Crystalline structure of the gas vesicle wall from Anabaena flos-aquae.

The gas vesicles isolated from Anabaena flos-aquae have been studied by X-ray diffraction. Electron microscopy has previously shown that the gas vesicles are elongated shapes, with a thin wall having regular striations (ribs) at right-angles to the long axis. The X-ray diffraction pattern from a specimen of oriented, intact vesicles includes a number of sharp reflections which are attributed to regular structure in the plane of the wall. After correcting for the imperfect alignment of the long axes of the vesicles, the in-plane reflections are all seen to lie on a few, regularly spaced lines parallel to the long axis. This result shows for the first time that there are subunits regularly spaced along each rib, one subunit every 11 Å. The spacing of the in-plane reflections along each line is consistent with a rib periodicity of 46 Å. The 11 Å repeat, together with the 46 Å repeating distance from rib to rib and the average wall thickness of about 20 Å, define a volume for the subunit. Assuming a reasonable value for the density of the protein making up the wall, the molecular weight of the subunit indicated is about 8000 g/mol.The X-ray data also indicate that a large part of the protein is in the β-sheet conformation. In this structure there are parallel, or anti-parallel, polypeptide chains which are hydrogen-bonded to one another in a regular way to form a thin sheet. Assuming the wall contains β-sheet in two layers, one on top of the other and with the chains in each layer tilted at 35 ° to the long axis of the vesicle, we can explain a number of the X-ray observations: (1) oriented arcs with a Bragg spacing of 4.7 Å, which is the distance between the axes of neighbouring chains in each layer; (2) diffraction oriented in the direction of the chains at a spacing of 6 to 7 Å, which is the repeating distance of the dipeptide unit along the chain; (3) the 11 Å repeat, which is the repeating distance of pairs of chains along each rib; and (4) a broad band of diffraction at right-angles to the plane of the wall and centred at a spacing of 10 Å, which is a reasonable value for the distance between the mid-planes of the two sheets. Moreover, we can also find the remaining lattice parameter, the angle relating the centres of the subunits in neighbouring ribs. Thus the shortest line joining the centres makes an angle of 86 ° with the direction of the ribs.     

Structure of polar pili from Pseudomonas aeruginosa strains K and O

The polar pili of Pseudomonas aeruginosa strains K and O are hollow cylinders with 52 Å outer diameter and 12 Å inner diameter. There is a girdle of low electron density (interpreted as due to a local concentration of hydrophobic amino acid side-chains) centred at 31 Å diameter. Similar X-ray diffraction patterns are obtained from oriented fibres of the two types of pili, to a resolution of 7 Å in the equatorial direction and 4 Å in the meridional direction. The two types of pilin protein subunits have a similar molecular weight, and their sequences contain a number of homologous regions. They form a helical array with 4.06 to 4.08 units per turn of a basic helix that has a pitch of 40.8 Å for strain K pili and 41.3 Å for strain O pili at 75% relative humidity. A method is described for distinguishing between very similar diffraction patterns.There is strong intensity at 10 Å near the equator and at 5 Å near the meridian on the diffraction patterns. This intensity distribution is characteristic of α-helical rods running roughly in the direction of the fibre axis. The orientation of these rods was established by the fit between the transform of an α-helical polyalanine model and the strong near-equatorial layer-line.     

Morphological and structural studies of poly(gly-gly-ala)

The ultrastructural morphology and x-ray and electron diffraction of poly (Gly-Gly-Ala) have been studied. The polymer has two forms; the first, form I possesses a super-folded cross-β structure, long fibers of which show some twisting and intertwining. Form II precipitates in a less distinct fibrous form from aqueous solution. The x-ray diffraction and oriented electron diffraction data suggest that form II is a polyglycine II helix situated in a monoclinic cell with dimensions a = 8.86 Å, b = 22.0 Å, c = 9.42 Å, and β = 90°. Combined with the morphological evidence it appears likely that form II is also in an antiparallel superfolded array.     

A 12 Å resolution X-ray diffraction study of the profile structure of isolated bovine retinal rod outer segment disk membranes

Electron density profiles of disk membranes isolated from bovine retinal rod outer segments have been determined to 12 Å resolution by analysis of the X-ray diffraction from oriented multilayers, in the absence of lipid phase separation. Data were collected on both film and a two-dimensional TV-detector; both detectors yielded identical patterns consisting of relatively sharp lamellar reflections of small mosaic spread. The unit cell repeat was reversibly varied over the range of 143 to 183 Å. The diffraction patterns changed dramatically at 150 Å; consequently, the low (less than 150 Å) and high (greater than 150 Å) periodicity data were independently analyzed via a swelling algorithm. The high periodicity data yielded two statistically equivalent phase choices corresponding to two symmetric, but different membrane profiles. The low periodicity data yielded essentially one, characteristically asymmetric profile. These profiles have been modeled with regard to the separate profiles of rhodopsin, lipid and water, subject to the known composition of the isolated disk membranes.     

Pf1 bacteriophage replication-assembly complex: X-ray fibre diffraction and scanning transmission electron microscopy

X-ray fibre diffraction and scanning transmission electron microscopy have been used to investigate the structure of an intracellular complex between circular single-stranded viral DNA and a viral DNA-binding protein. This complex is an intermediate between replication and assembly of the filamentous bacteriophage Pf1. By scanning transmission electron microscopy, the complex has a length of 1.00 μm and M_r = 29.6 × 10⁶. It consists of 1770 protein subunits, each of 15,400 M_r, and one viral DNA molecule of 2.3 × 10⁶M_r: there are 4.2 ± 0.5 nucleotides per subunit. The structure is flexible in solution, but in oriented dry fibres it forms a regular helix of 45 Å pitch having 6.0 dimeric protein subunits per turn, with an axial spacing of 7.5 Å between dimers and 1.9 Å between adjacent nucleotides. Model calculations suggest that the protein dimers may be oriented in a direction approximately perpendicular to the 45 Å helix, so that each dimer spans the two anti-parallel DNA chains. The results imply that conformational changes are required of the DNA as it is transferred from the double-stranded form to the replication-assembly complex, and subsequently to the virion.     

The structure of the purple membrane from Halobacterium hallobium: analysis of the X-ray diffraction pattern.

An X-ray diffraction analysis of oriented specimens of the purple membrane from Halobacterium halobium shows that the protein and lipid components are packed in a P3 hexagonal lattice, with one protein molecule per asymmetric unit. The structure is made up of a single layer of the protein molecules, oriented vectorially in the same direction across the membrane.The presence of strong diffraction peaks equatorially centred at 10 Å, and axially at 5 Å and 1.5 Å, show that the protein molecules, which make up most of the mass of the membrane, are composed to a considerable extent of α-helices, 25 to 35 Å long, arranged roughly perpendicular to the plane of the membrane to form superhelical groupings of the “coiled-coil” type.The surface of the membrane is flat, with no bumps or dimples large enough to affect the X-ray pattern when the electron density of the suspending medium is altered. The phospholipids may be less exactly positioned in the lattice than the protein, since the presence of uranyl acetate, which is expected to co-ordinate with the acidic phosphate groups, produces intensity changes only at low resolution.     

Crystal structure of polyglycine I

An electron diffraction study has been made of oriented polyglycine I (the β modification of polyglycine) and of single crystals grown from solution. The unit cell is very similar to that postulated by Astbu?y (1949). It is monoclinic with parameters a = 9.54 Å, b(chainaxis) = 7.044 Å, c = 3.67 Å and β = 113°. Examination of the possible structures suggests that polyglycine I does not have the familiar antiparallel pleated sheet, but rather the closely related antiparallel rippled sheet structure first described by Pauling &; Corey (1953a).     

Neutron diffraction studies of oral stratum corneum model lipid membranes

In this work we have investigated model lipid mixtures simulating a lipid component of oral stratum corneum (OSC). Neutron diffraction experiments on oriented samples have revealed that SM (bovine brain)/dipalmitoylphosphatidylethanolamine/dipalmitoylphosphatidylcholine (DPPE/DPPC) mixtures at molar ratios of 1/2/1 and 1/1/1 are one-phase membranes. The incorporation of low concentrations of ceramide 6 and cholesterol into SM/DPPC/DPPE bilayers does not result in a phase separation, affecting membrane hydration. The model OSC membrane composed of ceramide 6/cholesterol/fatty acids/cholesterol sulfate/SM (bovine brain)/DPPE/DPPC is characterized by coexistence of several lamellar phases, that behave differently during their hydration in water excess. The phase with lamellar repeat distance of about 45 Å is likely a ceramide-rich phase and shows a restricted swelling in water, while another phase with repeat distance of 50 Å swells very quickly on 15 Å and then disappears. Our results indicate that phospholipid-rich and ceramide-rich domains could possibly coexist in the intercellular space of oral epithelium.     

Electron density levels of sarcoplasmic reticulum membranes

Low-angle X-ray diffraction has been recorded from oriented preparations of sacroplasmic reticulum membranes in fluid media containing glycerol solutions in different concentrations. Discrete diffraction orders of a lamellar repeat distance ranging from 200 Å to 250 Å have been recorded. Fourier synthesis at a resolution of 17 Å for 0, 10, 20, and 30% glycerol-treated sarcoplasmic reticulum membranes are described. An electron density scale in electrons/$\text{A}\text{?}{}^3$ for these Fourier syntheses has been determined. The question of the correctness of our asymmetric electron density profile for the sarcoplasmic reticulum membrane is critically examined. A study is made on the choice of phases and on the method used to process the X-ray intensities.     

The role of CS<Subscript>2</Subscript> in CS<Subscript>2</Subscript>/NMP mixed solvent in weakening the hydrogen bond of OH–N in coal: a DFT investigation

The interaction processes of trace amounts of N-methyl-2-pyrrolidinone (NMP), CS₂/NMP (1:1 by volume) and pure NMP solvent with the hydrogen bond of OH?N in coal were constructed and simulated by density functional theory methods. The distances and bond orders between the main related atoms, and the hydrogen bond energy of OH?N were calculated. The calculated results show that pure NMP solvent does not weaken the hydrogen bond of OH?N in coal. However, trace amounts of NMP and CS₂/NMP (1:1 by volume) have a strong capacity to weaken the hydrogen bond of OH?N in coal. The H2–N3 distances are elongated from 1.87 Å to 3.80 Å and 3.44 Å, the bond orders of H2–N3 all disappear, and the corresponding hydrogen bond energies of OH?N in coal decrease from 45.72 kJ mol^?1 to 7.06 and 11.24 kJ mol^?1, respectively. These results show that CS₂ added to pure NMP solvent plays an important role in releasing the original capacity of NMP to weaken the hydrogen bond of OH?N in coal, in agreement with experimental observations.     

A helical,polymeric extracellular protein associated with the luminal surface of Haemonchus contortus intestinal cells

The structure of the intestinal cells of the parasitic nematode Haemonchus contortus is described. The cells have numerous microvilli about 0.09 μ in diameter; most being 5.5–7.5 μ in length. The microvillar (plasma) membrane is coated with a layer of amorphous material (glycocalyx) about 60 Å thick which is electron dense in sectioned preparations. Associated with the surface of this material, and filling the spaces between the microvilli, are filaments in the form of helices about 400 Å in diameter and of variable pitch. The helices appear to be flexible but they are aligned approximately with the long axes of the microvilli. There are up to ten helices per microvillus; they extend beyond the tips of the microvilli and are up to 10 μ long. The material has been obtained nearly pure in small amounts. It is primarily protein and it is proposed that it should be called contortin. The monomeric form (of molecular weight about 60,000) has been identified with a Y-shaped structure with arms about 45 Å long and 25 Å wide seen in negatively stained preparations. The helical filament appears to be formed by lateral polymerization of pairs of these units.     

Structure of the cytochrome c oxidase dimer electron microscopy of two-dimensional crystals

We have studied the structure of beef heart mitochondrial cytochrome c oxidase dimers by image-processing of electron micrographs of the vesicle crystal form. Specimens were prepared by different procedures, which contrast different features of the crystals. Heavy-atom shadowing of freeze-dried crystals contrasts the exterior or M-side surface (mitochondrial matrix-side) and reveals a 100 Å long ellipsoidal dimer oriented with its long axis in the (?1, 1) direction of the 95 Å × 125 Å rectangular unit cell. The M-side surface structure correlates well with the intra-bilayer structure revealed by contrast matching extra-bilayer protein with glucose. Frozen suspensions of vesicle crystals fracture predominantly along hydrophilic surfaces revealing the interior C-side (mitochondrial cytoplasm-facing surface) of vesicle crystals. The C-side surface revealed in shadowed replicas of fracture surfaces shows the ends of the dimers furthest from the bilayer surface; they consist of two structural domains separated by 70 to 80 Å. We present a new interpretation of the structure of the cytochrome oxidase dimer based on these data and on the y-shaped monomer structure described by Fuller et al. (1979). A cytochrome oxidase dimer is formed from two y-shaped monomers joined along one set of identical M-domain arms with the other arms approximately 70 Å apart along a unit cell diagonal in the (?1, 1) direction. The arms of the monomers lie within and perpendicular to the phospholipid bilayer, and they protrude approximately 25 Å beyond the bilayer surface on the M-side. The y tails represent the C-side domains, which are closely apposed across the dimer 2-fold axis near the C-side bilayer surface. Further away from the bilayer surface, C-side domains split away from one another forming a large cleft.     

Gap junction structures: V. Structural chemistry inferred from X-ray diffraction measurements on sucrose accessibility and trypsin susceptibility

X-ray diffraction patterns have been recorded from partially oriented specimens of gap junctions isolated from mouse liver and suspended in sucrose solutions of different concentration and thus of different electron density. Analysis of these diffraction patterns has shown that sucrose is excluded from the 6-fold rotation axis of the junction lattice for a length of about 100 Å. This indicates that the aqueous channel of the junctions is in the closed, high resistance state in these preparations. Mapping of the sucrose-accessible space in the junction indicates that the cross-sectional area of the channel entrance on the cytoplasmic side of the membrane could be up to five times larger than the area of the transmembrane channel. Sucrose does not penetrate more than 20 Å into the membrane along the channel. Apparently the aqueous channel, 8 to 10 Å in radius for most of its length, is narrowed or blocked by a small feature about 50 Å from the center of the gap. Very close interactions exist between the gap junction protein and the lipid polar head groups on the cytoplasmic surface of the membrane. In this region, the protein intercalates between the polar head groups. These results suggest that the gap junction protein may have a functional two-domain structure. One domain, with a molecular weight of about 15,000, spans one bilayer and half of the gap and is contained largely within a radius of 25 Å from the 6-fold axis. The second domain is smaller and occupies the cytoplasmic surface of the gap junction membrane. Trypsin digestion removes about 4000 M_rmr from the cytoplasmic surface domain of the junction protein. Most of the material susceptible to trypsin digestion is located more than 28 å from the 6-fold axis.     

Mass,length, composition and structure of the filamentous bacterial virus fd

Determinations by three independent methods gave an average of (14.6 ± 0.6) × 10⁶ daltons for the anhydrous mass of the filamentous bacterial virus fd; a determination of the mass per unit length by light scattering of the virus in solution gave 1560 ±60 daltons/Å; and three independent methods show that 12.0±O.2% of the virus mass is from the single-stranded circular DNA molecule. The data give an average axial distance of 3.82 ±0.15 Å between major coat protein subunits (5240 daltons each) for virus in solution. The DNA has an up strand and a down strand within the filament, and an average axial distance of 3.29 ± 0.14 Å between neighbouring nucleotides in a given strand is obtained from the data. There are 2.32 ±0.07 nucleotides per major coat protein subunit and hence each of the nucleotides cannot interact in the same way with subunits of coat protein. The results provide a basis for the interpretation of X-ray diffraction patterns of oriented fibers of the virus. The uncertainties cited above are 95% confidence limits.     

X-ray diffraction and infrared studies of an -helical fragment from -keratin

Fragments of α-keratin were obtained by partial proteolysis of the low-sulphur protein fraction, S-carboxymethylkerateine-A, from wool. X-ray diffraction and infrared absorption studies were made on oriented films formed from these fragments. The results indicate that the fragments have a coiled-coil α-helical conformation similar to that in α-keratins, and that the films consist of particles approximately 160 Å in length arranged end-to-end.     

Filamentous bacteriophage Pf1 structure determined at 7 Å resolution by refinement of models for the α-helical subunit

The molecular structure of filamentous bacteriophage Pf1 has been determined to 7 Å resolution by analysis of X-ray diffraction data from partially oriented fibers of virus particles. The continuous intensity distribution along layer-lines was measured by numerically separating contributions from overlapping layer-lines. The data were phased by an iterative refinement technique that used the known spatial extent and high α-helical content of the virus particle to refine a structural model. This refinement converges to a unique structural solution that is consistent with the X-ray data and with information derived from physical and chemical studies. The coat protein consists of two α-helical segments: one, almost parallel to the particle axis, is centered at a radius of about 15 Å; the other, at about 25 Å radius, is tilted by about 25 ° to the particle axis. This structure is consistent with every generalization about α-helical packing. The inner and outer segments interlock along most of their length with a crossing angle of 20.5 °. The inner α-helical segments also interact with symmetry-related copies of themselves, as do the outer segments. The double layer of tightly packed, intricately interlocked α-helices forms a stable, 20 Å thick protein coat around the viral DNA.     

X-ray studies on the conformation of poly-N -carbobenzoxy-L- , -diaminobutyric acid and poly-N -carbobenzoxy-L-ornithine

X-ray diagrams from oriented films and fibers of poly-N^γ-carbobenzoxy-L -α,γ-diaminobutyric acid (PCLB) and of poly-N^δ-carbobenzoxy-L-ornithine (PCLO) have been examined. The conformation in the solid state for both polymers is that of an α-helix, 18/5 for PCLB and 11/3 for PCLO, respectively. Furthermore, while the PCLB molecules are packed in a trigonal lattice whose dimensions, on hexagonal axes, are a = 27.5 and c = 27.0 Å, the PCLO unit cell is monoclinic with a = 23.3, b = 22.7, c = 16.2 Å, and γ = 119.2°.     

The reaction center profile structure derived from neutron diffraction

Both reaction center protein from the photosynthetic bacteria Rhodopseudomonas sphaeroides and egg phosphatidylcholine can be deuterium labelled; the reaction center protein can be incorporated into the phosphatidylcholine bilayers forming a homogeneous population of unilamellar vesicles. The lipid profile and the reaction center profile within these reconstituted membrane profiles were directly determined to 32 Å resolution using lamellar neutron diffraction from oriented membrane multilayers containing either deuterated or protonated reaction centers, and either deuterated or protonated phosphatidylcholine. The 32 Å resolution reaction center profile shows that the protein spans the membranes, and has an asymmetric mass distribution along the perpendicular to the membrane plane. These results were combined with previously described X-ray diffraction results in order to extend the resolution of the derived reaction center profile to 9 Å.     

Filamentous Bacterial viruses

The filamentous bacterial virus is a simple and well-characterized model system for studying how genetic information is transformed into molecular machines. The viral DNA is a single-stranded circle coding for about 10 proteins. The major viral coat protein is largely α-helical, with about 46 amino acid residues. Several thousand identical copies of this protein in a helical array form a hollow cylindrical tube 1–2μ long, of outer diameter 60 Å and inner diameter 20 Å, with the twisted circular DNA extending down the core of the tube. Before assembly, the viral coat protein spans the cell membrane, and assembly involves extrusion of the coat from the membrane. X-ray fibre diffraction patterns of the Pf 1 species of virus at 4°C, oriented in a strong magnetic field, give three-dimensional data to 4 Å resolution. An electron density map calculated from native virus and a single iodine derivative, using the maximum entropy technique, shows a helix pitch of 5.9 Å. This may indicate a stretched A-helix, or it may indicate a partially 3₁₀ helix conformation, resulting from the fact that the coat protein is an integral membrane protein before assembly, and is still in the hydrophobic environment of other coat proteins after assembly.     

X-ray diffraction studies of bacterial pili

A sample of bacterial pili was prepared from Escherichia coli. An X-ray diffraction pattern was obtained from an oriented wet gel specimen in 0.01 m-phosphate buffer (pH 7.0) packed in a capillary tube. Sixteen independent spots were observed with the spacing of the outermost being 4.2 Å. Analysis of the diffraction pattern shows that the arrangement of subunits in pili rods is strictly simple-helical with 3.14₅ units being present in one turn of the helix and the axial rise per unit being 8.09_o Å.