is proposed and demonstrated. Through-space correlation is established via a second cross polarization from13C to1H and subsequent1H spin diffusion. A third cross polarization results in the final13C–13C isotropic chemical shift correlation. The1H spin diffusion time is a variable parameter allowing different mean square magnetization displacements to be probed. Experimental results on mixtures of differently13C-labeled alanine and polyethylene indicate that this site-selective 2D technique can be used to characterize domain sizes and proximities over a wide range of length scales (1–200 nm) in solids such as polymers or biological materials.

Broadband Polarization Transfer under Magic-Angle Spinning: Application to Total Through-Space-Correlation NMR Spectroscopy

A pulse sequence is described that leads to a broadband recoupling of the dipolar interaction in magic-angle-spinning solid-state NMR experiments of13C spins. The sequence is based on a combination of rotating frame and laboratory frame transfer periods. The recovered dipolar interaction is only weakly dependent on spectral parameters but is a faithful measure for the internuclear distances. Furthermore, a pure zero-quantum term is recovered (of the type found in static “spin-diffusion” experiments). This makes the pulse sequence particularly suited for incorporation into two-dimensional total through-space correlation experiments that deliver simultaneous information about all dipolar couplings in a single 2D experiment. It is found that the necessary decoupling from abundant protons is best performed in two steps: first, the strong homonuclear couplings between the high-γ spins are averaged by Lee–Goldburg irradiation and, second, the heteronuclear dipolar interaction is averaged by the combined application of an RF field to the low-γ spins and magic-angle sample spinning. Phase-inversion and amplitude attenuation in the rotating frame and refocusing pulses in the laboratory frame part of the pulse sequence are introduced to achieve an optimum chemical-shift offset-independence and for the suppression of unwanted double-quantum transitions. The design principles are explained in detail. Finally, the pulse scheme is applied to total-correlation spectroscopy of a uniformly labeled amino acid. The experimental cross-peak intensities are in qualitative agreement with the known crystal structure of the model compound.

Probing Through-Bond Connectivities and Through-Space Distances in Solids by Magic-Angle-Spinning Nuclear Magnetic Resonance

The application of a new solid-state NMR technique, total through-bond correlation spectroscopy, and of an improved scheme for total through-space correlation spectroscopy to structure determinatio...

Unambiguous NOE assignments in proteins by a combination of through-bond and through-space correlations

Heteronuclear editing has found widespread use in the detection ofproton–proton dipolar interactions in isotopically labelled proteins.However, in cases where both the resonances of protons and directly bound13C or 15N spins of two or more sites aredegenerate, unambiguous assignments are difficult to obtain by conventionalmethods. Here, we present simple extensions of well-known triple-resonancepulse sequences which improve the dispersion of NOESY spectra. In order torecord the chemical shifts of backbone nuclei which allow a resolution ofoverlapping cross peaks, the magnetization is relayed via the scalarcoupling network either before or after the NOE mixing period. The novelpulse sequences are applied to flavodoxin from the sulfate-reducing organismDesulfovibrio vulgaris. A number of previously unassigned NOE interactionsinvolving α-, β- and amide protons can be unequivocallyidentified, suggesting that the accuracy of protein structure determinationcan be improved.

Paramagnetic NMR Spectroscopy of Microperoxidase-8

Microperoxidase-8 (MP8) is the heme octapeptide derived from enzymatic proteolysis of horse-heart cytochrome c. Not only is MP8 a functional peroxidase (it catalyzes the oxidation of various substrates by hydrogen peroxide), it has also served as a useful calibration for the interpretation of the electronic spectroscopic properties of heme proteins. NMR structural characterization of MP8 has been difficult, owing to extensive aggregation at millimolar concentrations. We have obtained well-resolved 1H and 13C NMR spectra of monomeric ferric MP8-CN in mixed aqueous−organic solvent mixtures containing excess cyanide. Most peptide resonances were assigned by through-bond correlations using TOCSY spectra; heme resonances were identified largely by through-space correlations using NOESY spectra. HMQC spectra were interpreted with the aid of proton assignments to identify 13C resonances. Most peptide resonances appear within the diamagnetic region and are very sharp, the exceptions being resonances associated with the His18 residue. Protons on the His18 imidazole ring exhibit very broad resonances, reflecting efficient relaxation. The signals of heme substituents are shifted outside of the diamagnetic envelope, with heme methyl resonances appearing between 10 and 25 ppm. The pattern of MP8-CN heme methyl resonances bears a striking resemblance to those of intact cyanoferric heme c protein derivatives. Large amide-proton/α-proton coupling constants and interresidue NOE contacts were found between residues 14 and 18, while moderate amide-α coupling constants were found between residues 19 and 21. The imidazole group of His18 remains coordinated to the ferric center in MP8; and the pattern of heme methyl resonances confirms that a fixed axial imidazole orientation is preserved in the isolated heme active site. The observed interresidue NOE's and amide−H/Hα proton coupling constants indicate that His18 is part of a rigid loop of five residues anchored to the heme that serves to orient the axial imidazole, while residues 19−21 form a flexible C-terminal domain.

High-resolution mono- and multidimensional magic angle spinning 1H nuclear magnetic resonance of membrane peptides in nondeuterated lipid membranes and H2O

High-speed (14 kHz) solid-state magic angle spinning (MAS) 1H NMR has been applied to several membrane peptides incorporated into nondeuterated dilauroyl or dimyristoylphosphatidylcholine membranes suspended in H2O. It is shown that solvent suppression methods derived from solution NMR, such as presaturation or jump-return, can be used to reduce water resonance, even at relatively high water content. In addition, regioselective excitation of 1H peptide resonances promotes an efficient suppression of lipid resonances, even in cases where these are initially two orders of magnitude more intense. As a consequence, 1H MAS spectra of the peptide low-field region are obtained without interference from water and lipid signals. These display resonances from amide and other exchangeable 1H as well as from aromatic nonexchangeable 1H. The spectral resolution depends on the specific types of resonance and membrane peptide. For small amphiphilic or hydrophobic oligopeptides, resolution of most individual amide resonance is achieved, whereas for the transmembrane peptide gramicidin A, an unresolved amide spectrum is obtained. Partial resolution of aromatic 1H occurs in all cases. Multidimensional 1H-MAS spectra of membrane peptides can also be obtained by using water suppression and regioselective excitation. For gramicidin A, F2-regioselective 2D nuclear Overhauser effect spectroscopy (NOESY) spectra are dominated by intermolecular through-space connectivities between peptide aromatic or formyl 1H and lipid 1H. These appear to be compatible with the known structure and topography of the gramicidin pore. On the other hand, for the amphiphilic peptide leucine-enkephalin, F2-regioselective NOESY spectra mostly display cross-peaks originating from though-space proximities of amide or aromatic 1H with themselves and with aliphatic 1H. F3-regioselective 3D NOESY-NOESY spectra can be used to obtain through-space correlations within aliphatic 1H. Such intrapeptide proximities should allow determination of the conformation of the peptide in membranes. It is suggested that high-speed MAS multidimensional 1H NMR of peptides in nondeuterated membranes and in H2O can be used for studies of both peptide structure and lipid-peptide interactions.

Band-selective 3D NOESY-TOCSY: measurement of through-space correlations between aliphatic protons of membrane peptides and proteins in non-deuterated detergents.

Recently the use of band-selective excitation to obtain 1H 2D NMR spectra of membrane peptides and proteins in non-deuterated detergents has been demonstrated [Seigneuret, M. and Levy, D. (1995) J. Biomol. NMR, 5, 345-352]. A limitation of the method was the inability to obtain through-space correlation between aliphatic protons. Here, a 3D F3-band-selective NOESY-TOCSY experiment is described that allows such correlations to be observed in the presence of an excess of non-deuterated detergent. Application to the measurement of proximities between aliphatic protons of the membrane peptide mastoparan X solubilized in non-deuterated n-octylglucoside is presented. With this additional experiment, it is now possible to obtain the same amount of structural constraints on membrane peptides and protein in non-deuterated detergent as in deuterated detergent and therefore to perform complete structural studies.

A high-resolution 1H NMR approach for structure determination of membrane peptides and proteins in non-deuterated detergent: Application to mastoparan X solubilized in n-octylglucoside

Application of 1H 2D NMR methods to solubilized membrane proteins and peptides has up to now required the use of selectively deuterated detergents. The unavailability of any of the common biochemical detergents in deuterated form has therefore limited to some extent the scope of this approach. Here a 1H NMR method is described which allows structure determination of membrane peptides and small membrane proteins by 1H 2D NMR in any type of non-deuterated detergent. The approach is based on regioselective excitation of protein resonances with DANTE-Z or spin-pinging pulse trains. It is shown that regioselective excitation of the amide-aromatic region of solubilized membrane proteins and peptides leads to an almost complete suppression of the two orders of magnitude higher contribution of the protonated detergent to the 1H NMR spectrum. Consistently TOCSY, COSY and NOESY sequences incorporating such regioselective excitation in the F2 dimension yield protein 1H 2D NMR spectra of quality comparable to those obtained in deuterated detergents. Regioselective TOCSY and NOESY spectra display all through-bond and through-space correlations within amide-aromatic protons and between these protons and aliphatic and alpha-protons. Regioselective COSY spectra provide scalar coupling constants between amide and alpha-protons. Application of the method to the membrane-active peptide mastoparan X, solubilized in n-octylglucoside, yields complete sequence-specific assignments and extensive secondary structure-related spatial proximities and coupling constants.(ABSTRACT TRUNCATED AT 250 WORDS)

Tautomeric states of the active‐site histidines of phosphorylated and unphosphorylated IIIGlc, a signal‐transducing protein from escherichia coli, using two‐dimensional heteronuclear NMR techniques

IIIGlc is an 18.1-kDa signal-transducing phosphocarrier protein of the phosphoenolpyruvate:glycose phosphotransferase system from Escherichia coli. The 1H, 15N, and 13C histidine ring NMR signals of both the phosphorylated and unphosphorylated forms of IIIGlc have been assigned using two-dimensional 1H-15N and 1H-13C heteronuclear multiple-quantum coherence (HMQC) experiments and a two-dimensional 13C-13C-1H correlation spectroscopy via JCC coupling experiment. The data were acquired on uniformly 15N-labeled and uniformly 15N/13C-labeled protein samples. The experiments rely on one-bond and two-bond J couplings that allowed for assignment of the signals without the need for the analysis of through-space (nuclear Overhauser effect spectroscopy) correlations. The 15N and 13C chemical shifts were used to determine that His-75 exists predominantly in the N epsilon 2-H tautomeric state in both the phosphorylated and unphosphorylated forms of IIIGlc, and that His-90 exists primarily in the N delta 1-H state in the unphosphorylated protein. Upon phosphorylation of the N epsilon 2 nitrogen of His-90, the N delta 1 nitrogen remains protonated, resulting in the formation of a charged phospho-His-90 moiety. The 1H, 15N, and 13C signals of the phosphorylated and unphosphorylated proteins showed only minor shifts in the pH range from 6.0 to 9.0. These data indicate that the pK alpha values for both His-75 and His-90 in IIIGlc and His-75 in phospho-IIIGlc are less than 5.0, and that the pK alpha value for phospho-His-90 is greater than 10. The results are presented in relation to previously obtained structural data on IIIGlc, and implications for proposed mechanisms of phosphoryl transfer are discussed.

Structures of Larger Proteins in Solution: Three- and Four-Dimensional Heteronuclear NMR Spectroscopy

Three- and four-dimensional heteronuclear nuclear magnetic resonance (NMR) spectroscopy offers dramatic improvements in spectral resolution by spreading through-bond and through-space correlations in three and four orthogonal frequency axes. Simultaneously, large heteronuclear couplings are exploited to circumvent problems due to the larger linewidths that are associated with increasing molecular weight. These novel experiments have been designed to extend the application of NMR as a method for determining three-dimensional structures of proteins in solution beyond the limits of conventional two-dimensional NMR (approximately 100 residues) to molecules in the 150- to 300-residue range. This potential has recently been confirmed with the determination of the high-resolution NMR structure of a protein greater than 150 residues, namely, interleukin-1 beta.

Overcoming the overlap problem in the assignment of 1H NMR spectra of larger proteins by use of three-dimensional heteronuclear 1H-15N Hartmann-Hahn-multiple quantum coherence and nuclear Overhauser-multiple quantum coherence spectroscopy: application to interleukin 1 beta.

The application of three-dimensional (3D) heteronuclear NMR spectroscopy to the sequential assignment of the 1H NMR spectra of larger proteins is presented, using uniformly labeled (approximately 95%) [15N]interleukin 1 beta, a protein of 153 residues and molecular mass of 17.4 kDa, as an example. The two-dimensional (2D) 600-MHz spectra of interleukin 1 beta are too complex for complete analysis, owing to extensive cross-peak overlap and chemical shift degeneracy. We show that the combined use of 3D 1H-15N Hartmann-Hahn-multiple quantum coherence (HOHAHA-HMQC) and nuclear Overhauser-multiple quantum coherence (NOESY-HMQC) spectroscopy, designed to provide the necessary through-bond and through-space correlations for sequential assignment, provides a practical general-purpose method for resolving ambiguities which severely limit the analysis of conventional 2D NMR spectra. The absence of overlapping cross-peaks in these 3D spectra allows the unambiguous identification of C alpha H(i)-NH(i+1) and NH(i)-NH(i+1) through-space nuclear Overhauser connectivities necessary for connecting a particular C alpha H(i)-NH(i) through-bond correlation with its associated through-space sequential cross-peak The problem of amide NH chemical shift degeneracy in the 1H NMR spectrum is therefore effectively removed, and the assignment procedure simply involves inspecting a series of 2D 1H-1H slices edited by the chemical shift of the directly bonded 15N atom. Connections between residues can be identified almost without any knowledge of the spin system types involved, though this type of information is clearly required for the eventual placement of the connected residues within the primary sequence.