SJL/J mice are highly susceptible to infection by mouse adenovirus type 1.

Mouse adenovirus type 1 (MAV-1) targets endothelial and monocyte/macrophage cells throughout the mouse. Depending on the strain of mouse and dose or strain of virus, infected mice may survive, become persistently infected, or die. We surveyed inbred mouse strains and found that for the majority tested the 50% lethal doses (LD(50)s) were >10(4.4) PFU. However, SJL/J mice were highly susceptible to MAV-1, with a mean LD(50) of 10(-0.32) PFU. Infected C3H/HeJ (resistant) and SJL/J (susceptible) mice showed only modest differences in histopathology. Susceptible mice had significantly higher viral loads in the brain and spleen at 8 days postinfection than resistant mice. Infection of primary macrophages or mouse embryo fibroblasts from SJL/J and C3H/HeJ mice gave equivalent yields of virus, suggesting that a receptor difference between strains is not responsible for the susceptibility difference. When C3H/HeJ mice were subjected to sublethal doses of gamma irradiation, they became susceptible to MAV-1, with an LD(50) like that of SJL/J mice. Antiviral immunoglobulin G (IgG) levels were measured in susceptible and resistant mice infected by an early region 1A null mutant virus that is less virulent that wild-type virus. The antiviral IgG levels were high and similar in the two strains of mice. Taken together, these results suggest that immune response differences may in part account for differences in susceptibility to MAV-1 infection.

Mouse adenovirus type 1 replication in vitro is resistant to interferon.

The effects of mouse interferon (IFN)-alpha/beta and recombinant IFN-gamma on mouse adenovirus type 1 (MAV-1) replication were investigated in single-cycle infectious virus yield reduction assays on mouse L929 cells. Viral yields at 3 days postinfection indicated that wt MAV-1 and pmE314, an early region 3 null mutant, were relatively insensitive to both IFN-alpha/beta and IFN-gamma, whereas early region 1A (E1A) mutants pmE109 (null), dlE105 (conserved region 1 deletion, CR1 Delta), dlE102 (CR2 Delta), and dlE106 (CR3 Delta) were sensitive. MAV-1 E1A that was inducibly expressed in mouse fibroblast 37.1 cells rescued vesicular stomatitis virus from the antiviral effect of IFN-alpha/beta but not from the antiviral effect of IFN-gamma. Interferon-inducible gene expression was reduced in 37.1 cells as compared to the parental 3T6 cell line. Steady-state levels of IFN-inducible gene mRNAs were also reduced in 3T6 cells infected with the wild-type virus and pmE314 but not in cells infected with pmE109. These results suggest that the MAV-1 E1A gene product is capable of interfering with the signaling pathways of both types of IFN, although modulation of IFN-alpha/beta antiviral activity was more pronounced.

In vitro and in vivo characterization of a mouse adenovirus type 1 early region 3 null mutant.

Previous attempts to construct a mouse adenovirus type 1 early region 3 (E3) null mutant by initiator codon mutagenesis were unsuccessful because one of the E3 proteins, gp11K, is synthesized as a fusion protein from a late viral mRNA (A. N. Cauthen and K. R. Spindler, Virology 259:119-128, 1999). Therefore, a different mutagenesis strategy was employed that inserted termination codons into all three reading frames of the E3 proteins. This strategy produced a mutant, pmE314, that was null for the expression of E3 proteins as determined by immunoprecipitation with E3-specific antisera. This mutant grew as well as wild-type (wt) virus in both 3T6 mouse fibroblasts and mouse brain microvascular endothelial cells. However, the 50% lethal dose for pmE314 in adult NIH Swiss outbred mice was approximately 6 log units higher than that of wt virus, indicating that pmE314 was less virulent in mice. In situ hybridization experiments revealed that the absence of the E3 proteins did not alter the tropism of the mutant virus from that of wt virus. When the histopathology was evaluated, the characteristics of the pmE314 infection at both doses administered were strikingly different from those exhibited by wt virus. The central nervous system of wt-infected mice exhibited damage to the endothelium and recruitment of inflammatory cells, whereas the central nervous system of pmE314-infected mice showed no inflammatory response and only mild signs of endothelial damage.

Novel expression of mouse adenovirus type 1 early region 3 gp11K at late times after infection.

Mutations were introduced into mouse adenovirus type 1 (MAV-1) early region 3 (E3) initiator codons by homologous recombination between viral DNA and a plasmid containing a mutagenized E3 region. The resulting mutant virus, pmE312, contained ATG --> TTA mutations at codon positions 1 and 4 and was expected to be null for the expression of the E3 proteins. However, gp11K, an MAV-1 E3 glycoprotein of 14K molecular weight, was detected in mutant-infected cell lysates at levels about 10-12% of that of wild-type (wt) virus at late times in infection. The gp11K polypeptide produced by pmE312 at late times was immunoprecipitated with two E3-specific antisera prepared against different regions of the protein. Like gp11K produced by wt virus infections, it was sensitive to endoglycosidase H (endo H) and thus resident in the endoplasmic reticulum (ER). In pmE312-infected cells treated with cytosine arabinoside (araC), an inhibitor of DNA replication, the gp11K protein was not detected by immunoprecipitation. This indicates that gp11K expression in pmE312-infected cells at late times was dependent on DNA replication and that it was thus translated from a late transcript. In vitro translation of poly(A)+ RNA from mock-, wild-type-, and pmE312-infected cells showed that gp11K was translated from late mRNA as an approximately 28K fusion between a late protein and gp11K. Our data are consistent with a model in which gp11K is expressed at late times as a late protein-gp11K chimera in both wt- and mutant-infected cells. This chimera is then processed: removal of a large N-terminal sequence results in the observed 14K ER-localized gp11K.

Involvement of epitope mimicry in potentiation but not initiation of autoimmune disease.

We have examined whether the peptide (368-381) from the murine adenovirus type 1 E1B sequence, exhibiting a high degree of homology with the known pathogenic thyroglobulin (Tg) T cell epitope (2695-2706), can induce experimental autoimmune thyroiditis (EAT) in SJL/J mice. The viral peptide was a poor immunogen at the T or B cell level and did not elicit EAT either directly or by adoptive transfer assays. Surprisingly, however, the viral peptide was highly antigenic in vitro, activating a Tg2695-2706-specific T cell clone and reacting with serum IgG from mice primed with the Tg homologue. The viral peptide also induced strong recall responses in Tg2695-2706-primed lymph node cells, and subsequent adoptive transfer of these cells into naive mice led to development of highly significant EAT. These data demonstrate that nonimmunogenic viral peptides can act as agonists for preactivated autoreactive T cells and suggest that epitope mimicry may at times play a potentiating rather than a precipitating role in the pathogenesis of autoimmune disease.

Mouse adenovirus type 1 early region 1A is dispensable for growth in cultured fibroblasts.

Mouse adenovirus type 1 (MAV-1) mutants with deletions of conserved regions of early region 1A (E1A) or with point mutations that eliminate translation of E1A were used to determine the role of E1A in MAV-1 replication. MAV-1 E1A mutants expressing no E1A protein grew to titers comparable to wild-type MAV-1 titers on mouse fibroblasts (3T6 fibroblasts and fibroblasts derived from Rb+/+, Rb+/-, and Rb-/- transgenic embryos). To test the hypothesis that E1A could induce a quiescent cell to reenter the cell cycle, fibroblasts were serum starved to stop DNA replication and cellular replication and then infected with the E1A mutant and wild-type viruses. All grew to equivalent titers. Steady-state levels of MAV-1 early mRNAs (E1A, E1B, E2, E3, and E4) from 3T6 cells infected with wild-type or E1A mutant virus were examined by Northern analysis. Steady-state levels of mRNAs from the mutant-infected cells were comparable to or greater than the levels found in wild-type virus infections for most of the early regions and for two late genes. The E2 mRNA levels were slightly reduced in all mutant infections relative to wild-type infections. E1A mRNA was not detected from infections with the MAV-1 E1A null mutant, pmE109, or from infections with similar MAV-1 E1A null mutants, pmE112 and pmE113. The implications for the lack of a requirement of E1A in cell culture are discussed.

The role of mouse adenovirus type 1 early region 1A in acute and persistent infections in mice.

Mouse adenovirus type 1 (MAV-1) early region 1A (E1A) viral mutants were used to determine the importance of this region in pathogenesis and establishment of a persistent infection in the natural host. Lethal dose analysis with adult male Swiss outbred mice revealed a significant reduction in virulence for all of the E1A mutants. During acute infections with 10(5) PFU of virus, an E1A null mutant, pmE109, was found in the same organs (brain, spleen, and spinal cord) and the same cell types (endothelial cells and mononuclear cells in lymphoid tissue) as wild-type virus. Another null mutant, pmE112, was detected in the same organs but in lower numbers. However, when mice were given a lower dose, 1 PFU, pmE109 and pmE112 reached none of the target organs analyzed by 14 days postinfection (p.i.). The absence of E1A did not hinder the ability of MAV-1 to establish a persistent infection. Viral nucleic acid was detected by PCR amplification or in situ hybridization in the kidneys, brains, spleens, and prefemoral lymph nodes of mice infected with wild-type or mutant virus up to 55 weeks p.i. The brain, spleen, and lymph node are recognized sites of acute viral infection but are previously unrecognized sites for MAV-1 persistence. Evidence for the potential reactivation of persistent MAV-1 infections is also presented.

Distribution of mouse adenovirus type 1 in intraperitoneally and intranasally infected adult outbred mice.

In situ nucleic acid hybridization and immunohistochemistry were used to determine the histological localization of mouse adenovirus type 1 (MAV-1) during acute infection of adult mice infected either intraperitoneally or intranasally with 1,000 PFU of wild-type virus. Organ samples were collected from days 1 to 17 postinfection for the intraperitoneally infected mice and from days 1 to 13 for the intranasally infected mice. Endothelial cells of the brain and spinal cord showed extensive evidence of MAV-1 infection. Endothelial cells in lungs, kidneys, and other organs were also positive for MAV-1, indicating a widespread involvement of the systemic circulation. The presence of viral nucleic acid and/or antigen was also demonstrated in lymphoid tissue. The spleens, Peyer's patches, and peripheral lymph nodes showed positive staining at various times postinfection in mice infected by either route. Virus-infected cells in the spleen exhibited a stellate shape and were localized to the red pulp and germinal centers, suggesting that they are cells of the mononuclear phagocytic system.

Completion of the DNA sequence of mouse adenovirus type 1: sequence of E2B, L1, and L2 (18-51 map units).

The DNA sequence of 9991 nt, corresponding to 18-51 map units of mouse adenovirus type 1 (MAV-1), was determined, completing the sequence of the Larsen strain of MAV-1. The length of the complete MAV-1 genome is 30,946 nucleotides, consistent with previous experimental estimates. The 18-51 map unit region encodes early region 2B proteins necessary for adenoviral replication as well as late region L1 and L2 structural and packaging proteins. Sequence comparison in this region with human adenoviruses indicates broad similarities, including colinear preservation of all recognized open reading frames (ORFs), with highest amino acid identity occurring in the DNA polymerase and polypeptide III (penton base subunit) ORFs. Virus-associated (VA) RNA is not encoded in the region where VA RNAs are found in the human adenoviruses, between E2B and L1, nor is it encoded anywhere in the entire MAV-1 genome. The MAV-1 polypeptide III lacks the arginine-glycine-aspartic acid (RGD) motif which is involved in an association with cell-surface integrins. Only one RGD sequence is found in an identified coding region in the entire MAV-1 genome. Similar to the porcine adenovirus, this RGD sequence is found in the C-terminus of the MAV-1 fiber protein.

Interaction of mouse adenovirus type 1 early region 1A protein with cellular proteins pRb and p107.

We demonstrated functional associations between mouse adenovirus type 1 (MAV-1) early region 1A (E1A) protein and both the mouse retinoblastoma protein (pRb) and the mouse pRb-related protein, p107. Interactions between MAV-1 E1A and mouse pRb or mouse p107 proteins were examined in infected cell lysates using a mouse embryonic fibroblast cell line infected with wild-type and mutant MAV-1 viruses. Using a polyclonal antibody to MAV-1 E1A, exogenously added mouse pRb or mouse p107 was coimmunoprecipitated from wild-type, dIE105 (CR1 delta)-, and dIE106 (CR3 delta)-infected cell lysates. No coimmunoprecipitation was seen with cell lysates from dIE102 (CR2 delta) or pmE109, a mutant virus that produces no detectable E1A protein due to an ATG to TTG point mutation in the initiator methionine. Introduction of mouse pRb into SAOS-2 cells resulted in a flat and enlarged cell phenotype, whereas cotransfection of mouse pRb and MAV-1 E1A resulted in a significant reduction of flat cells, presumably due to E1A binding pRb. CR1 delta and CR2 delta E1A proteins were less effective at reducing the number of flat, enlarged cells induced by pRb expression than were the CR3 delta or wild-type E1A proteins. The reduced ability of these mutants to inactivate pRb relative to wild-type E1A correlated with their reduced ability to bind pRb in the in vitro coimmunoprecipitation experiments. As a measure of p107/MAV-1 E1A complex formation in MAV-1-infected cells, we used mobility shift assays to examine cell extracts for the presence of p107-containing E2F protein-DNA complexes. Mock-, dIE102-, and pmE109-infected cell extracts formed a p107-containing complex, whereas wild-type-infected cell extracts did not. Thus the formation of a p107-E2F complex in wild-type- or these mutant-infected extracts inversely correlated with the presence of E1A-p107 complexes identified in the vitro coimmunoprecipitation experiments. This is consistent with E1A-p107 complexes forming in wild-type MAV-1-infected cells.

Analysis of early region 3 mutants of mouse adenovirus type 1.

Early region 3 (E3) of mouse adenovirus type 1 has the potential to produce three proteins which have identical amino termini but unique carboxy-terminal sequences. Three recombinant deletion viruses were constructed so that each could produce only one of the three E3 proteins. A fourth mutant that should produce no E3 proteins was also constructed. These recombinants were able to grow in mouse 3T6 cells and produced wild-type levels of viral mRNAs and proteins except for those specifically deleted by the mutations. Early mRNA production from the mutant viruses was analyzed by reverse transcriptase PCR and confirmed that each deletion mutant would be able to produce only one of the three E3 proteins. Late mRNA production was analyzed by Northern (RNA) blotting and found to be similar in wild-type and mutant viruses. Capsid morphology was unaltered in the mutant viruses as seen by electron microscopy. Immunoprecipitation of E3 proteins from infections of mouse 3T6 cells using an antiserum specific for all three E3 proteins was used to examine the effect of the introduced mutations on protein expression. Two mutants produced only one class of E3 protein as predicted from their specific mutations and mRNA expression profiles. One mutant virus failed to produce any detectable E3 proteins. The predicted E3-null mutant was found to be leaky and could produce low levels of E3 proteins. Outbred Swiss mice were infected with the E3 mutant viruses to determine if the E3 proteins have an effect on the pathogenicity of the virus in mice. All of the mutants showed decreased pathogenicity as determined by increased 50% lethal doses, indicating that the proteins of the E3 region are important determinants of the pathogenesis of mouse adenovirus in its natural host.

Lack of effect of mouse adenovirus type 1 infection on cell surface expression of major histocompatibility complex class I antigens.

It has been proposed that adenoviruses establish and maintain persistent infections by reducing the class I major histocompatibility complex-associated presentation of viral antigens to cytotoxic T lymphocytes, leading to ineffective cell-mediated immunity and impaired clearance of infected cells (W.S.M. Wold and L. R. Gooding, Virology 184:1-8, 1991). Early region 3 of human adenovirus types 2 and 5 encodes a 19-kDa glycoprotein that associates with the class I major histocompatibility complex (MHC) antigens in the endoplasmic reticulum and prevents their maturation and transport to the cell surface. Early region 1A of human adenovirus type 12 encodes a protein that inhibits class I MHC mRNA production at the transcriptional or posttranscriptional processing level. Unlike human adenovirus infections, however, mouse adenovirus type 1 (MAV-1) infection of a variety of cell types did not affect the surface expression of 10 different mouse class I MHC allotypes. MAV-1-infected cells also regenerated cell surface class I MHC antigens following proteolytic removal as efficiently as mock-infected cells. The ability of cells to present antigen to class I MHC (Kb)-ovalbumin-specific T-cell hybridoma cells was likewise unaltered by MAV-1 infection. Thus, the ability of MAV-1 to persist cannot be explained by the model of reduced class I MHC-associated antigen presentation proposed for human adenoviruses.

Conservation of DNA sequence in the predicted major late promoter regions of selected mastadenoviruses.

The major late promoter (MLP) of the subgroup C human adenoviruses is a preeminent model for the study of the mechanisms of basal and activated transcription, both in vivo and in vitro. However, while the structure and function of the human virus MLP has been the subject of extensive investigation, the conservation of the various promoter elements among the adenoviruses from different species has not been examined. Conservation of specific elements would strongly suggest the importance and universality of their function. To address this issue, sequences were obtained from cloned DNAs of several representative Mastadenoviridae, mouse adenovirus type 1 (MAV-1), Tupaia adenovirus type 1 (TAV-1), and two bovine adenoviruses of two distinct subgroups, BAV-3 and BAV-7. The results of the sequencing studies showed that the TATA box and an upstream inverted CAAT box are conserved in all species and that the binding site for transcription factor USF is present in all except MAV-1, in which a sequence similar to an Sp1-binding site is present at a similar position. The initiator element (INR) sequence is not well conserved, and only one or other of the two downstream activating elements, DE1 and DE2, is predicted to be present in the nonprimate virus MLP regions. Ribonuclease protection assays on RNA isolated from MAV-1-infected cells late in infection indicated that the predicted MLP is functional, and transcription initiation and splice donor sites were identified. The human virus MLP is embedded in the essential DNA polymerase sequence on the opposite DNA strand. The primary amino acid sequences of the C-terminal regions of the predicted DNA polymerases show strong conservation of sequence motifs observed in replicative polymerases ranging from prokaryotes to mammals, and additional regions of strong conservation among the adenovirus polymerases. Pairwise comparisons between the newly sequenced regions of the polymerases and previously published sequences show that BAV-7 is most dissimilar to all others, while TAV-1 has a greater similarity to the primate sequences than to the others. The sequence data from both strands were also used to construct phylogenetic trees, based on BAV-7 as the outgroup. The trees constructed from the two sets of sequences are broadly similar, showing close relationships between primate viruses, but differing in the order of divergence of TAV-1 and MAV-1 branches.

Sequence of the mouse adenovirus type-1 DNA encoding the 100-kDa, 33-kDa and DNA-binding proteins.

The genomic nucleotide sequence for the region of 66 to 77 map units (m.u.) of mouse adenovirus type 1 (MAV-1) was determined and predicted to encode proteins homologous to the human adenovirus (Ad) 100-kDa, 33kDa and DNA-binding proteins (DBP). The putative MAV-1 100-kDa protein has 65-70% amino-acid similarity to 100-kDa proteins from five different human Ad serotypes. The mRNA for the putative 33-kDa protein is internally spliced within the coding sequence, as are its human Ad counterparts [Oosterom-Dragon and Anderson, J. Virol 45 (1983) 251-263]. The N-terminal region of the putative MAV-1 33-kDa protein has 41-44% similarity to two human Ad 33-kDa N-termini, and the C-terminal regions are more conserved, with 60-65% similarity. The MAV-1 DBP is predicted to be encoded in this region and was compared to six different human Ad DBP N-and C-termini. The N-termini of the MAV-1 and Ad DBP were 33-48% similar and the C-termini were 56-60% similar. The MAV-1 DBP contains conserved regions (CR) 1,2 and 3, and it retains important residues for a putative zinc finger (Zf) motif identified in Ad DBP [Eagle and Klessig, Virology 187 (1992) 777-787]. Additional sequence features of these proteins have also been identified.

Susceptibility and signs associated with mouse adenovirus type 1 infection of adult outbred Swiss mice.

Adult Swiss outbred mice from two sources had a nearly 6,000-fold difference in susceptibility to mouse adenovirus type 1-induced disease. This difference was not attributable to differential organ tropism. Signs associated with mouse adenovirus type 1 infection that have not been previously reported are described at the clinical, gross pathological, and histological levels.

Characterization of an 11K protein produced by early region 3 of mouse adenovirus type 1.

Early region 3 (E3) of mouse adenovirus type 1 produces three mRNAs that can encode three proteins with unique carboxy-terminal exons. A bacterial fusion protein encoding the unique terminus of one the three predicted proteins was used to generate antiserum in rabbits. This antiserum detected a 14K protein on a Western blot of infected cell lysates. Immunoprecipitation and endoglycosidase H digestion revealed that the 14K protein was a glycoprotein with a core molecular weight of 11K, and we are designating this protein E3 gp 11K. Through in vitro translation experiments we determined that the previously predicted signal sequence of gp11K was cleaved when the protein was expressed during an infection. Biochemical and immunofluorescence microscopy data indicated that E3 gp11K was localized to the endoplasmic reticulum of infected cells. Biochemical experiments further indicated that gp11K is a peripheral membrane protein.

Sequence of the mouse adenovirus serotype-1 DNA encoding the precursor to capsid protein VI.

The nucleotide sequence predicted to encode the precursor to virion structural protein VI (preVI) of mouse adenovirus (Ad) serotype-1 (MAV-1) was determined. The 237-amino-acid sequence has 45% identity and 66% similarity to the human Ad serotype-2 preVI sequence. There is a marked conservation at the C terminus, the last eleven residues of which may be necessary for activating the Ad endoproteinase, and at the N terminus, including the consensus endoproteinase cleavage site.

Transcription mapping of mouse adenovirus type 1 early region 4.

Early region 4 (E4) of mouse adenovirus type 1 was analyzed by Northern blotting, cDNA sequencing, and S1 nuclease protection and primer extension assays. The transcription map of this region was dissimilar to the consensus human adenovirus E4 transcription map in which all transcripts have identical 5' and 3'-terminal sequences. Seven classes of mouse adenovirus type 1 mRNAs were identified; all shared the same 3' end. Three classes of unspliced mRNAs differed at their 5' start sites, two classes of spliced transcripts differed in the locations of their splice acceptors, and two classes of spliced messages differed in their splice donors and acceptors. From the structure of the various transcripts, translational products were predicted. In addition to a predicted polypeptide with similarity to the human adenovirus 2 E4 34K protein previously identified (A. O. Ball, C. W. Beard, P. Villegas, and K. R. Spindler, 1991, Virology 180, 257-265), two open reading frames with similarity to human adenovirus 2 E4 open reading frames 2 and 3 were found.

Early region 4 sequence and biological comparison of two isolates of mouse adenovirus type 1.

The DNA sequence of 88-100 map units of mouse adenovirus type 1 (MAV-1) was determined. One translational open reading frame showed 48% sequence similarity to a human adenovirus type 2 early region 4 protein. Based on the protein similarity, genome location, and transcriptional polarity, we concluded that this region of MAV-1 corresponds to early region 4. A 241-bp sequence consisting of 10 imperfect direct repeats with sequence similarity to minisatellite DNA was found in this region. Two virus isolates with different passage histories were examined and were found to have a sequence polymorphism within this region. The two viruses were compared for growth in cell culture and mice and small quantitative differences were observed only in vivo.