A new strategy for backbone resonance assignment in large proteins using a MQ-HACACO experiment

A new strategy of backbone resonance assignment is proposed based on a combination of the most sensitive TROSY-type triple resonance experiments such as TROSY-HNCA and TROSY-HNCO with a new 3D multiple-quantum HACACO experiment. The favourable relaxation properties of the multiple-quantum coherences and signal detection using the ¹³C antiphase coherences optimize the performance of the proposed experiment for application to larger proteins. In addition to the ¹H^N, ¹⁵N,¹³C and ¹³C chemical shifts the 3D multiple-quantum HACACO experiment provides assignment for the ¹H resonances in constrast to previously proposed experiments for large proteins. The strategy is demonstrated with the 44 kDa uniformly ¹⁵N,¹³C-labeled and fractionally 35% deuterated trimeric B. subtilis Chorismate Mutase measured at 20°C and 9°C. Measurements at the lower temperature indicate that the new strategy can be applied to even larger proteins with molecular weights up to 80 kDa.     

Novel 2D and 3D multiple-quantum bi-directional HCNCH experiments for the correlation of ribose and base protons/carbons in 13C/15N labeled RNA

Multiple-quantum 2D and 3D bi-directional HCNCH experiments are presented for the correlation of base and ribose protons/carbons in ¹³C/¹⁵N labeled HIV-1 TAR RNA. In both 2D and 3D experiments, the magnetization of H1 is transferred to H6/H8 and H1 through H1-C1-N1/9-C6/8-H6/8 and H1-C1-N1/9-C1-H1 pathways, and the magnetization of H6/8 is transferred to H1 and H6/8 through H6/8-C6/8-N1/9-C1-H1 and H6/8-C6/8-N1/9-C6/8-H6/8 pathways. Chemical shifts of four different nuclei (H1, C1, C6/8 and H6/8) are sampled in the 2D experiment. The correlation of base and ribose protons/carbons is established by the rectangular arrangement of crossover and out-and-back peaks in the proton/carbon correlated spectrum. The rectangular connections can be further resolved using the nitrogen dimension in a ¹H/¹³C/¹⁵N 3D experiment. Furthermore, by taking advantage of the well separated chemical shifts of N1 (pyrimidine) and N9 (purine), the 2D spectrum can be simplified into two sub-spectra based on their base type. Both experiments were tested on a ¹³C/¹⁵N labeled 27-mer HIV-1 TAR RNA containing a UUCG hairpin loop.     

Transverse relaxation optimised spin-state selective NMR experiments for measurement of residual dipolar couplings

Three transverse relaxation optimised NMR experiments (TROSY) for the measurement of scalar and dipolar couplings suitable for proteins dissolved in aqueous iso- and anisotropic solutions are described. The triple-spin-state-selective experiments yield couplings between ¹H^N-¹³C, ¹⁵N-¹³C, ¹H^N-¹³C _i–1, ¹⁵N-¹³C _i–1, ¹H^N-¹³C_i–1, ¹⁵N-¹³C_i–1, and ¹³C_i–1-¹³C _i–1 without introducing nonessential spectral crowding compared with an ordinary two-dimensional ¹⁵N-¹H correlation spectrum and without requiring explicit knowledge of carbon assignments. This set of /-J-TROSY experiments is most useful for perdeuterated proteins in studies of structure–activity relationships by NMR to observe, in addition to epitopes for ligands, also conformational changes induced by binding of ligands.     

Novel projected 4D triple resonance experiments for polypeptide backbone chemical shift assignment

Here we present a novel suite of projected 4D triple-resonance NMR experiments for efficient sequential assignment of polypeptide backbone chemical shifts in ¹³C/¹⁵N doubly labeled proteins. In the 3D HNN[CAHA] and 3D HNN(CO)[CAHA] experiments, the ¹³C and ¹H chemical shifts evolve in a common dimension and are simultaneously detected in quadrature. These experiments are particularly useful for the assignment of glycine-rich polypeptide segments. Appropriate setting of the ¹H radiofrequency carrier allows one to place cross peaks correlating either backbone ¹⁵N/¹H^N/¹³C or ¹⁵N/¹H^N/¹H chemical shifts in separate spectral regions. Hence, peak overlap is not increased when compared with the conventional 3D HNNCA and HNN(CA)HA. 3D HNN[CAHA] and 3D HNN(CO)[CAHA] are complemented by 3D reduced-dimensionality (RD) HNN COCA and HNN CACO, where ¹³C and ¹³C chemical shifts evolve in a common dimension. The ¹³C shift is detected in quadrature, which yields peak pairs encoding the ¹³C chemical shift in an in-phase splitting. This suite of four experiments promises to be of value for automated high-throughput NMR structure determination in structural genomics, where the requirement to independently sample many indirect dimensions in a large number of NMR experiments may prevent one from accurately adjusting NMR measurement times to spectrometer sensitivity.     

1H-filtered correlation experiments for assignment and determination of coupling constants in backbone labelled proteins

The implementation of [¹³C,¹³C,¹⁵N,²H] labelled amino acids into proteins allows the acquisition of high resolution triple resonance experiments. We present for the first time resonance assignments facilitated by this new labelling strategy. The absence of ¹J_C,C couplings enables us to measure ¹J_C,C scalar and ¹D_C,C residual dipolar coupling constants using modified HNCA experiments which do not suffer from sensitivity losses characteristic for ¹³C constant time experiments.     

Unambiguous through-bond sugar-to-base correlations for purines in 13C, 15N-labeled nucleic acids: The HsCsNb,HsCs(N)bCb,and HbNbCb experiments

Summary A set of three 3D (¹H, ¹³C, ¹⁵N) triple-resonance correlation experiments has been designed to provide H1-H8 intraresidue sugar-to-base correlations in purines in an unambiguous and efficient manner. Together, the H_sC_sN_b, H_sC_s(N)_bC_b, and H_bN_bC_b experiments correlate the H1 sugar proton to the H8 proton of the attached base by means of the {H1, C1, N9, C8, H8} heteronuclear scalar coupling network. The assignment strategy presented here allows for unambiguous H1-H8 intraresidue correlations, provided that no two purines have both the same H1 and C1 chemical shifts and the same C8 and N9 chemical shifts. These experiments have yielded H1-H8 intraresidue sugar-to-base correlations for all five guanosines in the [¹³C, ¹⁵N] isotopically labeled RNA duplex r(GGCGCUUGCGUC)₂.     

Preparation and heteronuclear 2D NMR spectroscopy of a DNA dodecamer containing a thymidine residue with a uniformly 13C-labeled deoxyribose ring

Summary [¹³C₅]-2-Deoxy-d-ribose, synthesized from [¹³C₆]-d-glucose (98% ¹³C), was coupled with thymine to give [1,2,3,4,5-¹³C₅]-thymidine (T) in an 18% overall yield. The thymidine was converted to the 3-phosphoramidite derivative and was then incorporated into a dodecamer 5-d(CGCGAATTCGCG)-3 by solid-phase DNA synthesis. Preparation of 0.24 mole of the labeled dodecamer, which is sufficient for a single NMR sample, consumed only 25 mg of glucose. By virtue of the ¹³C labels, all of the ¹H-¹H vicinal coupling constants in the sugar moieties were accurately determined by HCCH-E.COSY.     

Measurement of the protein backbone dihedral angle φ based on quantification of remote CSA/DD interference in inter-residue 13C′(i − 1)-13Cα(i) multiple-quantum coherences

A novel triple-resonance NMR method is presented for the measurement of the protein backbone dihedral angle based on differential multiple-quantum relaxation induced by relaxation interference between ¹H(i)-¹³C(i) dipolar and ¹³C(i–1) (carbonyl) chemical shift anisotropy mechanisms. The method employs a simultaneous transfer of ¹⁵N magnetization to the inter- and intra-residue ¹³C carbons as well as the directly attached carbonyl carbon ¹³C. Results obtained on ¹³C,¹⁵N-labeled ubiquitin demonstrate the potential of the method.     

The catalysis of nucleotide polymerization by compounds of divalent lead

Summary Soluble lead salts and a number of lead-containing minerals catalyze the formation of oligonucleotides from nucleoside 5-phosphorimidazolides. The effectiveness of lead compounds correlates strongly with their solubility. Under optimal conditions we were able to obtain 18% of pentamer and higher oligomers from ImpA. Reactions involving ImpU gave smaller yields.Abbreviations A adenosine - U uridine - Im imidazole - MeIm 1-methyl-imidazole - EDTA ethylenediaminetetraacetic acid - pA adenosine 5-phosphate - pU uridine 5-phosphate - Ap adenosine cyclic 2:3-phosphate - ATP adenosine 5-triphosphate - AppA P₁,P₂-diadenosine 5-diphosphate - pNp (N = A,U) nucleotide 2(3), 5-diphosphate - ImpA adenosine 5-phosphoreimidazolide - ImpU uridine 5-phosphorimidazolide - A ²pA adenylyl-[25]-adenosine - A ³pA adenylyl-[35]-adenosine - pA ²pA 5-phospho-adenylyl-[25]-adenosine - pA ³pA 5-phospho-adenylyl-[35]-adenosine - pUpU 5-phospho-uridylyl-uridine - pApU 5-phospho-adenylyl-uridine - pUpA 5-phospho-uridylyladenine - (pA)n (n, 2,3,4,) oligoadenylates with 5 terminal phosphate - ImpApA 5-phosphorimidazolide of adenylyl adenosine - (pA) ₅₊ pentamer and higher oligoadenylates with 5 terminal phosphate - (Ap)nA (n = 2,3,4) oligoadenylates without terminal phosphates In the following we do not specify the nature of the internucleotide linkageIn the following we do not specify the nature of the internucleotide linkage     

Heteronuclear relayed E.COSY applied to the determination of accurate 3J(HN,C′) and 3J(Hβ,C′) coupling constants in Desulfovibrio vulgaris flavodoxin

Summary A simple constant-time 3D heteronuclear NMR pulse sequence has been developed to quantitatively determine the heteronuclear three-bond couplings ³J(H^N,C) and ³J(H,C) in uniformly ¹³C-enriched proteins. The protocols for measuring accurate coupling constants are based on ¹H,¹³C-heteronuclear relayed E.COSY [Schmidt, J.M., Ernst, R.R., Aimoto, S. and Kainosho, M. (1995) J. Biomol. NMR, 6, 95–105] in combination with numerical least-squares spectrum evaluation. Accurate coupling constants are extracted from 2D spectrum projections using 2D multiplet simulation. Confidence intervals for the obtained three-bond coupling constants are calculated from F-statistics. The three-bond couplings are relevant to the determination of and X ₁ dihedral-angle conformations in the amino acid backbone and side chain. The methods are demonstrated on the recombinant ¹³C, ¹⁵N-doubly enriched 147-amino acid protein Desulfovibrio vulgaris flavodoxin with bound flavin mononucleotide in its oxidized form. In total, 109 ³J(H^N,C) and 100 ³J(H,C) coupling constants are obtained from a single spectrum.Abbreviations ANOVA analysis of variances - COSY correlated spectroscopy - E.COSY exclusive correlation spectroscopy - FMN flavin mononucleotide - HMQC heteronuclear multiple-quantum coherence - HSQC heteronuclear single-quantum coherence     

Application of H(N)CA,CO-E.COSY experiments for calibrating the φ angular dependences of vicinal couplings J(C′i−1,Hi α), J(C′i−1,Ci β) and J(C′i−1,C′i) in proteins

A triple-resonance NMR technique suitable for the determination ofcarbonyl-related couplings in polypeptide systems is introduced. Theapplication of three novel pulse sequences to uniformly¹³C/¹⁵N-enriched proteins yields E.COSY-likemultiplet patterns exhibiting either one of the³J(C_i–1,H_i ), ³J(C_i–1,C_i ) and³J(C_i–1,C_i)coupling constants in the indirectly detected ¹³Cdimension, depending on the passive spin selected. The experiments aredemonstrated with oxidized flavodoxin from Desulfovibrio vulgaris. On thebasis of the J-values measured and the backbone -angles derived from ahigh-resolution X-ray structure of the protein, the three associated Karplusequations were reparametrized. The root-mean-square differences between theexperimental coupling constants and those predicted by the optimized Karpluscurves are 0.41, 0.33 and 0.32 Hz for³J(C_i–1,H_i ),³J(C_i–1,C_i ) and³J(C_i–1,C_i),respectively. The results are compared with the Karplus parameters previouslypublished for the same couplings.     

Triple-resonance NOESY-based experiments with improved spectral resolution: Applications to structural characterization of unfolded, partially folded and folded proteins

NMR-based structural studies of macromolecules focus to a large extent on the establishmentof interproton distances within the molecule based on the nuclear Overhauser effect (NOE).Despite the improvements in resolution resulting from multidimensional NMR experiments,the detailed characterization of disordered states of proteins or highly overlapped regions offolded molecules using current NMR methods remains challenging. A suite of triple-resonanceNOESY-type pulse schemes is presented which require uniform 15N and 13C labeling andmake use of the chemical shift dispersion of backbone 15N and 13C (carbonyl)resonances to increase the spectral resolution. In particular, for the case of partially folded andunfolded proteins, the experiments exploit the fact that the dispersion of 15N and 13Cresonances is comparable to that observed in folded states. Ambiguities that arise in theassignment of NOEs as a result of the severe chemical shift degeneracy in 1H and aliphatic13C nuclei are resolved, therefore, by recording the chemical shifts of 15N or 13Ceither before or after the NOE mixing period. Applications of these methods to the study ofthe unfolded state of the N-terminal SH3 domain of drk (drkN SH3) and a partially foldedlarge fragment of staphylococcal nuclease (SNase), 131, are presented. Inaddition, an application to folded SNase in complex with the ligands thymidine3,5-bisphosphate (pdTp) and Ca2+ is illustrated which allows the assignmentof NOEs between degenerate H protons or protons resonating close to water.     

High-resolution 3D HNCOCA experiment applied to a 28 kDa paramagnetic protein

Summary A new triple-resonance 3D HNCOCA pulse scheme is presented, designed to identify the backbone nuclei (H^N, N, CO, C) of doubly labelled proteins. The two carbon frequencies are labelled along the same indirect dimension and the corresponding dwell times can be independently scaled in order to account for the relaxation properties and chemical shift ranges of the CO and C. If one takes advantage of the symmetry properties of the spectra in the course of the peak picking, this 3D scheme has the same sensitivity as the 4D experiment, but with an improved resolution. The sequence is illustrated on a 0.5 mM sample of Rhodobacter capsulatus cytochrome c a homodimeric paramagnetic protein of 2×14 kDa. A resonance assignment strategy, based on a low-concentration ¹³C/¹⁵N-labelled sample and a more concentrated ¹⁵N-labelled sample, is proposed for proteins where the expression system shows a limited efficiency.     

Measurement of two- and three-bond 13C−1H J couplings to the Cδ carbons of leucine residues in staphylococcal nuclease

Summary A new ¹H-detected 3D NMR experiment is described that permits quantitative measurement of two- and three-bond ¹³C–¹H couplings in proteins with selectively ¹³C-enriched methyl sites. The method is demonstrated for staphylococcal nuclease selectively [5,5 ¹³C]-labeled in all 11 leucine positions and ligated with thymidine 3,5-biphosphate and Ca²⁺. Two- and three-bond ¹³C methyl-proton couplings are reported and, together with the measured three-bond J_CC in uniformly ¹³C-enriched staphylococcal nuclease, the ²- and the stereospecific assignments of the C methyl group with respect to the prochiral -protons were determined. The same residues that were previously found to have high degrees of internal mobility on the basis of ¹³C relaxation times have measured coupling constants that are indicative of motional averaging.     

Detection of C′,C<Superscript>α</Superscript> correlations in proteins using a new time- and sensitivity-optimal experiment

Sensitivity- and time-optimal experiment, called COCAINE (CO-CA In- and aNtiphase spectra with sensitivity Enhancement), is proposed to correlate chemical shifts of ¹³C and ¹³C spins in proteins. A comparison of the sensitivity and duration of the experiment with the corresponding theoretical unitary bounds shows that the COCAINE experiment achieves maximum possible transfer efficiency in the shortest possible time, and in this sense the sequence is optimal. Compared to the standard HSQC, the COCAINE experiment delivers a 2.7-fold gain in sensitivity. This newly proposed experiment can be used for assignment of backbone resonances in large deuterated proteins effectively bridging ¹³C and ¹³C resonances in adjacent amino acids. Due to the spin-state selection employed, the COCAINE experiment can also be used for efficient measurements of one-bond couplings (e.g. scalar and residual dipolar couplings) in any two-spin system (e.g. the N/H in the backbone of protein).     

A set of HNCO-based experiments for measurement of residual dipolar couplings in 15N, 13C, (2H)-labeled proteins

Several HNCO-based three-dimensional experiments are described for the measurement of ¹³C(i–1)-¹³C(i–1), ¹⁵N(i)-¹³C(i–1), ¹⁵N(i)-¹³C(i), ¹⁵N(i)-¹³C(i–1), ¹H^N(i)-¹³C(i), ¹H^N(i)-¹³C(i–1), and ¹³C(i–1)-¹³C(i–1) scalar and dipolar couplings in ¹⁵N, ¹³C, (²H)-labelled protein samples. These pulse sequences produce spin-state edited spectra superficially resembling an HNCO correlation spectrum, allowing accurate and simple measurement of couplings without introducing additional spectral crowding. Scalar and dipolar couplings are measured with good sensitivity from relatively large proteins, as demonstrated with three proteins: cardiac Troponin C, calerythrin and ubiquitin. Measurement of several dipolar couplings between spin-1/2 nuclei using spin-state selective 3D HNCO spectra provides a wealth of structural information.     

Efficient and precise measurement of H(alpha)-C(alpha), C(alpha)-C', C(alpha)-C(beta) and H(N)-N residual dipolar couplings from 2D H(N)-N correlation spectra

A suite of experiments are presented for the measurement of H–C, C–C, C–C and H^N–N couplings from uniformly ¹⁵N, ¹³C labeled proteins. Couplings are obtained from a series of intensity modulated two-dimensional H^N–N spectra equivalent to the common ¹H–¹⁵N–HSQC spectra, alleviating many overlap and assignment issues associated with other techniques. To illustrate the efficiency of this method, H–C, C–C, and H^N–N isotropic scalar couplings were determined for ubiquitin from data collected in less than 4.5 h, C–C data collection required 10 h. The resulting couplings were measured with an average error of ±0.06, ±0.05, ±0.04 and ±0.10 Hz, respectively. This study also shows H–C and C–C couplings, valuable because they provide orientation of bond vectors outside the peptide plane, can be measured in a uniform and precise way. Superior accuracy and precision to existing 3D measurements for C–C couplings and increased precision compared to IPAP measurements for H^N–N couplings are demonstrated. Minor modifications allow for acquisition of modulated H^N–C 2D spectra, which can yield additional well resolved peaks and significantly increase the number of measured RDCs for proteins with crowded ¹H–¹⁵N resonances.     

A novel PH-CT-COSY methodology for measuring JPH coupling constants in unlabeled nucleic acids. Application to HIV-2 TAR RNA

A quantitative analysis of J_PH scalar couplings in nucleic acids is difficult due to small couplings to phosphorus, the extreme overlap of the sugar protons and the fast relaxation of the spins involved in the magnetization transfer. Here we present a new methodology that relies on heteronuclear Constant Time Correlation Spectroscopy (CT-COSY). The three vicinal ³J_PH3, ³J_PH5 and ³J_PH5 scalar couplings can be obtained by monitoring the intensity decay of the P_i-H3_{i – 1} peak as a function of the constant time T in a 2D correlation map. The advantage of the new method resides in the possibility of measuring the two ³J_PH5 and ³J_PH5 scalar couplings even in the presence of overlapped H5/H5 resonances, since the quantitative information is extracted from the intensity decay of the P-H3 peak. Moreover, the relaxation of the H3 proton is considerably slower than that of the H5/H5 geminal protons and the commonly populated conformations of the phosphate backbone are associated with large ³J_PH3 couplings and relatively small ³J_{PH5 / H5}. These two facts lead to optimal signal-to-noise ratio for the P-H3 correlation compared to the P-H5/H5 correlation.The heteronuclear CT-COSY experiment is suitable for oligonucleotides in the 10–15 kDa molecular mass range and has been applied to the 30mer HIV-2 TAR RNA. The methodology presented here can be used to measure P-H dipolar couplings (D_PH) as well. We will present qualitative results for the measurement of P-H_base and P-H2 dipolar couplings in the HIV-2 TAR RNA and will discuss the reasons that so far precluded the quantification of the D_PHs for the 30mer RNA.     

Untersuchungen zum C′3-Polymorphismus (β 1c-Globulin)

Zusammenfassung Serumproben von 1322 Blutspendern aus Hessen, 40 Familien mit 89 Kindern, 20 Mutter-Kind-Kombinationen und 268 Sera einer Bantupopulation aus Portugiesisch Angola wurden mit einer modifizierten Technik der Hochspannungs-Dünnschichtelektrophorese auf Agarosegel hinsichtlich des C3-Polymorphismus untersucht. Die Genfrequenzen für Weiße (C3^S=0.779, C3^F=0.215) und Neger (C3^S=0.95, C3^F=0,048) stimmen gut mit den Werten anderer Autoren überein. Insgesamt ließen sich bei Weißen 9 Phänotypen sicher abgrenzen, bei Negern 3. Familienstudien bestätigten den für die Allele C3^S und C3^F angenommenen Vererbungsmodus (autosomal codominant) ausnahmslos. Die Frage der Lagerungsstabilität des C3 wurde abschließend untersucht.

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Investigations on C3-polymorphism ( _1c-Globulin)Gene frequencies and family studies in blood donors from Hessen and a Bantu population

Summary Serum samples of 1322 unrelated individuals from Hessen (Germany), 40 families with 89 children, 20 mother-child-combinations and 268 sera of a Bantu population from Angola were examined for C3 polymorphism using a modified technique of high voltage agarose gel electrophoresis. The gene frequencies for Caucasians (C3^S=0.779, C3^F=0.215) and negroes (C3^S=0.95, C^F=0.048) are in good accordance with those obtained by other authors. In total 9 different phenotypes were observed in Caucasians, 3 phenotypes in negroes. Family studies verify the supposed way of inheritance (autosomal codominant for C3^S and C3^F) without exception. Finally the problem of C3-inactivation by storage was investigated.

     

Self-consistent 3J coupling analysis for the joint calibration of Karplus coefficients and evaluation of torsion angles

The concept of self-consistent J coupling evaluation exploits redundant structure information inherent in large sets of 3J coupling constants. Application to the protein Desulfovibrio vulgaris flavodoxin demonstrates the simultaneous refinement of torsion-angle values and related Karplus coefficients. The experimental basis includes quantitative coupling constants related to the polypeptide backbone torsion originating from a variety of heteronuclear 2D and 3D NMR correlation experiments, totalling 124 3J(HN,H), 129 3J(HN,C), 121 3J(HN,C), 128 3J(Ci–1,Hi), 121 3J(Ci–1,Ci), and 122 3J(Ci–1,Ci). Without prior knowledge from either X-ray crystallography or NMR data, such as NOE distance constraints, accurate dihedral angles are specified for 122 non-glycine and non-proline residues out of a total of 147 amino acids. Different models of molecular internal mobility are considered. The Karplus coefficients obtained are applicable to the conformational analysis of torsions in other polypeptides.