5.5 Å crystallographic structure of penicillin β-lactamase and radius of gyration in solution

An electron density map of crystalline R-TEM Escherichia coli β-lactamase (penicillinase) has been calculated from X-ray diffraction data at 5.5 Å resolution with protein phases based on Friedel mates from a high-quality samarium derivative. The mean figure of merit for 854 independent reflections is 0.75. The monomeric molecule is slightly ellipsoidal and contains one and possibly two regions of α-helix which are 25 Å long. The Crystallographic search for the substrate binding site has so far been inconclusive. The radius of gyration of the enzyme in solution at pH 7 is 17.1 ± 1.0 Å from small-angle X-ray scattering measurements. This compares with 18.6 å calculated from the low-resolution electron density map of the molecule in the crystal.     

A low-resolution model of crystalline methionyl-transfer RNA synthetase from Escherichia coli

When submitted to a controlled proteolysis by trypsin, native methionyl-tRNA synthetase from Escherichia coli (a dimer of molecular weight 172,000) yields a well-defined fragment of molecular weight 64,000 composed of one single polypeptide chain. This fragment retains full specificity towards methionine and tRNA^met, and has unimpaired activity in both the activation reaction and aminoacyl-tRNA formation. Crystals of this active fragment have been studied by X-ray crystallography and, using two isomorphous heavy-atom derivatives, a 4 Å electron density map has been calculated.The molecule appears as an elongated ellipsoid of overall dimensions 90 Å × 43 Å × 43 Å. It is clearly built of two parts separated by a large cleft. The volume of one of these “domains” is approximately twice that of the other; these results are consistent with our present knowledge of the chemistry of the protein.     

X-ray crystallographic studies of seal myoglobin: The molecule at 2.5 Å resolution

The three-dimensional structure of metmyoglobin from the common seal has been determined at 2.5 Å resolution. The isomorphous replacement technique has been employed using two derivatives, the mercuri-iodide and the aurichloride. Four-circle diffractometer data to a Bragg angle θ = 18.05 ° were measured for one complete set of Friedel pairs of reflexions from each type of protein crystal. Atomic positions for the individual atoms in the (HgI^?₃₎-group at the two sites of attachment were obtained from three-dimensional difference electron density maps and were further refined. A ‘best’ electron density map of the native protein based on refined heavy-atom parameters was interpreted with the help of the known amino acid sequence, and co-ordinates for all the non-hydrogen atoms were measured from the model. Those of the globin were further constrained according to the ‘modelfit’ procedure of Dodson et al. (1976). The molecule is described in detail; the conformations of the side-chains relative to the positions of the heavy atoms and to the interface between neighbouring molecules are discussed. A preliminary residue by residue comparison of the seal and sperm whale myoglobin molecules is presented in the accompanying paper.     

Application of the automated interpretation of electron density maps to Bence-Jones protein Rhe

The automated system for interpreting electron density maps of proteins has been applied to a newly calculated map of Bence-Jones protein Rhe. In order to test the methods and criteria incorporated in the program system, interpretation of Rhe was performed independently of the interpretation by Wang et al. (1974, 1975a,b²), who have used classical Richards box techniques. The automated system produced a single polypeptide chain which accounts for the whole molecule. Much of the secondary structure is detected and atomic co-ordinates are built for most of the main-chain atoms. The results indicate that the program system is able to interpret and build provisional main-chain co-ordinates for an electron density map of reasonable quality.     

Determination of chemical identity and occupancy from experimental density maps

Three basic electronic properties of molecules, electron density (ED), charge density (CD), and electrostatic potentials (ESP), are dependent on both atomic mobility and occupancy of components in the molecules. Small protein subunits may bind large macromolecular complexes with a reduced occupancy or an increased atomic mobility or both due to affinity‐based functional regulation, and so may substrates, products, cofactors, ions or solvent molecule to the active sites of enzymes. A quantitative theory is presented in this study that describes the dependence of atomic functions on atomic B‐factor in Fourier transforms of the corresponding maps. An application of this theory is described to an experimental ED map at 1.73‐Å resolution, and to an experimental CD map at 2.2‐Å resolution. All the three density functions are linearly proportional to occupancy when the structure factor F(000) term of Fourier transforms of experimental density maps is included. Upon application of this theory to both experimental CD and ESP maps recently reported for photosystem II‐light harvesting complex II supercomplex at 3.2‐Å resolution, the occupancy of two extrinsic protein subunits PsbQ and PsbP is determined to be 20.4 ± 0.2%, and the negative mean ESP value of vitreous ice displaced by the supercomplex on electron scattering path is estimated to be 3% of the mean ESP value of protein α‐helices.     

A crystallographic model for azurin a 3 A resolution.

The structure of the blue copper protein azurin (M_r 14,000) from Pseudomonas aeruginosa has been determined from a 3.0 Å resolution electron density map computed with phases based on a uranyl derivative to 3 Å resolution and a platinum derivative to 3.7 Å. Interpretation of the somewhat noisy map was based on comparison of the density of the four molecules in the asymmetric unit with their averaged density. The polypeptide chain folds into an eight-strand β barrel with an additional flap containing a short helix. The copper atom is bound at one end and on the inside of the barrel, probably to a cysteine, a methionine, and two histidine residues.     

X-ray analysis of the disk of tobacco mosaic virus protein. 3. A low resolution electron density map

The structure of the disk of tobacco mosaic virus protein at low resolution has been determined by X-ray crystal analysis. Signs for the three principal projections were found by isomorphous replacement, using a mercury derivative. The heavy-atom positions were located by interpretation of difference Patterson maps on the basis of the non-crystallographic 17-fold rotational symmetry of the disk, and of the packing of the disks determined in the preceding paper (Finch et al., 1974).The electron density in the corresponding three projections was computed to a resolution of 6 Å. From the projections in the [100] and [010] directions, which are at right-angles to the 17-fold rotation axis, a three-dimensional electron density map has been calculated making use of the non-crystallographic symmetry. The procedure is similar to the three-dimensional image reconstruction technique used in electron microscopy.The map indicates that the subunits in the two rings face the same way and, hence, that the disk is polar. There are differences between the subunits in the two rings at high radius, which are presumably a consequence of the pairing interaction responsible for stabilizing the two-layer polar structure. The map has been compared with a low-resolution map of the intact virus, and certain common features can be identified, notably the site of the nucleic acid.     

The crystal structure of phosphorylase beta at 6 A resolution

The determination of the crystal structure of phosphorylase b in the presence of IMP at 6 Å resolution is described. The structure determination is based on two heavy-atom isomorphous derivatives and their anomalous contributions. The molecular boundary is clearly distinguishable in the electron density map, except in the region of subunit-subunit contact about the crystallographic dyad axis, which is the symmetry axis of the dimer. The dimer molecule is roughly ellipsoidal in shape with dimensions 63 Å × 63 Å × 116 Å. There is a pronounced cavity on the enzyme surface but it is not yet known if this is a substrate binding site.     

Spatial organization of catalase proteins

The three-dimensional structure of the heme-containing fungal catalase fromPenicillium vitale (m.m. 2,80,000) has been studied by X-ray analysis at 2.0 A resolution. The molecule is tetramer, each subunit contains 670 aminoacid residues identified to construct “X-ray” primary structure. The subunit is built of three compact domains and their connections. The first domain of about 350 residues contains aβ-barrel flanked by helices, the second domain of 70 residues is formed by four helices and the third one is composed of 150 residues and is topologically similar to flavodoxin. The active site including heme is deeply buried near theβ-barrel. A comparison of the structure of catalase fromPenicillium vitale with that of beef liver catalase revealed very close structural homology of the first and the second domain, but the third domain is entirely absent in beef liver catalase. A catalase from thermophillic bacteriaThermus thermophilus (m.m. 2,10,000) has been first isolated, crystallized and studied by X-ray analysis. Crystals are cubic, space group is P2₁3, a = 133.4 Å. The molecule is a hexamer with trigonal symmetry 32. The electron density map at 3 Å resolution made it possible to trace the polypeptide chain. The main structural motif is formed by four near parallel helices. There is no heme inThermus thermophilus catalase, the active site is between the four helices and contains two manganese ions.     

Low resolution structure of adenylate kinase

A low resolution model of adenylate kinase has been derived from a 6 Å electron density map. The molecular shape can be described approximately as an oblate ellipsoid with dimensions 40 Å × 40 Å × 30 Å. The molecule is composed of two globular units separated by a 10 Å deep cleft. In contrast to the bigger unit, the smaller globule appears to contain a high amount of α-helical structure. The location of the active centre is discussed.The crystals used for X-ray diffraction analysis belong to one of the enantiomorphic trigonal space groups P3₁21 or P3₂21, with one molecule in the asymmetric unit. The phase determination was based on four isomorphous heavy atom derivatives. Frequent transitions between different crystal forms complicate the analysis.     

The positions of the N-terminus and residue 68 in tobacco mosaic virus

Specific chemical modifications of the tobacco mosaic virus coat protein lead to new heavy-atom derivatives. They can be used for the determination of phases in the isomorphous replacement method, but more important they are necessary as markers if one wants to trace the polypeptide chain through an electron density map of limited resolution (10 Å). In addition to the positions of two residues known from previous work, two more residues out of the 158 have now been located in three dimensions. The N-terminus is at the outside of the particle (r = 88 Å), and Lys-68 lies at a radius of 72 Å.     

Automated interpretation of electron density maps as applied to Bence-Jones protein Rhe

Previous results obtained from the computerized interpretation (Greer, 1976) of a 3.0 Å electron density map of Bence—Jones protein Rhe have been compared with results (Wang et al., 1979) obtained by classical Richards' box techniques (Richards, 1968). Although the overall agreement between the two models is generally good, the computerized results contain several significant errors in the assignment of α-carbon atoms, which in our opinion are unlikely to be corrected without using human intervention together with other methods. However this test does show that the computerized method has potential.     

Location of the N-acetyl-d-neuraminic acid binding site in wheat germ agglutinin: A crystallographic study at 2.8 Å resolution

The crystal structure of the non-covalent complex between wheat germ agglutinin (isolectin no. 2) and N-acetyl-d-neuraminic acid, a saccharide widely found at the termini of carbohydrate chains in membrane glycoproteins and known to interact with wheat germ agglutinin, has been determined from an electron density difference map at 2.8 Å resolution. This map exhibits two strong binding sites on the wheat germ agglutinin dimer molecule which are located in corresponding crevices at the protomer/protomer interface. Amino acid sidechains from B and C-type domains of opposite protomers contribute to the binding site. The N-acetylneuraminic acid molecule is oriented such that its acetyl group becomes essentially buried upon binding, whereas the charged carboxylate and the glycerol groups point away from the protein surface, but are also able to make contact with surface side-chains. Model building shows that substituents of the pyranoside ring which had been predicted as essential for binding from solution studies, are situated favorably to allow interactions to be made with main and side-chain atoms of the protein molecule.     

Structure of yeast hexokinase. II. A 6 angstrom resolution electron density map showing molecular shape and heterologous interaction of subunits

An electron density map of yeast hexokinase has been calculated at 6 Å resolution using six heavy atom derivatives. The map shows each of the enzyme's two 51,000 molecular weight subunits to consist of two separate lobes connected by a narrow bridge of density. Furthermore, these two subunits are related to each other in the asymmetric unit of the crystal by a quasi-2-fold rather than a true 2-fold axis. That is, they are related by a rotation of 180 ° plus a relative translation of 3.6 Å along the symmetry axis. This gives rise to a heterologous subunit interaction and a possibility of non-identical structure and function for these chemically identical subunits. The molecule is quite asymmetric, having dimensions of 150 Å × 45 Å × 55 Å. Each subunit is about 80 Å × 40 Å × 50 Å.A portion of an electron density map at 3 Å resolution has been also calculated, based on phases from two heavy atom derivatives. Polypeptide backbone and side chains are visible in this map.     

Cryo‐EM map interpretation and protein model‐building using iterative map segmentation

A procedure for building protein chains into maps produced by single‐particle electron cryo‐microscopy (cryo‐EM) is described. The procedure is similar to the way an experienced structural biologist might analyze a map, focusing first on secondary structure elements such as helices and sheets, then varying the contour level to identify connections between these elements. Since the high density in a map typically follows the main‐chain of the protein, the main‐chain connection between secondary structure elements can often be identified as the unbranched path between them with the highest minimum value along the path. This chain‐tracing procedure is then combined with finding side‐chain positions based on the presence of density extending away from the main path of the chain, allowing generation of a C_α model. The C_α model is converted to an all‐atom model and is refined against the map. We show that this procedure is as effective as other existing methods for interpretation of cryo‐EM maps and that it is considerably faster and produces models with fewer chain breaks than our previous methods that were based on approaches developed for crystallographic maps.     

Structure of yeast hexokinase. 3. Low resolution structure of a second crystal form showing a different quaternary structure, heterologous interaction of subunits and substrate binding

A 7 Å resolution electron density map of a second crystal form (called BII) of yeast hexokinase B has been obtained. This crystal form, unlike the first crystal form (BI), binds nucleotide and sugar substrates. While the overall tertiary structure of each subunit appears to be largely the same in both crystal forms, the quaternary structure of the dimer is completely different in the two crystals. The two subunits in the crystallographic asymmetric unit of form BII are related by a molecular screw axis; that is, the two subunits are related by a 160 ° rotation and a 13 Å translation of one subunit relative to the other along the symmetry axis resulting in non-equivalent environments for the two chemically identical subunits. A deep cleft divides each subunit into two domains or lobes of roughly equal size. The helical regions which are clearly visible as rods of electron density in this map constitute at least 40 to 50% of the polypeptide chain and 70 to 80% of one of the lobes. At this resolution the molecule does not appear to be homologous in detail to other kinases such as phosphoglycerate kinase and adenylate kinase. Sugar substrates and inhibitors bind deeply in the cleft which separates the two lobes and produce substantial alterations in the protein structure.     

Three-dimensional structures of cytochrome c oxidase vesicle crystals in negative stain

We have investigated the structure of cytochrome c oxidase vesicle crystals by analysis at 20 Å resolution of electron micrographs of negatively stained specimens. The map clearly shows the shape of the part of the cytochrome c oxidase molecule which protrudes from the lipid bilayer. On the side of the membrane corresponding to the cytoplasmic face of the mitochondrial inner membrane, the molecule projects over 50 Å into solution. About half of the mass of the protein is in this domain, which contains the cytochrome c binding site. On the side of the membrane corresponding to the matrix face, no features are observed, which at this resolution means the protein protrudes less than 20 Å. In vesicle crystals, and probably in the mitochondrion, cytochrome c oxidase monomers are closely paired as dimers, with a clear cleft showing the boundary between monomers.     

Sequence of rubredoxin by x-ray diffraction

A tentative amino acid sequence has been determined for rubredoxin from Clostridium pasteurianum by examining the shapes of the side chains in an electron density map at 2 Å resolution. Superpositions of the appropiate portions of this map and “ball and stick” representations of the amino acids assigned are presented as evidence in support of our identifications. Discrepancies exist between the sequence shown here and that determined by chemical methods. The sequence deduced from the 2Å resolution map, however, represents our best estimate in the absence of chemical data and before refinement of the structure. We emphasize the results at 2 Å resolution because, until recently, the 2 Å resolution map was usually the final result of an X-ray structure determination. It is instructive to show the level of reliability that can be expected at that stage and to illustrate the kinds of mistakes that are likely to occur when making identifications from electrondensity maps.     

The crystal structure of penicillopepsin at 6Åresolution

A 6Åresolution electron density map of crystals of penicillopepsin, an acid protease from Penicillium janthinellum, has been computed from multiple isomorphous replacement phases determined from two heavy metal derivatives, K₂PtCl₆ and UO₂Cl₂. The mean figure of merit of the map is 0.939. The boundaries of the molecules, of which there are four per unit cell, are readily discernible. The molecule is highly asymmetric with approximate dimensions 60Å× 40Å× 30Å. The molecule consists of two distinct lobes separated by a deep cleft, which is probably the extended substrate binding site.     

The three-dimensional structure of mitochondrial aspartate aminotransferase at 4.5 A resolution

An X-ray crystallographic study at 4.5 Å resolution has been carried out with triclinic crystals of chicken mitochondrial aspartate aminotransferase.In the electron density map, the enzyme is clearly visible as an isologous α₂-dimer (105 Å × 60 Å × 50 Å) in which the subunits are associated about a molecular 2-fold axis. Each subunit of dimensions 70 Å × 50 Å × 40 Å contains at least seven helices, one of which is about 50 Å long.Difference maps have revealed the positions of the pyridoxyl and the phosphate moieties of the coenzyme as well as the general substrate binding area. The active sites are on opposite sides of the dimer, about 30 Å apart and close to the intersubunit boundary, so that probably both subunits contribute to each active site. An isolated chain segment, passing in front of the active site and ending in contact with the neighbouring subunit is interpreted as one of the chain termini.