A preliminary time-of-flight neutron diffraction study on amicyanin from Paracoccus denitrificans.

Crystals of the blue copper protein amicyanin suitable for neutron diffraction were grown by the sitting-drop method, followed by repeated macroseeding using solutions prepared with D(2)O. Although the crystal sizes were the same, crystals grown using solutions made up in H(2)O in the initial stages of macroseeding and solutions with D(2)O in later stages did not diffract neutrons well. However, when the protein was initially exchanged with buffered D(2)O and then crystallized and also macroseeded using solutions made up in D(2)O throughout, the crystals diffracted neutrons to high resolution. One of those crystals was used to collect a data set to a resolution of 1.9 A.

Enhanced visibility of hydrogen atoms by neutron crystallography on fully deuterated myoglobin.

Although hydrogens comprise half of the atoms in a protein molecule and are of great importance chemically and structurally, direct visualization of them by using crystallography is difficult. Neutron crystallography is capable of directly revealing the position of hydrogens, but its use on unlabeled samples faces certain technical difficulties: the large incoherent scattering of hydrogen results in background scattering that greatly reduces the signal to noise of the experiment. Moreover, whereas the scattering lengths of C, N, and O are positive, that of hydrogen is negative and about half the magnitude. This results in density for hydrogens being half as strong and close to the threshold of detection at 2.0-A resolution. Also, because of its opposite sign, there is a partial cancellation of the hydrogen density with that from neighboring atoms, which can lead to ambiguities in interpretation at medium resolution. These difficulties can be overcome by the use of deuterated protein, and we present here a neutron structure of fully deuterated myoglobin. The structure reveals a wealth of chemical information about the molecule, including the geometry of hydrogen bonding, states of protonation of histidines, and the location and geometry of water molecules at the surface of the protein. The structure also should be of broader interest because it will serve as a benchmark for molecular dynamics and energy minimization calculations and for comparison with NMR studies.

A low-resolution low-temperature neutron diffraction study of myoglobin.

Diffraction data to 5 A resolution were collected on a myoglobin crystal at 80, 130, 180 and 240 K. The linear coefficient of thermal expansion for myoglobin was determined to be 45 x 10(-6) K(-1), based on the measured expansion of the unit-cell parameters. The nature of the hydration layers surrounding the protein in the crystal is described in terms of a shell solvent model, which was used to calculate the coefficient of thermal expansion in reasonable agreement with the measured value. Wilson statistics were calculated and discussed in terms of an averaged disorder model. [F(T(2)) - F(80 K) exp(-iphi)] Fourier maps were calculated where T(2) was taken as 130, 180 and 240 K, respectively. None of these difference maps showed any features above 2.0sigma in the protein region. The 130 and 240 K difference maps showed many small and widely distributed negative difference features and showed very few positive difference features above 2.5sigma in the solvent region. However, the 180 K difference map showed an extensive negative difference feature at the interface between symmetry-related molecules, occurring in the vicinity of residues 40-50 on one molecule and 76-80 on a symmetry-related molecule. These difference neutron Fourier maps indicate a concerted effect at 180 K, which is interpreted in terms of an onset of extended lattice disorder.

High-level expression and deuteration of sperm whale myoglobin. A study of its solvent structure by X-ray and neutron diffraction methods.

Neutron diffraction has become one of the best ways to study light atoms, such as hydrogens. Hydrogen however has a negative coherent scattering factor, and a large incoherent scattering factor, while deuterium has virtually no incoherent scattering, but a large positive coherent scattering factor. Beside causing high background due to its incoherent scattering, the negative coherent scattering of hydrogen tends to cancel out the positive contribution from other atoms in a neutron density map. Therefore a fully deuterated sample will yield better diffraction data with stronger density in the hydrogen position. On this basis, a sperm whale myoglobin gene modified to include part of the A c11 protein gene has been cloned into the T7 expression system. Milligram amounts of fully deuterated holo-myoglobin have been obtained and used for crystallization. The synthetic sperm whale myoglobin crystallized in P2(1) space group isomorphous with the native protein crystal. A complete X-ray diffraction dataset at 1.5A has been collected. This X-ray dataset, and a neutron data set collected previously on a protonated carbon-monoxymyoglobin crystal have been used for solvent structure studies. Both X-ray and neutron data have shown that there are ordered hydration layers around the protein surface. Solvent shell analysis on the neutron data further has shown that the first hydration layer behaves differently around polar and apolar regions of the protein surface. Finally, the structure of per-deuterated myoglobin has been refined using all reflections to a R factor of 17%.

Myoglobin solvent structure at different temperatures.

The structure of the solvent surrounding myoglobin crystals has been analyzed using neutron diffraction data, and the results indicate that the water around the protein is not disordered, but rather lies in well-defined hydration shells. We have analyzed the structure of the solvent surrounding the protein by collecting neutron diffraction data at four different temperatures, namely, 80, 130, 180, and 240K. Relative Wilson Statistics applied to low resolution data showed evidence of a phase transition in the region of 180K. A plot of the liquidity factor, Bsn, versus distance from the protein surface begins with a high plateau near the surface of the protein and drops to two minima at distances from the protein surface of about 2.35A and 3.85A. Two distinct hydration shells are observed. Both hydration shells are observed to expand as the temperature is increased.

Understanding water: molecular dynamics simulations of myoglobin.

Molecular dynamics simulations were performed on CO myoglobin to evaluate the stability of the bound water molecules as determined in a neutron diffraction analysis. The myoglobin structure derived from the neutron analysis provided the starting coordinate set used in the simulation. The simulations show that only a few water molecules are tightly bound to protein atoms, while most solvent molecules are labile, breaking and reforming hydrogen bonds. Comparison between myoglobin in solution and in a single crystal highlighted some of the packing effects on the solvent structure and shows that water solvent plays an indispensable role in protein dynamics and structural stability. The described observations explain some of the differences in the experimental results of protein hydration as observed in NMR, neutron and X-ray diffraction studies.

Molecular dynamics simulation of hydration in myoglobin.

This study was carried out to evaluate the stability of the 89 bound water molecules that were observed in the neutron diffraction study of CO myoglobin. The myoglobin structure derived from the neutron analysis was used as the starting point in the molecular dynamics simulation using the software package CHARMM. After solvation of the protein, energy minimization and equilibration of the system, 50 ps of Newtonian dynamics was performed. This data showed that only 4 water molecules are continuously bound during the length of this simulation while the other solvent molecules exhibit considerable mobility and are breaking and reforming hydrogen bonds with the protein. At any instant during the simulation, 73 of the hydration sites observed in the neutron structure are occupied by water.

Hydration in protein crystallography.

Water in close proximity to the protein surface is fundamental to protein folding, stability, recognition and activity. Protein structures studied by diffraction methods show ordered water molecules around some charged, polar, and non-polar (hydrophobic) amino acids, although the later are only observed when they are at the interface between symmetry related molecules in the crystal. Water networks surrounding the protein have been observed for small proteins. Crystallographically observed water molecules are referred to as bound structural water molecules. During crystallographic data analysis, bound water molecules are often treated as though they belong to the protein. Recent developments in the treatment of the bulk solvent contribution to the low order diffraction data allow a better evaluation of the surface structure of the protein and a better localization of bound waters. The mobility of bound waters is studied by means of temperature and occupancy factors. The bulk solvent has relatively large disorder (liquid like) which is represented by liquidity factors. Within this context water layers surrounding the protein have little mobility.

Neutron diffraction study of carbonmonoxymyoglobin.

Neutron diffraction data from a crystal of carbonmonoxymyoglobin were refined by PROLSQ, a modern restrained least-squares procedure in reciprocal space, in conjunction with a solvent analysis technique, to a final R-factor of 11.3%. The ligand CO occupies two sites and its binding conformations are distorted from the linear conformation. The N epsilon atom of the distal histidine residue is deprotonated (not deuterated), and a water molecule is bound to the N delta atom of the distal histidine. The side-chain of Lys56 (D6) exists in two alternative charge-binding sites. His24 (B5) and His119 (GH1) share a hydrogen atom. His12 (A10) and His36 (C1) are deprotonated. The deprotonated imidazole ring of His12 (A10) may act as a hydrogen-bond acceptor. The heme group is planar within 0.09 A root-mean-square (r.m.s.) deviation from planarity. The solvent environments for the two propionic acid groups are different. The side-chain of Arg45 (CD3) forms hydrogen bonds with the side-chain of Asp60 (E3) and one of the two propionic acid groups. An average N-2H . . . O angle in helical regions is 147 (+/- 11) degrees. Eleven main-chain amide hydrogen atoms from hydrophobic residues do not exchange with deuterium. The overall atomic occupancy factors for the main-chain and side-chain atoms are quite uniform, at 0.97 (+/- 0.07) and 0.93 (+/- 0.10), respectively, as shown by an occupancy analysis made at the end of the refinement procedure.

Small-angle neutron scattering from the reconstituted TF1 of H(+)-ATPase from thermophilic bacterium PS3 with deuterated subunits.

Subunits alpha, beta and gamma of adenosine triphosphatase (H(+)-ATPase) from the thermophilic bacterium PS3 (TF1) have been over-expressed in Escherichia coli. alpha and beta subunits deuterated to the level of 90% were obtained by culturing E. coli in 2H2O medium. Both the subunits and the reconstituted alpha beta gamma complex, TF1, which contain the deuterated components in various combinations, were studied in solution by small-angle neutron scattering. The individual shapes of the subunits and their organization in the alpha beta gamma-TF1 complex were examined using the techniques of selective deuteration and contrast variation. The alpha and beta subunits are well approximated as ellipsoids of revolution having minor semi-axes of 20.4(+/- 0.4) and 20.0(+/- 0.2) A, and major semi-axes of 53.0(+/- 1.4) and 55.8(+/- 0.9) A, respectively. In the TF1 complex, three beta subunits are aligned to form an equilateral triangle, with their major axes tilted by 35 degrees with respect to the 3-fold axis of the complex. The beta-beta distance is about 53 A. Three alpha subunits are similarly arranged, positioned between the beta subunits, and with their direction of tilt opposite to that of the beta subunits. The centers of the alpha and beta subunits lie in the same plane, forming a hexagon. Adjacent subunits overlap in this model, suggesting that they are not simple ellipsoids of revolution.

Solvent effect in protein crystals. A neutron diffraction analysis of solvent and ion density.

In protein crystallography, it has been customary to omit the low-order data in refinement procedures. These data contain, however, important information about the gross features of the unit cell content and particularly the scattering density of the solvent, i.e. solvent structure. In order to use the low-order Bragg reflections, a solvent evaluation procedure has been developed that permits the description of the low-order structure factors (F) as a combination of solvent and protein terms. This permits the use of all observed F values in a least-squares refinement, results in better refinement (lower R factor) and permits easier placement of water and ion locations. Coupled with the measurement of the crystal density by a density-gradient technique, the evaluation of the solvent scattering makes it possible to determine the amount of salt present in the solvent space. For myoglobin crystals grown from solutions containing close to 40% (w/w) ammonium sulfate only 13% (w/w) of salt is present in the solvent space. This is equivalent to seven (ionized) ammonium sulfate molecules, which is larger than the two to three sulfate ions observed in the crystal solvent space by X-ray diffraction.

A complete mapping of the proteins in the small ribosomal subunit of Escherichia coli.

The relative positions of the centers of mass of the 21 proteins of the 30S ribosomal subunit from Escherichia coli have been determined by triangulation using neutron scattering data. The resulting map of the quaternary structure of the small ribosomal subunit is presented, and comparisons are made with structural data from other sources.

Low-angle neutron scattering analysis of Na/K-ATPase in detergent solution.

Purified Na/K-ATPase from guinea pig renal outer medulla has been delipidated and solubilized in Brij 58 (polyoxyethylene ether; C-16, E-20). At a concentration of 2 mg of Brij 58/mg of protein, about one-half the enzyme complement was solubilized and almost 50% of Na/K-ATPase activity was retained by the enzyme-micelle complex. Guinier plots of the neutron scattering profiles yielded no evidence of heterogeneity with respect to subunit composition or the state of aggregation in the solubilized oligomers. Contrast matching with D2O used to obtain estimates of the molecular weight of the micellar form of Na/K-ATPase gave a mean value of 310,000 +/- 42,700, which corresponds to an alpha 2 beta 2 tetramer. A Stuhrmann plot of the neutron scattering data yielded an estimated radius of gyration of 67 A. The Stuhrmann plot also indicated an asymmetrical distribution of neutron scattering density. On the basis of the Stuhrmann plot parameters, the estimated molecular weight, and the radius of gyration, a low-resolution model was formulated of the oligomeric unit of Na/K-ATPase.

Quantitation of water in membranes by neutron diffraction and X-ray techniques.

The general principle of placing neutron and X-ray scattering density profiles on an absolute scale is being applied to an increasing number of problems in structural biology. This maximizes the information from the experiments by facilitating the identification of various molecular species. The greater detail available on the membrane water distribution has been highlighted in this chapter. The quantitative analysis of water in the headgroup region and the intermembrane water layer provides valuable information on membrane structure and function. The single most important limitation of the method is the lack of resolution. Improvements in experimental techniques will improve the resolution in a number of situations.

5-A Fourier map of gramicidin A phased by deuterium-hydrogen solvent difference neutron diffraction.

Crystals of ion-free gramicidin A (P212121: a = 24.61, b = 32.28, c = 32.52) have been investigated using neutron diffraction. A difference analysis of crystals soaked in ethanol/H2O as opposed to ethanol-d6/D2O has led to single isomorphous replacement Fourier projections of the structure at 5-A resolution. The gramicidin dimer appears to be a 32-A-long cylinder oriented parallel to the c-axis in these crystals.