Anomalous Difference Fourier Map Research Articles

Crystal structure of an indigoidine synthase A (IndA)‐like protein (TM1464) from Thermotoga maritima at 1.90 Å resolution reveals a new fold

Crystal structure of an indigoidine synthase A (IndA)‐like protein (TM1464) from <i>Thermotoga maritima</i> at 1.90 Å resolution reveals a new fold

Structural Basis of Citrate-dependent and Heparan Sulfate-mediated Cell Surface Retention of Cobra Cardiotoxin A3

Anionic citrate is a major component of venom, but the role of venom citrate in toxicity other than its inhibitory effect on the cation-dependent action of venom toxins is poorly understood. By immobilizing Chinese hamster ovary cells in microcapillary tubes and heparin on sensor chips, we demonstrated that heparan sulfate-mediated cell retention of the major cardiotoxin (CTX) from the Taiwan cobra, CTX A3, near membrane surfaces is citrate-dependent. X-ray determination of a CTX A3-heparin hexasaccharide complex structure at 2.4 A resolution revealed a molecular mechanism for toxin retention in which heparin-induced conformational changes of CTX A3 lead to citrate-mediated dimerization. A citrate ion bound to Lys-23 and Lys-31 near the tip of loop II stabilizes hydrophobic contact of the CTX A3 homodimer at the functionally important loop I and II regions. Additionally, the heparin hexasaccharide interacts with five CTX A3 molecules in the crystal structure, providing another mechanism whereby the toxin establishes a complex network of interactions that result in a strong interaction with cell surfaces presenting heparan sulfate. Our results suggest a novel role for venom citrate in biological activity and reveal a structural model that explains cell retention of cobra CTX A3 through heparan sulfate-CTX interactions.

Structural and Kinetic Analyses of the Interaction of Anthrax Adenylyl Cyclase Toxin with Reaction Products cAMP and Pyrophosphate

Anthrax edema factor (EF) raises host intracellular cAMP to pathological levels through a calcium-calmodulin (CaM)-dependent adenylyl cyclase activity. Here we report the structure of EF.CaM in complex with its reaction products, cAMP and PP(i). Mutational analysis confirmed the interaction of EF with cAMP and PP(i) as depicted in the structural model. While both cAMP and PP(i) have access to solvent channels to exit independently, PP(i) is likely released first. EF can synthesize ATP from cAMP and PP(i), and the estimated rate constants of this reaction at two physiologically relevant calcium concentrations were similar to those of adenylyl cyclase activity of EF. Comparison of the conformation of adenosine in the structures of EF.CaM.cAMP.PP(i) with EF.CaM.3.dATP revealed about 160 degrees rotation in the torsion angle of N-glycosyl bond from the +anti conformation in 3.dATP to -syn in cAMP; such a rotation could serve to distinguish against substrates with the N-2 amino group of purine. The catalytic rate of EF for ITP was about 2 orders of magnitude better than that for GTP, supporting the potential role of this rotation in substrate selectivity of EF. The anomalous difference Fourier map revealed that two ytterbium ions (Yb(3+)) could bind the catalytic site of EF.CaM in the presence of cAMP and PP(i), suggesting the presence of two magnesium ions at the catalytic site of EF. We hypothesize that EF could use a "histidine and two-metal ion" hybrid mechanism to facilitate the cyclization reaction.

Metal sites in 3,4-dihydroxy-2-butanone 4-phosphate synthase from Methanococcus jannaschii in complex with the substrate ribulose 5-phosphate.

The crystal structure of Methanococcus jannaschii 3,4-dihydroxy-2-butanone 4-phosphate synthase in complex with the substrate ribulose 5-phosphate at a dimetal centre has recently been determined at 1.7 A resolution. The enzyme converts ribulose 5-phosphate into 3,4-dihydroxy-2-butanone 4-phosphate, while its C4 atom is released as formate. The resulting four-carbon body supplies all eight C atoms for the xylene moiety of riboflavin. Three of the four hydroxyl groups of ribulose 5-phosphate were coordinated by the metal ions. Based on crystallographic refinement, the metals were assigned as zinc and calcium, which were present in the crystallization buffer. Neither metal supports the enzymatic reaction. In the present study, the correctness of this assignment is assessed using anomalous diffraction data collected at the high-energy side of the zinc absorption edge (lambda = 1.2823 A). Only the three tentative zinc ions give strong peaks in an anomalous difference Fourier map (>20sigma), whereas the four tentative calcium ions do not show anomalous signals above the noise level. These results confirm the initial assignment. In addition, the resolution was improved to 1.55 A.

Crystal structure of the Escherichia coli YcdX protein reveals a trinuclear zinc active site.

Crystal structure of the Escherichia coli YcdX protein reveals a trinuclear zinc active site.

Applications of anomalous scattering from S atoms for improved phasing of protein diffraction data collected at Cu Kalpha wavelength.

The anomalous signal of S atoms is easily detected at the Cu Kalpha wavelength of a non-synchrotron source with current data-collection methods. The position of sulfur and other anomalous scatterers can be located through an anomalous difference Fourier map (F+ - F-, phi(calc) - 90 degrees). It has been discovered experimentally that even low-quality preliminary phases are often sufficient to find anomalous scatterers. Their anomalous signal in the native crystal can contribute to significant improvement in phase refinement. This technique has been applied to solve the crystal structures of orthorhombic lysozyme and thaumatin. Furthermore, the structure of trypsin was solved using only the diffraction data set from a native crystal collected at a single wavelength (Cu Kalpha) from a rotating-anode X-ray generator. The anomalous scattering of sulfur was essential to solve the structure of trypsin which was initially phased from a single intrinsic Ca2+ atom. The positions of the S atoms of lysozyme and thaumatin were found using the initial SIRAS phases and used in phase refinement. The overall figures of merit and those in each resolution shell were consistently improved. This resulted in much improved electron-density maps even when the diffraction data were limited to 2.5 A resolution or worse. Furthermore, peaks from S atoms and other anomalous scatterers in anomalous difference Fourier maps can confirm the tracing of the peptide chain and also provide independent unbiased confirmation of molecular-replacement results. Thus, the anomalous signal of S atoms can contribute to many aspects of solving protein structures and should be used routinely.

Selenomethionine Incorporation in Saccharomyces cerevisiae RNA Polymerase II

A protocol for the incorporation of SeMet into yeast proteins is described. Incorporation at a level of about 50% suffices for the location of Se sites in an anomalous difference Fourier map of the 0.5 MDa yeast RNA polymerase II. This shows the utility of the approach as an aid in the model-building of large protein complexes.

Use of CrKα radiation to enhance the signal from anomalous scatterers including sulfur

The anomalous signals from scatterers such as sulfur (S) and arsenic (As) were compared in diffraction data sets collected from an X-ray source with three different targets, Au, Cu and Cr, on a multi-target rotating anode. HIV-1 integrase crystals served as the test case for this study. The crystalline specimen of HIV-1 integrase contains in each protein molecule two As atoms, each covalently bound to a cysteine S atom, and two additional S atoms derived from methionine. It was found that the CrKα radiation gave the clearest peaks in anomalous difference Fourier maps, although the signal-to-noise ratios of the anomalous signal for the CuKα and CrKα data were similar but better than that for AuLα. This result was in spite of the fourfold higher flux from the Cu anodeversusthe Cr anode. For all three X-ray wavelengths, anomalous difference Fourier maps calculated with bias-removed phases derived from the known atomic model revealed clear peaks at the two As sites. However, only in the map calculated using the CrKα data were both peaks of the expected ellipsoidal shape, enveloping the As atom and the adjacent S atom. None of the S sites was apparent in difference maps calculated using the AuLα data. The ability to enhance the S-derived anomalous signal using CrKα radiation has particularly useful applications in the structure determination of proteins, for example in resolving ambiguities in the chain tracing of a protein with numerous disulfide bonds and in assigning amino acid identities. Additionally, anomalous difference Patterson maps calculated from the CrKα data were sufficiently clear to identify the As-related peaks. These results form the groundwork for in-house phase determination with the multi-wavelength anomalous diffraction method.

Crystallization and preliminary diffraction studies of two quinoprotein alcohol dehydrogenases (ADHs): a soluble monomeric ADH from Pseudomonas putida HK5 (ADH-IIB) and a heterotrimeric membrane-bound ADH from Gluconobacter suboxydans (ADH-GS).

Crystals of a soluble monomeric quinocytochrome alcohol dehydrogenase (ADH-IIB) and of a trimeric membrane-associated quinocytochrome alcohol dehydrogenase (ADH-GS) have been obtained. The ADH-IIB crystals are triclinic, with one monomer in the unit cell, and were obtained in the presence of PEG 8000, sodium citrate, HEPES buffer and 2-propanol. X-ray data were collected at 110 K to 1. 9 A resolution (R(merge) = 6.4%) and the orientation of a methanol dehydrogenase search molecule (from Methylophilus methylotrophus W3A1) was obtained by molecular replacement. Preliminary refinement of this model (10.0-3.0 A resolution, R = 0.37, R(free) = 0.40) led to tentative identification of the two highest peaks in a native anomalous difference Fourier map as the Fe atom of the heme and a calcium ion interacting with the PQQ prosthetic group. The ADH-GS crystals are tetragonal, displaying six similar lattices, both primitive and centered, and were grown by the sitting-drop method after replacement of Triton X-100 by dodecylmaltoside or octaethylene glycol monododecyl ether in the presence of ammonium sulfate and sodium acetate buffer, with and without PEG 3500 and calcium ion. The best diffraction is obtained at 110 K where the resolution extends to about 4 A in the a and b directions and about 3 A in the c direction.

Crystallization and a 5 A X-ray diffraction study of Aphanothece sacrum ferredoxin.

A chloroplast-type ferredoxin containing two non-heme iron and two labile sulfur atoms per molecule was prepared from Aphanothece sacrum. Crystals were obtained by dialysis against 75% saturated a-monium sulfate solution, and belong to the tetragonal system with cell dimensions a = b = 92.2 A and c = 47.6 A, containing four molecules in an asymmetric unit. The electron density map at 5 A resolution was calculated by using the best phase angles determined by the single isomorphous replacement method coupled with the anomalous dispersion effect. An anomalous dispersion difference Fourier map for the native crystal clearly showed four humps corresponding to the iron atoms in an asymmetric unit. The electron densis surface.