Comparison of <Superscript>13</Superscript>CH<Subscript>3</Subscript>, <Superscript>13</Superscript>CH<Subscript>2</Subscript>D,and <Superscript>13</Superscript>CHD<Subscript>2</Subscript> methyl labeling strategies in proteins

A comparison of three labeling strategies for studies involving side chain methyl groups in high molecular weight proteins, using ¹³CH₃,¹³CH₂D, and ¹³CHD₂ methyl isotopomers, is presented. For each labeling scheme, ¹H–¹³C pulse sequences that give optimal resolution and sensitivity are identified. Three highly deuterated samples of a 723 residue enzyme, malate synthase G, with ¹³CH₃,¹³CH₂D, and ¹³CHD₂ labeling in Ile δ1 positions, are used to test the pulse sequences experimentally, and a rationalization of each sequence’s performance based on a product operator formalism that focuses on individual transitions is presented. The HMQC pulse sequence has previously been identified as a transverse relaxation optimized experiment for ¹³CH₃-labeled methyl groups attached to macromolecules, and a zero-quantum correlation pulse scheme (¹³CH₃ HZQC) has been developed to further improve resolution in the indirectly detected dimension. We present a modified version of the ¹³CH₃ HZQC sequence that provides improved sensitivity by using the steady-state magnetization of both ¹³C and ¹H spins. The HSQC and HMQC spectra of ¹³CH₂D-labeled methyl groups in malate synthase G are very poorly resolved, but we present a new pulse sequence, ¹³CH₂D TROSY, that exploits cross-correlation effects to record ¹H–¹³C correlation maps with dramatically reduced linewidths in both dimensions. Well-resolved spectra of ¹³CHD₂-labeled methyl groups can be recorded with HSQC or HMQC; a new ¹³CHD₂ HZQC sequence is described that provides improved resolution with no loss in sensitivity in the applications considered here. When spectra recorded on samples prepared with the three isotopomers are compared, it is clear that the ¹³CH₃ labeling strategy is the most beneficial from the perspective of sensitivity (gains ≥2.4 relative to either ¹³CH₂D or ¹³CHD₂ labeling), although excellent resolution can be obtained with any of the isotopomers using the pulse sequences presented here.     

Optimal methyl labeling for studies of supra-molecular systems

Selective methyl labeling combined with HMQC spectroscopy that exploits a TROSY effect in ¹³CH₃ spin systems has significantly extended the utility of solution NMR spectroscopy in studies of high molecular weight particles. Herein we compare the utility of ¹³CH₃- versus ¹³CHD₂-labeling of Ile, Leu, Val probes in supra-molecular systems through quantification of relative signal-to-noise ratios in optimized spectra of highly deuterated, ¹³CH₃- and ¹³CHD₂-labeled samples of the half proteasome (α₇α₇, 360 kDa). It is shown that the sensitivity of spectra recorded on Ile, Leu, Val ¹³CH₃-labeled samples is between 1.5 and 2 fold higher than the corresponding data sets obtained on α₇α₇ with ¹³CHD₂ probes. Thus, labeling of supra-molecules with ¹³CH₃ isotopomers remains the method of choice, but in applications where ¹³CHD₂ moieties are required, sensitivity will in general not be limiting.     

Effect of deuteration on some structural parameters of methyl groups in proteins as evaluated by residual dipolar couplings

One bond methyl ¹H-¹³C and ¹³C_methyl–¹³C scalar and residual dipolar couplings have been measured at sites in an ¹⁵N, ¹³C, 50% ²H labeled sample of the B1 immunoglobulin binding domain of peptostreptococcal protein L to investigate changes in the structure of methyl groups in response to deuterium substitution. Both one bond methyl ¹H-¹³C and ¹³C_methyl–¹³C scalar coupling constants have been found to decrease slightly with increasing deuterium content. Previous studies have shown that ¹H-¹³C couplings in methyl groups are exquisitely sensitive to electronic structure, with decreases in coupling values as a function of deuteration consistent with a slight lengthening of the remaining H-C bonds. Changes in the H_methylC_methylC angle are found to be small, with average differences on the order of 0.3 ± 0.1° and 0.4 ± 0.2° between CH₃, CH₂D and CH₃, CHD₂ isotopomers, respectively. Knowledge of methyl geometry is a prerequisite for the extraction of accurate dynamics parameters from spin relaxation studies involving these groups.     

An (H)C(CO)NH-TOCSY pulse scheme for sequential assignment of protonated methyl groups in otherwise deuterated 15N, 13C-labeled proteins

Summary A biosynthetic strategy has recently been developed for the production of ¹⁵N, ¹³C, ²H-labeled proteins using ¹H₃C-pyruvate as the sole carbon source and D₂O as the solvent. The methyl groups of Ala, Val, Leu and Ile (2 only) remain highly protonated, while the remaining positions in the molecule are largely deuterated. An (H)C(CO)NH-TOCSY experiment is presented for the sequential assignment of the protonated methyl groups. A high-sensitivity spectrum is recorded on a ¹⁵N, ¹³C, ²H, ¹H₃C-labeled SH2 domain at 3°C (correlation time 18.8 ns), demonstrating the utility of the method for proteins in the 30–40 kDa molecular weight range.     

Effects of D-glucose upon D-fuctose metabolism in rat hepatocytes: A 13C NMR study

Isolated hepatocytes from fed rats were exposed for 120 min to D-glucose (10 mM) and either D-[1-¹³C]fructose, D-[2-¹³C]fructose or D-[6-¹³C]fructose (also 10 mM) in the presence of D₂O. The identification and quantification of ¹³C-enriched D-fructose and its metabolites (D-glucose, L-lactate, L-alanine) in the incubation medium and the measurement of their deuterated isotopomers indicated, by comparison with a prior study conducted in the absence of exogenous D-glucose, that the major effects of the aldohexose were to increase the recovery of ¹³C-enriched D-fructose, decrease the production of ¹³C-enriched D-glucose, restrict the deuteration of the ¹³C-enriched isotopomers of D-glucose to those generated by cells exposed to D-[2-¹³C]fructose, and to accentuate the lesser deuteration of the C₂ (as compared to C₅) of ¹³C-enriched D-glucose derived from D-[2-¹³C]fructose. The ratio between C2-deuterated and C₂-hydrogenated L-lactate, as well as the relative amounts of the CH₃-, CH₂D-, CHD₂ and CD₃- isotopomers of ¹³C-enriched L-lactate were not significantly different, however, in the absence or presence of exogenous D-glucose. These findings indicate that exogenous D-glucose suppressed the deuteration of the C₁ of D-[1-¹³C]glucose generated by hepatocytes exposed to D-[1-¹³C]fructose or D-[6-¹³C]fructose, as otherwise attributable, in part at least, to gluconeogenesis from fructose-derived [3-¹³C]pyruvate, and apparently favoured the phosphorylation of D-fructose by hexokinase isoenzymes, probably through stimulation of D-fructose phosphorylation by glucokinase.     

Selective <Superscript>1</Superscript>H-<Superscript>13</Superscript>C NMR spectroscopy of methyl groups in residually protonated samples of large proteins

Methyl ¹³CHD₂ isotopomers of all methyl-containing amino-acids can be observed in residually protonated samples of large proteins obtained from [U-¹³C,¹H]-glucose/D₂O-based bacterial media, with sensitivity sufficient for a number of NMR applications. Selective detection of some subsets of methyl groups (Ala^β, Thr^γ2) is possible using simple ‘out-and-back’ NMR methodology. Such selective methyl-detected ‘out-and-back’ NMR experiments allow complete assignments of threonine γ2 methyls in residually protonated, [U-¹³C,¹H]-glucose/D₂O-derived samples of an 82-kDa enzyme Malate Synthase G. [U-¹³C,¹H]-glucose/D₂O-derived protein samples are relatively inexpensive and are usually available at very early stages of any NMR study of high-molecular-weight systems.     

Support of1H NMR assignments in proteins by biosynthetically directed fractional13C-labeling

Summary Biosynthetically directed fractional incorporation of¹³C into proteins results in nonrandom¹³C-labeling patterns that can be investigated by analysis of the¹³C–¹³C scalar coupling fine structures in heteronuclear¹³C–¹H or homonuclear¹³C–¹³C correlation experiments. Previously this approach was used for obtaining stereospecific¹H and¹³C assignments of the diastereotopic methyl groups of valine and leucine. In the present paper we investigate to what extent the labeling patterns are characteristic for other individual amino acids or groups of amino acids, and can thus be used to support the¹H spin-system identifications. Studies of the hydrolysates of fractionally¹³C-labeled proteins showed that the 59 aliphatic carbon positions in the 20 proteinogenic amino acids exhibit 16 different types of¹³C–¹³C coupling fine structures. These provide support for the assignment of the resonances of all methyl groups in a protein, which are otherwise often poorly resolved in homonuclear¹H NMR spectra. In particular, besides the individual methyl assignments in Val and Leu, unambiguous distinctions are obtained between the methyl groups of Ala and Thr, and between the - and -methyl groups of Ile. In addition to the methyl resonances, the CH₂ groups of Glu and Gln can be uniquely assigned because of the large coupling constant with the -carbon, and the identification of most of the other spin systems can be supported on the basis of coupling patterns that are common to small groups of amino acid residues.Abbreviations NOE nuclear Overhauser effect - fractional¹³C labeling biosynthetically directed fractional¹³C-labeling - TOCSY total correlation spectroscopy - ROESY rotating frame Overhauser enhancement spectroscopy - [¹³C,¹H]-COSY two-dimensional¹³C–¹H correlation spectroscopy - isotopomer isotope isomer - P22 c2 repressor c2 repressor of the salmonella phage P22 consisting of a polypeptide chain with 216 residues - P22 c2(1-76) N-terminal domain of the P22 c2 repressor with residues 1–76     

Anti-hyperglycemic effect of loquat leaf extract is associated with the redistribution of glucose carbon to its metabolites: a <Superscript>13</Superscript>C-tracing study in HepG2 cells

Introduction

Loquat leaf extract (LLE) is commonly used in China for a variety of ailments including diabetes. Several recent reports implicate LLE and a sesquiterpene glycoside, one of its components, as being an anti-hyperglycemic agent. However, the underlying mechanism of action of this anti-hyperglycemic agent has not been reported.

Objective

We have conducted a tracer-based metabolomics study to investigate the effects of sesquiterpene and loquat extract on the balance of flux of central glucose metabolism in HepG2 cells and to compare with those of “insulin sensitizers”, metformin and rosiglitazone.

Methods

Human hepatoma HepG2 cells in confluence culture were incubated in Dulbecco’s modified Eagle’s medium containing 50% [1, 2 ¹³C₂]-glucose in the presence of rosiglitazone, metformin, LLE or pure sesquiterpene. Cells were harvested in 48 h. Mass isotopomers of metabolites (glycogen, ribose, deoxyribose, glutamate and palmitate) were determined.

Results

¹³C labeling in metabolic intermediates were summarized in a mass isotopomer matrix. Treatment with loquat extract/sesquiterpene, metformin and rosiglitazone each produced distinctive mass isotopomer patterns reflecting disparate effects on the contribution of glucose to various metabolites production, and on several metabolic flux ratios. The overall effect of LLE and sesquiterpene on glucose metabolism is clearly different from those of the known “insulin sensitizers”.

Conclusion

Our study demonstrates the utility of isotopomer matrix in summarizing metabolic actions of LLE on the balance of fluxes occurring within the central glucose metabolism in HepG2 cells. ¹³C carbon tracing (tracer-based metabolomics) is a useful systems biology tool to elucidate glucose metabolic pathways affected by diabetes and its treatment.

     

Measurement of methyl 13C-1H cross-correlation in uniformly 13C-, 15N-, labeled proteins

An understanding of side chain motions in protein is of great interest since side chains often play an important role in protein folding and intermolecular interactions. A novel method for measuring the dynamics of methyl groups in uniformly ¹³C-, ¹⁵N-labeled proteins has been developed by our group. The method relies on the difference in peak intensities of ¹³C quartet components of methyl groups, in a spectrum recording the free evolution of ¹³C under proton coupling in a constant-time period. Cross-correlated relaxation rates between ¹³C-¹H dipoles can be easily measured from the intensities of the multiplet components. The degree of the methyl restrictions (S ²) can be estimated from the cross-correlated relaxation rate. The method is demonstrated on a sample of human fatty acid binding protein in the absence of fatty acid. We obtained relaxation data for 33 out of 46 residues having methyl groups in apo-IFABP. It has been found that the magnitude of the CSA tensor of spin ¹³C in a methyl group could be estimated from the intensities of the ¹³C multiplet components.     

A tracked approach for automated NMR assignments in proteins (TATAPRO)

A novel automated approach for the sequence specific NMR assignments of ¹H^N, ¹³C, ¹³C, ¹³C/¹H and ¹⁵N spins in proteins, using triple resonance experimental data, is presented. The algorithm, TATAPRO (Tracked AuTomated Assignments in Proteins) utilizes the protein primary sequence and peak lists from a set of triple resonance spectra which correlate ¹H^N and ¹⁵N chemical shifts with those of ¹³C, ¹³C and ¹³C/¹H. The information derived from such correlations is used to create a `master_list' consisting of all possible sets of ¹H^N _i, ¹⁵N_i, ¹³C _i, ¹³C _i, ¹³C_i/¹H _i, ¹³C _i–1, ¹³C _i–1 and ¹³C_i–1/ ¹H _i–1 chemical shifts. On the basis of an extensive statistical analysis of ¹³C and ¹³C chemical shift data of proteins derived from the BioMagResBank (BMRB), it is shown that the 20 amino acid residues can be grouped into eight distinct categories, each of which is assigned a unique two-digit code. Such a code is used to tag individual sets of chemical shifts in the master_list and also to translate the protein primary sequence into an array called pps_array. The program then uses the master_list to search for neighbouring partners of a given amino acid residue along the polypeptide chain and sequentially assigns a maximum possible stretch of residues on either side. While doing so, each assigned residue is tracked in an array called assig_array, with the two-digit code assigned earlier. The assig_array is then mapped onto the pps_array for sequence specific resonance assignment. The program has been tested using experimental data on a calcium binding protein from Entamoeba histolytica (Eh-CaBP, 15 kDa) having substantial internal sequence homology and using published data on four other proteins in the molecular weight range of 18–42 kDa. In all the cases, nearly complete sequence specific resonance assignments (> 95%) are obtained. Furthermore, the reliability of the program has been tested by deleting sets of chemical shifts randomly from the master_list created for the test proteins.     

Expression of deuterium-isotope-labelled protein in the yeast Pichia pastoris for NMR studies

Deuterium isotope labelling is important for NMR studies of large proteins and complexes. Many eukaryotic proteins are difficult to express in bacteria, but can be efficiently produced in the methylotrophic yeast Pichia pastoris. In order to facilitate NMR studies of the malaria parasite merozoite surface protein-1 (MSP1) complex and its interactions with antibodies, we have investigated production of the MSP1-19 protein in P. pastoris grown in deuterated media. The resulting deuteration patterns were analyzed by NMR and mass spectrometry. We have compared growth characteristics and levels of heterologous protein expression in cells adapted to growth in deuterated media (95% D₂O), compared with expression in non-adapted cells. We have also compared the relative deuteration levels and the distribution pattern of residual protiation in protein from cells grown either in 95% D₂O medium with protiated methanol as carbon source, or in 95% D₂O medium containing deuterated methanol. A high level of uniform C deuteration was demonstrated, and the consequent reduction of backbone amide signal linewidths in [¹H/¹⁵N]-correlation experiments was measured. Residual protiation at different positions in various amino acid residues, including the distribution of methyl isotopomers, was also investigated. The deuteration procedures examined here should facilitate economical expression of ²H/¹³C/¹⁵N-labelled protein samples for NMR studies of the structure and interactions of large proteins and protein complexes.     

Contribution of methanol to the production of methane and its <Superscript>13</Superscript>C-isotopic signature in anoxic rice field soil

Conversion of methanol to CH₄ has a large isotope effect so that a small contribution of methanol-dependent CH₄ production may decrease the ¹³CH₄ of total CH₄ production. Therefore, we investigated the role of methanol for CH₄ production. Methanol was not detectable above 10 M in anoxic methanogenic rice field soil. Nevertheless, addition of ¹³C-labeled methanol (99% enriched) resulted in immediate accumulation of ¹³CH₄. Addition of 0.1 M ¹³C-methanol resulted in increase of the ¹³CH₄ from –47 to –6 within 2 h, followed by a slow decrease. Addition of 1 M ¹³C-methanol increased ¹³CH₄ to +500 within 4 h, whereas 10 M increased ¹³CH₄ to +2500 and continued to increase. These results indicate that the methanol concentrations in situ, which diluted the ¹³C-methanol added, were 0.1 M and that the turnover of methanol contributed only about 2% to total CH₄ production at 0.1 M. However, contribution increased up to 5 and 17% when 1 and 10 M methanol were added, respectively. Anoxic rice soil that was incubated at different temperatures between 10 and 37 °C exhibited maximally 2–6% methanol-dependent methanogenesis about 1–2 h after addition of 1 M ¹³C-methanol. Only at 50 °C, contribution of methanol to CH₄ production reached a maximum of 10%. After longer (7–10 h) incubation, however, contribution generally was only 2–4%. Methanol accumulated in the soil when CH₄ production was inhibited by chloroform. However, the accumulated methanol accounted for only up to 0.7 and 1.2% of total CH₄ production at 37 and 50 °C, respectively. Collectively, our results show that methanol-dependent methanogenesis was operating in anoxic rice field soil but contributed only marginally to total CH₄ production and the isotope effect observed at both low and high temperature.     

An Economical Method for Production of 2H,13CH3-Threonine for Solution NMR Studies of Large Protein Complexes: Application to the 670 kDa Proteasome

NMR studies of very high molecular weight protein complexes have been greatly facilitated through the development of labeling strategies whereby ¹³CH₃ methyl groups are introduced into highly deuterated proteins. Robust and cost-effective labeling methods are well established for all methyl containing amino acids with the exception of Thr. Here we describe an inexpensive biosynthetic strategy for the production of L-[α-²H; β−²H;γ-¹³C]-Thr that can then be directly added during protein expression to produce highly deuterated proteins with Thr methyl group probes of structure and dynamics. These reporters are particularly valuable, because unlike other methyl containing amino acids, Thr residues are localized predominantly to the surfaces of proteins, have unique hydrogen bonding capabilities, have a higher propensity to be found at protein nucleic acid interfaces and can play important roles in signaling pathways through phosphorylation. The utility of the labeling methodology is demonstrated with an application to the 670 kDa proteasome core particle, where high quality Thr ¹³C,¹H correlation spectra are obtained that could not be generated from samples prepared with commercially available U-[¹³C,¹H]-Thr.     

Specific 15N, NH correlations for residues in15 N, 13C and fractionally deuterated proteins that immediately follow methyl-containing amino acids

A triple-resonance pulse scheme is described which records¹⁵N, NH correlations of residues that immediately follow amethyl-containing amino acid. The experiment makes use of a¹⁵N, ¹³C and fractionally deuterated proteinsample and selects for CH₂D methyl types. The experiment isthus useful in the early stages of the sequential assignment process as wellas for the confirmation of backbone ¹⁵N, NH chemical shiftassignments at later stages of data analysis. A simple modification of thesequence also allows the measurement of methyl side-chain dynamics. This isparticularly useful for studying side-chain dynamic properties in partiallyunfolded and unfolded proteins where the resolution of aliphatic carbon andproton chemical shifts is limited compared to that of amide nitrogens.     

The fate of <Superscript>13</Superscript>C<Superscript>15</Superscript>N labelled glycine in permafrost and surface soil at simulated thaw in mesocosms from high arctic and subarctic ecosystems

Aims

Poorly drained arctic ecosystems are potential large emitters of methane (CH₄) due to their high soil organic carbon content and low oxygen availability. In wetlands, aerenchymatous plants transport CH₄ from the soil to the atmosphere, but concurrently transport O₂ to the rhizosphere, which may lead to oxidation of CH₄. The importance of the latter process is largely unknown for arctic plant species and ecosystems. Here, we aim to quantify the subsurface oxidation of CH₄ in a waterlogged arctic ecosystem dominated by Carex aquatilis ssp. stans and Eriophorum angustifolium, and evaluate the overall effect of these plants on the CH₄ budget.

Methods

A mesocosms study was established based on the upper 20 cm of an organic soil profile with intact plants retrieved from a peatland in West Greenland (69°N). We measured dissolved concentrations and emissions of ¹³CO₂ and ¹³CH₄ from mesocosms during three weeks after addition of ¹³C-enriched CH₄ below the mesocosm.

Results

Most of the recovered ¹³C label (>98 %) escaped the ecosystem as CH₄, while less than 2 % was oxidized to ¹³CO₂.

Conclusions

It is concluded that aerenchymatous plants control the overall CH₄ emissions but, as a transport system for oxygen, are too inefficient to markedly reduce CH₄ emissions.

     

Probing slow timescale dynamics in proteins using methyl <Superscript>1</Superscript>H CEST

Although ¹⁵N- and ¹³C-based chemical exchange saturation transfer (CEST) experiments have assumed an important role in studies of biomolecular conformational exchange, ¹H CEST experiments are only beginning to emerge. We present a methyl-TROSY ¹H CEST experiment that eliminates deleterious ¹H–¹H NOE dips so that CEST profiles can be analyzed robustly to extract methyl proton chemical shifts of rare protein conformers. The utility of the experiment, along with a version that is optimized for ¹³CHD₂ labeled proteins, is established through studies of exchanging protein systems. A comparison between methyl ¹H CEST and methyl ¹H CPMG approaches is presented to highlight the complementarity of the two experiments.     

Stereospecific assignments of glycine in proteins by stereospecific deuteration and 15N labeling

Summary A method is described for stereospecifically assigning the -protons of glycine residues in proteins. The approach involves the stereospecific deuteration and ¹⁵N labeling of glycine and subsequent selective incorporation of this residue into the protein. The stereospecific assignments of the glycine -protons are obtained from a comparison of a 3D ¹⁵N-resolved TOCSY spectrum of the uniformly ¹⁵N-labeled protein with a 2D/3D ¹⁵N-edited TOCSY spectrum of the protein, containing the stereospecifically deuterated and ¹⁵N-labeled glycine. The approach is demonstrated by stereospecifically assigning the glycine -protons of the FK506 binding protein when bound to the immunosuppressant ascomycin.     

A simple and sensitive experiment for measurement of JCC couplings between backbone carbonyl and methyl carbons in isotopically enriched proteins

Summary A simple 2D difference experiment is described that allows quantitative measurement of ¹³C–¹³C J couplings between backbone carbonyl and side-chain carbons. Precise ³J_CC values were measured from data recorded in just 2 h for a 1-mM solution of the 20-kD complex between the protein calmodulin and a 26-residue synthetic peptide. The J couplings aid in determining the ¹ angles of valine, isoleucine and threonine residues, and in making stereospecific assignments of the Val C methyl groups. Error analysis indicates that the uncertainty in the derived J couplings is generally less than ca. 0.3 Hz.     

Selective `unlabeling' of amino acids in fractionally 13C labeled proteins: An approach for stereospecific NMR assignments of CH3 groups in Val and Leu residues

A novel methodology for stereospecific NMR assignments of methyl (CH₃) groups of Val and Leu residues in fractionally ¹³C-labeled proteins is presented. The approach is based on selective `unlabeling' of specific amino acids in proteins while fractionally <sup>13</sup>C-labeling the rest. A 2D [<sup>13</sup>C-<sup>1</sup>H] HSQC spectrum recorded on such a sample is devoid of peaks belonging to the `unlabeled' amino acid residues. Such spectral simplification aids in unambiguous stereospecific assignment of diastereotopic CH₃ groups in Val and Leu residues in large proteins. This methodology has been demonstrated on a 15 kDa calcium binding protein from Entamoeba histolytica (Eh-CaBP).