Perdeuterated Proteins Research Articles

Double-Nucleus Enhanced Recoupling for Efficient 13C MAS NMR Correlation Spectroscopy of Perdeuterated Proteins

The use of both proton and deuterium dipolar coupling networks to obtain efficient (13)C magic-angle-spinning NMR correlation spectroscopy is introduced. This new strategy aims to improve the efficiency of (13)C spin diffusion in perdeuterated proteins. The method is called double-nucleus enhanced recoupling (DONER), and it provides significantly improved transfer efficiency for carbon spin diffusion at low proton density. The C(alpha) cross-peak intensity in the DONER experiment is approximately 3 and approximately 5 times stronger than those in conventional radio-frequency-assisted diffusion (RAD) and proton-driven spin diffusion (PDSD) experiments, respectively. Remarkably, the full cross-peak pattern for the aliphatic region of an extensively perdeuterated SH3 protein sample can be obtained using the DONER approach with direct (13)C excitation.

Chemical shift assignments for human apurinic/apyrimidinic endonuclease 1

Apurinic/apyrimidinic endonuclease 1 (APE1 or Ref-1) is the major enzyme in mammals for processing abasic sites in DNA. These cytotoxic and mutagenic lesions arise via spontaneous rupture of the base-sugar bond or the removal of damaged bases by a DNA glycosylase. APE1 cleaves the DNA backbone 5' to an abasic site, giving a 3'-OH primer for repair synthesis, and mediates other key repair activities. The DNA repair functions are essential for embryogenesis and cell viability. APE1-deficient cells are hypersensitive to DNA-damaging agents, and APE1 is considered an attractive target for inhibitors that could potentially enhance the efficacy of some anti-cancer agents. To enable an important new method for studying the structure, dynamics, catalytic mechanism, and inhibition of APE1, we assigned the chemical shifts (backbone and (13)C(beta)) of APE1 residues 39-318. We also report a protocol for refolding APE1, which was essential for achieving complete exchange of backbone amide sites for the perdeuterated protein.

Optimum levels of exchangeable protons in perdeuterated proteins for proton detection in MAS solid-state NMR spectroscopy

We present a systematic study of the effect of the level of exchangeable protons on the observed amide proton linewidth obtained in perdeuterated proteins. Decreasing the amount of D(2)O employed in the crystallization buffer from 90 to 0%, we observe a fourfold increase in linewidth for both (1)H and (15)N resonances. At the same time, we find a gradual increase in the signal-to-noise ratio (SNR) for (1)H-(15)N correlations in dipolar coupling based experiments for H(2)O concentrations of up to 40%. Beyond 40%, a significant reduction in SNR is observed. Scalar-coupling based (1)H-(15)N correlation experiments yield a nearly constant SNR for samples prepared with < or =30% H(2)O. Samples in which more H(2)O is employed for crystallization show a significantly reduced NMR intensity. Calculation of the SNR by taking into account the reduction in (1)H T (1) in samples containing more protons (SNR per unit time), yields a maximum SNR for samples crystallized using 30 and 40% H(2)O for scalar and dipolar coupling based experiments, respectively. A sensitivity gain of 3.8 is obtained by increasing the H(2)O concentration from 10 to 40% in the CP based experiment, whereas the linewidth only becomes 1.5 times broader. In general, we find that CP is more favorable compared to INEPT based transfer when the number of possible (1)H,(1)H interactions increases. At low levels of deuteration (> or =60% H(2)O in the crystallization buffer), resonances from rigid residues are broadened beyond detection. All experiments are carried out at MAS frequency of 24 kHz employing perdeuterated samples of the chicken alpha-spectrin SH3 domain.

Coupled Decomposition of Four-Dimensional NOESY Spectra

Four-dimensional (4D) NOESY spectra provide unambiguous distance information at a resolution that cannot be achieved in fewer dimensions and thus increase the quality of biomolecular structure determination substantially. Since the degree of chemical shift degeneracy increases with protein size, the use of 4D NOESY spectra is particularly important for large proteins. The potential high resolution in 4D spectra cannot be achieved in a reasonable time with conventional acquisition routines that sample the Nyquist grid uniformly. It can, however, be obtained with nonuniform sampling of the data grid, but optimal processing of such data has not yet been established. Here we describe a processing method for a pair of sparsely sampled 4D NOESY spectra, a methyl-methyl and an amide-methyl NOESY, recorded on a perdeuterated protein with protonated isoleucine, leucine, and valine methyl groups. The coupled multidimensional decomposition (Co-MDD) of these two spectra together with a 2D template spectrum results in a substantial increase in sensitivity, evidenced by 50-100% additional cross peaks, when compared to alternative processing schemes. At the same time, Co-MDD allows the use of low sparse levels of 10-15% of the full data grid for NOESY spectra. For the 283-residue integral human membrane protein VDAC-1, which has a rotational correlation time of about 70 ns in detergent micelles, the two 4D Co-MDD NOESYs yielded a total of 366 NOEs, resulting in 139 unambiguous upper limit distance constraints for the structure calculation.

Perdeuteration, purification, crystallization and preliminary neutron diffraction of an ocean pout type III antifreeze protein.

The highly homologous type III antifreeze protein (AFP) subfamily share the capability to inhibit ice growth at subzero temperatures. Extensive studies by X-ray crystallography have been conducted, mostly on AFPs from polar fishes. Although interactions between a defined flat ice-binding surface and a particular lattice plane of an ice crystal have now been identified, the fine structural features underlying the antifreeze mechanism still remain unclear owing to the intrinsic difficulty in identifying H atoms using X-ray diffraction data alone. Here, successful perdeuteration (i.e. complete deuteration) for neutron crystallographic studies of the North Atlantic ocean pout (Macrozoarces americanus) AFP in Escherichia coli high-density cell cultures is reported. The perdeuterated protein (AFP D) was expressed in inclusion bodies, refolded in deuterated buffer and purified by cation-exchange chromatography. Well shaped perdeuterated AFP D crystals have been grown in D(2)O by the sitting-drop method. Preliminary neutron Laue diffraction at 293 K using LADI-III at ILL showed that with a few exposures of 24 h a very low background and clear small spots up to a resolution of 1.85 A were obtained using a ;radically small' perdeuterated AFP D crystal of dimensions 0.70 x 0.55 x 0.35 mm, corresponding to a volume of 0.13 mm(3).

An efficient protocol for the complete incorporation of methyl-protonated alanine in perdeuterated protein

A strategy for the introduction of ((1)H,(13)C-methyl)-alanine into perdeuterated proteins is described. Specific protonation of alanine methyl groups to a level of 95% can be achieved by overexpressing proteins in M9/D(2)O based bacterial growth medium supplemented with 800 mg/l of 2-[(2)H], 3-[(13)C] L: -alanine. However, though simple, this approach results in undesired, non-specific background labeling due to isotope scrambling via different amino acid metabolic pathways. Following a careful analysis of known metabolic pathways we found that co-addition of perdeuterated forms of alpha-ketoisovalerate-d(7), succinate-d(4) and L: -isoleucine-d(10) with labeled L: -alanine, reduces undesired background labeling to <1%. When combined with recently developed methyl TROSY experiments, this methyl-specific labeling protocol permits the acquisition of excellent quality correlation spectra of alanine methyl groups in high molecular weight proteins. Our cost effective strategy offers a significant enhancement in the level of incorporation of methyl-labeled alanine in overexpressed proteins over previously reported methods.

Residual methyl protonation in perdeuterated proteins for multi-dimensional correlation experiments in MAS solid-state NMR spectroscopy

NMR studies involving perdeuterated proteins focus in general on exchangeable amide protons. However, non-exchangeable sites contain as well a small amount of protons as the employed precursors for protein biosynthesis are not completely proton depleted. The degree of methyl group protonation is in the order of 9% for CD 2H using >97% deuterium enriched glucose. We show in this manuscript that this small amount of residual protonation is sufficient to perform 2D and 3D MAS solid-state NMR experiments. In particular, we suggest a HCCH-TOBSY type experiment which we successfully employ to assign the methyl resonances in aliphatic side chains in a perdeuterated sample of the SH3 domain of chicken α-spectrin.

Measurement of N15-T1 relaxation rates in a perdeuterated protein by magic angle spinning solid-state nuclear magnetic resonance spectroscopy

In this paper, we present the measurement of (15)N-T(1) relaxation times in the solid state for a perdeuterated protein for which exchangeable protons are back substituted during recrystallization using a buffer which contains 10% H(2)O and 90% D(2)O. We find large variations of the (15)N relaxation time, even within the same beta sheet. By comparing (15)N-T(1) relaxation times measured for a protonated and a deuterated protein (using the above mentioned approach), we conclude that (1)H driven (15)N,(15)N spin diffusion has a significant impact on the absolute (15)N relaxation time in protonated proteins. This effect is important for a quantitative analysis of relaxation data in terms of molecular dynamics.

Quantitative measurement of differential15NHα/βT2 relaxation rates in a perdeuterated protein by MAS solid-state NMR spectroscopy

Dynamic parameters become more and more accessible in the study of uniformly isotopically enriched proteins by MAS solid-state NMR. We demonstrate that T(2)-related relaxation properties can quantitatively be determined in a sample of a perdeuterated microcrystalline protein by the measurement of (15)N,(1)H dipole, (15)N CSA cross-correlated relaxation rates. We find that the measured cross-correlated relaxation rates are independent of the MAS rotation frequency, and therefore reflect local dynamic fluctuations of the protein structure.

Direct Observation of Dipolar Couplings and Hydrogen Bonds across a β-Hairpin in 8 M Urea

A detailed, quantitative description of the unfolded states of proteins at atomic resolution has been elusive due to enormous experimental and theoretical problems resulting from the huge number of degrees of freedom of an unfolded structural ensemble. In particular, direct long-range information has been extremely sparse. Here we show that such long-range information can be obtained by NMR with high sensitivity and precision from HN−HN residual dipolar couplings (RDCs) and hydrogen bond (H-bonds) scalar couplings for an unfolded, perdeuterated (amide protonated) protein (urea-denatured ubiquitin at pH 2.5). Besides numerous sequential contacts, the RDCs reveal the persistence of native-like structure in ubiquitin's first β-hairpin. This native-like structure is confirmed by the direct detection of H-bonds via h3JNC‘ H-bond scalar couplings as well as by chemical shifts, 3JHNHA couplings, and relaxation rates. A quantitative analysis suggests that despite 25% native backbone torsion angles indicated by the chemical shifts, the H-bonds of the hairpin are formed to a much lesser degree in urea.

Structure of human ferritin L chain

Ferritin is the major iron-storage protein present in all cells. It generally contains 24 subunits, with different ratios of heavy chain (H) to light chain (L), in the shape of a hollow sphere hosting up to 4500 ferric Fe atoms inside. H-rich ferritins catalyse the oxidation of iron(II), while L-rich ferritins promote the nucleation and storage of iron(III). Several X-ray structures have been determined, including those of L-chain ferritins from horse spleen (HoSF), recombinant L-chain ferritins from horse (HoLF), mouse (MoLF) and bullfrog (BfLF) as well as recombinant human H-chain ferritin (HuHF). Here, structures have been determined of two crystal forms of recombinant human L-chain ferritin (HuLF) obtained from native and perdeuterated proteins. The structures show a cluster of acidic residues at the ferrihydrite nucleation site and at the iron channel along the threefold axis. An ordered Cd2+ structure is observed within the iron channel, offering further insight into the route and mechanism of iron transport into the capsid. The loop between helices D and E, which is disordered in many other L-chain structures, is clearly visible in these two structures. The crystals generated from perdeuterated HuLF will be used for neutron diffraction studies.

Characterization of Dynamics of Perdeuterated Proteins by MAS Solid-State NMR

We show in this communication that dynamic information for uniformly 2H,13C,15N isotopically enriched, crystalline proteins can be obtained by MAS solid-state NMR spectroscopy. The experiments make use of the deuterium quadrupolar tensor, which is the dominant interaction mechanism. Dynamic properties are accessed by measurement of the size of the quadrupolar coupling constant, Cq, and the value of the asymmetry parameter, eta, via evolution of the deuterium chemical shift, as well as by measurement of deuterium T1 relaxation times. Three-dimensional experiments are performed in order to obtain site-specific resolution. Due to proton dilution, no proton decoupling is required in the carbon evolution periods at MAS rotation frequencies of 10 kHz.

Neutron protein crystallography is greatly enhanced using perdeuterated proteins

Neutron protein crystallography is greatly enhanced using perdeuterated proteins

Structural stability and dynamics of hydrogenated and perdeuterated cytochrome P450cam (CYP101).

Perdeuterated and hydrogenated cytochrome P450cam (P450cam), from Pseudomonas putida, has been characterized concerning thermal stability and structural dynamics. For the first time, Fourier transform infrared (FTIR) spectroscopy was used to characterize a perdeuterated protein. The secondary structure compositions were determined from the fitted amide I' spectral region, giving band populations at 10 degrees C for the perdeuterated protein of 22% between 1605 and 1624 cm(-1) (beta-sheets), 47% between 1633 and 1650 cm(-1) (alpha-helix (29%) plus unordered/3(10)-helix (18%)), and 28% between 1657 and 1677 cm(-1) (turns) and for the hydrogenated protein of 22% between 1610 and 1635 cm(-1) (beta-sheets), 52% between 1640 and 1658 cm(-1) (alpha-helix (41%) plus unordered/3(10)-helix (11%)), and 24% between 1665 and 1680 cm(-1) (turns). Thermal unfolding experiments revealed that perdeuterated P450cam was less stable than the hydrogenated protein. The midpoint transition temperatures were 60.8 and 64.4 degrees C for the perdeuterated and hydrogenated P450cam, respectively. Step-scan time-resolved FTIR was applied to the P450cam-CO complex to study the ligand-rebinding process after flash photolysis. Rebinding of the ligand occurred with the same kinetics and rate constants k(on), 8.9 x 10(4) and 8.3 x 10(4) M(-1) s(-1) for the perdeuterated and hydrogenated P450cam, respectively.Perdeuterated P450cam was expressed for a neutron crystallographic study to determine the specific hydration states and hydrogen-bonding networks at the active site. The analyses presented here show that perdeuterated P450cam is structurally similar to its hydrogenated counterpart, despite its reduced thermal stability, suggesting that information obtained from the neutron structure will be representative of the normal hydrogenated P450cam.

Production and preliminary analysis of perdeuterated yeast inorganic pyrophosphatase crystals suitable for neutron diffraction.

Yeast inorganic pyrophosphatase (Y-PPase) is a model system for studying phosphoryl-transfer reactions catalysed by multiple metal ions. To understand the process requires knowledge of the positions of the protons in the active site, which can be best achieved by neutron diffraction analysis. In order to reduce the hydrogen incoherent-scattering background and to improve the signal-to-noise ratio of the neutron reflections, deuterated protein was produced. Deuterated protein 96% enriched with deuterium was produced in high yield and crystals as large as 2 mm on one side were obtained. These crystals have unit-cell parameters a = 58.9, b = 103.9, c = 117.0 A, alpha = beta = gamma = 90 degrees at 273 K and diffract neutrons to resolutions of 2.5-3 A. The X-ray structure of the perdeuterated protein has also been refined at 273 K to 1.9 A resolution.

A novel method for the biosynthesis of deuterated proteins with selective protonation at the aromatic rings of Phe, Tyr and Trp.

A novel biosynthetic strategy is described for the preparation of deuterated proteins containing protons at the ring carbons of Phe, Tyr and Trp, using the aromatic amino acid precursor shikimic acid. Specific protonation at aromatic side chains, with complete deuteration at C(alpha/beta) positions was achieved in proteins overexpressed in bacteria grown in shikimate-supplemented D2O medium. Co-expression of a shikimate transporter in prototrophic bacteria resulted in protonation levels of 62-79%, whereas complete labeling was accomplished using shikimate auxotrophic bacteria. Our labeling protocol permits the measurement of important aromatic side chain derived distance restraints in perdeuterated proteins that could be utilized to enhance the accuracy of NMR structures calculated using low densities of NOEs from methyl selectively protonated samples.

Extending the range of amide proton relaxation dispersion experiments in proteins using a constant-time relaxation-compensated CPMG approach.

Relaxation compensated constant-time Carr-Purcell-Meiboom-Gill relaxation dispersion experiments for amide protons are presented that detect mus-ms time-scale dynamics of protein backbone amide sites. Because of their ten-fold larger magnetogyric ratio, much shorter 180 degrees pulses can be applied to (1)H than to (15)N spins; therefore, off-resonance effects are reduced and a wider range of effective rf fields can often be used in the case of (1)H experiments. Applications to [(1)H-(15)N]-ubiquitin and [(1)H-(15)N]-perdeuterated HIV-1 protease are discussed. In the case of ubiquitin, we present a pulse sequence that reduces artifacts that arise from homonuclear (3)J(H(N)-H(alpha)) coupling. In the case of the protease, we show that relaxation dispersion of both (1)H and (15)N spins provides a more comprehensive picture of slow backbone dynamics than does the relaxation dispersion of either spin alone. We also compare the relative merits of (1)H versus (15)N transverse relaxation measurements and note the benefits of using a perdeuterated protein to measure the relaxation dispersion of both spin types.

High-accuracy residual 1HN-13C and 1HN-1HN dipolar couplings in perdeuterated proteins.

Truncation by the presence of many short-range residual dipolar couplings (RDCs) hinders the observation of long-range RDCs in weakly aligned biomacromolecules. Perdeuteration of proteins followed by reprotonation of labile hydrogen positions greatly alleviates this problem. Here we show that for small perdeuterated proteins, a large number (up to 10 in protein G) of long-range RDCs to 13C and 1HN can be observed from individual amide protons. The 1HN <--> 13C RDCs comprise correlations to 13Calpha, 13Cbeta, and 13C' nuclei of the same and the preceding amino acid, as well as 13C' nuclei of hydrogen-bonded amino acids. The accuracy of the coupling constants is very high and defines individual internuclear distances to within few picometers. Deviations between measured RDC values and values predicted from the 1.1 A crystal structure of protein G are mainly found in two surface-exposed loop regions. The deviations show a strong correlation to the B-factor of the crystal structure.

Optimized labeling of 13CHD2 methyl isotopomers in perdeuterated proteins: potential advantages for 13C relaxation studies of methyl dynamics of larger proteins.

13CHD2 methyl isotopomers are particularly useful to study methyl dynamics in proteins because, as compared with other methyl isotopomers, the 13C relaxation mechanism for this isotopomer is straightforward. However, in the case of proteins, where (omega tau)2 >> 1, the refocused INEPT pulse sequence does not completely suppress unwanted 13CH3 signals. The presence of weak 13CH3 peaks is usually not a serious problem for smaller proteins because there are relatively few methyl signals and they are sharp; however, signal overlap becomes more common as the size of the protein increases. We overcome this problem by preparing a protein using a 98% D2O cell culture medium containing 3-(13)C pyruvic acid, 50-60% deuterated at the 3-position, and 4-(13)C 2-ketobutyric acid, 98% and 62% deuterated at the 3- and 4-positions, respectively. This approach significantly reduces the population of the CH3 isotopomer while optimizing the production of 13CHD2, the isotopomer desired for 13C relaxation measurements. In larger proteins where the deuterium T2 may be too short to measure accurately, we also suggest the alternative measurement of the proton T2 of the 13CH2D methyl isotopomer, because these protons are well-isolated from other protons in these highly deuterated samples.

Utilization of site-directed spin labeling and high-resolution heteronuclear nuclear magnetic resonance for global fold determination of large proteins with limited nuclear overhauser effect data.

To test whether distances derived from paramagnetic broadening of (15)N heteronuclear single quantum coherence (HSQC) resonances could be used to determine the global fold of a large, perdeuterated protein, we used site-directed spin-labeling of 5 amino acids on the surface of (15)N-labeled eukaryotic translation initiation factor 4E (eIF4E). eIF4E is a 25 kDa translation initiation protein, whose solution structure was previously solved in a 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate hydrate (CHAPS) micelle of total molecular mass approximately 45-50 kDa. Distance-dependent line broadening consistent with the three-dimensional structure of eIF4E was observed for all spin-label substitutions. The paramagnetic broadening effects (PBEs) were converted into distances for modeling by a simple method comparing peak heights in (15)N-HSQC spectra before and after reduction of the nitroxide spin label with ascorbic acid. The PBEs, in combination with HN-HN nuclear Overhauser effects (NOEs) and chemical shift index (CSI) angle restraints, correctly determined the global fold of eIF4E with a backbone precision of 2.3 A (1.7 A for secondary structure elements). The global fold was not correctly determined with the HN-HN NOEs and CSI angles alone. The combination of PBEs with simulated restraints from another nuclear magnetic resonance (NMR) method for global fold determination of large proteins (methyl-protonated, highly deuterated samples) improved the quality of calculated structures. In addition, the combination of the two methods simulated from a crystal structure of an all alpha-helical protein (40 kDa farnesyl diphoshphate synthase) correctly determined the global fold where neither method individually was successful. These results show the potential feasibility of obtaining medium-resolution structures for proteins in the 40-100 kDa range via NMR.