Three-dimensional structure of the adenovirus major coat protein hexon.

The three-dimensional crystal structure of the adenovirus major coat protein is presented. Adenovirus type 2 hexon, at 967 residues, is now the longest polypeptide whose structure has been determined crystallographically. Taken with our model for hexon packing, which positions the 240 trimeric hexons in the capsid, the structure defines 60% of the protein within the 150 X 10(6) dalton virion. The assembly provides the first details of a DNA-containing animal virus that is 20 times larger than the spherical RNA viruses previously described. Unexpectedly, the hexon subunit contains two similar beta-barrels whose topology is identical to those of the spherical RNA viruses, but whose architectural role in adenovirus is very different. The hexon structure reveals several distinctive features related to its function as a stable protective coat, and shows that the type-specific immunological determinants are restricted to the virion surface.

Spherical viruses.

In the past two years, structural studies on spherical viruses have experienced a significant advance with the dramatic increase in the resolution attainable by cryo-electron microscopy and image reconstruction. X-ray crystallography, both alone and, increasingly, in combination with electron microscopy, continues to play a crucial role in elucidating how viruses function.

Combined EM/X-ray imaging yields a quasi-atomic model of the adenovirus-related bacteriophage PRD1 and shows key capsid and membrane interactions.

BACKGROUND: The dsDNA bacteriophage PRD1 has a membrane inside its icosahedral capsid. While its large size (66 MDa) hinders the study of the complete virion at atomic resolution, a 1.65-A crystallographic structure of its major coat protein, P3, is available. Cryo-electron microscopy (cryo-EM) and three-dimensional reconstruction have shown the capsid at 20-28 A resolution. Striking architectural similarities between PRD1 and the mammalian adenovirus indicate a common ancestor. RESULTS: The P3 atomic structure has been fitted into improved cryo-EM reconstructions for three types of PRD1 particles: the wild-type virion, a packaging mutant without DNA, and a P3-shell lacking the membrane and the vertices. Establishing the absolute EM scale was crucial for an accurate match. The resulting "quasi-atomic" models of the capsid define the residues involved in the major P3 interactions, within the quasi-equivalent interfaces and with the membrane, and show how these are altered upon DNA packaging. CONCLUSIONS: The new cryo-EM reconstructions reveal the structure of the PRD1 vertex and the concentric packing of DNA. The capsid is essentially unchanged upon DNA packaging, with alterations limited to those P3 residues involved in membrane contacts. These are restricted to a few of the N termini along the icosahedral edges in the empty particle; DNA packaging leads to a 4-fold increase in the number of contacts, including almost all copies of the N terminus and the loop between the two beta barrels. Analysis of the P3 residues in each quasi-equivalent interface suggests two sites for minor proteins in the capsid edges, analogous to those in adenovirus.

Small angle x-ray scattering studies on adenovirus type 2 hexon.

Adenovirus type 2 hexons have been studied in solution by small angle X-ray scattering, and the following molecular parameters determined: radius of gyration (Rg) = 4.9 nm, molecular weight (M) = 310.000, invariant volume (Vinv) = 630 mn3, maximal distance (Dmax) = 14.5--15.5 nm. A diffraction pattern was obtained up to an angular increment of h = 2.5 nm-1. Various models for the hexon have been explored by calculating the diffraction pattern from the Debye formula for 1200 spheres arranged to define the scattering volume of each model. Models were first built according to electron micrographic results. Later, preliminary results of a crystallographic study were used for model building. The experimental pattern and the pattern resulting from the model determined by crystallographic methods were compared and showed good agreement.

The structure of the adenovirus capsid. II. The packing symmetry of hexon and its implications for viral architecture.

The orientation and location of the 240 hexons comprising the outer protein shell of adenovirus have been determined. Electron micrographs of the capsid and its fragments were inspected for the features of hexon known from the X-ray crystallographic model as described in the accompanying paper. A capsid model is proposed with each facet comprising a small p3 net of 12 hexons, arranged as a triangular sextet with three outer hexon pairs. The sextet is centrally placed about the icosahedral threefold axis, with its edges parallel to those of the facet. The outer pairs project over the facet edges on one side of the icosahedral twofold axes at each edge. The model capsid is defined by the underlying icosahedron, of edge 445 A, upon which hexons are arranged. The hexons are thus bounded by icosahedra with insphere radii of 336 A and 452 A. A quartet of hexons forms the asymmetric unit of an icosahedral hexon shell, which can be closed by the addition of pentons at the 12 vertices. Considering the hexon trimer as a complex structure unit, its interactions in the four topologically distinct environments are very similar, with conservation of at least two-thirds of the inter-hexon bonding. The crystal-like construction explains the flat facets and sharp edges characteristic of adenovirus. Larger "adenovirus-like" capsids of any size could be formed using only one additional topologically different environment. The construction of adenovirus illustrates how an impenetrable protein shell can be formed, with highly conserved intermolecular bonding, by using the geometry of an oligomeric structure unit and symmetry additional to that of the icosahedral point group. This contrasts with the manner suggested by Caspar & Klug (1962), in which the polypeptide is the structure unit, and for which the number of possible bonding configurations required of a structure unit tends to infinity as the continuously curved capsid increases in size. The known structures of polyoma and the plant viruses with triangulation number equal to 3 are evaluated in terms of hexamer-pentamer packing, and evidence is presented for the existence of larger subunits than the polypeptide in both cases. It is suggested that spontaneous assembly can occur only when exact icosahedral symmetry relates structure units or sub-assemblies, which would themselves have been formed by self-limiting closed interactions. Without such symmetry, the presence of scaffolding proteins or nucleic acid is necessary to limit aggregation.

The structure of the adenovirus capsid. I. An envelope model of hexon at 6 A resolution.

The structure of hexon, the major coat protein of adenovirus, has been determined by X-ray crystallography. Electron density maps were obtained with phases based on five heavy-atom derivatives at 2.9 A resolution. The main experimental finding derives from a low resolution electron density map calculated at 6.0 A resolution, but based on phases determined by the multiple isomorphous replacement method at 2.9 A resolution. Hexon consists of three subunits together forming two major components of different morphological symmetry. A triangular top with three towers of density is superimposed on a more bulky pseudo-hexagonal base. The symmetry of the top is in accord with the trimeric nature of hexon, but that of the base derives from the molecular function, which is to provide a densely packed impenetrable protective outer layer for the virion. A close-packed array of hexons forms a planar facet of the icosahedral capsid, with the tops presenting a spiky appearance that is consistent with electron micrographs of the adenovirus capsid. Hexon is hollow, permitting it to occupy a larger volume than normal for the same quantity of protein. The polypeptide chain has been traced in the 2.9 A electron density map for several non-contiguous stretches, allowing C alpha co-ordinates to be measured for 820 out of the 967 amino acid residues. The overall folding pattern confirms the assignment of shape, but the lack of connectivity so far precludes its complete description. The modest amount of alpha-helix and beta-sheet present is in accord with spectroscopic results.

Crystallization and preliminary X-ray analysis of human alpha-galactosidase A complex.

Human alpha-galactosidase A (alpha-D-galactoside galactohydrolase; EC 3.2.1.22), the glycosylated lysosomal enzyme deficient in Fabry disease, has been crystallized as a complex with the inhibitor N-6-aminohexanoyl-alpha-D-galactopyranosylamine. The "hanging drop" method of vapor diffusion was used to grow crystals from solutions containing 50 mM sodium phosphate (pH 4.0 to 4.5), 120 to 170 mM ZnCl2 and 8 to 10% polyethylene glycol 3350. X-ray diffraction data collected from these crystals indicate that the crystals belong to the orthorhombic space group C222(1) with cell dimensions of a = 93.8 A, b = 141.1 A and c = 184.4 A. The crystals diffract to a resolution of 3 A and native data have been collected to 3.5 A resolution. Assuming one dimer per asymmetric unit with a total molecular mass of 110 kDa (with oligosaccharide chains), the Matthews' coefficient is Vm = 2.77 A3/dalton corresponding to a solvent content of 55% (v/v). The self-rotation function reveals that a non-crystallographic 2-fold axis relates the subunits of each dimer.

The structure of the adenovirus capsid. III. Hexon packing determined from electron micrographs of capsid fragments.

The orientation and relative positions of all 240 hexons in the icosahedral outer capsid of adenovirus have been determined. Two types of capsid fragments, obtained after selective disruption of the virion, were analyzed using electron microscopy and image-processing techniques. Planar inverted groups-of-nine, arising from the central region of the capsid facet, were minimally stained to reveal the morphology of restricted regions of their component hexons. Images shown to be related by correspondence analysis were averaged and features of the individual hexon molecule, known from an X-ray crystallographic investigation, were used in their interpretation. The study confirms earlier observations that the hexons in the group-of-nine are distributed on a p3 net, shows that the hexons form a close-packed array using the pseudo-hexagonal shape of the hexon base, and provides their relative positions. Twenty interlocking groups-of-nine account for 180 of the 240 hexons present in the viral capsid. The orientation of the remaining 60 peripentonal hexons was obtained from a rotationally averaged image of a quarter-capsid, a novel viral fragment comprising five complete facets. Each peripentonal hexon forms planar asymmetric interactions with two neighbors in an adjacent group-of-nine so that it lies on an extension of the p3 net. The complete facet thus consists of 12 hexons arranged on a planar p3 net, with a shape that permits interlocking of hexons at the capsid edge. The relative positions of the hexons have been determined to within 5 A using the molecular model, and indicate that the pseudo-hexagonal basal regions are close-packed in a manner that maximizes the hexon-hexon contacts. The results confirm the model proposed earlier for the arrangement of hexons within the adenovirus capsid (Burnett, 1985), and show the power of the inter-disciplinary approach.

Crystallization of the major coat protein of PRD1, a bacteriophage with an internal membrane.

The major multimeric coat protein, P3, of the bacterial virus PRD1 has been crystallized by vapor diffusion from polyethylene glycol 4000. The PRD1-P3 crystals belong to the orthorhombic space group P2(1)2(1)2(1) with unit cell dimensions a = 121.6 A, b = 123.2 A, c = 128.6 A and diffract to 3.0 A resolution. Density measurements show that there is one trimer (3 x 43.1 kDa) per asymmetric unit and a high solvent content of 67%. A self-rotation function calculation shows a pronounced peak indicating a non-crystallographic threefold axis. This indicates that the major viral capsomer is a trimer and allows the viral T-number to be postulated.

The refined crystal structure of hexon, the major coat protein of adenovirus type 2, at 2.9 A resolution.

The crystal structure of hexon, the major coat protein from adenovirus type 2, has been refined at 2.9 A resolution. Hexon is a homo-trimer (molecular mass 3 x 109,077 Da) and crystallizes in the cubic space group P2(1)3, with a cell edge of 150.5 A. There are four molecules in the unit cell so that the crystallographic asymmetric unit contains one subunit of the trimer. The electron density in most regions is well-defined and 880 amino acid residues, of the 967 in this unusually long polypeptide chain, have been located and fitted. The N terminus (1 to 43) and three internal stretches (192 to 203, 270 to 291 and 444 to 453) are not defined, and a stretch (168 to 207) with unclear side-chain density is modelled as poly(Ala/Gly). The current refined model, consisting of 6943 non-hydrogen protein atoms and 85 water molecules, yields an R-factor of 19.9% for 18,176 reflections in the resolution range 5.0 to 2.9 A. The model has reasonable geometry with root-mean-square deviations from ideal bond lengths of 0.022 A and angle-related 1-3 distances of 0.056 A. The overall shape of the trimeric hexon molecule is unusual and may be divided into a pseudo-hexagonal base rich in beta-structure, and a triangular top formed from three long loops containing some secondary structure. The base contains two similar pedestal domains, P1 and P2, each of which is a flattened eight-stranded beta-barrel with the "jelly-roll greek key" topology characteristic of other viral coat proteins. P1 and P2 are related by an approximate 6-fold operation about the molecular 3-fold axis so that six barrels form the walls of the tubular hexon base. The hexon bases form close-packed p3 arrays on each facet of the icosahedral adenovirus virion. Unlike other viral capsids, the barrel axes are almost perpendicular to rather than parallel with the capsid surface. The hexon top, which consists of intimately interacting loops emerging from P1 and P2 in the base, has a triangular outline and so does not exhibit the pseudo-symmetry of the base. The structure of the hexon trimer shows how economically it meets the demands of its function as a stable protective viral coat, reveals the significance of the special features in its unusual amino acid sequence, and explains its biochemical and immunological properties. The molecule is hollow, with a large central cavity, and so has a high effective volume for its mass.(ABSTRACT TRUNCATED AT 400 WORDS)

Structural studies on adenoviruses.

The adenovirus genome encodes more than 40 proteins, of which 11 combine with the viral DNA to form an icosahedral capsid of approximately 150 MDa molecular weight and approximately 900 A in diameter. This chapter reviews the information that structural biology techniques have provided about the adenovirus proteins and capsid. The structures of two capsid proteins (hexon and fiber) and two non-structural polypeptides (DNA-binding protein and protease) have been solved by X-ray crystallography. Fiber and its knob have been the focus of the latest structural studies, due to their role in host recognition and consequently in virus targeting for human gene therapy. The current model for the large capsid comes from a combination of electron microscopy and crystallography. The resultant images have revealed a surprising similarity between adenovirus and a bacterial virus, which suggests their common evolutionary origin.

Control of EVI-1 oncogene expression in metastatic breast cancer cells through microRNA miR-22.

Metastasis in breast cancer carries a disproportionately worse prognosis than localized primary disease. To identify microRNAs (miRNA) involved in metastasis, the expression of 254 miRNAs was measured across the following cell lines using microarray analysis: MDA-MB-231 breast cancer cells, cells that grew as a tumor in the mammary fat pad of nude mice (TMD-231), metastatic disease to the lungs (LMD-231), bone (BMD-231) and adrenal gland (ADMD-231). A brain-seeking variant of this cell line (231-BR) was used additionally in validation studies. Twenty miRNAs were upregulated and seven were downregulated in metastatic cancer cells compared with TMD-231 cells. The expression of the tumor suppressor miRNAs let-7 and miR-22 was consistently downregulated in metastatic cancer cells. These metastatic cells expressed higher levels of putative/proven miR-22 target oncogenes ERBB3, CDC25C and EVI-1. Introduction of miR-22 into cancer cells reduced the levels of ERBB3 and EVI-1 as well as phospho-AKT, an EVI-1 downstream target. The miR-22 primary transcript is located in the 5'-untranslated region of an open reading frame C17orf91, and the promoter/enhancer of C17orf91 drives miR-22 expression. We observed elevated C17orf91 expression in non-basal subtype compared with basal subtype breast cancers. In contrast, elevated expression of EVI-1 was observed in basal subtype and was associated with poor outcome in estrogen receptor-negative breast cancer patients. These results suggest that metastatic cancer cells increase specific oncogenic signaling proteins through downregulation of miRNAs. Identifying such metastasis-specific oncogenic pathways may help to manipulate tumor behavior and aid in the design of more effective targeted therapies.

Molecular composition of the adenovirus type 2 virion.

The representation of the different structural polypeptides within the adenovirus virion has been accurately determined, and the particle molecular weight has been derived. A stoichiometric analysis was performed with [35S]methionine as a radiolabel, and analytical sodium dodecyl sulfate-polyacrylamide gel electrophoresis was used to separate the polypeptides. The recently available sequence of the adenovirus type 2 genome was used to determine the number of methionines in each polypeptide. The resulting relative representation was placed on an absolute scale by using the known number of hexon polypeptides per virion. The analysis provides new information on the composition of the vertex region, which has been the subject of some controversy. Penton base was found to be present in 60 copies, distributed as pentamers at each of the 12 vertices. Three fiber monomers were associated with one penton base to form the penton complex. Polypeptide IX was present in 240 copies per virion and 12 copies per group-of-nine hexons, supporting a model proposed earlier for the distribution of this protein. The location of polypeptide IX explains the dissociation of the virus outer capsid into groups-of-nine hexons. The penton base was microheterogeneous, and the relative amounts suggest that the symmetry mismatch, which occurs within the penton complex between base and fiber, is resolved by the synthesis of penton base polypeptides from two closely spaced start codons.

Type-specific epitope locations revealed by X-ray crystallographic study of adenovirus type 5 hexon.

A major obstacle to the use of adenovirus as a vector for gene therapy is the host immune response to hexon, the major protein component of the icosahedral capsid. A solution lies in creating novel vectors with modified or chimeric hexons to evade the immune response to native hexon. The crystal structure of hexon from human adenovirus type 5 (ad5), the type primarily used for gene therapy, has been determined to facilitate the design of such molecules. As the 951-amino-acid (aa) ad5 hexon sequence is closely related to that of ad2 (967 aa; 86% aa identity), the ad5 structure was solved by molecular replacement with a model constructed from the known ad2 hexon. During refinement, greater than 25% of the sequence was reassigned, resulting in a relocation of two epitope regions, from buried positions in the ad2 model to external sites at the top of the ad5 molecule. The resultant model is in better agreement with crystallographic data, while maintaining the overall topology of ad2 hexon. This work suggests that all hexons have the same basic fold and that the ad5 hexon structure provides an accurate and representative model for designing new adenovirus vectors.

Distribution and complementarity of hydropathy in multisubunit proteins.

A survey of 40 multisubunit proteins and 2 protein-protein complexes was performed to assay quantitatively the distribution of hydropathy among the exterior surface, interior, contact surface, and noncontact exterior surface of the isolated subunits. We suggest a useful way to present this distribution by using a "hydropathy level diagram." Additionally, we have devised a function called "hydropathy complementarity" to quantitate the degree to which interacting surfaces have matching hydropathy distributions. Our survey revealed the following patterns: (1) The difference in hydropathy between the interior and exterior of subunits is a fairly invariant quantity. (2) On average, the hydropathy of the contact surface is higher than that of the exterior surface, but is not greater than that of the protein as a whole. There was variation, however, among the proteins. In some instances, the contact surface was more hydrophilic than the noncontact exterior, and in a few cases the contact surface was as hydrophobic as the protein interior. (3) The average interface manifests significant hydropathy complementarity, signifying that proteins interact by placing hydrophobic centers of one surface against hydrophobic centers of the other surface, and by similarly matching hydrophilic centers. As a measure of recognition and specificity, hydropathy complementarity could be a useful tool for predicting correct docking of interacting proteins. We suggest that high hydropathy complementarity is associated with static inflexible interactions. (4) We have found that some subunits that bind predominantly through hydrophilic forces, such as hydrogen bonds, ionic pairs, and water and metal bridges, are involved in dynamic quaternary organization and allostery.

DARWIN: a program for docking flexible molecules.

A new program named "DARWIN" has been developed to perform docking calculations with proteins and other biological molecules. The program uses the Genetic Algorithm to optimize the molecule's conformation and orientation under the selective pressure of minimizing the potential energy of the complex. A unique feature of DARWIN is that it communicates with the molecular mechanics program CHARMM to make the energy calculations. A second important feature is its parallel interface, which allows simultaneous use of multiple stand-alone copies of CHARMM to rapidly evaluate large numbers of potential solutions. This permits an "accuracy first" approach to docking, which avoids many of the common assumptions and shortcuts often made to reduce computation time. The method was applied to three protein-carbohydrate complexes: the crystallographically determined structures of Concanavalin A and Fab Se155-4; and a model structure for Fab ME36.1. Conformations close to the crystal structures were obtained with this approach, but some "false positive" solutions were also selected. Many of these could be eliminated by introducing different methods for simulating solvent effects. An effective screening method for docking a database of compounds to a single target enzyme using DARWIN is also presented.

Isolation and crystallization of lambda exonuclease.

lambda Exonuclease is a deoxyribonuclease induced by bacteriophage lambda. Mutations in the structural gene for the protein affect general recombination and indicate a possible function for the enzyme. A large scale isolation procedure was employed to purify enough enzyme from a heat-induced lambda lysogen for X-ray crystallographic analysis. Analytical ultracentrifugation and SDS-polyacrylamide electrophoresis revealed that lambda exonuclease is a tetramer with molecular mass 107,000 Da. Crystallization trials produced morphologically perfect crystals of a size suitable for X-ray diffraction studies. Cubic crystallographic symmetry was indicated by the lack of birefringence when the crystals were inspected with polarized light. X-ray precession photographs indicated that lambda exonuclease crystallizes in a space group of P4(1)32, or its enantiomorph P4(3)32, with 24 tetramers in the unit cell of edge 210 A.

Difference imaging of adenovirus: bridging the resolution gap between X-ray crystallography and electron microscopy.

While X-ray crystallography provides atomic resolution structures of proteins and small viruses, electron microscopy provides complementary structural information on the organization of larger assemblies at lower resolution. A novel combination of these two techniques has bridged this resolution gap and revealed the various structural components forming the capsid of human type 2 adenovirus. An image reconstruction of the intact virus, derived from cryo-electron micrographs, was deconvolved with an approximate contrast transfer function to mitigate microscope distortions. A model capsid was calculated from 240 copies of the crystallographic structure of the major capsid protein and filtered to the correct resolution. Subtraction of the calculated capsid from the corrected reconstruction gave a three-dimensional difference map revealing the minor proteins that stabilize the virion. Elongated density penetrating the hexon capsid at the facet edges was ascribed to polypeptide IIIa, a component required for virion assembly. Density on the inner surface of the capsid, connecting the ring of peripentonal hexons, was assigned as polypeptide VI, a component that binds DNA. Identification of the regions of hexon that contact the penton base suggests a structural mechanism for previously proposed events during cell entry.