Cell transformation by the left terminal regions of the adenovirus 40 and 41 genomes

Enteric adenoviruses

The 41 serotypes of human adenoviruses are classified into six subgenera (A-F) with different tropisms. Enteric infections are caused in children by serotypes Ad40 and Ad41 of subgenus F. Serotypes Ad40 and Ad41 transform embryonic cells but cannot induce tumours in newborn hamsters. They differ from all other (established) human adenoviruses by being unable to replicate in conventional cell cultures. Ad40 and Ad41 grow in 293 cells (human embryonic kidney cells immortalized by transfection with the E1A, E1B regions of Ad5). In spite of the difficulty of isolating Ad40 and Ad41 they can be directly identified in stools by enzyme-linked immunosorbent assay (ELISA) and solid-phase immuno-electron microscopy. The amount of viral DNA in stool preparations is sufficient for identification by DNA restriction or dot-blot analysis. Adenoviruses have been associated with 7-17% of cases of diarrhoea in children. Ad40 and Ad41 cause diarrhoea throughout the year. Clinical features are watery stools, vomiting and moderately elevated temperature; respiratory symptoms are infrequent. The diarrhoea is protracted (mean 8.6 and 12.2 days for Ad40 and Ad41 respectively). Children with rotavirus diarrhoea vomited more frequently and had a higher temperature and diarrhoea of shorter duration. The impact of enteric adenoviruses in the aetiology of diarrhoea world-wide is not known but is accessible to investigation.

Enteric adenovirus type 41 isolates: cloning, physical maps and diversity in restriction enzyme cleavage pattern

Adenovirus (Ad) type 40 and 41 DNAs were directly extracted from stool specimens of children with gastroenteritis. Two new strains of Ad41, Sanekata and Ehime strain, were cloned and their restriction maps were constructed. The left terminal end of the cloned Ad41 genome, EcoRI-E fragment of the Sanekata strain and EcoRI-F fragment of the Ehime strain, had transforming ability in rat 3Y1 cells. Only one of the 35 isolates of Ad40 tested showed a different restriction profile, while three different restriction profiles were found in DNAs from Ad41 isolates.

The E1B transcription map of the enteric adenovirus type 41

Enteric adenovirus type 41 (Ad41) is defective for growth in conventional established cell lines. Ad41 is dependent on the Ad5 early regions E1A/E1B since it cannot grow in HEK cells but only in 293 HEK cells transformed by Ad5 E1 region. However, Hep-2 cells have also been shown to support the growth of Ad41 to some extent. The nucleotide sequence of the E1B region of the Ad41 strain D389 has been determined. When compared to the corresponding region of the Ad41 prototype strain (Tak) the degree of homology in the DNA sequences was close to 100%. The mRNAs from the E1B region of the Ad41 strain D389 have been studied by Northern blot, primer extension, and polymerase chain reaction-cDNA analysis. E1B transcripts corresponding to Ad2 14 S, 22 S, and 9 S mRNAs were identified but no 13 S mRNA equivalent was detected, a pattern similar to that seen in the Ad40 and Ad12 transcription maps. However, the Ad41 E1B 14S mRNA equivalent has one additional small exon of 23 nucleotides, created by a donor and an acceptor splice site located at positions not seen in other E1B transcripts of human adenoviruses analyzed so far. The coding potential for E1B 19K, 55K, and 15K proteins and for pIX is retained in the Ad41 transcripts. In contrast to other adenoviruses, except for the closely related Ad40, the ORF of pIX starts in the intron of the 22 S mRNA.

Enteric adenovirus type 40:E1B transcription map and identification of novel E1A-E1B cotranscripts in lytically infected cells

Adenovirus 40 (Ad40) is defective for growth in tissue culture but is complemented when the Ad2/5 or Ad12 E1B 55K protein is supplied in trans. Ad40 E1B mRNA has not been detected in E1-transformed cells, or at early times in lytically infected cells. In cells constitutively expressing the E1B region of Ad2, Ad40 E1B mRNAs are detected at late times in infection, after the onset of DNA replication. We have determined the Ad40 E1B transcription map from RNA produced at late times in infected KB16 cells, using S1 nuclease, primer extension, PCR-cDNA analysis, and Northern blotting. E1B transcripts corresponding to Ad2 14 S, 22 S, and 9 S mRNAs were identified but no 13 S mRNA equivalent was detected, a pattern similar to that seen in the Ad12 transcription map. The coding potential for E1B 19K, 55K, and 15K proteins and for ppIX is retained in the Ad40 transcripts. In addition we find novel E1A-E1B cotranscript counterparts of the 14 S and 22 S mRNAs. These contain the first 40 codons of the E1A first exon linked to a site 4-5 nt downstream of the E1B cap site, retaining all the coding potential of the E1B mRNAs. No new open reading frames are created by the junction, and the E1A ORF terminates with one codon added after the junction. Each E1A-E1B cotranscript is present in abundance comparable to that of its authentic E1B counterpart. The E1A-E1B junction is unusual in that it does not conform to splice consensus sequences and thus may not be generated by a conventional splicing mechanism.

Cellular transformation by E1 genes of enteric adenoviruses

The ability of Ad40 and Ad41 E1A plus E1B genes to transform BRK cells was considerably lower than that of Ad5 and Ad12 corresponding genes. However, as for Ad5, the E1A genes of enteric adenoviruses could cooperate with an activated ras oncogene for full cell transformation and the Ad41 E1B could be complemented by E1A gene of Ad5 or Ad12 for cell transformation. Complementation studies suggested that the conserved region 1 of Ad41 E1A was responsible for this inefficient transformation. The Ad40- and Ad41-transformed cell lines exhibited a low level of major histocompatibility complex (MHC) class I antigens correlated to the low level of Ad12-transformed cells. Class I MHC antigen amounts expressed at the surface of the cells transformed by the weakly oncogenic Ad3 were between the high level of Ad5- and the low level of Ad12-transformed cells.

Enteric adenovirus type 40: expression of E1B mRNA and proteins in permissive and nonpermissive cells

The enteric adenovirus type 40 (strain Dugan) grows well in tissue culture only when the E1B 55K protein of Ad5 or Ad12 is supplied in trans, either constitutively expressed in an established cell line or by coinfection with an appropriate helper virus (V. Mautner, N. Mackay, and V. Steinthorsdottir, 1989, Virology 171, 619-622). The synthesis of Ad40 E1B mRNAs and proteins has been examined under permissive and nonpermissive conditions: At late times postinfection in permissive cells, E1B-specific mRNA species of 22 and 13-14 S are made, as well as 15 and 9 S messages for the late IVa2 and ppIX proteins. None of these are detected before the onset of DNA replication and none of them accumulate in the presence of a cytosine arabinoside block to DNA replication. The failure to detect cytoplasmic mRNAs as early times cannot be attributed to a failure of mRNA transport from the nucleus as there is no accumulation of nuclear E1 RNA. In nonpermissive Hela cells only traces of E1B- and ppIX-specific mRNAs are detectable, at very late times postinfection. Antibodies raised to synthetic oligopeptides corresponding to the N- and C-terminal domains of the putative E1B 19K and 55K proteins show a high titer against the cognate peptide by ELISA, but only the E1B 19K C-terminus-specific sera have detected a unique polypeptide in Ad40-infected cells, at late times postinfection. There is no shut-off of host protein synthesis in permissive cells, despite the expression of Ad2 55K protein.

Enteric adenovirus 41 (Tak) requires low serum for growth in human primary cells

It had been postulated that due to lack of growth of enteric adenovirus 41 (Ad41) on human primary cells and its growth on Graham-293 cells there was a defect in the Ad41 E1A region. However, we found as a result of careful evaluation of Ad41 growth on several primary cell lines (HEK, WI-38, or Detroit 551) that efficient viral multiplication is possible if the serum concentration in the medium used postinfection (p.i.) is kept between 0.2 and 1%. In contrast, only slight growth of Ad41 occurs in infected cells maintained in 5% serum and virtually no viral replication is found in infected cells cultivated in medium with 10% serum. The serum inhibitory effect appears limited to primary cells because no difference in Ad41 replication, as assayed by accumulation of Ad41 DNA, was found in infected continuous cell lines (HEp-2, 293) cultivated p.i. in either 1 or 10% FBS. Also, this effect appears specific for enteric adenoviruses, such as Ad41, since conventional adenoviruses, such as Ad5, grow well in both 1 and 10% FBS. The above results show that Ad41 can grow in a variety of primary cell lines, under specific culture conditions. In addition, we found that Ad41-infected primary cells grown in medium containing 0.2% serum had an increase in synthesis of the 70-kDa heat shock protein (HSP70) at about 6 hr p.i. and also Ad41 was able to complement the Ad5 E1A deletion mutant dl312. These results show that the E1A function of Ad41 is not impaired in infected cells.

Enteric adenoviruses

Human adenoviruses are classified into 47 serotypes and six subgenera (A-F) with different tropisms. In recent years adenovirus type 40 (Ad40) and 41 (Ad41) of subgenus F have been shown to be causative agents in enteric infections, which is second in importance only to rotaviruses as a cause of infantile gastroenteritis. Infection with EAds occurs worldwide and has been associated with 4-17% of cases of diarrhoea in children. AD40 and Ad41 primarily affect young children less than 2 years of age and occur throughout the year. The clinical characteristics include watery diarrhoea accompanied by vomiting, low grade fever and mild dehydration. A distinct feature of EAds infection is the protracted diarrhoea (mean 8.6 and 12.2 days for Ad40 and Ad41, respectively). Respiratory symptoms are infrequent. Serotypes Ad40 and Ad41 differ from all other (established) adenoviruses by being unable to replicate in conventional cell cultures. These fastidious viruses only grow in selected cell lines, 293 cells being the most commonly used. In spite of the difficulty of isolating Ad40 and Ad41, they can be directly identified and typed by ELISA and solid-phase immune electron microscopy. The amount of viral DNA in stool specimens is sufficient for identification by DNA restriction and dot-blot assays. The recent development of highly sensitive and specific monoclonal antibody-based ELISAs enable accurate diagnosis of adenovirus gastroenteritis in routine work and make possible the evaluation of the role of the enteric adenoviruses in diarrhoeal disease in the developing countries.

Complementation of enteric adenovirus type 40 for lytic growth in tissue culture by E1B 55K function of adenovirus types 5 and 12

The enteric adenovirus type 40 strain Dugan (Ad40) cannot be passaged in HeLa cells, but will grow in 293 cells, which express Ad5 E1 functions. To determine the reason for this limited host range, KB cell lines expressing Ad2 E1A, E1B, or E1A + E1B (L. E. Babiss, C. S. H. Young, P. B. Fisher, and H. S. Ginsberg, 1983, J. Virol. 46, 454-465) have been tested for their ability to support Ad40 replication. Only cell lines which supply E1B functions, but not those expressing E1A alone, are permissive for Ad40, suggesting that Ad40 may require some function supplied by E1B or induced in E1B-containing cells. In coinfection assays Ad40 complements Ad5 dl312 (delta E1A) but not Ad5 dl313 (delta E1B) and is itself complemented by dl312 but not by dl313. Mutants of Ad2 and Ad12 with lesions in E1B 55K or 19K protein have been used to further delineate the requirements for Ad40 growth in HeLa cells. For mutants lacking 55K function there is minimal complementation in either direction, whereas those lacking only the 19K product are able to complement Ad40.

Human viral gastroenteritis

During the last 15 years, several different groups of fastidious viruses that are responsible for a large proportion of acute viral gastroenteritis cases have been discovered by the electron microscopic examination of stool specimens. This disease is one of the most prevalent and serious clinical syndromes seen around the world, especially in children. Rotaviruses, in the family Reoviridae, and fastidious fecal adenoviruses account for much of the viral gastroenteritis in infants and young children, whereas the small caliciviruses and unclassified astroviruses, and possibly enteric coronaviruses, are responsible for significantly fewer cases overall. In addition to electron microscopy, enzyme immunoassays and other rapid antigen detection systems have been developed to detect rotaviruses and fastidious fecal adenoviruses in the stool specimens of both nonhospitalized patients and those hospitalized for dehydration and electrolyte imbalance. Experimental rotavirus vaccines have also been developed, due to the prevalence and seriousness of rotavirus infection. The small, unclassified Norwalk virus and morphologically similar viruses are responsible for large and small outbreaks of acute gastroenteritis in older children, adolescents, and adults. Hospitalization of older patients infected with these viruses is usually not required, and their laboratory diagnoses have been limited primarily to research laboratories.

Interaction between the octamer-binding protein nuclear factor III and the adenovirus origin of DNA replication

Nuclear factor III (NFIII) is a HeLa sequence-specific DNA-binding protein that stimulates initiation of adenovirus DNA replication in vitro and may be involved in regulation of transcription of several cellular and viral genes. We have studied the interaction between NFIII and the binding site in the adenovirus type 2 (Ad2) origin in detail by methidiumpropyl-EDTA.iron(II) and hydroxyl radical footprinting and by alkylation interference experiments. Our results indicate that (i) the core of the recognition sequence is 5'-TATGATAAT-3'; (ii) both major and minor groove base contacts are detected, and all base pairs in the core are involved in binding; (iii) many backbone contacts are observed divided into a large domain coinciding with the core and a small domain; (iv) contact points are not confined to one side of the DNA helix in contrast to the nuclear factor I (NFI)-binding site; (v) the binding site overlaps the NFI-binding site for at least one nucleotide. A number of Ad2 mutants as well as related binding sites in the origins of other adenovirus serotypes were systematically compared for binding with NFIII. The results are in good agreement with the contact point studies and show that at least one AT base pair is commonly required by NFI and NFIII for optimal binding. The strongest binding site, which contains the octamer/decanucleotide motif (ATGCAAAT[NA]), was found in the Ad4 origin, which lacks an NFI-binding site. Stimulation of in vitro DNA replication of Ad2, Ad4, and Ad12 by NFIII showed that the maximal level of stimulation is dependent on the affinity of NFIII for the origin.

Characterization of adenovirus type 40 E1 region

The left-most 3.9 kb of adenovirus type 40 (Ad40) DNA has been sequenced using cloned viral DNA fragments. The Ad40 E1 region is deduced to code for at least four polypeptides, 221 and 249 amino acids as E1A products in addition to 166 and 475 amino acids as E1B products. E1B polypeptides share about 50% homology with well-defined adenovirus types, 2/5, 7, and 12, throughout the E1B sequences. E1A homology of Ad40 to these types is relatively lower than that of E1B, while highly conserved regions of E1A are retained to a certain level in Ad40 as well. Activity for morphological transformation of Ad40 E1A on 3Y1 cells is considerably lower when compared to that of Ad5 and Ad12 E1A genes. Transient chloramphenicol acetyltransferase (CAT) expression assay shows that Ad40 E1A has a trans-acting function, though lower than that of other E1A genes, on adenovirus early promoter. The Ad40 E1A promoter also holds only a little cis-acting activity in 3Y1 cells. Lower activities of both Ad40 E1A promoter and certain E1A functions may explain in part the difficulty in propagation of Ad40.

Transcriptional activation by the E1A regions of adenovirus types 40 and 41

In order to establish whether the poor growth of the two fastidious adenoviruses types 40 and 41 (Ad40 and Ad41) in HeLa cells is due to a reduced trans-activation by the early region 1A (E1A), we have determined the trans-activating effect of this region on the expression of the chloramphenicol acetyltransferase (CAT) gene controlled by the Ad2 E4 promoter. Cotransfection of HeLa cells with plasmids containing the E1A regions of Ad5, Ad40, and Ad41, respectively, and the CAT gene controlled by the Ad2 E4 promoter showed that activation of the E4 promoter by the E1A regions of Ad40 and Ad41 depends on the same sequence elements of the E4 promoter as activation by the Ad5 E1A gene products. The level of activation, however, is significantly lower. This might partly explain the reduced growth in HeLa cells of the two viruses.

Structure and organization of the left-terminal DNA regions of fastidious adenovirus types 40 and 41

To determine whether differences in structure and organization of the transforming regions of Ad40 and Ad41 could explain the fastidious growth of these viruses, we have sequenced these regions and analyzed the structure of the corresponding mRNAs. These regions are 85% homologous to each other and exhibit 52% of homology to the analogous Ad5 region. Like the other adenoviruses, the Ad40 and Ad41 transforming regions contain two transcriptional units, E1a and E1b. Differences and similarities in the strategic sequences of these transcription units and Ad5 regulatory elements are discussed. Northern blotting and S1-nuclease analysis of RNA isolated from transformed cells reveal that in Ad40-transformed cells region E1a is transcribed into three partially overlapping mRNAs, while no transcription of region E1b can be detected. In Ad41-transformed cells only one E1a mRNA is found, comparable to the larger Ad40 E1a mRNA. In the Ad41 E1b region a single mRNA species is synthesized, which is comparable to the E1b messenger found in cells transformed by other adenovirus serotypes. Comparison of the large proteins encoded by the Ad40 and Ad41 E1a regions with the corresponding Ad5 E1a protein shows a relatively low homology in three conserved regions. These results are discussed in relation to the transforming capacity and the fastidious growth of Ad40 and Ad41 in conventional cell lines.