Stability of the structure and antigenic determinants of adenovirus type 1 native hexon to proteases

Hexon capsomers of human adenovirus type 1 (h1) labeled by iodine 125 were digested in a native state (trimers) by trypsin, chymotrypsin or papain, and the resulting hydrolysates were analyzed by SDS-PAGE. In each case, a discrete and temporally stable pattern of relatively large fragments was revealed. The degree of hexon polypeptide hydrolysis was maximal for papain, intermediate for chymotrypsin and minimal for trypsin, the largest fragments in the digest being 32, 40 and 80 kD, respectively. At room temperature, all the electrophoretically discernible hexon proteolytical fragments were held together in structures resembling intact hexon trimers and could be regarded as "hexon cores", of which papain hexon cores were the most stable during SDS-PAGE. Radioimmunoprecipitation analysis revealed a complete absence of native hexon antigenicity in thermodenaturated fragments of hexon protease digests, while native trypsin, chymotrypsin and papain hexon cores could be precipitated by hexon-specific antibodies. The immunoprecipitated material contained all of the hexon fragments found in appropriate hexon cores and retained the structure of the original cores. Trypsin, chymotrypsin and papain hexon cores were shown to possess at least part of native Ad h1 hexon antigenic determinants of each of the following specificities: species-specific (epsilon), cross-reactive with hexon of human adenoviruses (h3 and h6), simian adenovirus (sim 16), bovine adenoviruses (bos 3 and bos 7) and avian adenovirus (Aviadenovirus gal 1 or CELO). Thus, the full spectrum of known hexon antigenic determinants (species-specific to intergenus-crossreactive) is at least portly stable against protease attack of native hexon capsomers.     

The 100K-chaperone protein from adenovirus serotype 2 (Subgroup C) assists in trimerization and nuclear localization of hexons from subgroups C and B adenoviruses

Recombinant hexons from subgroup C adenoviruses (Ad2 and Ad5) and from a member of subgroup B (Ad3) adenoviruses have been expressed in insect cells. When expressed alone, all three hexons were found to be insoluble and accumulated as inclusion bodies in the cytoplasm. However, co-expression of recombinant Ad2, Ad5 or Ad3 hexon with Ad2 L4-100K protein resulted in the formation of soluble trimeric hexons. EM analysis of hexons revealed that they were indistinguishable from native hexon capsomers isolated from Ad2-infected human cells, or released from partially disrupted adenovirions. This suggests that 100K acts as a chaperone for hexon folding and self-assembly into capsomer in insect cells. Since 100K protein assists in the trimerization of subgroup C hexon, and of subgroup B hexon protein, it implies that it functions in a manner that is both homo- and heterotypic. During the course of recombinant protein expression, the 100K protein was found in association with hexon monomers and trimers within the cytoplasm. In the nucleus, however, 100K was found in complexes with hexon trimers exclusively. EM observation of purified 100K protein samples showed a dumb-bell-shaped molecule compatible with a monomeric protein. EM analysis of hexon-100K protein complexes showed that interaction of hexon with the 100K protein occurred via one of the globular domains of the 100K protein molecule. Our data confirm the role of the 100K protein as a scaffold protein for hexon, and provide evidence suggesting its function in hexon nuclear import in insect cells.     

Conditions of stability for the quaternary structure and antigenic activity of adenovirus hexon

The procedure of SDS-PAGE was modified by lowering the temperature of protein sample dissociation to allow the separation of denaturated adenoviral hexon chains and native hexon capsomers (trimers) in the same gel. By combining the modified SDS-PAGE with dot and blot radioimmunoassays, the range of stability of the simian adenovirus SA7 hexon quaternary structure and its antigenicity was studied against a number of physical and chemical agents known to dissociate and denaturate proteins. A perfect correlation was found between the hexon native quaternary structure (trimer) and its immunoreactivity with anti-hexon immunoglobulins. The pattern of hexon trimer stability to a wide spectrum of denaturants suggests that its subunits are held together, mainly by hydrophobic interactions, in such a way that the innersubunit contact regions make up the "hydrophobic core" of the hexon molecule.     

Characterization of two temperature-sensitive mutants of type 5 adenovirus with mutations in the 100,000-dalton protein gene.

Complementation analysis assigned the mutations of strains H5ts115 and H5ts116, two hexon-minus mutants, to the 100,000-dalton (100K) protein gene. Heterotypic marker rescue (i.e., type 5 adenovirus [Ad5] temperature-sensitive mutants DNA X EcoRI restriction fragments of Ad2 DNA) confirmed the results of previous marker rescue mapping studies, and the heterotypic recombinants yielded unique hybrid (Ad5-Ad2) 100K proteins which were intermediate in size between Ad5 and Ad2 proteins and appeared to be as functionally active as the wild-type 100K protein. Phenotypic characterization of these mutants showed that both the hexon polypeptides and the 100K polypeptides were unstable at the nonpermissive temperature, whereas fiber and penton were not degraded, and that the 100K protein made at 39.5 degrees C could not be utilized after a shift to the permissive temperature (32 degrees C). The role of the 100K protein in the assembly of the hexon trimer was also examined by in vitro protein synthesis. Normally, hexon polypeptides synthesized during an in vitro reaction are assembled into immunoreactive hexons. However, this assembly was inhibited by preincubation of the cell extract with anti-100K immunoglobulin G; neither anti-fiber immunoglobulin G nor normal rabbit immunoglobulin G inhibited hexon assembly. It is postulated that an interaction between the 100K protein and hexon polypeptides is required for effective assembly of hexon trimers.     

Structural and phylogenetic analysis of adenovirus hexons by use of high-resolution x-ray crystallographic,molecular modeling,and sequence-based methods

A major impediment to the use of adenovirus as a gene therapy vector and for vaccine applications is the host immune response to adenovirus hexon-the major protein component of the icosahedral capsid. A solution may lie in novel vectors with modified or chimeric hexons designed to evade the immune response. To facilitate this approach, we have distinguished the portion of hexon that all serotypes have in common from the hypervariable regions that are responsible for capsid diversity and type-specific immunogenicity. The common hexon core-conserved because it forms the viral capsid-sets boundaries to the regions where modifications can be made to produce nonnative hexons. The core has been defined from the large and diverse set of known hexon sequences by an accurate alignment based on the newly refined crystal structures of human adenovirus types 2 (Ad2) and Ad5 hexon. Comparison of the two hexon models, which are the most accurate so far, reveals that over 90% of the residues in each have three-dimensional positions that closely match. Structures for more distant hexons were predicted by building molecular models of human Ad4, chimpanzee adenovirus (AdC68), and fowl adenovirus 1 (FAV1 or CELO). The five structures were then used to guide the alignment of the 40 full-length (>900 residues) hexon sequences in public databases. Distance- and parsimony-based phylogenetic trees are consistent and reveal evolutionary relationships between adenovirus types that parallel those of their animal hosts. The combination of crystallography, molecular modeling, and phylogenetic analysis defines a conserved molecular core that can serve as the armature for the directed design of novel hexons.     

Immunoenzyme analysis of adenovirus hexon. Determination of antibodies from hyperimmunized chickens

We have elaborated three systems of enzyme-linked immunosorbent assay (ELISA) for detection of chicken IgG antibodies specific for hexon antigens of three immunologically distinct adenovirus groups: those of mammalian adenoviruses (Mastadenovira), typical avian adenoviruses (Aviadenovira) and of egg-drop syndrome-76 (EDS-76) virus. In each system the antibodies against respective hexons were specifically detected. In mammalian adenovirus hexons the ELISA detects primarily the type-specific (epsilon) and genus-specific (alpha) antigenic determinants. The time course of anti-hexon antibodies content was followed during immunization. The level of anti-hexon antibodies in egg yolk reflects adequately their content in blood serum. The technique is suitable for serological diagnosis of chicken adenoviral infections as well as for characterization of egg-yolk antibodies obtained by preparative hyperimmunization of hens.     

Identification of sites in adenovirus hexon for foreign peptide incorporation

Adenovirus type 5 (Ad5) is one of the most promising vectors for gene therapy applications. Genetic engineering of Ad5 capsid proteins has been employed to redirect vector tropism, to enhance infectivity, or to circumvent preexisting host immunity. As the most abundant capsid protein, hexon modification is particularly attractive. However, genetic modification of hexon often results in failure of rescuing viable viruses. Since hypervariable regions (HVRs) are nonconserved among hexons of different serotypes, we investigated whether the HVRs could be used for genetic modification of hexon by incorporating oligonucleotides encoding six histidine residues (His6) into different HVRs in the Ad5 genome. The modified viruses were successfully rescued, and the yields of viral production were similar to that of unmodified Ad5. A thermostability assay suggested the modified viruses were stable. The His6 epitopes were expressed in all modified hexon proteins as assessed by Western blotting assay, although the intensity of the reactive bands varied. In addition, we examined the binding activity of anti-His tag antibody to the intact virions with the enzyme-linked immunosorbent assay and found the His6 epitopes incorporated in HVR2 and HVR5 could bind to anti-His tag antibody. This suggested the His6 epitopes in HVR2 and HVR5 were exposed on virion surfaces. Finally, we examined the infectivities of the modified Ad vectors. The His6 epitopes did not affect the native infectivity of Ad5 vectors. In addition, the His6 epitopes did not appear to mediate His6-dependent viral infection, as assessed in two His6 artificial receptor systems. Our study provided valuable information for studies involving hexon modification.     

Electrophoretic purification of biologically active structural proteins of the simian adenovirus SA7 in the presence of sodium dodecyl sulfate

The modification of disc electrophoresis technique in polyacrylamide gel with sodium dodecylsulphate (SDS) has been elaborated for synchronous isolation of some structural proteins in biologically active form and in preparative quantities from adenoviruses. Virions of SA7 adenovirus were mildly dissociated in SDS solution at 20 degrees C and structural proteins were stained by fluorescamin. After separation the zones of proteins corresponding to the native capsomeres of hexon and protein IV as well as the zones of inner proteins V and VII have been identified as fluorescent at UV-irradiation, excised and extracted by SDS solution. After the removal of SDS by protein precipitation in acetone the preparations of hexon and IV reveal the quaternary structure of native capsomers and full spectrum of antigenic and immunogenic activities of native proteins. Preparations of inner proteins V and VII possess activity in condensing adenoviral DNA. The technique is usable for preparative purification of inner polypeptide VI SA7, as well as capsomers and inner proteins of other adenoviruses.     

Structure of a Cell Entry Defective Human Adenovirus Provides Insights into Precursor Proteins and Capsid Maturation

Maturation of adenoviruses is distinguished by proteolytic processing of several interior minor capsid proteins and core proteins by the adenoviral protease and subsequent reorganization of adenovirus core. We report the results derived from the icosahedrally averaged cryo-EM structure of a cell entry defective form of adenovirus, designated ts1, at a resolution of 3.7 Å as well as of the localized reconstructions of unique hexons and penton base. The virion structure revealed the structures and organization of precursors of minor capsid proteins, pIIIa, pVI and pVIII, which are closely associated with the hexons on the capsid interior. In addition to a well-ordered helical domain (a.a. 310–397) of pIIIa, highlights of the structure include the precursors of VIII display significantly different structures near the cleavage sites. Moreover, we traced residues 4–96 of the membrane lytic protein (pVI) that includes an amphipathic helix occluded deep in the hexon cavity suggesting the possibility of co-assembly of hexons with the precursors of VI. In addition, we observe a second copy of pVI ordered up to residue L40 in the peripentonal hexons and a few fragments of density corresponding to 2nd and 3rd copies of pVI in other hexons. However, we see no evidence of precursors of VII binding in the hexon cavity. These findings suggest the possibility that differently bound pVI molecules undergo processing at the N-terminal cleavage sites at varying efficiencies, subsequently creating competition between the cleaved and uncleaved forms of VI, followed by reorganization, processing, and release of VI molecules from the hexon cavities.     

Pseudopackaging of adenovirus type 5 genomes into capsids containing the hexon proteins of adenovirus serotypes B, D, or E

Adenoviruses (Ad) show promise as a vector system for gene delivery in vivo. However, a major challenge in the development of Ad vectors is the circumvention of the host immune responses to Ad infection, including both the host cytotoxic T-cell response and the humoral response resulting in neutralizing antibodies. One method to circumvent the effect of neutralizing antibodies against an Ad vector is to use different Ad serotypes to deliver the transgene of interest. This approach has been demonstrated with Ad genomes of highly related members of subgroup C. However, it is not known whether an Ad5-based vector DNA molecule can be packaged into capsids of evolutionarily more divergent adenoviruses. The aim of these studies was to determine if capsids containing hexon proteins from other Ad subgroups could package the Ad5 genome. A genetic approach utilizing an Ad5 temperature-sensitive (ts) mutant with a mutation in the hexon protein was used. When grown at the nonpermissive temperature, Ad5 ts147 replicates normally, providing a source of Ad5 DNA for virus assembly, but does not produce virus particles due to the hexon protein mutation. Coinfection of Ad5 ts147 with a wild-type virus of other Ad serotypes (Ad3, Ad4, or Ad9), which supply functional hexon proteins, resulted in the pseudopackaging of the Ad5 DNA genome. Furthermore, the pseudopackaged Ad5 DNA virions obtained in the coinfections were infectious. Therefore, switching hexons did not impair the infectivity or uncoating process of the pseudopackaged virion. Since hexon protein is a major antigenic determinant of the Ad capsid, this approach may prove useful to reduce the antigenicity of therapeutic Ad vectors and allow repeated vector administration.     

Antigenic composition of adenovirus hexons]

Quantitative relations between the group-specific and the type-specific components of the hexons of adenovirus type 2 and 5 were studied by means of FITC-conjugated Fab-fragments of antibodies directed against type 2 and type 5 hexons. From the sedimentation constant of the complexes of hexons and Fab in the region of excess of Fab we conclude that there are at least 20 determinants on the hexon. Half of these are type-specific and the others are group-specific. Both components of the type 2 hexon consist of equal parts of carbodiimide sensitive and carbodiimide resistent determinants.     

Adenovirus assembly: self-assembly of partially digested hexons.

Papainic hydrolysis of adenovirus type 2 hexon capsomers was apparently limited and induced self-aggregation of hexons in a preferred oligomeric species, hexon trimers, sedimenting at about 19X, and retaining their immunological properties. These hexon trimers were composed of two classes of trimer molecules with different electric charges. The relevance of this trimer aggregation phenomenon to the adenovirus assembly process is discussed.     

Image reconstruction reveals the complex molecular organization of adenovirus

The three-dimensional structure of adenovirus has been determined by image reconstruction from cryo-electron micrographs. Comparison with the high resolution X-ray crystal structure of hexon, the major capsid protein, enabled an unusually detailed interpretation of the density map and confirmed the validity of the reconstruction. The hexon packing in the capsid shows more extensive intermolecular interfaces between facets than previously proposed. The reconstruction provides the first three-dimensional visualization of the vertex proteins, including the penton base and its associated protruding fiber. Three minor capsid proteins that stabilize and modulate capsomer interactions are revealed. One of these components stabilizes the group-of-nine hexons in the center of each facet and the other two bridge hexons in adjacent facets. The strategic positions of these proteins highlight the importance of cementing proteins in stabilizing a complex assembly.     

Membrane regulation of the chromosomal replication activity of E.coli DnaA requires a discrete site on the protein.

The capacity of DnaA protein to initiate DNA synthesis at the chromosomal origin is influenced profoundly by the tightly bound nucleotides ATP and ADP. Acidic phospholipids can catalyze the conversion of inactive ADP-DnaK protein into the active ATP form. Proteolytic fragments of the nucleotide form of DnaA protein were examined to determine regions of the protein critical for functional interaction with membranes. A 35 kDa chymotryptic and 29 kDa tryptic fragment retained the tightly bound nucleotide. The fragments, whose amino-termini are within three residues of each other, but differ at their carboxyl ends, showed strikingly different behavior when treated with acidic phospholipids. The larger chymotryptic fragment released the bound nucleotide in the presence of acidic, but not neutral phospholipids. In contrast, the smaller tryptic fragment was inert to both forms of phospholipids. Acidic membranes, but not those composed of neutral phospholipids, protect from tryptic digestion a small portion of the segment that constitutes the difference between the 29 and 35 kDa fragments. The resulting 30 kDa tryptic fragment, which possesses this protected region, interacts functionally with acidic membranes to release the bound effector nucleotide. Inasmuch as the anionic ganglioside GM1, a compound structurally dissimilar to acidic glycerophospholipids, efficiently releases the nucleotide from DnaA protein, an acidic surface associated with a hydrophobic environment is the characteristic of the membrane that appears crucial for regulatory interaction with DnaA protein.     

Membrane regulation of the chromosomal replication activity of E. coli DnaA requires a discrete site on the protein.

The capacity of DnaA protein to initiate DNA synthesis at the chromosomal origin is influenced profoundly by the tightly bound nucleotides ATP and ADP. Acidic phospholipids can catalyze the conversion of inactive ADP-DnaA protein into the active ATP form. Proteolytic fragments of the nucleotide form of DnaA protein were examined to determine regions of the protein critical for functional interaction with membranes. A 35 kDa chymotryptic and 29 kDa tryptic fragment retained the tightly bound nucleotide. The fragments, whose amino-termini are within three residues of each other, but differ at their carboxyl ends, showed strikingly different behavior when treated with acidic phospholipids. The larger chymotryptic fragment released the bound nucleotide in the presence of acidic, but not neutral phospholipids. In contrast, the smaller tryptic fragment was inert to both forms of phospholipids. Acidic membranes, but not those composed of neutral phospholipids, protect from tryptic digestion a small portion of the segment that constitutes the difference between the 29 and 35 kDa fragments. The resulting 30 kDa tryptic fragment, which possesses this protected region, interacts functionally with acidic membranes to release the bound effector nucleotide. Inasmuch as the anionic ganglioside GM1, a compound structurally dissimilar to acidic glycerophospholipids, efficiently releases the nucleotide from DnaA protein, an acidic surface associated with a hydrophobic environment is the characteristic of the membrane that appears crucial for regulatory interaction with DnaA protein.     

In vitro reconstitution, hexon bonding and handedness of incomplete adenovirus capsid

Purified groups of nine hexons (nonamers) from trypsin and sodium deoxycholate-disrupted adenovirus type 5 were found to re-aggregate at low pH values into pairs, rings of five and icosahedral shells of twenty nonamers. Electron microscopy and ultracentrifugation showed that these shells are the same as normal adenovirus capsids minus the twelve vertex assemblies of six capsomers each.The pyramidal rings of five nonamers provided the first clear evidence that the adenovirus capsid is left-handed. Dissociation of the nonamers suggested that they are organized as a central hexon trimer plus three differently bonded dimers, and not as a true p3 net. New evidence is presented, based on two-dimensional hexon crystals, that individual hexons have 3-fold cyclic symmetry and the whole question of hexon-hexon bonding is discussed in the light of these observations.     

Structural organization of the human glucocorticoid receptor determined by one- and two-dimensional gel electrophoresis of proteolytic receptor fragments

The structural organization of the steroid-binding protein of the IM-9 cell glucocorticoid receptor was investigated by using one- and two-dimensional gel electrophoresis of proteolytic receptor fragments. One-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of receptor fragments isolated after trypsin digestion of immunopurified [3H]dexamethasone 21-mesylate ([3H]DM-) labeled receptor revealed the presence of a stable 26.5-kilodalton (kDa) steroid-containing, non-DNA-binding fragment, derived from a larger, less stable, 29-kDa fragment. The 26.5-kDa tryptic fragment appeared to be completely contained within a 41-kDa, steroid-containing, DNA-binding species isolated after chymotrypsin digestion of the intact protein. Two-dimensional electrophoretic analysis of the [3H]DM-labeled tryptic fragments resolved two (pI congruent to 5.7 and 7.0) 26.5-kDa and two (pI congruent equal to 5.7 and 6.8) 29-kDa components. This was the same number of isoforms seen in the intact protein, indicating that the charge heterogeneity of the steroid-binding protein is the result of modification within the steroid-containing, non-DNA-binding, 26.5-kDa tryptic fragment. Two-dimensional analysis of the 41-kDa [3H]DM-labeled chymotryptic species revealed a pattern of isoforms more complex than that seen either in the intact protein or in the steroid-containing tryptic fragments. These results suggest that the 41-kDa [3H]DM-labeled species resolved by one-dimensional SDS-PAGE after chymotrypsin digestion may be composed of several distinct proteolytic fragments.     

Hexon peptides of type 2, 3, and 5 adenoviruses and their relationship to hexon structure.

Peptides of hexons from type 2 and 5 (subgroup III) and type 3 (subgroup I) adenoviruses were produced by treatment with cyanogen bromide and were separated by isoelectric focusing in polyacrylamide gels containing 8 M urea. Peptides with identical isoelectric points, but from different hexon types, were considered to have structural similarities. According to this criterion for chemical relatedness, about two-thirds of the type 2 and 5 hexon peptides may be considered similar. In contrast, the majority of the type 3 hexon peptides differed chemically from peptides of type 2 and 5 hexons. Virions and free hexons were iodinated with 125-I in the presence of lactoperoxidase and H-2-O-2. When 125-I-labeled virions were disrupted and the hexon was purified, the highly labeled cyanogen bromide peptides were labeled. When purified hexons from the excess cellular pool were iodinated, peptides common to types 2, 3, and 5 (peptides 12 and 14) were most extensively labeled. Thus, hexons assembled in virions and those free in solution were iodinated differently. The data suggest that immunologically the hexons in viral capsids react differently from unassembled hexons because the polypeptide chains assume slightly different folding configurations in the two hexon forms and therefore expose different regions of the protein to antibodies.     

Antigenic determinants of adenovirus capsids. II. Homogeneity of hexons, and accessibility of their determinants, in the virion.

We have tested the two principal theories which explain the previous finding that small amounts of type-specific antibody to the adenovirus hexon can neutralize infectivity, whereas even large amounts of cross-reactive antibody do not. a) It has been suggested that the type-specific determinants are especially prominent in the virion. We have therefore measured the capacity of whole virus to bind appropriate antibodies, using a sensitive radioimmunoprecipitation (RIP) system. In fact, virions bound type-specific and cross-reactive antibodies impartially. Moreover, they bound both much less effectively than did free hexon or disrupted virus, suggesting that many of each kind of determinant are inaccessible in virions. b) It has been suggested that the type-specific determinants are confined to those hexons located next to the pentons, and that they are the targets for neutralizing antibody. We have therefore studied the antigenicity of peripentonal and nonamer hexons isolated from virions, and found that each possessed both kinds of determinants. Furthermore, these were present in the same proportion as in hexons purified from the soluble antigens in infected cells ("free hexons"). We concluded that the mechanism of neutralization by antibody is complicated, and that the type-specific determinants exposed on the virion must play a crucial role.     

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.