The three-dimensional structure of P2 myelin protein.

The three-dimensional structure of P2 protein from peripheral nervous system myelin has been determined at 2.7 A resolution by X-ray crystallography. The single isomorphous replacement/anomalous map was interpreted using skeletonized electron density on a computer graphics system. An atomic model was built using fragment fitting. The structure forms a compact 10-stranded up-and-down beta-barrel which encapsulates residual electron density that we interpret as a fatty acid molecule. This beta-barrel shows some similarity to, but is different from, the retinol binding protein family of structures. The relationship of the P2 structure to a family of cytoplasmic, lipid binding proteins is described.     

The structure of yeast enolase at 2.25-A resolution. An 8-fold beta + alpha-barrel with a novel beta beta alpha alpha (beta alpha)6 topology

The three-dimensional structure of yeast enolase has been determined by the multiple isomorphous replacement method followed by the solvent flattening technique. A polypeptide model, corresponding with the known amino acid sequence, has been fitted to the electron density map. Crystallographic restrained least-squares refinement of the model without solvent gave R = 20.0% for 6-2.25-A resolution with good geometry. A model with 182 water molecules and 1 sulfate which is still being refined has presently R = 17.0%. The molecule is a dimer with subunits related by 2-fold crystallographic symmetry. The subunit has dimensions 60 X 55 X 45 A and is built from two domains. The smaller N-terminal domain has an alpha + beta structure based on a three-stranded antiparallel meander and four helices. The main domain is an 8-fold beta + alpha-barrel. The enolase barrel is, however, different from the triose phosphate isomerase barrel; its topology is beta beta alpha alpha (beta alpha)6 rather than (beta alpha)8 as found in triose phosphate isomerase. The inner beta-barrel is not entirely parallel, the second strand is antiparallel to the other strands, and the direction of the first helix is also reversed with respect to the other helices. This supports the hypothesis that some enzymes evolved independently producing the stable structure of beta alpha barrels with either enolase or triose phosphate isomerase topology. The active site of enolase is located at the carboxylic end of the barrel. A fragment of the N-terminal domain and two long loops protruding from the barrel domain form a wide crevice leading to the active site region. Asp246, Glu295, and Asp320 are the ligands of the conformational cation. Other residues in the active site region are Glu168, Asp321, Lys345, and Lys396.     

Structure of a T = 1 aggregate of alfalfa mosaic virus coat protein seen at 4.5 A resolution

A T = 1 empty aggregate of alfalfa mosaic virus coat protein had been crystallized in a hexagonal unit cell and its orientation was determined with the rotation function. A single heavy-atom derivative has now been prepared and the position of the two Hg atoms per protein subunit were determined using a systematic Patterson search procedure, given the particle orientation. Phases, initially determined by single isomorphous replacement, were refined by six cycles of electron density averaging and solvent leveling to produce a 4.5 A resolution electron density map. The protein coat is confined between 95 and 58 A radius. The subunit boundary could be delineated easily. It has a central cavity reminiscent of the beta-barrel in other spherical plant viruses, but its topology could not be determined unambiguously. The spherical particle has large holes at the 5-fold axes, consistent with previous observations. The subunits have substantial interactions at the 2 and 3-fold axes. The structure of the elongated particles is discussed in relation to these results.     

Structure determination of Panulirus interruptus haemocyanin at 3.2 A resolution. Successful phase extension by sixfold density averaging

The three-dimensional structure of Panulirus interruptus haemocyanin has been determined at 3.2 A resolution by X-ray diffraction techniques. Starting from a double isomorphous replacement map at 4 A resolution, the phases of the 32,709 reflections were first improved by six cycles of sixfold molecular averaging and solvent flattening. This also generated phase for 3078 reflections with no isomorphous replacement data. Next, phases for the reflections between 4.0 A and 3.2 A were obtained by a stepwise expansion procedure. In each expansion step 2000 to 3000 new reflections were added to the set of already phased reflections, followed by a few cycles of density averaging and solvent flattening at constant resolution. The eventual map at 3.2 A was calculated with 63,843 reflections with an average Sim weight of 0.75 and an overall R-factor of 23.5%. The polypeptide chain could be traced without any problems, while the dinuclear copper site, disulphide bridges and the first three moieties of the carbohydrate chain were clearly visible. Each subunit consists of three distinct domains. The first domain is mainly helical, containing one disulphide bridge and the carbohydrate chain. The second domain is also predominantly helical and contains the dinuclear copper site at its centre. The core of the third domain is an anti-parallel beta-barrel with the same topology as in the immunoglobulins and Cu,Zn-superoxide dismutase. This domain contains two disulphide bridges. Two long loops extend from the beta-barrel and have numerous interactions with the other two domains. The two copper ions are at approximately 3.7 +/- 0.25 A from each other and co-ordinated by six histidines, which are strictly conserved in all seven arthropodan haemocyanins with known amino acid sequences. No bridging protein ligand is present in the electron density distribution. Hydroxyl groups from tyrosines, which are invariant among arthropodan haemocyanins, are 17.4 A or more removed from the centre of the two copper ions. The closest Panulirus tyrosine hydroxyl is 10.6 A from the copper ions. So, it appears unlikely that tyrosine is involved in the co-ordination of the coppers either in the deoxy or in the oxy form of arthropodan haemocyanins.     

Purification and characterization of a biliverdin-associated protein from the hemolymph of Manduca sexta

A biliverdin binding protein, insecticyanin, has been isolated from the hemolymph of the fourth instar tobacco hornworm Manduca sexta. The protein has been purified to apparent homogeneity by conventional chromatography with a cumulative yield of 40-50%. The protein (Mw 71 600) is composed of three subunits (Mr 23 000). Each subunit binds one biliverdin molecule. Proton magnetic resonance spectroscopy and absorption spectroscopy demonstrate that the bilin is the biliverdin IX gamma isomer.     

X-ray structure determination of telokin, the C-terminal domain of myosin light chain kinase, at 2.8 A resolution.

The three-dimensional structure of telokin, an acidic protein identical to the C-terminal portion of smooth muscle myosin light chain kinase from turkey gizzard, has been determined at 2.8 A resolution and refined to a crystallographic R-factor of 19.5% for all measured X-ray data from 30 A to 2.8 A. Crystals used in the investigation belonged to the space group P3(2)21, with one molecule per asymmetric unit and unit cell dimensions of a = b = 64.4 A and c = 50.6 A. Telokin contains 154 amino acid residues, 103 of which were visible in the electron density map. The overall molecular fold of telokin consists of seven strands of antiparallel beta-pleated sheet that wrap around to form a barrel. There is also an extended tail of eight amino acid residues at the N terminus that does not participate in beta-sheet formation. The beta-barrel can be simply envisioned as two layers of beta-sheet, nearly parallel to one another, with one layer containing four and the other three beta-strands. This type of beta-barrel, as seen in telokin, was first observed for the CH2 domain of an immunoglobulin fragment Fc. Telokin is an intracellular protein and, as such, does not contain the disulphide linkage between beta-strands B and F normally observed in the immunoglobulin constant domains. It does, however, contain two cysteine amino acid residues (Cys63 and Cys115) that are situated at structurally identical positions to those forming the disulphide linkage in the immunoglobulin constant domain.     

Low resolution structure of bovine rhodopsin determined by electron cryo-microscopy.

The visual pigment rhodopsin is a member of the G protein-coupled receptor family. Electron cryo-microscopy was used to determine the three-dimensional structure of bovine rhodopsin from tilted two-dimensional crystals embedded in vitrified water. The effective resolution in a map obtained from the 23 best crystals was about 9.5 A horizontally and approximately 47 A normal to the plane of the membrane. Four clearly resolved tracks of density in the map correspond to four alpha-helices oriented nearly perpendicular to the plane of the membrane. One of these helices appears to be more tilted than anticipated from the projection structure published previously. The remaining three helices are presumably more highly tilted, given that they form a continuous "arc-shaped" feature and could not be resolved to the same extent. The overall density distribution in the low resolution map shows an arrangement of the helices in which the "arc-shaped" feature is extended by a fourth, less tilted helix. The band of these four tilted helices is flanked by a straight helix on the outer side and a pair of straight helices on its inner side.     

Activity and specificity of human aldolases

The structure of the type I fructose 1,6-bisphosphate aldolase from human muscle has been extended from 3 A to 2 A resolution. The improvement in the resulting electron density map is such that the 20 or so C-terminal residues, known to be associated with activity and isozyme specificity, have been located. The side-chain of the Schiff's base-forming lysine 229 is located towards the centre of an eight-stranded beta-barrel type structure. The C-terminal "tail" extends from the rim of the beta-barrel towards lysine 229, thus forming part of the active site of the enzyme. This structural arrangement appears to explain the difference in activity and specificity of the three tissue-specific human aldolases and helps with our understanding of the type I aldolase reaction mechanism.     

Three-dimensional pattern recognition: an approach to automated interpretation of electron density maps of proteins

A procedure is outlined for reducing the high resolution electron density map of a protein to a set of connected thin lines which follow the density. The side chain representations are removed from this skeleton leaving primarily main chain, disulfide bridges and very strong hydrogen bonds. Crystallographic and local operators are used to separate one protein molecule from the neighboring chains in the crystal. Provisional α-carbon positions along the skeletal main chain are derived by application of the “4 Å rule”.The application of these methods to the 2.0 Å electron density map of ribonuclease S (Wyckoff et al., 1970) is described. The skeleton of the isolated molecule that is produced in this fashion provides a good over-all view of the three-dimensional folding of the protein. The results suggest that the skeleton representation can be a valuable supplement to the present methods of map interpretation and a significant step towards complete automation of the interpretation process.The three-dimensional pattern recognition procedures described may have much broader applications than the protein structure problem for which they have been developed.     

Crystal structure of muconate lactonizing enzyme at 6.5 A resolution

We have obtained crystals of Pseudomonas putida muconate lactonizing enzyme. They diffract to better than 2.4 A resolution and have two monomers in the asymmetric unit, related by a non-crystallographic 2-fold axis. The cell dimensions are 139.3 A X 139.3 A X 84.1 A, and the space group is I4. The electron density map at 6.5 A resolution shows that the enzyme is an octamer with D4 symmetry.     

Structural analysis of T4 DNA helix destabilizing protein (gp32 I) crystal by electron microscopy

Low dose electron diffraction and imaging techniques have been applied to the study of the crystalline structure of gp32*I, a DNA helix destabilizing protein derived from bacteriophage T4 gene 32 protein. A quantitative analysis of intensities from electron diffraction patterns from tilted, multilayered gp32*I crystal has provided the unit cell thickness of the crystal. The three-dimensional phases indicate that the space group P2(1)2(1)2. By taking into account the unit cell volume and the solvent content in the crystal, it was deduced that there is one gp32*I molecule in each asymmetric unit. A projected density map of unstained, glucose-embedded gp32*I crystal was synthesized with amplitudes from electron diffraction intensities and phases from electron images with reflections out to 7.6 A. Because of the similarity in the scattering density between glucose and protein, this projected map cannot be interpreted with certainty. A low resolution three-dimensional reconstruction shows that the protein molecule is about 90 A long and about 20 A in diameter. Because the dimer is formed around a dyad axis, the protein molecules comprising it must be arranged head-to-head. This dimeric arrangement of the proteins in the unit cell may be implicated as one of the conformational states of this protein in solution.     

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.     

Functional implications of interleukin-1 beta based on the three-dimensional structure.

The molecular structure of interleukin-1 beta, a hormone-like cytokine with roles in several disease processes, has been determined at 2.0 A resolution and refined to a crystallographic R-factor of 0.19. The framework of this molecule consists of 12 antiparallel beta-strands exhibiting pseudo-3-fold symmetry. Six of the strands make up a beta-barrel with polar residues concentrated at either end. Analysis of the three-dimensional structure, together with results from site-directed mutagenesis and biochemical and immunological studies, suggest that the core of the beta-barrel plays an important functional role. A large patch of charged residues on one end of the barrel is proposed as the binding surface with which IL-1 interacts with its receptor.     

Crystallization, structure determination and least-squares refinement to 1.75 A resolution of the fatty-acid-binding protein isolated from Manduca sexta L.

The molecular structure of an insect fatty-acid-binding protein isolated from Manduca sexta L. has been determined and refined to a nominal resolution of 1.75 A. Crystals used in the investigation were grown from 1.6 M-ammonium sulfate solutions buffered at pH 4.5 with 50 mM-sodium succinate, and belonged to space group P2(1) with unit cell dimensions of a = 27.5 A, b = 71.0 A, c = 28.7 A and beta = 90.8 degrees. An electron density map, phased with four heavy-atom derivatives and calculated to 2.5 A resolution, allowed for complete tracing of the 131 amino acid residue polypeptide chain. Subsequent least-squares refinement of the model reduced the R-factor from 46.0% to 17.3% using all measured X-ray data from 30.0 A to 1.75 A. Approximately 92% of the amino acid residues fall into classical secondary structural elements including ten strands of anti-parallel beta-pleated sheet, two alpha-helices, one type I turn, three type II turns, four type II' turns and one type III turn. As in other fatty-acid-binding proteins, the overall molecular architecture of the insect molecule consists of ten strands of anti-parallel beta-pleated sheet forming two layers that are nearly orthogonal to one another. A helix-turn-helix motif at the N-terminal portion of the protein flanks one side of the up-and-down beta-barrel. The functional group of the fatty acid is within hydrogen-bonding distance of Gln39, Tyr129, Arg127 and a sulfate molecule, while the aliphatic portion of the ligand is surrounded by hydrophobic amino acid residues lining the beta-barrel. The binding of the carboxylic acid portion of the ligand is very similar to that observed in P2 myelin protein and the murine adipocyte lipid-binding protein, but the positioning of the hydrocarbon tail after approximately C6 is completely different.     

Three-dimensional structure of a mammalian purple acid phosphatase at 2.2 A resolution with a mu-(hydr)oxo bridged di-iron center.

The crystal structure of purple acid phosphatase from rat bone has been determined by molecular replacement and the structure has been refined to 2.2 A resolution to an R -factor of 21.3 % (R -free 26.5 %). The core of the enzyme consists of two seven-stranded mixed beta-sheets, with each sheet flanked by solvent-exposed alpha-helices on one side. The two sheets pack towards each other forming a beta-sandwich. The di-iron center, located at the bottom of the active-site pocket at one edge of the beta-sandwich, contains a mu-hydroxo or mu-oxo bridge and both metal ions are observed in an almost perfect octahedral coordination geometry. The electron density map indicates that a mu-(hydr)oxo bridge is found in the metal center and that at least one solvent molecule is located in the first coordination sphere of one of the metal ions. The crystallographic study of rat purple acid phosphatase reveals that the mammalian enzymes are very similar in overall structure to the plant enzymes in spite of only 18 % overall sequence identity. In particular, coordination and geometry of the iron cluster is preserved in both enzymes and comparison of the active-sites suggests a common mechanism for the mammalian and plant enzymes. However, significant differences are found in the architecture of the substrate binding pocket.     

Structure of glycogen phosphorylase a at 3.0 A resolution and its ligand binding sites at 6 A.

A model of the polypeptide backbone of the dimer of glycogen phosphorylase a (EC 2.4.1.1) was built from a 3 A resolution electron density map derived from x-ray diffraction analysis of native tetragonal crystals and two heavy atom isomorphous replacement derivatives. Each identical subunit of the dimer has a compact shape with overall dimensions of 85 X 75 X 55 A and is tightly associated with its 2-fold symmetry related subunit. There are three major excursions of the polypeptide chain of one monomer across the 2-fold axis to make extensive contacts with the other subunit. The active site, of which there are two per dimer, is shared between the two subunits at their interface and comprises a pocket-like region within a "V"-shaped framework of two alpha helices. Within this region are found the binding sites for the substrates, glucose-1-P and arsenate, a competitive inhibitor, UDP-glucose, and the allosteric effector, AMP. The site of metabolic control, Ser-14 phosphate, is hydrogen-bonded to a side chain on the outside of one of the alpha helices forming the active site and is 15 A from the AMP binding site. Maltoheptaose, a glycogen analogue and substrate for these enzymatically active crystals, binds in a second region of interest. Even at concentrations above its Km, when binding is sufficiently tight that all seven glucose moieties may be discerned, the closest of these is 25 A from the glucose-1-P binding site. We suggest that this polysaccharide binding site may represent a storage site whereby phosphorylase is bound to the glycogen particle in the muscle cell. The polypeptide chain in a third region has the same topological structure as has been observed for the nucleotide binding domains in the dehydrogenases. Adenine or adenosine (but not AMP) bind here in a position similar to the adenine ring of NAD in the dehydrogenases while glucose binds 17 A away in an interior crevice near the center of the monomer.     

The molecular structure of UDP-galactose 4-epimerase from Escherichia coli determined at 2.5 A resolution.

UDP-galactose 4-epimerase catalyzes the conversion of UDP-galactose to UDP-glucose during normal galactose metabolism. The molecular structure of UDP-galactose 4-epimerase from Escherichia coli has now been solved to a nominal resolution of 2.5 A. As isolated from E. coli, the molecule is a dimer of chemically identical subunits with a total molecular weight of 79,000. Crystals of the enzyme used for this investigation were grown as a complex with the substrate analogue, UDP-benzene, and belonged to the space group P2(1)2(1)2(1) with unit cell dimensions of a = 76.3 A, b = 83.1 A, c = 132.1 A, and one dimer per asymmetric unit. An interpretable electron density map calculated to 2.5 A resolution was obtained by a combination of multiple isomorphous replacement with six heavy atom derivatives, molecular averaging, and solvent flattening. Each subunit of epimerase is divided into two domains. The larger N-terminal domain, composed of amino acid residues 1-180, shows a classic NAD+ binding motif with seven strands of parallel beta-pleated sheet flanked on either side of alpha-helices. The seventh strand of the beta-pleated sheet is contributed by amino acid residues from the smaller domain. In addition, this smaller C-terminal domain, consisting of amino acid residues 181-338, contains three strands of beta-pleated sheet, two major alpha-helices and one helical turn. The substrate analogue, UDP-benzene, binds in the cleft located between the two domains with its phenyl ring in close proximity to the nicotinamide ring of NAD+. Contrary to the extensive biochemical literature suggesting that epimerase binds only one NAD+ per functional dimer, the map clearly shows electron density for two nicotinamide cofactors binding in symmetry-related positions in the dimer. Likewise, each subunit in the dimer also binds one substrate analogue.     

Crystal structure of amine oxidase from bovine serum

Copper-containing amine oxidase extracted from bovine serum (BSAO) was crystallized and its three-dimensional structure at 2.37A resolution is described. The biological unit of BSAO is a homodimer, formed by two monomers related to each other by a non-crystallographic 2-fold axis. Each monomer is composed of three domains, similar to those of other amine oxidases from lower species. The two monomers are structurally equivalent, despite some minor differences at the two active sites. A large funnel allows access of substrates to the active-site; another cavity, accessible to the solvent, is also present between the two monomers; this second cavity could allow the entrance of molecular oxygen necessary for the oxidative reaction. Some sugar residues, bound to Asn, were still present and visible in the electron density map, in spite of the exhaustive deglycosylation necessary to grow the crystals. The comparison of the BSAO structure with those of other resolved AO structures shows strong dissimilarities in the architecture and charge distribution of the cavities leading to the active-site, possibly explaining the differences in substrate specificity.     

The three-dimensional structure of canavalin from jack bean (Canavalia ensiformis).

The three-dimensional structure of the vicilin storage protein canavalin, from Canavalia ensiformis, has been determined in a hexagonal crystal by x-ray diffraction methods. The model has been refined at 2.6 A resolution to an R factor of 0.197 with acceptable geometry. Because of proteolysis, 58 of 419 amino acids of the canavalin polypeptide are not visible in the electron density map. The canavalin subunit is composed of two extremely similar structural domains that reflect the tandem duplication observed in the cDNA and in the amino acid sequence. Each domain consists of two elements, a compact, eight-stranded beta-barrel having the "Swiss roll" topology and an extended loop containing several short alpha-helices. The root mean square deviation between 84 pairs of corresponding C alpha atoms making up the strands of the two beta-barrels in a subunit is 0.78 A, and for 112 pairs of structurally equivalent C alpha atoms of the two domains the deviation is 1.37 A. The interface between domains arises from the apposition of broad hydrophobic surfaces formed by side chains originating from one side of the beta-barrels, supplemented by at least four salt bridges. The interfaces between subunits in the trimer are supplied by the extended loop elements. These interfaces are also composed primarily of hydrophobic residues supplemented by six salt bridges. The canavalin subunits have dimensions about 40 x 40 x 86 A, and the oligomer is a disk-shaped molecule about 88 A in diameter with a thickness of about 40 A. The distribution of domains lends a high degree of pseudo-32-point group symmetry to the molecule. There is a large channel of 18 A diameter, lined predominantly by hydrophilic and charged amino acids, running through the molecule along the 3-fold axis. The majority of residues conserved between domains and among vicilins occur at the interface between subunits but appear otherwise arbitrarily distributed within the subunit, although predominantly on its exterior.     

Crystal structure of recombinant human interleukin-1 beta at 2.0 A resolution

The crystal structure of recombinant human interleukin-1 beta (IL-1 beta) has been determined at 2.0 A resolution and refined to a crystallographic R-factor of 0.19. Three heavy-atom derivatives were identified and used for multiple isomorphous replacement phasing. Interpretation of the resulting electron density map revealed a structure in which there are 12 antiparallel beta-strands and no alpha-helix. The single 153-residue polypeptide chain is folded into a six-stranded beta-barrel similar in architecture to the Kunitz-type trypsin inhibitor found in soybeans. The molecule displays approximate 3-fold symmetry about the axis of the beta-barrel. Each successive pair of component strands of the barrel brackets an extensive sequence outside the barrel that includes an additional pair of beta-strands and a prominent loop. Together, these three external segments conceal much of the perimeter and one end of the barrel, leaving only the end supporting the chain termini fully exposed. The structure can be used to identify portions of the polypeptide chain that are exposed on the surface of the molecule, some of which must be epitopes recognized by interleukin-1 beta receptors.