Broadband homonuclear chemical shift correlation at high MAS frequencies: a study of tanh/tan adiabatic RF pulse schemes without $${^{{\bf 1}}\hbox{{\bf H}}}$$ decoupling during mixing

At high magic angle spinning (MAS) frequencies the potential of tanh/tan adiabatic RF pulse schemes for ¹³C chemical shift correlation without ¹H decoupling during mixing has been evaluated. It is shown via numerical simulations that a continuous train of adiabatic ¹³C inversion pulses applied at high RF field strengths leads to efficient broadband heteronuclear decoupling. It is demonstrated that this can be exploited effectively for generating through-bond and through-space, including double-quantum, correlation spectra of biological systems at high magnetic fields and spinning speeds with no ¹H decoupling applied during the mixing period. Experiments carried out on a polycrystalline sample of histidine clearly suggest that an improved signal to noise ratio can be realised by eliminating ¹H decoupling during mixing.     

Design of high-power,broadband 180° pulses and mixing sequences for fast MAS solid state chemical shift correlation NMR spectroscopy

An approach for the design of high-power, broadband 180° pulses and mixing sequences for generating dipolar and scalar coupling mediated ¹³C–¹³C chemical shift correlation spectra of isotopically labelled biological systems at fast magic-angle spinning frequencies without ¹H decoupling during mixing is presented. Considering RF field strengths in the range of 100–120 kHz, as typically available in MAS probes employed at high spinning speeds, and limited B ₁ field inhomogeneities, the Fourier coefficients defining the phase modulation profile of the RF pulses were optimised numerically to obtain broadband inversion and refocussing pulses and mixing sequences. Experimental measurements were carried out to assess the performance characteristics of the mixing sequences reported here.     

Broadband RFDR with adiabatic inversion pulses

With a view to obtain ¹³C chemical shift correlation spectra of uniformly labelled peptides/proteins at high magnetic fields and high magic angle spinning frequencies (_r/2 20 kHz), the efficacy of RFDR with adiabatic inversion pulses has been assessed via numerical simulations and experimental measurements employing different adiabatic pulse phasing schemes, shapes and durations. It is demonstrated that homonuclear dipolar recoupling with superior performance under resonance offset and H ₁ inhomogeneity effects and without strong dependence on the ¹³C chemical shift differences can be achieved with adiabatic pulses. It is shown that ¹³C chemical shift correlation spectra in the entire range of carbon chemical shifts can be obtained efficiently with short adiabatic inversion pulses. In situations where correlation spectra of only the aliphatic region are required, the possibility for minimising the interference between the recoupling and decoupling RF fields with long adiabatic pulses, at low recoupling power levels and without compromising the broadband RFDR characteristics, is also indicated.     

Broadband homonuclear TOCSY with amplitude and phase-modulated RF mixing schemes

We have explored the design of broadband scalar coupling mediated ¹³C–¹³C and cross-relaxation suppressed ¹H–¹H TOCSY sequences employing phase/amplitude modulated inversion pulses. Considering a variety of supercycles, pulsewidths and a RF field strength of 10 kHz, the Fourier coefficients defining the amplitude and phase modulation profiles of the 180° pulses were optimised numerically so as to obtain efficient magnetisation transfer within the desired range of resonance offsets. The coherence transfer characteristics of the mixing schemes were assessed via numerical simulations and experimental measurements and were compared with commonly used sequences based on rectangular RF pulses. The efficacies of the clean ¹H–¹H TOCSY sequences were also examined via numerical simulations for application to weakly oriented systems and sequences with efficient, broadband and clean dipolar transfer characteristics were identified. In general, the amplitude and phase modulated TOCSY sequences presented here have moderately better performance characteristics than the sequences currently employed in biomolecular NMR spectroscopy.     

Solid state NMR of proteins at high MAS frequencies: symmetry-based mixing and simultaneous acquisition of chemical shift correlation spectra

We have carried out chemical shift correlation experiments with symmetry-based mixing sequences at high MAS frequencies and examined different strategies to simultaneously acquire 3D correlation spectra that are commonly required in the structural studies of proteins. The potential of numerically optimised symmetry-based mixing sequences and the simultaneous recording of chemical shift correlation spectra such as: 3D NCAC and 3D NHH with dual receivers, 3D NC??C and 3D C??NCA with sequential ¹³C acquisitions, 3D NHH and 3D NC??H with sequential ¹H acquisitions and 3D CANH and 3D C??NH with broadband ¹³C?C¹⁵N mixing are demonstrated using microcrystalline samples of the ??1 immunoglobulin binding domain of protein G (GB1) and the chicken ??-spectrin SH3 domain.     

Methods for sequential resonance assignment in solid, uniformly 13C, 15N labelled peptides: quantification and application to antamanide

The application of adiabatic polarization-transfer experiments to resonance assignment in solid, uniformly ¹³C-¹⁵N-labelled polypeptides is demonstrated for the cyclic decapeptide antamanide. A homonuclear correlation experiment employing the DREAM sequence for adiabatic dipolar transfer yields a complete assignment of the C and aliphatic side-chain ¹³C resonances to amino acid types. The same information can be obtained from a TOBSY experiment using the recently introduced P9¹ ₁₂ TOBSY sequence, which employs the J couplings as a transfer mechanism. A comparison of the two methods is presented. Except for some aromatic phenylalanine resonances, a complete sequence-specific assignment of the ¹³C and ¹⁵N resonances in antamanide is achieved by a series of selective or broadband adiabatic triple-resonance experiments. Heteronuclear transfer by adiabatic-passage Hartmann–Hahn cross polarization is combined with adiabatic homonuclear transfer by the DREAM and rotational-resonance tickling sequences into two- and three-dimensional experiments. The performance of these experiments is evaluated quantitatively.     

Diversity of mammary tumor viral genes within the genus Mus, the species Mus musculus, and the strain C3H.

Proviral sequences complementary to the C3H mouse mammary tumor virus RNA genome are present in the DNA of early occurring mammary tumors of C3H/HeN mice and are absent from apparently normal C3H/HeN tissues; these sequences are non-germ line transmitted in C3H/HeN mice and have been termed tumor-associated sequences; (W. Drohan et al., J. Virol. 21:986-995, 1977). We report here that tumor-associated sequences are present in the DNA of spontaneous mammary tumors that occur early in the life of several inbred, high-tumor-incidence mouse strains but are absent in mammary tumors that occur later in life in low- and moderate-tumor-incidence strains. These sequences are also absent in apparently normal organs tested from numerous laboratory mouse strains, feral mice, Mus musculus subspecies, and other Mus species. Sequences represented in tumor-associated sequence RNA, however, are present as endogenous provirus in GR mice (at approximately four copies per haploid genome) and in two of five substrains of C3H mice tested (at approximately one copy per haploid genome). The two substrains of C3H mice positive for endogenous tumor-associated sequence provirus were recently (circa 1930) separated from the negative substrains of C3H mice. The results may be explained by the unlikely chance segregation of proviral sequences or by the recent integration of viral genes (within the last few decades). Whereas radioactively labeled mouse mammary tumor virus 60-70S RNA or complementary DNA detected mouse mammary tumor virus-related proviral information in all laboratory mouse strains, feral mice, subspecies of M. musculus, and other species of Mus, the use of tumor-associated sequence RNA clearly revealed the genetic diversity that may exist between different colonies or substrains of "inbred" laboratory mice commonly used in cancer research.     

Unique backbone-water interaction detected in sphingomyelin bilayers with 1H/31P and 1H/13C HETCOR MAS NMR spectroscopy

Two-dimensional ¹H/³¹P dipolar heteronuclear correlation (HETCOR) magic-angle spinning nuclear magnetic resonance (NMR) is used to investigate the correlation of the lipid headgroup with various intra- and intermolecular proton environments. Cross-polarization NMR techniques involving ³¹P have not been previously pursued to a great extent in lipid bilayers due to the long ¹H-³¹P distances and high degree of headgroup mobility that averages the dipolar coupling in the liquid crystalline phase. The results presented herein show that this approach is very promising and yields information not readily available with other experimental methods. Of particular interest is the detection of a unique lipid backbone-water intermolecular interaction in egg sphingomyelin (SM) that is not observed in lipids with glycerol backbones like phosphatidylcholines. This backbone-water interaction in SM is probed when a mixing period allowing magnetization exchange between different ¹H environments via the nuclear Overhauser effect (NOE) is included in the NMR pulse sequence. The molecular information provided by these ¹H/³¹P dipolar HETCOR experiments with NOE mixing differ from those previously obtained by conventional NOE spectroscopy and heteronuclear NOE spectroscopy NMR experiments. In addition, two-dimensional ¹H/¹³C INEPT HETCOR experiments with NOE mixing support the ¹H/³¹P dipolar HETCOR results and confirm the presence of a H₂O environment that has nonvanishing dipolar interactions with the SM backbone.     

Minimizing the effects of radio-frequency heating in multidimensional NMR experiments

Summary Application of radio-frequency power in multidimensional NMR experiments can significantly increase the sample temperature compared to that of the surrounding gas flow. Radio-frequency heating effects become more severe at higher magnetic field strengths and ionic strengths. The effects are particularly noticeable for experiments that utilize ¹H and/or ¹³C isotropic mixing and broadband decoupling. If radio-frequency power is applied during the systematically increasing evolution period t₁, the sample temperature can change with t₁ and thereby cause line-shape distortions. Such distortions are easily avoided by ensuring that the average radio-frequency power remains constant during the entire experiment.     

Pulse design for broadband correlation NMR spectroscopy by multi-rotating frames

We present a method for designing radio-frequency (RF) pulses for broadband or multi-band isotropic mixing at low power, suitable for protein NMR spectroscopy. These mixing pulses are designed analytically, rather than by numerical optimization, by repeatedly constructing new rotating frames of reference. We show how pulse parameters can be chosen frame-by-frame to systematically reduce the effective chemical shift bandwidth, but maintain most of the effective J-coupling strength. The effective Hartmann-Hahn mixing condition is then satisfied in a multi-rotating frame of reference. This design method yields multi-band and broadband mixing pulses at low RF power. In particular, the ratio of RF power to mixing bandwidth for these pulses is lower than for existing mixing pulses, such as DIPSI and FLOPSY. Carbon-carbon TOCSY experiments at low RF power support our theoretical analysis.     

Mouse mammary tumor virus proviral sequences congenital to C3H/Sm mice are differentially hypomethylated in chemically induced, virus-induced, and spontaneous mammary tumors

C3H/Sm mice have lost the exogenous milk-borne mouse mammary tumor virus (MMTV) characteristic of the C3H strain and have a very low (1.5%) incidence of spontaneous mammary tumors, yet they are highly susceptible to mammary carcinogenesis by either chemical carcinogens or infection with the milk-borne virus. We have analyzed the MMTV proviral DNA content of normal tissues and of spontaneous, virus-induced, and chemically induced mammary tumors by restriction endonuclease digestion and Southern blot analysis. Although the results clearly showed additional MMTV sequences in the virus-induced tumor which are not present in normal liver DNA, none of the spontaneous or chemically induced tumors could be shown to contain either newly acquired exogenous or amplified endogenous MMTV sequences. Interestingly, mammary tumors arising in C3H/Sm mice treated simultaneously with infectious MMTV (C3H) and dimethylbenz[a]anthracene (DMBA) possessed new exogenous MMTV DNA even though no quantitative change in tumor production was observed when these mice were compared with C3H/Sm mice treated with DMBA alone (Smith et al., Int. J. Cancer 26:373-379, 1980). Our data indicate that the endogenous MMTV proviral units are extensively methylated in normal tissues, such as livers and normal nonlactating mammary glands. In the absence of MMTV (C3H), we found that in the rare, spontaneously occurring C3H/Sm mammary tumors, certain endogenous MMTV sequences were specifically hypomethylated. Hypomethylation of endogenous MMTV sequences was also noted in the chemically induced mammary tumors, even though radioimmune competition assays for MMTV gp52 and p28 are negative (Smith et al., Int. J. Cancer 27:81-86, 1981). Our results support the conclusion that amplification of endogenous MMTV sequences is not intrinsic to C3H/Sm mouse mammary tumors arising spontaneously or after induction by chemicals. On the other hand, integration of exogenous MMTV DNA into the genome was a constant feature of mammary tumors developing in MMTV (C3H)-infected C3H/Sm mice, even when DMBA was used as the carcinogen. Hypomethylation of some endogenous MMTV sequences is characteristic of C3H/Sm mammary tumors, whether spontaneous or induced by chemicals, which suggests that these sequences are located in actively transcribing regions of the tumor cell genome.     

Robust refocusing of 13C magnetization in multidimensional NMR experiments by adiabatic fast passage pulses

We show that adiabatic fast passage (AFP) pulses are robust refocusing elements of transverse ¹³C magnetization in multidimensional NMR experiments. A pair of identical AFP pulses can refocus selected parts or a complete ¹³ C chemical shift range in ¹³C spectra. In the constant time ¹³C-¹H HSQC, replacement of attenuated rectangular pulses by selective AFP pulses results in a sensitivity enhancement of up to a factor of 1.8. In the 3D CBCA(CO)NH the signal-to-noise ratio is increased by a factor of up to 1.6.     

REDOR: an assessment of the efficacy of dipolar recoupling with adiabatic inversion pulses

A numerical assessment of the efficacy of REDOR recoupling of heteronuclear dipolar interactions employing adiabatic dephasing pulses has been carried out by considering an isolated dipolar coupled spin 1/2 I-S system. At moderate magic angle spinning frequencies in the range of 3–6 kHz and when the CSA of the dephased spins is large, it is shown that efficient broadband heteronuclear dipolar recoupling and reliable distance estimates can be achieved even under conditions where a significant fraction of the rotor period is occupied by the adiabatic pulse. The efficacy of REDOR with adiabatic inversion pulses has been demonstrated experimentally in two model ¹⁵N-¹³C spin systems, (¹³C,¹⁵N) Aib-(¹⁵N) Aib-NH₂ (Aib = -aminoisobutyric acid) and (1-¹³C,¹⁵N) glycine.     

1H, 13C and 199Hg NMR characteristics of new amine-mercuric chloride complexes

Reduction of some N-alkylimines has been achieved with NaBH₄ to give the corresponding secondary amines with high yields (85–95%). These amines were characterized on the bases of their ¹H and ¹³C NMR spectra. The reaction of these amines with mercuric chloride to afford the corresponding complexes was found to occur through a weak dative bond between the nitrogen lone pair of electrons and the mercury atom to form HgCl₂L₂ complexes. The ¹H, ¹³C and ¹⁹⁹Hg NMR chemical shifts have been obtained as well as ¹J(¹³CH) and ²J(¹³CH) coupling constants. Labelling with nitrogen-15 revealed that there is a weak coupling between the nitrogen and the ¹⁹⁹Hg.     

1H, 13C and 15N chemical shift assignments of Na-FAR-1, a helix-rich fatty acid and retinol binding protein of the parasitic nematode Necator americanus

The fatty acid and retinol-binding (FAR) proteins are a family of unusual helix-rich lipid binding proteins found exclusively in nematodes, and are secreted by a range of parasites of humans, animals and plants. Na-FAR-1 is from the parasitic nematode Necator americanus, an intestinal blood-feeding parasite of humans. Sequence-specific ¹H, ¹³C and ¹⁵N resonance assignments have been obtained for the recombinant 170 amino acid protein, using three-dimensional triple-resonance heteronuclear magnetic resonance experiments. Backbone assignments have been obtained for 99.3 % of the non-proline HN/N pairs (146 out of 147). The amide resonance of T45 was not observed, probably due to rapid exchange with solvent water. A total of 96.9 % of backbone resonances were identified, while 97.7 % assignment of amino acid sidechain protons is complete. All Hα(166), Hβ(250) and Hγ(160) and 98.4 % of the Hδ (126 out of 128) atoms were assigned. In addition, 99.4 % Cα (154 out of 155) and 99.3 % Cβ (143 out of 144) resonances have been assigned. No resonances were observed for the NH_n groups of R93 N_εH_ε, arginine, N_η1H₂, N_η2H₂, histidine N_δ1H_δ1, N_ε1H_ε1 and lysine N_ζ3H₃. Na-FAR-1 has a similar overall arrangement of α-helices to Ce-FAR-7 of the free-living Caeorhabditis elegans, but with an extra C-terminal helix.     

Adiabatic TOBSY in rotating solids

A MAS solid state NMR approach for achieving efficient scalar coupling mediated through-bond (13)C chemical shift correlations of the aliphatic carbons in uniformly labelled peptides/proteins is described. The method involves the application of a continuous train of adiabatic inversion pulses, as in the adiabatic TOCSY experiments carried out in solution state NMR studies. While rotor synchronised application of adiabatic inversion pulses leads to dipolar correlations, it is shown here via numerical simulations and experimental measurements that asynchronous application of adiabatic pulses can facilitate the mapping of through-bond connectivities. The method employs a suitable phasing scheme for generating the desired isotropic mixing Hamiltonian and requires moderate (13)C RF field strength only.     

Tailoring broadband inversion pulses for MAS Solid state NMR

A simple approach is demonstrated for designing optimised broadband inversion pulses for MAS solid state NMR studies of biological systems. The method involves a two step numerical optimisation procedure and takes into account experimental requirements such as the pulse length, resonance offset range and extent of H₁ inhomogeneity compensation needed. A simulated annealing protocol is used initially to find appropriate values for the parameters that define the well known tanh/tan adiabatic pulse such that a satisfactory spin inversion is achieved with minimum RF field strength. This information is then used in the subsequent stage of refinement where the RF pulse characteristics are further tailored via a local optimisation procedure without imposing any restrictions on the amplitude and frequency modulation profiles. We demonstrate that this approach constitutes a generally applicable tool for obtaining pulses with good inversion characteristics. At moderate MAS frequencies the efficacy of the method is experimentally demonstrated for generating double-quantum NMR spectra via the zero-quantum dipolar recoupling scheme RFDR.     

Optimization of <Superscript>1</Superscript>H decoupling eliminates sideband artifacts in 3D TROSY-based triple resonance experiments

TROSY-based triple resonance experiments are essential for protein backbone assignment of large biomolecular systems by solution NMR spectroscopy. In a survey of the current Bruker pulse sequence library for TROSY-based experiments we found that several sequences were plagued by artifacts that affect spectral quality and hamper data analysis. Specifically, these experiments produce sidebands in the ¹³C(t ₁) dimension with inverted phase corresponding to ¹H_N resonance frequencies, with approximately 5% intensity of the parent ¹³C crosspeaks. These artifacts originate from the modulation of the ¹H_N frequency onto the resonance frequency of ¹³Cα and/or ¹³Cβ and are due to 180° pulses imperfections used for ¹H decoupling during the ¹³C(t ₁) evolution period. These sidebands can become severe for CA_i, CA_i?1 and/or CB_i, CB_i?1 correlation experiments such as TROSY-HNCACB. Here, we implement three alternative decoupling strategies that suppress these artifacts and, depending on the scheme employed, boost the sensitivity up to 14% on Bruker spectrometers. A class of comparable Agilent/Varian pulse sequences that use WALTZ16 ¹H decoupling can also be improved by this method resulting in up to 60–80% increase in sensitivity.     

Broadband <Superscript>15</Superscript>N–<Superscript>13</Superscript>C dipolar recoupling via symmetry-based RF pulse schemes at high MAS frequencies

An approach for generating efficient RN_n^{n_S, n_k} {\rm{RN}}_{n}^{\nu_{\rm{S}}, {\nu_{\rm{k}}}} symmetry-based dual channel RF pulse schemes for γ-encoded broadband ¹⁵N–¹³C dipolar recoupling at high magic angle spinning frequencies is presented. The method involves the numerical optimisation of the RF phase-modulation profile of the basic “R” element so as to obtain heteronuclear double quantum dipolar recoupling sequences with satisfactory magnetisation transfer characteristics. The basic “R” element was implemented as a sandwich of a small number of short pulses of equal duration with each pulse characterised by a RF phase and amplitude values. The performance characteristics of the sequences were evaluated via numerical simulations and ¹⁵N–¹³C chemical shift correlation experiments. Employing such ¹³C–¹⁵N double-quantum recoupling sequences and the multiple receiver capabilities available in the current generation of NMR spectrometers, the possibility to simultaneously acquire 3D NCC and CNH chemical shift correlation spectra is also demonstrated.