Immunological relationships between hexons of certain human adenoviruses

Phylogenetic and Recombination Analysis of Clinical Vitreous Humor-Derived Adenovirus Isolates Reveals Discordance Between Serotype and Phylogeny

Purpose

To sequence, identify, and perform phylogenetic and recombination analysis on three clinical adenovirus samples taken from the vitreous humor at the Bascom Palmer Eye Institute.

Methods

The PacBio Sequel II was used to sequence the genomes of the three clinical adenovirus isolates. To identify the isolates, a full genome-based multiple sequence alignment (MSA) of 722 mastadenoviruses was generated using multiple alignment using fast Fourier transform (MAFFT). MAFFT was also used to generate genome-based human adenovirus B (HAdV-B) MSAs, as well as HAdV-B fiber, hexon, and penton protein-based MSAs. To examine recombination within HAdV-B, RF-Net 2 and Bootscan software programs were used.

Results

In the course of classifying three new atypical ocular adenovirus samples, taken from the vitreous humor, we found that all three isolates were HAdV-B species. The three Bascom Palmer HAdV-B genomes were then combined with over 300 HAdV-B genome sequences, including nine ocular HAdV-B genome sequences. Attempts to categorize the penton, hexon, and fiber serotypes using phylogeny of the three Bascom Palmer samples were inconclusive due to incongruence between serotype and phylogeny in the dataset. Recombination analysis using a subset of HAdV-B strains to generate a hybridization network detected recombination between nonhuman primate and human-derived strains, recombination between one HAdV-B strain and the HAdV-E outgroup, and limited recombination between the B1 and B2 clades.

Conclusions

The discordance between serotype and phylogeny detected in this study suggests that the current classification system does not accurately describe the natural history and phylogenetic relationships among adenoviruses.

Epidemiological investigation of outbreaks of fowl adenovirus infections in commercial chickens in China

One hundred and five fowl adenovirus (FAdV) strains were isolated in China from 2015 to 2016 from poultry with inclusion body hepatitis (IBH) and hydropericardium syndrome (HPS). Polymerase chain reactions determined that 68 were FAdV species C, five were FAdV species D, two were FAdV species E, and 30 contained two or more different FAdV strains. A phylogenetic analysis showed that the isolated FAdV strains clustered into three major groups: FAdV-C, FAdV-D and FAdV-E. Based on a hexon gene sequencing analysis, these viruses were genetically related to FAdV-4, FAdV-7, FAdV-8b and FAdV-11, of which FAdV-4 was dominant (93% of the strains). An epidemiological analysis showed that FAdVs had been circulating in broilers, domestic chickens, and layers, and co-infections with other immunosuppressive pathogens, such as chicken infectious anaemia virus, Marek's disease virus and reticuloendotheliosis virus, were identified. To control FAdVs, strict biosecurity protection measures are necessary, and a continued surveillance of FAdVs is needed to increase our understanding of the epidemiology of the viruses that are associated with IBH and HPS.

Computational analysis of four human adenovirus type 4 genomes reveals molecular evolution through two interspecies recombination events

Computational analysis of human adenovirus type 4 (HAdV-E4), a pathogen that is the only HAdV member of species E, provides insights into its zoonotic origin and molecular adaptation. Its genome encodes a domain of the major capsid protein, hexon, from HAdV-B16 recombined into the genome chassis of a simian adenovirus. Genomes of two recent field strains provide a clue to its adaptation to the new host: recombination of a NF-I binding site motif, which is required for efficient viral replication, from another HAdV genome. This motif is absent in the chimpanzee adenoviruses and the HAdV-E4 prototype, but is conserved amongst other HAdVs. This is the first report of an interspecies recombination event for HAdVs, and the first documentation of a lateral partial gene transfer from a chimpanzee AdV. The potential for such recombination events are important when considering chimpanzee adenoviruses as candidate gene delivery vectors for human patients.

Preparation and evaluation of chicken embryo-adapted fowl adenovirus serotype 4 vaccine in broiler chickens

The current study was planned to develop an efficient vaccine against hydropericardium syndrome virus (HSV). Currently, formalin-inactivated liver organ vaccines failed to protect the Pakistan broiler industry from this destructive disease of economic importance. A field isolate of the pathogenic hydropericardium syndrome virus was adapted to chicken embryos after four blind passages. The chicken embryo-adapted virus was further serially passaged (12 times) to get complete attenuation. Groups of broiler chickens free from maternal antibodies against HSV at the age of 14 days were immunized either with 16th passage attenuated HSV vaccine or commercially formalized liver organ vaccine. The antibody response, measured by enzyme-linked immunosorbent assay was significantly higher (P < 0.05) in the group immunized with the 16th passage attenuated HSV vaccine compared to the group immunized with liver organ vaccine at 7, 14, and 21 days post-immunization. At 24 days of age, the broiler chickens in each group were challenged with 10(3.83) embryo infectious dose(50) of pathogenic HSV and were observed for 7 days post-challenge. Vaccination with the 16th passage attenuated HSV gave 94.73% protection as validated on the basis of clinical signs (5.26%), gross lesions in the liver and heart (5.26%), histopathological lesions in the liver (1.5 ± 0.20), and mortality (5.26%). The birds inoculated with liver organ vaccine showed significantly low (p < 0.05; 55%) protection estimated on the basis of clinical signs (40%), gross lesions in the liver and heart (45%), histopathological lesions in the liver (2.7 ± 0.72), and mortality (35%). Birds in the unvaccinated control group showed high morbidity (84%), mortality (70%), gross (85%), and histopathological lesions (3.79 ± 0.14) with only 10% protection. In conclusion, this newly developed HSV vaccine proved to be immunogenic and has potential for controlling HSV infections in chickens.

Rapid type-specific diagnosis of adenovirus type 4 infection using a hexon-based quantitative fluorogenic PCR

A hexon-based fluorogenic polymerase chain reaction (PCR) assay utilizing the 5'-nuclease activity of DNA Taqpolymerase was developed as a rapid and type-specific diagnostic system for adenovirus type 4 (Ad4) detection and quantification. The assay consists of a pair of flanking primers and an internal fluorescence labeled probe that allows real time amplification to quantify the Ad4 virus. One out of 12 flanking primer pairs evaluated (combinations of three forward primers and four reverse primers) was found to be optimal for Ad4 virus detection that yielded background-free operation, i.e., no fluorescent signal generated by non-template controls. The assay was employed to detect Ad4 reference virus strain RI-67, Wyeth Ad4 vaccine strain and 71 different clinical Ad4 isolates from US military recruits used in this study with consistent sensitivity (lower detection limit) of 2-4 pfu per PCR reaction. The assay showed linear Ad4 detection with a dynamic range of greater than five logs (from 2-4 pfu/assay to greater than 10(5) pfu/assay). This Ad4-specific assay did not crossreact with representative members of Ad subgroups A, B, C, D and F at viral concentrations greater than 10(8) pfu/ml. It was also demonstrated that Ad4 viruses could be efficiently detected from throat swabs (71/72 specimens or 98.6% detection sensitivity) of infected patients by the Ad4-specific PCR. In general, there was a good correlation between PCR determined viral titers in throat swabs and time required to detect viral cytopathic effects (CPE) in cell culture. Evaluation of the simple Ad4 specific assay developed in this study could be used to provide a rapid clinically relevant diagnosis of Ad4 infections in patients with acute respiratory disease (ARD).

Detection of fowl adenovirus associated with hydropericardium hepatitis syndrome by a polymerase chain reaction

Hydropericardium hepatitis syndrome (HHS), previously unknown in the broiler industry, is an emerging disease that causes severe hydropericardium. A polymerase chain reaction (PCR) was developed to detect the fowl adenovirus (FAV) associated with HHS. The virus from infected livers was purified, with confirmation by electron microscopy and experimental infection. Methods were developed to isolate the viral DNA from purified virus and infected tissues. Available sequence data on the hexon gene of fowl adenoviruses and other adenoviruses were aligned to determine the conserved and variable regions. Primers were constructed from the alignment data. The amplified fragment consisted of the variable region of the hexon gene flanked by conserved primer sites. Optimum conditions were standardized to achieve the amplification of the desired fragment. As expected, the amplified product was found to be of 0.7 kg size. The nucleotide sequence analysis confirmed the specific nature of the product. Amplification of the specific product could be obtained not only from the DNA isolated from the purified virus but also from the total DNA extracted from infected tissues. The PCR was useful for the detection of FAV associated with HHS.

Sequence of the avian adenovirus FAV 1 (CELO) DNA encoding the hexon-associated protein pVI and hexon

The genomic region of the avian adenovirus FAV1 (CELO) encoding the precursor to virion structural protein VI (p VI) and the major capsid protein hexon has been sequenced. The 223-unit sequence of the CELO pVI protein has two potential Ad endoproteinase cleavage sites and a conserved C-terminal sequence including the Cys residue supposedly involved in endoproteinase activation. The CELO hexon gene sequence predicts a 942-residue protein (106.7 kDa). Multiple sequence alignment with other six known hexon protein sequences (human, bovine, murine, and avian) reveals high overall homology. The identity is highest in the regions corresponding to the pedestals which from the base of the hexon, and lowest in the regions corresponding to the loops which are exposed on the outer surface of the virion.

Hexon sequence of adenovirus type 7 and comparison with other serotypes of subgenus B

The hexon gene of human adenovirus (AV) type 7 (subgenus B) was sequenced. The determined nucleotide and the predicted amino acid sequences were compared to the corresponding sequences of AV3 and AV16. The hexons of AV7 and AV3 revealed an overall homology of 94.3% at the protein level, whereas the AV7 and AV16 hexons only showed an overall homology of 85.7%. Utilizing the three-dimensional model of the AV2 hexon, the structure of the AV7 hexon was predicted. The major differences between the three subgenus B hexon polypeptides were confined to the I1 and I2 surface loops. The AV7 I4 hexon loop was 100% identical to the other subgenus B I4 loops, but differed from the corresponding regions of other subgenera. This supports the idea that this loop carries a subgenus-specific determinant.

Type- and group-specific polymerase chain reaction for adenovirus detection

We report on a 1,551-base-pair-long DNA sequence, encoding the variable region and parts of the flanking conserved regions of the human adenovirus type 8 (AV8) hexon, and a sequence comprising 1,404 base pairs, encoding the corresponding regions of the human adenovirus type 31 (AV31). Comparison of the hexon sequences showed that the major sequence changes were located in loops I1 and I2 of the hexon polypeptides which form the surface of the virion. We established a type-specific polymerase chain reaction (PCR), using a combination of a group-specific (general) primer, located in a conserved region of the hexon gene, and type-specific primers located in the region that encodes for loop I2 of the AV8 (subgroup D), AV31 (subgroup A) and AV40 and 41 (both subgroup F) hexon polypeptides. We performed PCR directly from several different clinical specimens or from isolates (AV31). Type-specificity was confirmed by restriction analysis. We also carried out several PCR directly from faecal specimens, using a group-specific primer pair and compared the sensitivity of PCR with that of electron microscopy and enzyme immuno assay.

The hexon genes of adenoviruses of subgenus C: comparison of the variable regions

We report on a 1402-base pair long DNA sequence, encoding for the variable region and parts of the flanking conserved regions of the human adenovirus type 1 (AV1) hexon, and a DNA sequence comprising 1396 base pairs, encoding for the corresponding regions of the human adenovirus type 6 (AV6) hexon. AV1 and AV6, together with AV2 and AV5, belong to subgenus C. Comparison of the predicted amino acid sequences of AV1 and AV6 with those of AV2 and AV5 revealed that the variable hexon region could be subdivided into highly variable, variable and conserved regions. Regions differing between AV2, AV5, AV1 and AV6 were the same as those which were registered as different when comparing AV40 and AV41 (subgenus F), suggesting that these areas of the hexon protein represent type-specific antigenic determinants. Alignment of the amino acid sequences to the known 3-dimensional structure of the AV2 hexon demonstrated that the major amino acid changes were located in the L1 and L2 loops that form the surface of the hexon. Comparison of sequencing data between the serotypes might elucidate questions concerning evolution within subgenus C.

Comparative study of adenoviruses with monoclonal antibodies

The obtainment of monoclonal antibodies for adenovirus species 4(Ad4) is described. The specificities of selected monoclonal antibodies were determined by means of viral neutralization test in cell culture, immunofluorescence and Enzyme-Linked Immunosorbent Assay (ELISA), in the presence of the following species of human adenovirus: 1, 2, 5 (subgenus C), 4 (subgenus E), 7 and 16 (subgenus B) and 9 (subgenus D). Two monoclonal antibodies species specific to adenovirus 4 (1CIII and 3DIII) and one monoclonal antibody that cross reacted with adenovirus species 4 and 7 (2HIII) were obtained.

Characterization of group II avian adenoviruses with a panel of monoclonal antibodies

The interaction between a panel of ten monoclonal antibodies and hemorrhagic enteritis virus, a group II avian adenovirus, was determined. The monoclonal antibodies reacted with all nine isolates of group II avian adenoviruses, but not with any of five types of group I avian adenoviruses. All ten monoclonal antibodies recognized antigenic determinants on the hexon protein of hemorrhagic enteritis virus when analyzed by immunoprecipitation and immunoblotting. They reacted only with the native hexon protein and not with protein denatured by sodium dodecyl sulfate or guanidine-HCl/urea treatment combined with reduction and carboxymethylation. Based on the results of competitive binding assays, the panel of monoclonal antibodies could be subdivided into two groups, which recognized different antigenic domains of the hemorrhagic enteritis virus hexon protein. The monoclonal antibodies in group 1 neutralized hemorrhagic enteritis virus infectivity while the monoclonal antibodies of group 2 did not. Group 1 consisted of eight monoclonal antibodies which could be further subdivided into subgroups 1A, 1B, 1C and 1D. The subdivision of the monoclonal antibodies was based on the degree of blocking in the competitive binding assays and differences in their ability to induce enhancement. In general, the monoclonal antibodies had a higher avidity for the virulent isolate of hemorrhagic enteritis virus than for the avirulent hemorrhagic enteritis virus isolate.

The degree of genetic variability among adenovirus type 4 strains isolated from man and chimpanzee

A total of 8 different genome types of adenovirus type 4 (Ad 4), Ad 4p, Ad 4p 1-3, Ad 4a, Ad 4a 1, Ad 4b, and Ad 4ch were identified among 50 selected human adenovirus isolates and 2 chimpanzee adenovirus strains using 16 restriction endonucleases Bam HI, Bcl I, Bgl I, Bgl II, Bst EII, Dra I, Eco RI, Eco RV, Hind III, Hpa I, Sal I, Sma I, Ssp I, Pst I, Xba I, and Xho I. They could be divided into three genomic clusters. Cluster 1 contained Ad 4p and Ad 4p 1-3; cluster 2 contained Ad 4a, ad 4a 1 and Ad 4b; whereas the chimpanzee Ad 4 genome type was the unique member of cluster 3. The degree of genetic variability within each cluster was minor. The genome types within one cluster display 95-99% pairwise comigrating restriction fragments (PCRF). However, the genetic space between the three clusters was large. The genome types between different clusters share only 25-46% PCRF. A comparative PCRF analysis performed with restriction endonucleases Apa I, Nar I, Nae I, Sac II, and Sma I recognizing exclusively G and C sequences and Dra I, Ssp I recognizing exclusively A and T containing sequences revealed that G and C rich regions were significantly more conserved than A and T rich regions.

Purification of adenovirus hexon by high performance liquid chromatography

Hexon is the major structural protein of adenovirus, and has significance in studies of virus structure and function, vaccine development, and immunodiagnosis. We describe a simple, single-step, anion-exchange high performance liquid chromatography (HPLC) method for the high yield purification of hexon. Purity of the isolated hexon was assessed by SDS-PAGE and HPLC methods. The isolated hexon was immunologically reactive with anti-hexon monoclonal antibody in a dot-blot assay. It also retained immunogenicity, as polyclonal antisera from rabbits immunized with hexon showed the desired antigen specificity. The enhanced speed of this purification method allows for the efficient isolation of hexon from various serotypes, and thus may facilitate comparative studies of hexon immunobiology.

Preparation and characterization of monoclonal antibodies to enteric adenovirus types 40 and 41

We have prepared monoclonal antibodies to each of the enteric adenoviruses types 40 and 41. Three different hybridoma cell lines were selected which produced antibody found to react by radioimmunoprecipitation with adenovirus (Ad) hexon antigens. One was specific for Ad 40, another for Ad 41, and a third one reacted with both types. When tested in an enzyme immunoassay against all 41 known human Ad types, the type-specific monoclonal antibody against Ad 40 reacted homotypically, as did the monoclonal antibody against Ad 41. In addition, these monoclonal antibodies neutralized the homologous enteric Ad type. The monoclonal antibody which reacted with both enteric Ad types also showed lower levels of reactivity with the group C adenoviruses types 2, 5, and 6. The monoclonal antibodies produced will provide a definitive means for rapid identification of specific Ad types, and will be useful in defining the relationship of enteric adenoviruses to other types.

Determination of different antigenic sites on the adenovirus hexon using monoclonal antibodies

Eighteen mouse ascitic fluids containing monoclonal antibodies (MAbs) directed against crystallized hexon of adenovirus (AV) type 1 were used to map the antigenic structure of the capsomer in reciprocal competitive binding ELISA. With the help of peroxidase-labelled MAbs at least nine epitopes (epitope clusters) located on three distinct antigenic sites were identified on the hexon. Epitope on antigenic site I recognized by two MAbs could be the genus specific antigenic determinant based on the broad reactivity patterns of the MAbs. Epitopes on the antigenic site II recognized by fifteen MAbs could be divided into seven epitope clusters according to the competition patterns. Antigenic site III recognized by one MAb completely differs from the antigenic site I and on the basis of one-way blocking with all the MAbs specific for antigenic site II, should be also different from the latter one. The data suggest that the seven epitope clusters of antigenic site II contain partially overlapping epitopes and may be a part of a large single immunodominant antigenic region on AV 1 hexon as well as on hexons of heterologous types.

Grouping of monoclonal antibodies to adenovirus hexons by their cross-reactivity

Thirty two mouse ascitic fluids containing monoclonal antibodies (MAbs) directed against the hexon of human adenovirus type 1 were examined. The type and degree of cross-reactivity (CR) of the MAbs were determined by ELISA and hemagglutination methods with 10 heterologous hexon types. The similarity and the dissimilarity of the MAbs was also characterized by the correlation coefficient calculated from their reactivity values. On the basis of these, the 32 MAbs could be divided into five groups and fourteen individual MAbs, which altogether recognized 19 distinct epitopes. One of the recognized epitopes is the genus specific epitope of adenovirus hexons; the others are interspecies specific ones which can be found on the surface of the different hexon types in characteristic, mosaic-like combinations. The type and degree of CR of the MAbs lead to the conclusion that there exists a close antigenic relationship among the members of subgenus C of human adenoviruses and there is also a definite antigenic relationship between subgenera C and D. Hexons belonging to the oncogenic subgenera A and B display a much looser antigenic relationship with subgenus C.

Comparison of neutralization and DNA restriction enzyme methods for typing clinical isolates of human adenovirus

Sixty-five adenovirus isolates collected over a 3.5-year period were typed by both standard microneutralization techniques and restriction endonuclease digestion of viral DNA. Of the 65 isolates, 47 (72.3%) representing six adenovirus types could be typed by microneutralization. Eighteen isolates demonstrated partial neutralization with standard antisera to two or more adenovirus serotypes and thus could not be definitively typed. DNA analysis permitted typing of 64 of the 65 isolates (98.5%) (including four isolates which contained mixtures of two adenovirus types), and 12 different types were identified. Neutralization and DNA typing disagreed for five isolates, and in each case, digestion with multiple restriction endonucleases and DNA hybridization studies were consistent with the type assigned by DNA analysis. In addition, the DNA analysis method allowed the identification of genomic variants (genome types) of five adenovirus types. We conclude that typing clinical isolates of adenovirus by restriction endonuclease digestion of viral DNA can be done rapidly, provides additional epidemiological and typing information, and provides fewer ambiguous results than does typing by neutralization.

Importance of enteric adenoviruses 40 and 41 in acute gastroenteritis in infants and young children

In a prospective 1-year study of acute infantile gastroenteritis, adenoviruses were detected in the stools or by seroconversions, or both, in 56 of 416 (13.5%) ill children. By use of DNA restriction enzyme analysis, enzyme immunoassay, and culture techniques, 33 of 56 (59%) adenovirus specimens were identified as enteric adenoviruses 40 and 41 (Ad40 and Ad41). They were found as the sole recognizable cause of diarrhea in 30 of 416 (7.2%) ill children and in 0 of 200 controls. Three additional ill children had enteric adenoviruses as a part of a dual infection. Evidence for established adenoviruses (Ad1 through Ad39) in gastroenteritis was found in 15 of 416 (3.6%) ill children but also in 3 of 200 (1.5%) controls. Eight adenovirus specimens remained untyped. Seroconversions were demonstrated in 17 of 18 (94%) paired serum samples from patients shedding enteric adenoviruses. The predominant symptom of infections with enteric adenoviruses was diarrhea, with a mean duration of 8.6 days (Ad40) and 12.2 days (Ad41). One-third of the children with Ad41 infections had prolonged symptoms (greater than or equal to 14 days). The frequency of respiratory symptoms was low (21%). The established adenoviruses presented a different clinical picture, characterized by diarrhea of shorter duration, higher fever, and significantly increased occurrence of respiratory symptoms (79%). In conclusion, enteric adenoviruses appear to be an important cause of acute infantile gastroenteritis, second only to rotaviruses in this study.

Analysis of Ad5 hexon and 100K ts mutants using conformation-specific monoclonal antibodies

Adenovirus type 5 ts mutants deficient in hexon metabolism were investigated using conformation-specific monoclonal antibodies directed against hexon capsomeres and the viral 100K protein. The ts mutants map either in the hexon structural gene or in the gene encoding the 100K protein, a major, late nonstructural protein. All of the mutants examined (ts1, ts2, ts3, ts4, ts17, and ts20 of J. F. Williams, M. Gharpure, S. Ustacelebi, and S. McDonald (1971). J. Gen. Virol. 11, 95-101) were unable to produce the capsomeric form of hexon (a trimer of three hexon monomers) at the nonpermissive temperature. However, all of the mutants retained the ability to produce a complex of 100K and hexon which has been demonstrated to play a major role in the assembly of hexon trimers. The mutants accumulated nontrimerized hexon in this ts complex in the perinuclear region of the cell. Several of the mutants (ts1, ts2, ts3) were found to successfully assemble hexon synthesized at the nonpermissive temperature upon shift down to the permissive temperature, even in the presence of a protein synthesis inhibitor. The mutant, ts2, which maps in the hexon structural gene, was found to be dependent on protein synthesis for transport of hexon trimers into the nucleus during temperature shift down, while the 100K ts mutants, ts1 and ts3, were independent of protein synthesis for both hexon assembly and transport.

Restriction mapping and molecular cloning of adenovirus type 4 (subgroup E) DNA

The locations of thirty restriction endonuclease cleavage sites were determined on the genome of adenovirus type 4 (Ad4), the sole member of the subgroup E adenovirions. The restriction endonucleases Bg/II, EcoRI, HindIII, HpaI, KpnI, SalI, and XbaI cut Ad4 DNA 10, 3, 2, 3, 5, 5 and 3 times, respectively. Orientation of the linear Ad4 map with respect to left and right molecular ends was accomplished by taking advantage of the limited sequence homology between Ad2 and Ad4. Ten non-overlapping fragments of Ad4 DNA representing 98% of the genome, map units 1.6 to 99.6, have been cloned into the plasmid vector pKC7.

Solid-phase immune electron microscopy (SPIEM) by use of protein A and its application for characterization of selected adenovirus serotypes

Staphylococcal protein A was used for the anchoring of specific antibodies for a solid-phase immune electron microscope method (SPIEM). More IgG adsorbed to grids in the absence of protein A than in its presence. However, the virus trapping efficiency was markedly improved in the presence of protein A. The specificity of the test was evaluated by use of different adenovirus preparations and matching rabbit hyperimmune sera. The degree of serological reaction was evaluated by counting the number of particles attached to the grid. Type specific reactions and inter- and intrasubgroup reactions were identified.

Hind III restriction site map of the human adenovirus type 1 DNA

The physical map of human adenovirus type 1 DNA was constructed with the Hind III restriction enzyme. Direct comparison of the DNA fragments with those of adenovirus type 2 revealed that the genome of adenovirus type 1 is 200 to 300 base pairs longer. The difference are located outside the region of the inverted terminal repetition within three distinct loci. Fragment Hind III-F of type 1 DNA which is presumed to carry all the genes responsible for in vitro transformation can be separated without considerable contamination by a single electrophoretic step.

Comparative sequence analysis of the inverted terminal repetitions from different adenoviruses

The comparative nucleotide sequences of the region of inverted terminal repetition from a representative member of group C (nononcogenic), group B (weakly oncogenic), and group A (highly oncogenic) adenoviruses are analyzed. Our data show that (i) the length of this unique region increases with the oncogenicity of the serotype, (ii) a unique homologous region--14 nucleotides long--is present exactly at the same distance from the terminus, and (iii) a hexanucleotide sequence, T-G-A-C-G-T, is present at the site where the terminal repetition diverges.

Identification of an enteric adenovirus by immunoelectroosmophoresis (IEOP) technique

Infantile gastroenteritis can be caused by several of the established adenovirus types. There are also adenoviruses that defy in vitro cultivation but have been recognized by electron microscopy. One isolate of these viruses, which have been designated enteric adenoviruses, has been characterized. Several of the established adenovirus types are shed in stools over long periods. The conditions for direct identification of enteric adenoviruses by immunoelectroosmophoresis (IEOP) have therefore been evaluated. Application of this technique requires highly specific reagents. However, a high prevalence of antibodies in rabbits reacting with human rotavirus was noted. For these reasons, immunoadsorbent purified antibodies were prepared. Because of the difficulty in purifying immunogens from stools, an immunization procedure characterized by immunization with adenovirus subunits bound to affinity chromatography beads was elaborated. An identification procedure for adenoviruses causing infantile gastroenteritis based a) on IEOP using group-specific and monospecific antibodies and b) on the determination of the in vitro cultivatability is suggested.

Immunological basis of the adenovirus 8-9 cross-reaction

The dedecon and hexon components of adenovirus types 8 and 9 have been extensively purified for use in establishing the basis of the cross-reaction between these types. Dodecons, the complete hemagglutinins, were purified 304- to 362-fold by fluorocarbon extraction, calcium phosphate batch chromatography, and ion-exchange column chromatography. Hexons, the group complement-fixation (CF) antigens, were purified 230- to 240-fold by erythrocyte adsorption, ion-exchange chromatography, and exclusion chromatography. Component antisera prepared in rabbits were tested in reciprocal fashion with crude virus and dodecon and hexon components. By hemagglutination-inhibition (HI), the dodecons of types 8 and 9 demonstrated the same predominantly one-sided relationship characteristic of the crude antigens. Some neutralizing activity was associated with both dodecons and hexons of each type. However, combining anti-dodecon and anti-hexon sera or producing antisera against the combined dodecon-hexon components resulted in neutralizing titers which were identical to titers obtained with antisera against the crude virus harvests. Dedecons of each type appear to share at least one antigenic determinant with hexons of the same type, and this determinant may reside on the vertex capsomere. Hexons possess group- and type-specific determinants, as shown by CF, neutralization, and immunodiffusion tests, and may exhibit some minor relationship between types 8 and 9. The results with the purified components are consistent with the predominantly one-sided antigenic relationship between types 8 and 9 in the conventional HI tests and the largely type-specific relationship by neutralization tests.

Immunological and other biological characteristics of pentons of human adenoviruses

Comparative hemagglutination-enhancement (HE) tests demonstrated diversified patterns of antigenic specificities both in the fiber and vertex capsomer part of pentons of human adenovirus types 3, 11 (subgroup I), 9, 15 (II), 1, 2, 4, 5, 6 (III), and 12. All fibers contained a type-specific antigen. Subgroup II and III fibers, in addition, contained specificities both unique for each subgroup and also common to the two subgroups. Fibers of serotypes 4 and 12 displayed a somewhat deviating behavior. All vertex capsomers tested shared a group-specific part. This was the only antigenic specificity demonstrable for serotype 12. Maximal penton HE titers of all sera were reached in tests with incomplete hemagglutinin of type 11. In addition, maximal HE activity of sera against individual serotypes also was recorded against pentons of other members of the same subgroup. Antigen characteristics of vertex capsomers of type 4 indicated a closer relationship to subgroup I than to subgroup III. The toxin activity of pentons was more sensitive to trypsin treatment than their capacity to function as incomplete hemagglutinin. Homotypic antipenton sera, unabsorbed or absorbed with homotypic fibers to remove antibodies against this component, and, to a varying extent, also heterotypic antipenton sera could neutralize toxin activity. Antifiber sera could neutralize toxin activity of pentons carrying short fibers (10 nm, type 3) but not of those carrying long fibers (28 to 31 nm, type 2). It is concluded that toxin activity is carried by a specific part of vertex capsomers and that cell detachment can be brought about via a direct contact between this component and cell membranes. Fiber-mediated attachment does not seem to be necessary for this biological activity to become expressed.

Capsid mosaics of intermediate strains of human adenoviruses

Antisera against isolated capsid components of intermediate adenovirus strains, types 3-16 (the San Carlos agent) and 15-9 and of "parental" prototype strains were compared in neutralization tests, hemagglutination-inhibition (HI) tests employing soluble and virion-associated hemagglutinin as antigens, and by electron microscopy. Hexons of the intermediate strains were found to be similar to, but not identical to, those of the prototype strains with which a cross-reaction occurred in neutralization tests (types 3 and 15). In contrast, fibers of intermediate strains displayed characteristics relating them to the corresponding components of prototype strains to which a relationship has been found in HI tests. Fibers (and possibly even pentons) of types 9 and 15-9 appeared to be identical, whereas fibers of types 3-16 and 16 displayed antigen specificities of both common and unique nature.