Model of the trimeric fiber and its interactions with the pentameric penton base of human adenovirus by cryo-electron microscopy

Adenovirus invades host cells by first binding to host receptors through a trimeric fiber, which contains three domains: a receptor-binding knob domain, a long flexible shaft domain, and a penton base-attachment tail domain. Although the structure of the knob domain associated with a portion of the shaft has been solved by X-ray crystallography, the in situ structure of the fiber in the virion is not known; thus, it remains a mystery how the trimeric fiber attaches to its underlying pentameric penton base. By high-resolution cryo-electron microscopy, we have determined the structure of the human adenovirus type 5 (Ad5) to 3.6-Å resolution and have reported the full atomic models for its capsid proteins, but not for the fiber whose density cannot be directly interpreted due to symmetry mismatch with the penton base. Here, we report the determination of the Ad5 fiber structure and its mode of attachment to the pentameric penton base by using an integrative approach of multi-resolution filtering, homology modeling, computational simulation of mismatched symmetries, and fitting of atomic models into cryo-electron microscopy density maps. Our structure reveals that the interactions between the trimeric fiber and the pentameric penton base are mediated by a hydrophobic ring on the top surface of the penton base and three flexible tails inserted into three of the five available grooves formed by neighboring subunits of penton base. These interaction sites provide the molecular basis for the symmetry mismatch and can be targeted for optimizing adenovirus for gene therapy applications.     

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.     

Revised Crystal Structure of Human Adenovirus Reveals the Limits on Protein IX Quasi-Equivalence and on Analyzing Large Macromolecular Complexes

We report the revised crystal structure of a pseudo-typed human adenovirus at 3.8-Å resolution that is consistent with the atomic models of minor proteins determined by cryo-electron microscopy. The diffraction data from multiple crystals were rescaled and merged to increase the data completeness. The densities for the minor proteins were initially identified in the phase-refined omit maps that were further improved by the phases from docked poly-alanine models to build atomic structures. While the trimeric fiber molecules are disordered due to flexibility and imposition of 5-fold symmetry, the remaining major capsid proteins hexon and penton base are clearly ordered, with the exception of hypervariable region 1 of hexons, the RGD containing loop, and the N-termini of the penton base. The exterior minor protein IX together with the interior minor proteins IIIa and VIII stabilizes the adenovirus virion. A segment of N-terminal pro-peptide of VI is found in the interior cavities of peripentonal hexons, and the rest of VI is disordered. While the triskelion substructures formed by the N-termini of IX conform to excellent quasi 3-fold symmetry, the tetrameric coiled-coils formed by the C-termini and organized in parallel and anti-parallel arrangement do not exhibit any quasi-symmetry. This observation also conveys the pitfalls of using the quasi-equivalence as validation criteria for the structural analysis of extended (non-modular) capsid proteins such as IX. Together, these results remedy certain discrepancies in the previous X-ray model in agreement with the cryo-electron microscopy models.     

CryoEM structure at 9A resolution of an adenovirus vector targeted to hematopoietic cells

We report a sub-nanometer resolution cryo-electron microscopy (cryoEM) structural analysis of an adenoviral vector, Ad35F, comprised of an adenovirus type 5 (Ad5) capsid pseudo-typed with an Ad35 fiber. This vector transduces human hematopoietic cells via association of its fiber protein with CD46, a member of the complement regulatory protein family. Major advances in data acquisition and image processing allowed a significant improvement in resolution compared to earlier structures. Analysis of the cryoEM density was enhanced by docking the crystal structures of both the hexon and penton base capsid proteins. CryoEM density was observed for hexon residues missing from the crystal structure that include hypervariable regions and the epitope of a neutralizing monoclonal antibody. Within the penton base, density was observed for the integrin-binding RGD loop missing from the crystal structure and for the flexible beta ribbon of the variable loop on the side of the penton base. The Ad35 fiber is flexible, consistent with the sequence insert in the third beta-spiral repeat. On the inner capsid surface density is revealed at the base of the hexons and below the penton base. A revised model is presented for protein IX within the virion. Well-defined density was assigned to a conserved domain in the N terminus of protein IX required for incorporation into the virion. For the C-terminal domain of protein IX two alternate conformations are proposed, either binding on the capsid surface or extending away from the capsid. This model is consistent with the tolerance of the C terminus for inserted ligands and its potential use in vector retargeting. This structural study increases our knowledge of Ad capsid assembly, antibody neutralization mechanisms, and may aid further improvements in gene delivery to important human cell types.     

Cryoelectron microscopy map of Atadenovirus reveals cross-genus structural differences from human adenovirus

A three-dimensional (3D) cryoelectron microscopy reconstruction of the prototype Atadenovirus (OAdV [an ovine adenovirus isolate]) showing information at a 10.6-A resolution (0.5 Fourier shell correlation) was derived by single-particle analysis. This is the first 3D structure solved for any adenovirus that is not a Mastadenovirus, allowing cross-genus comparisons between structures and the assignment of genus-specific capsid proteins. Viable OAdV mutants that lacked the genus-specific LH3 and p32k proteins in purified virions were also generated. Negatively stained 3D reconstructions of these mutants were used to identify the location of protein LH3 and infer that of p32k within the capsid. The key finding was that LH3 is a critical protein that holds the outer capsid of the virus together. In its absence, the outer viral capsid is unstable. LH3 is located in the same position among the hexon subunits as its protein IX equivalent from mastadenoviruses but sits on top of the hexon trimers, forming prominent "knobs" on the virion surface that visually distinguish OAdV from other known AdVs. Electron density was also assigned to hexon and penton subunits and to proteins IIIa and VIII. There was good correspondence between OAdV density and human AdV hexon structures, which also validated the significant differences that were observed between the penton base protein structures.     

The Cleaved N-Terminus of pVI Binds Peripentonal Hexons in Mature Adenovirus

Mature human adenovirus particles contain four minor capsid proteins, in addition to the three major capsid proteins (penton base, hexon and fiber) and several proteins associated with the genomic core of the virion. Of the minor capsid proteins, VI plays several crucial roles in the infection cycle of the virus, including hexon nuclear targeting during assembly, activation of the adenovirus proteinase (AVP) during maturation and endosome escape following cell entry. VI is translated as a precursor (pVI) that is cleaved at both N- and C-termini by AVP. Whereas the role of the C-terminal fragment of pVI, pVIc, is well established as an important co-factor of AVP, the role of the N-terminal fragment, pVIn, is currently elusive. In fact, the fate of pVIn following proteolytic cleavage is completely unknown. Here, we use a combination of proteomics-based peptide identification, native mass spectrometry and hydrogen–deuterium exchange mass spectrometry to show that pVIn is associated with mature human adenovirus, where it binds at the base of peripentonal hexons in a pH-dependent manner. Our findings suggest a possible role for pVIn in targeting pVI to hexons for proper assembly of the virion and timely release of the membrane lytic mature VI molecule.     

Synthesis, Transport, and Morphogenesis of Type 5 Adenovirus Capsid Proteins

During the period between 20 and 24 hr after infection of KB cells with type 5 adenovirus, at a time when approximately 85% of the proteins made were virus-specific, viral proteins were synthesized on polyribosomes with an average sedimentation coefficient of 200S. The polypeptide chains synthesized during a 1-min period of labeling with (14)C-amino acids had an average sedimentation coefficient of 3.4S in sucrose gradients containing 1% sodium dodecyl sulfate. Within 1 min after completion, the newly made polypeptide chains were released from polyribosomes, and the majority were transported into the nuclei within 6 min. Meanwhile, the immunological reactivity of the newly synthesized proteins also increased rapidly. During the same 6-min interval after synthesis, the single polypeptide chains assembled into multimeric proteins with average sedimentation coefficients of 6S, 9S, and 12S. The 6S and 12S proteins were identified immunologically as the fiber and hexon capsid proteins, respectively. The 9S protein was trypsin-sensitive and appeared to be the precursor of the penton; it was tentatively identified as the penton base. The penton had a sedimentation coefficient of about 10.5S and sedimented with the hexon in sucrose gradients. The concomitant migration of nascent proteins into the nuclei, development of the capsid proteins' immunological reactivity, and morphogenesis of the multimeric capsid proteins suggest that the single polypeptide chains or small complexes were transported into the nuclei where they assembled into mature structural proteins of the virion.     

Protein ligands of the human adenovirus type 2 outer capsid identified by biopanning of a phage-displayed peptide library on separate domains of wild-type and mutant penton capsomers.

A filamentous phage-displayed random hexapeptide library was screened on the adenovirus type 2 (Ad2) penton capsomer and its separate domains, penton base, full-length fiber, fiber shaft and fiber knob. Affinity supports were designed to immobilize the penton ligate with a preferred orientation, via immuno-adsorption to pre-coated antibody. Three classes of phagotopes were distinguished in the eluates from the penton and fiber domains. (i) The first class represented peptide sequences identified in certain Ad2 capsid proteins, protein IIIa, protein pVIII, penton base and penton fiber. Data from specific ligand elution of phages bound to fiber and penton base wild-types and mutants suggested that the region overlapping the RLSNLLG motif at residues 254-260 in the penton base and the FNPVYP motif at residues 11-16 in the fiber tail formed mutual interacting sites in the penton capsomer. (ii) The second class consisted of phagotopes homologous to peptide sequences found in host cell membrane proteins involved in receptor or adhesion functions. One of the most abundant species corresponded to a conserved motif present in the beta-strand B of type III modules of human fibronectin. In addition, phages which were screened for their failure to bind to penton base RGD mutants were found to carry consensus motifs to peptide sequences present in the RGD recognition site of human integrin beta subunits. (iii) The third class comprised peptide motifs common to both viral and cellular proteins, suggesting that a mechanism of ligand exchange could occur during virus entry and uncoating, and virus assembly and release.     

Bacteriophage PRD1 contains a labile receptor-binding structure at each vertex.

Bacteriophage PRD1 is a membrane-containing virus with an unexpected similarity to adenovirus. We mutagenized unassigned PRD1 genes to identify minor capsid proteins that could be structural or functional analogs to adenovirus proteins.We report here the identification of an amber mutant, sus525, in an essential PRD1 gene XXXI. The gene was cloned and the gene product was overexpressed and purified to near homogeneity. Analytical ultracentrifugation and gel filtration showed that P31 is a homopentamer of about 70 kDa. The protein was shown to be accessible on the virion surface and its absence in the sus525 particles led to the deficiency of two other viral coat proteins, protein P5 and the adsorption protein P2. Cryo-electron microscopy and image reconstruction of the sus525 particles indicate that these proteins are located on the capsid vertices, because in these particles the entire vertex structure was missing along with the peripentonal major capsid protein P3 trimers. Sus525 particles package DNA effectively but loose it upon purification.All of the PRD1 vertex structures are labile and potentially capable of mediating DNA delivery; this is in contrast to other dsDNA phages which employ a single vertex for packaging and delivery. We propose that this arises from a symmetry mismatch between protein P2 and the pentameric P31 in analogy to that between the adenovirus penton base and the receptor-binding spike.     

Determination of the nucleotide sequence for the penton-base gene of human adenovirus type 5

The major structural proteins of adenovirus (Ad), which form the external capsid, are hexon, penton base and fiber. The primary structure of the Ad5 penton base has been deduced from the nucleotide sequence of the corresponding gene. It has 98.6% homology with the sequence of the analogous protein from Ad2. This result is in contrast with the significantly lower homology found for the two other major structural proteins, the hexon and the fiber.     

Multiple adenovirus serotypes use alpha v integrins for infection.

The nucleotide sequence encoding the penton base integrin-binding domains of several human adenoviruses was obtained by homology PCR. Each of the penton base proteins contains a conserved Arg-Gly-Asp (RGD) sequence that is predicted to lie at the apex of two extended alpha helices. The penton base RGD domain promotes efficient infection of host cells by multiple adenovirus serotypes via interaction with alpha v integrins, thus indicating that alpha v integrins play a central role in the entry of adenoviruses into host cells.     

Neutralization of adenoviruses: kinetics, stoichiometry, and mechanisms.

Kinetic curves for neutralization of adenovirus type 2 with anti-hexon serum revealed no lag periods even when the serum was highly diluted or when the temperature was lowered to 4 degrees C, thus indicating a single-hit mechanism. Multiplicity curves determined with anti-hexon serum displayed a linear correlation between the degree of neutralization and dilution of antiserum. Neutralization values experimentally obtained under steady-state conditions fully fitted a single-hit model based on Poisson calculations. Quantitation of the amount of 125I-labeled type-specific anti-hexon antibodies needed for full neutralization of adenovirus showed that 1.4 antibodies were attached per virion under such conditions. Virions already attached to HeLa cells at 4 degrees C were, to a large extent, neutralizable by anti-hexon serum, whereas anti-fiber and anti-penton base antisera were negative. It is suggested that adenovirus may be neutralized by two pathways: aggregation of the virions (extracellular neutralization) as performed by anti-fiber antibodies and blocking of virion entrance from the acidic endosomes into the cytoplasm (intracellular neutralization). The latter effect could be obtained by (i) covering of the penton bases, as performed by anti-penton base antibodies, thereby preventing interaction between the penton bases and the endosomal membrane, which results in trapping of virions within endosomes, and (ii) inhibition of the low-pH-induced conformational change of the viral capsid, which seems to occur in the endosomes and is necessary for proper exposure of the penton bases, as performed by anti-hexon antibodies.     

Structural and biochemical characterization of a human adenovirus 2/12 penton base chimera

The vertex of the adenoviral capsid is formed by the penton, a complex of two proteins, the pentameric penton base and the trimeric fiber protein. The penton contains all necessary components for viral attachment and entry into the host cell. After initial attachment via the head domain of the fiber protein, the penton base interacts with cellular integrins through an Arg-Gly-Asp (RGD) motif located in a hypervariable surface loop, triggering virus internalization. In order to investigate the structural and functional role of this region, we replaced the hypervariable loop of serotype 2 with the corresponding, but much shorter, loop of serotype 12 and compared it to the wild type. Here, we report the 3.6 A crystal structure of a human adenovirus 2/12 penton base chimera crystallized as a dodecamer. The structure is generally similar to human adenovirus 2 penton base, with the main differences localized to the fiber protein-binding site. Fluorescence anisotropy assays using a trimeric fiber protein mimetic called the minifiber and wild-type human adenovirus 2 and chimeric penton base demonstrate that fiber protein binding is independent of the hypervariable loop, with a K(d) for fiber binding estimated in the 1-2 microm range. Interestingly, competition assays using labeled and unlabeled minifiber demonstrated virtually irreversible binding to the penton base, which we ascribe to a conformational change, on the basis of comparisons of all available penton base structures.     

The structure of the human adenovirus 2 penton

The adenovirus penton, a noncovalent complex of the pentameric penton base and trimeric fiber proteins, comprises the vertices of the adenovirus capsid and contains all necessary components for viral attachment and internalization. The 3.3 A resolution crystal structure of human adenovirus 2 (hAd2) penton base shows that the monomer has a basal jellyroll domain and a distal irregular domain formed by two long insertions, a similar topology to the adenovirus hexon. The Arg-Gly-Asp (RGD) motif, required for interactions with cellular integrins, occurs on a flexible surface loop. The complex of penton base with bound N-terminal fiber peptide, determined at 3.5 A resolution, shows that the universal fiber motif FNPVYPY binds at the interface of adjacent penton base monomers and results in a localized structural rearrangement in the insertion domain of the penton base. These results give insight into the structure and assembly of the adenovirus capsid and will be of use for gene-therapy applications.     

Morphogenesis of human adenovirus type 2 studied with fiber- and fiber and penton base-defective temperature-sensitive mutants.

The nature, polypeptide composition, and antigenic composition of the particles formed by six human adenovirus type 2 temperature-sensitive (ts) mutants were studied. ts115, ts116, and ts125 were phenotypically fiber-defective mutants, and ts103, ts104, and ts136 failed to synthesize detectable amounts of fiber plus penton base at 39.5 degrees C. The mutants belonged to five complementation groups, one group including ts116 and ts125. Except for ts103 and ts136, the other mutants were capable of producing particles at 39.5 degrees C. ts116 and ts125 accumulated light assembly intermediate particles (or top components) at nonpermissive temperatures, with few virus particles. The sodium dodecyl sulfate polypeptide pattern of ts116- or ts125-infected cells, intermediate particles, and virus particles showed that polypeptide IV (fiber) was smaller by a molecular weight of 2,000 than that in the wild-type virion and was glycosylated. In fiber plus penton base-defective ts104-infected cells, equivalent quantities of top components and viruses with a buoyant density (rho) of 1.345 g/ml (rho = 1.345 particles) were produced at 39.5 degrees C. These rho = 1.345 particles corresponded to young virions, as evidenced by the presence of uncleaved precursors to proteins VI, VIII, and VII. These young virions matured upon a shift down. Virus capsid vertex antigenic components underwent a phase of eclipse during their incorporation into mature virus particles. No antigenic penton base or IIa was detected in intermediate particles of all the ts mutants tested. Only hexon and traces of fiber antigens were found in ts104 young virions. Penton base and IIIa appeared as fully antigenically expressed capsid subunits in mature wild-type virions or ts104 virions after a shift down. The ts104 lesion is postulated to affect a regulatory function related in some way to penton base and fiber overproduction and the maturation processing of precursors PVI, PVII, and PVII.     

SDS-acrylamide gel electrophoresis and its application to the proteins of poliovirus- and adenovirus-infected human cells

Sensitive techniques for acrylamide gel electrophoretic analysis have been applied to animal virus systems and have proven generally useful. Estimates of the number of kinds, molecular weights and number of molecules of proteins in almost any biological sample have been made with ease. As applied to the poliovirus-HeLa cell system they reveal four major proteins in the virion and at least ten additional proteins in the infected cell. Some of the intracellular and particulate proteins undergo cleavage reactions following a unique translation in which the genome is apparently translated in toto as one large polypeptide of molecular weight greater than 200,000 daltons. The splits occur at three levels: (a) during synthesis; (b) at intermediate stages; and (c) co-incident with maturation. In vitro studies on protein synthesis, RNA synthesis and virus assembly have substantiated and extended the in vivo observations. The structure of the adenovirion has been established in detail. Hexon, penton base, fiber and core polypeptides and certain relevant subviral structures have been identified. Nearly all of the proteins synthesized in the infected cells after 20 hours are viral. The major structural antigens (hexon and penton) predominate and are made in 10 to 50 fold excess but the internal core polypeptides are not produced in great excess. Studies on the synthesis of polypeptides and their assembly into morphological subunits and virions show that hexon and penton polypeptides are made in about four and two minutes respectively on cytoplasmic polyribosomes, that morphological subunits are formed within five minutes of synthesis of protein, and that there is a delay of greater than one half hour for entry of hexons into virions.     

Antibody-mediated uncoating of adenovirus in vitro

In a virus destabilization assay in vitro it was demonstrated that exposure of adenovirus to proteins will non-specifically protect the virus from being uncoated following transfer to low pH and hypotonic conditions. Such uncoating was also fully inhibited upon pretreatment of virus with 0.05% of the non-ionic detergent polyoxyethylenesorbitan monolaurate (Tween 20). However, in the presence of low concentrations of Tween 20 it was shown that monospecific immunoglobulins, directed against the fiber antigen and polyspecific antibodies produced in response to intact virions, were able to overcome the detergent-protecting effect of uncoating. Immunoglobulins directed towards the remaining outer-capsid components, the hexon, the penton base and the protein IIIa, revealed no such effects. The antifiber-mediated uncoating was paralleled by an aggregation of the virions. The data suggest that the virion-stabilizing effect of salt is enhanced by the hydrophobic action of a non-ionic detergent. Under these conditions the interaction between antifiber antibodies and fibers of the virion will trigger a destabilization of the virion upon transfer to low pH and hypotonic conditions.     

A quasi-atomic model of human adenovirus type 5 capsid

Adenoviruses infect a wide range of vertebrates including humans. Their icosahedral capsids are composed of three major proteins: the trimeric hexon forms the facets and the penton, a noncovalent complex of the pentameric penton base and trimeric fibre proteins, is located at the 12 capsid vertices. Several proteins (IIIa, VI, VIII and IX) stabilise the capsid. We have obtained a 10 A resolution map of the human adenovirus 5 by image analysis from cryo-electron micrographs (cryoEMs). This map, in combination with the X-ray structures of the penton base and hexon, was used to build a quasi-atomic model of the arrangement of the two major capsid components and to analyse the hexon-hexon and hexon-penton interactions. The secondary proteins, notably VIII, were located by comparing cryoEM maps of native and pIX deletion mutant virions. Minor proteins IX and IIIa are located on the outside of the capsid, whereas protein VIII is organised with a T=2 lattice on the inner face of the capsid. The capsid organisation is compared with the known X-ray structure of bacteriophage PRD1.     

Complementary peptide sequences in partner proteins of the adenovirus capsid

Peptides quite similar to the signal peptide of secretory proteins were found in adenovirus serotype 2 fibre. This was surprising because this protein does not have this property. Because the N-end fibre is implicated in the penton base-fibre interaction and complementary peptides to the N-sequence fibre were found in penton base protein, these complementary peptides might be involved in the protein-protein recognition and interaction process. So far, known structural data agree with such an hypothesis.     

The maturation of murine dendritic cells induced by human adenovirus is mediated by the fiber knob domain

We investigated the mechanism of adenovirus serotype 5 (Ad5)-mediated maturation of bone marrow-derived murine dendritic cells (DC) using (i) Ad5 vectors with wild-type capsid (AdE1 degrees, AdGFP); (ii) Ad5 vector mutant deleted of the fiber C-terminal knob domain (AdGFPDeltaknob); and (iii) capsid components isolated from Ad5-infected cells or expressed as recombinant proteins, hexon, penton, penton base, full-length fiber, fiber knob, and fiber mutants. We found that penton capsomer (penton base linked to its fiber projection), full-length fiber protein, and its isolated knob domain were all capable of inducing DC maturation, whereas no significant DC maturation was observed for hexon or penton base alone. This capacity was severely reduced for AdGFPDeltaknob and for fiber protein deletion mutants lacking the beta-stranded region F of the knob (residues Leu-485-Thr-486). The DC maturation effect was fully retained in a recombinant fiber protein deleted of the HI loop (FiDeltaHI), a fiber (Fi) deletion mutant that failed to trimerize, suggesting that the fiber knob-mediated DC activation did not depend on the integrity of the HI loop and on the trimeric status of the fiber. Interestingly, peptide-pulsed DC that had been stimulated with Ad5 knob protein induced a potent CD8+ T cell response in vivo.