Hiromasa Yagi

Nanometer-scale distance measurements in proteins using Gd3+ spin labeling

Methods for measuring nanometer-scale distances between specific sites in proteins are essential for analysis of their structure and function. In this work we introduce Gd(3+) spin labeling for nanometer-range distance measurements in proteins by high-field pulse electron paramagnetic resonance (EPR). To evaluate the performance of such measurements, we carried out four-pulse double-electron electron resonance (DEER) measurements on two proteins, p75ICD and tau(C)14, labeled at strategically selected sites with either two nitroxides or two Gd(3+) spin labels. In analogy to conventional site-directed spin labeling using nitroxides, Gd(3+) tags that are derivatives of dipicolinic acid were covalently attached to cysteine thiol groups. Measurements were carried out on X-band (approximately 9.5 GHz, 0.35 T) and W-band (95 GHz, 3.5 T) spectrometers for the nitroxide-labeled proteins and at W-band for the Gd(3+)-labeled proteins. In the protein p75ICD, the orientations of the two nitroxides were found to be practically uncorrelated, and therefore the distance distribution could as readily be obtained at W-band as at X-band. The measured Gd(3+)-Gd(3+) distance distribution had a maximum at 2.9 nm, as compared to 2.5 nm for the nitroxides. In the protein tau(C)14, however, the orientations of the nitroxides were correlated, and the W-band measurements exhibited strong orientation selection that prevented a straightforward extraction of the distance distribution. The X-band measurements gave a nitroxide-nitroxide distance distribution with a maximum at 2.5 nm, and the W-band measurements gave a Gd(3+)-Gd(3+) distance distribution with a maximum at 3.4 nm. The Gd(3+)-Gd(3+) distance distributions obtained are in good agreement with expectations from structural models that take into account the flexibility of the tags and their tethers to the cysteine residues. These results show that Gd(3+) labeling is a viable technique for distance measurements at high fields that features an order of magnitude sensitivity improvement, in terms of protein quantity, over X-band pulse EPR measurements using nitroxide spin labels. Its advantage over W-band distance measurements using nitroxides stems from an intrinsic absence of orientation selection.

Gadolinium tagging for high-precision measurements of 6 nm distances in protein assemblies by EPR

Double electron-electron resonance (DEER) distance measurements of a protein complex tagged with two Gd(3+) chelates developed for rigid positioning of the metal ion are shown to deliver outstandingly accurate distance measurements in the 6 nm range. The accuracy was assessed by comparison with modeled distance distributions based on the three-dimensional molecular structures of the protein and the tag and further comparison with paramagnetic NMR data. The close agreement between the predicted and experimentally measured distances opens new possibilities for investigating the structure of biomolecular assemblies. As an example, we show that the dimer interface of rat ERp29 in solution is the same as that determined previously for human ERp29 in the single crystal.

Structures of the thermophilic F1-ATPase ε subunit suggesting ATP-regulated arm motion of its C-terminal domain in F1

The ε subunit of bacterial and chloroplast FoF1-ATP synthases modulates their ATP hydrolysis activity. Here, we report the crystal structure of the ATP-bound ε subunit from a thermophilic Bacillus PS3 at 1.9-Å resolution. The C-terminal two α-helices were folded into a hairpin, sitting on the β sandwich structure, as reported for Escherichia coli. A previously undescribed ATP binding motif, I(L)DXXRA, recognizes ATP together with three arginine and one glutamate residues. The E. coli ε subunit binds ATP in a similar manner, as judged on NMR. We also determined solution structures of the C-terminal domain of the PS3 ε subunit and relaxation parameters of the whole molecule by NMR. The two helices fold into a hairpin in the presence of ATP but extend in the absence of ATP. The latter structure has more helical regions and is much more flexible than the former. These results suggest that the ε C-terminal domain can undergo an arm-like motion in response to an ATP concentration change and thereby contribute to regulation of FoF1-ATP synthase.

DOTA-Amide Lanthanide Tag for Reliable Generation of Pseudocontact Shifts in Protein NMR Spectra

Structural studies of proteins and protein-ligand complexes by nuclear magnetic resonance (NMR) spectroscopy can be greatly enhanced by site-specific attachment of lanthanide ions to create paramagnetic centers. In particular, pseudocontact shifts (PCS) generated by paramagnetic lanthanides contain important and unique long-range structure information. Here, we present a high-affinity lanthanide binding tag that can be attached to single cysteine residues of proteins. The new tag has many advantageous features that are not available in this combination from previously published tags: (i) it binds lanthanide ions very tightly, minimizing the generation of nonspecific effects, (ii) it produces PCSs with high reliability as its bulkiness prevents complete motional averaging of PCSs, (iii) it can be attached to single cysteine residues, alleviating the need of detailed prior knowledge of the 3D structure of the target protein, and (iv) it does not display conformational exchange phenomena that would increase the number of signals in the NMR spectrum. The performance of the tag is demonstrated with the N-terminal domain of the E. coli arginine repressor and the A28C mutant of human ubiquitin.

Spectroscopic selection of distance measurements in a protein dimer with mixed nitroxide and Gd3+ spin labels

The pulse DEER (Double Electron-Electron Resonance) technique is frequently applied for measuring nanometer distances between specific sites in biological macromolecules. In this work we extend the applicability of this method to high field distance measurements in a protein assembly with mixed spin labels, i.e. a nitroxide spin label and a Gd(3+) tag. We demonstrate the possibility of spectroscopic selection of distance distributions between two nitroxide spin labels, a nitroxide spin label and a Gd(3+) ion, and two Gd(3+) ions. Gd(3+)-nitroxide DEER measurements possess high potential for W-band long range distance measurements (6 nm) by combining high sensitivity with ease of data analysis, subject to some instrumental improvements.

W-band orientation selective DEER measurements on a Gd3+/nitroxide mixed-labeled protein dimer with a dual mode cavity.

Double electron-electron resonance (DEER) at W-band (95 GHz) was applied to measure the distance between a pair of nitroxide and Gd(3+) chelate spin labels, about 6 nm apart, in a homodimer of the protein ERp29. While high-field DEER measurements on systems with such mixed labels can be highly attractive in terms of sensitivity and the potential to access long distances, a major difficulty arises from the large frequency spacing (about 700 MHz) between the narrow, intense signal of the Gd(3+) central transition and the nitroxide signal. This is particularly problematic when using standard single-mode cavities. Here we show that a novel dual-mode cavity that matches this large frequency separation dramatically increases the sensitivity of DEER measurements, allowing evolution times as long as 12 μs in a protein. This opens the possibility of accessing distances of 8 nm and longer. In addition, orientation selection can be resolved and analyzed, thus providing additional structural information. In the case of W-band DEER on a Gd(3+)-nitroxide pair, only two angles and their distributions have to be determined, which is a much simpler problem to solve than the five angles and their distributions associated with two nitroxide spin labels.

Effect of nitrogen incorporation on electrical properties of boron-doped diamond films

The effect of a small amount of nitrogen incorporated in chemical vapor deposited diamond films on their electrical properties was studied. Upgrading the purity of CH4 gas from the conventional ultra-high purity to the grade with no detection of nitrogen resulted in improvement of electrical properties of the boron-doped homoepitaxial diamond films; the Hall mobility was increased by 4.3 times at the room temperature. Decrease in nitrogen concentration in the diamond films was confirmed by investigating the 2.16 eV center of cathodoluminescence induced by ion beam irradiation and subsequent annealing.

Proofreading exonuclease on a tether: the complex between the E. coli DNA polymerase III subunits α, ε, θ and β reveals a highly flexible arrangement of the proofreading domain

A complex of the three (αεθ) core subunits and the β2 sliding clamp is responsible for DNA synthesis by Pol III, the Escherichia coli chromosomal DNA replicase. The 1.7 Å crystal structure of a complex between the PHP domain of α (polymerase) and the C-terminal segment of ε (proofreading exonuclease) subunits shows that ε is attached to α at a site far from the polymerase active site. Both α and ε contain clamp-binding motifs (CBMs) that interact simultaneously with β2 in the polymerization mode of DNA replication by Pol III. Strengthening of both CBMs enables isolation of stable αεθ:β2 complexes. Nuclear magnetic resonance experiments with reconstituted αεθ:β2 demonstrate retention of high mobility of a segment of 22 residues in the linker that connects the exonuclease domain of ε with its α-binding segment. In spite of this, small-angle X-ray scattering data show that the isolated complex with strengthened CBMs has a compact, but still flexible, structure. Photo-crosslinking with p-benzoyl-L-phenylalanine incorporated at different sites in the α-PHP domain confirm the conformational variability of the tether. Structural models of the αεθ:β2 replicase complex with primer-template DNA combine all available structural data.

Stepwise Propagation of the ATP-induced Conformational Change of the F1-ATPase β Subunit Revealed by NMR

The rotation of F1-ATPase (F1) is driven by the open/close bending motion of the β subunit. The mechanism underlying the bending motion was investigated for the F1β monomer from thermophilic Bacillus PS3 (TF1β) in solution, using mutagenesis and NMR. The hydrogen bond networks involving the side chains of Lys-164 (numbering for TF1β; 162 for mitochondrial F1β in parentheses), Thr-165 (163), Arg-191 (189), Asp-252 (256), Asp-311 (315), and Arg-333 (337) in the catalytic region are significantly different for the ligand-bound and freeβ subunits in the crystal structures of mitochondrial F1. The role of each amino acid residue was examined by Ala substitution. β(K164A) reduced the affinity constant for 5′-adenyl-β,γ-imidodiphosphate by 20-fold and abolished the conformational change associated with nucleotide binding and the ATPase activity of α3β(K164A)3γ.β(T165A) andβ(D252A) exhibited no effect on the binding affinity but abolished the conformational change and the ATPase activity. The chemical shift perturbation of backbone amide signals of the segmentally labeled β(mutant) s indicated stepwise propagation of the open/close conversion on ligand binding. The key action in the conversion is the switching of the hydrogen-bonding partner of Asp-252 from Lys-164 to Thr-165. Residual dipolar coupling analysis revealed that the closed conformation of the β monomer was more closed than that in the crystal structure and was different for MgATP- and MgADP-boundβ subunits. Actually, MgATP induced a conformational change around Tyr-307 (311 for MF1β), whereas MgADP did not. The significance of these findings is discussed in connection with the catalytic rotation of F1-ATPase.

NMR study of complexes between low molecular mass inhibitors and the West Nile virus NS2B–NS3 protease

The two‐component NS2B–NS3 protease of West Nile virus is essential for its replication and presents an attractive target for drug development. Here, we describe protocols for the high‐yield expression of stable isotope‐labelled samples in vivo and in vitro. We also describe the use of NMR spectroscopy to determine the binding mode of new low molecular mass inhibitors of the West Nile virus NS2B–NS3 protease which were discovered using high‐throughput in vitro screening. Binding to the substrate‐binding sites S1 and S3 is confirmed by intermolecular NOEs and comparison with the binding mode of a previously identified low molecular mass inhibitor. Our results show that all these inhibitors act by occupying the substrate‐binding site of the protease rather than by an allosteric mechanism. In addition, the NS2B polypeptide chain was found to be positioned near the substrate‐binding site, as observed previously in crystal structures of the protease in complex with peptide inhibitors or bovine pancreatic trypsin inhibitor. This indicates that the new low molecular mass compounds, although inhibiting the protease, also promote the proteolytically active conformation of NS2B, which is very different from the crystal structure of the protein without inhibitor.