Identification of mouse adenovirus type 1 early region 1: DNA sequence and a conserved transactivating function.

The left end of the genome of mouse adenovirus type 1 (also known as strain FL) was characterized by determination of the DNA sequence, amino acid similarities with early region proteins of primate adenoviruses, and a functional assay. Several specific DNA sequence features were similar to those found in human adenoviruses, and open reading frames from this region could encode proteins similar to human adenovirus early region 1A and early region 1B proteins. DNAs from this region were tested in transient-expression assays in human and mouse cells were found to transactivate the human adenovirus type 5 early region 3 promoter fused to the chloramphenicol acetyltransferase gene. The data indicate structural and functional homologies between mouse adenovirus type 1 early region 1 and early region 1 of primate adenoviruses.     

Mouse adenovirus type 1 attachment is not mediated by the coxsackie-adenovirus receptor

Common human adenovirus (Ad) vectors are derived from serotype 2 or 5, which use the coxsackie-adenovirus receptor (CAR) as their primary cell receptor. We investigated the receptor usage of mouse adenovirus type 1 (MAV-1), which in vivo is characterized by a pronounced endothelial cell tropism. Alignment of the fiber knob sequences of MAV-1 and those of CAR-using adenoviruses, revealed that amino acid residues, critical for interaction with CAR, are not conserved in the MAV-1 fiber knob. Attachment of MAV-1 to Chinese hamster ovary (CHO) cells was not increased by stable transfection with mouse CAR, whereas the binding efficiency of Ad2 was 20-fold higher in the mouse CAR-transfectant compared to the wild type cells. Also, purified fiber knob of Ad5, which is interchangeable with the Ad2 fiber knob, did not compete with MAV-1 for receptor binding, indicating that MAV-1 binds to a receptor different from CAR. These results support further exploration of an MAV-1-derived vector as a potential vehicle for gene delivery to cell types which are not efficiently transduced by human adenovirus vectors.     

Frequency of cell transformation by the small DNA tumor viruses: infection of proliferating cells and quiescent cells

Small DNA-containing tumor viruses (simian virus 40, mouse polyoma-virus, and adenoviruses) malignantly transform fibroblasts of the susceptible rodents. Fibroblasts can exist, in vitro and in vivo, in either of the two states: the proliferating state or the quiescent state. In the present study, we examined whether the state of fibroblasts at the time of exposure to these DNA viruses affects the frequency of transformation. Dense-focus formation in monolayer culture of rat 3Y1 fibroblasts was used to quantitate transformation. Results show that the frequency of transformation by simian virus 40 and mouse polyomavirus was reduced when cells were in the proliferating state at the time of virus inoculation as compared to cells in the quiescent state, whereas that by adenovirus type 12 was similar in the two cellular states. The reduction of the frequency of transformation in proliferating cells infected with simian virus 40 was also observed in BALB/c 3T3 mouse cells. Mechanisms underlying the difference between the two cellular states and the difference between the papovavirus and adenovirus in this aspect of transformation remain to be investigated.     

The mouse adenovirus type 1 contains an unusual E3 region.

Since the E3 region of human adenoviruses codes for a series of proteins that are probably involved in viral pathogenesis, the nucleotide sequence for a 3.6-kilobase DNA fragment in the corresponding region (map units 77 through 89) of the mouse adenovirus type 1 genome has been determined. Analysis of the sequence revealed that the genes for the fiber and for the precursor to the hexon-associated protein, pVIII, that usually flank the E3 region, are well conserved. However, many of the open reading frames contained in the E3 region of human adenoviruses between the pVIII and the fiber genes were absent from the mouse adenovirus type 1 genome.     

Bovine Adenovirus

Nine strains of an adenovirus serotype were recovered in bovine testicle cell cultures from Japanese cattle suffering with an acute febrile illness accompanied by rhinorrhea and diarrhea. The isolated virus was shown to have the physicochemical properties of the adenovirus group such as the nucleic acid type, the size and ultrastructure of the virion, and the resistance to ether and chloroform. The isolated virus produced eosinophilic intranuclear inclusion bodies characteristic of adenoviruses and the group specific antigen of adenovirus in bovine testicle cell culture. According to the results of cross-neutralization tests the isolated virus represents a serological type distinct from bovine adenovirus types 1, 2 and 3 and from the Nagano virus. The isolated virus agglutinated erythrocytes of cattle, sheep, goat, guinea pig, rat, hamster and mouse, but not those of vervet monkey, horse, goose and chicken. HI test using cattle erythrocytes corroborated the results of serological typing by neutralization tests.     

Productive replication of human adenoviruses in mouse epidermal cells

In contrast to most cells of mouse origin, cell lines derived from mouse epidermis are permissive for replication of human adenovirus type 5. The extent of epidermal cell differentiation correlated with the level of E1A expression and virus replication. Mouse epidermal cells may provide useful models for cancer therapy using replication-competent human adenoviruses.     

Phylogenetic analysis of Kineococcus aurantiacus based on 16S rRNA gene sequences

Abstract The DNA of mouse adenovirus strain K87 (MAd-2) was cloned and mapped with restriction endonucleases Bgl II, Cla I, Eco RI, Hin dII and Sph I. Large differences were found the MAd-2 and MAd-1 (strain FL) DNA molecules in terms of number and location of restriction sites. The MAd-2 genome also appeared as larger size than in the MAd-1 genome (34.72 kb vs. 30.14 kb). Our results confirm the existence of two distinct adenovirus species in the mouse. Hybridization experiments, on the other hand, indicate that both MAd-1 and MAd-2 are genetically related to human adenovirus type 2 (HAd-2). Overlapping regions of DNA homology are located in genes coding for HAd-2 structural components which could explain serological relationships observed between the human and the murine adenoviruses.     

Influence of the deprivation of a single amino acid on cellular proliferation and survival in rat 3Y1 fibroblasts and their derivatives transformed by a wide variety of agents

We compared proliferation and survival of various syngeneic transformed cell lines under conditions of depletion of 15 amino acids in Dulbecco-Eagle's medium. We used a normal fibroblast line 3Y1 and 22 transformed sublines of 3Y1 which had been induced by one of seven transforming agents--simian virus 40, mouse polyomavirus, adenovirus type 12, E1A gene of adenovirus type 12, cDNA of Harvey murine sarcoma virus, Rous sarcoma virus, or N-methyl-N'-nitro-N-nitrosoguanidine. Unlike other untransformed cells examined (mouse BALB/c-3T3 line, mouse NIH-3T3 line, and primary Fischer rat embryo fibroblasts), 3Y1 ceased to proliferate and accumulated in a viable state with a G1-phase DNA content under 14 singular deprivations of amino acid. None of the transformed 3Y1 lines completely arrested in the G1 phase of the cell cycle and each showed different levels of survival, depending on each transforming agent. As for transformed 3Y1 cells induced by a given virus or a given transforming gene, any one of the three sublines shared the same trend with respect to proliferation and survival. Transformed derivatives induced by N-methyl-N'-nitro-N-nitrosoguanidine showed almost the same trend in proliferation, but the patterns of survival were not uniform. Our observations suggest that the unique responses of 3Y1 to amino acid depletion are differently modified by different transforming agents.     

Letter: Some unusual properties of replicating adenovirus type 2 DNA

Replicating adenovirus type 2 DNA was isolated from KB cells 13 hours after infection. The buoyant density in caesium chloride of the replicating DNA was found to be 5 to 10 mg/cm² greater than that of mature adenovirus type 2 DNA. The single-strand specific nuclease from Neurospora crassa released 25 to 30% of the radioactivity from replicating DNA and the density difference between replicating and mature adenovirus DNA was eliminated after digestion with this enzyme, but not after digestion with RNase or pronase. The results suggest that the complementary strands of adenovirus type 2 DNA are replicated asynchronously.     

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.     

Characterization of a cDNA encoding the bovine coxsackie and adenovirus receptor.

Non-human adenoviruses such as bovine adenovirus type 3 (BAV-3) that do not replicate in human cells but can infect human cells in culture could provide an attractive alternative to human adenoviral vectors for gene therapy. In addition, a large-animal model for genetic diseases can be very useful for the assessment of the efficacy of adenovector-mediated gene delivery in man. Recombinant human subgroup C adenovectors use the coxsackie and adenovirus receptor (CAR) to enter their target cells. Through RT-PCR and sequencing we determined the complete coding sequence of bovine CAR which serves as the primary adenoviral attachment site on bovine cells. A multiple sequence alignment, involving all the previously identified CAR species (man, mouse, rat, pig, and dog) showed that bovine CAR was most related to porcine CAR (92% nucleotide similarity) and demonstrated a highly conserved adenovirus binding Ig1 domain.     

An Adenovirus Isolated from the Feces of Mice

Cytopathogenic agents have been isolated in a search for viruses in the feces of apparently healthy mice (an inbred strain DK1) by using mouse kidney tissue culture. This report is concerned with the identification of strain K87, one of our isolates, as an adenovirus. Strain K87 was cytopathogenic to mouse kidney tissue culture but not to monkey kidney tissue culture, FL, and HeLa cells. The K87 strain was not able to grow in bacterial media and was resistant to penicillin, streptomycin and tetracycline. 5-Bromodeoxyuridine inhibited the occurrence of the cytopathogenic effect and virus replication in infected cells and the inhibitory effect was reversed by thymidine, suggesting that the virus contains DNA. Strain K87 was resistant to ethyl-ether but did not have the property of cationic stabilization to thermal inactivation. Electronmicroscopic observations of thin-sections of the K87-infected cells showed virus particles in crystalline array in the nuclei. Each virus particle was an icosahedron of about 75 mμ in diameter composed of 252 capsomeres, and without an envelope. By the complement fixation test, K87 was related serologically to a human adenovirus. All the facts indicate that strain K87 belongs to the adenovirus group. The problem whether strain K87 may be a new mouse adenovirus with pathogenicity and antigenicity different from that of a mouse adenovirus previously reported by Hartley and Rowe is discussed.     

Bovine Adenovirus

Two adenovirus strains were isolated in calf testicle cell cultures from blood specimens of cattle in Japan. This is the first isolation of bovine adenovirus reported in Japan. The isolates were antigenically similar to each other and distinct from the hitherto described serotypes 1, 2 and 3 of bovine adenovirus. Unfortunately, bovine adenovirus types 4 and 5 were not available for comparison, and hence, until the matter is settled, the virus will be called “Bovine adenovirus type Nagano”. Nagano virus was identified as adenovirus on the bases of the inhibitory effect of 5-iodo-2′-deoxyuridine on virus replication, ether-resistance, effect of temperature and pH on infectivity, and fine structure of the virus particle. The virus grew and formed intranuclear inclusion bodies, a characteristic of adenovirus, in bovine testicle cells but not in bovine kidney cells. The virus agglutinated rat erythrocytes very poorly, but not sheep, goat, cattle, horse, guinea pig, hamster, chicken, and mouse cells. The virus produced adenovirus group-specific antigen in cell cultures. Sero-negative calves were readily infected with the virus by the intravenous, subcutaneous, oral or intranasal routes of inoculation. The infected animals produced antibodies and showed a mild clinical reaction comprised of rhinorrhea, diarrhea and a degree of pyrexia; low-titered viremia of short duration and leukopenia were also observed. A serologic survey indicated wide-spread dissemination of the virus among Japanese cattle, but further studies are needed to determine the etiologic significance of the virus in the natural disease in cattle.     

Virus-Specific Ribonucleic Acid in the Nucleus and Cytoplasm of Rat Embryo Cells Transformed by Adenovirus Type 2

Nuclei were isolated from rat embryo cells transformed by adenovirus type 2. Nuclear and cytoplasmic virus-specific ribonucleic acids (RNA) were characterized and quantitated by deoxyribonucleic acid (DNA)-RNA hybrid formation with adenovirus DNA. The results indicate that most, if not all, virus-specific RNA molecules are synthesized in the cell nucleus and subsequently transported into cytoplasm where they degrade with a half-life of 1 to 2 hr. No difference in base sequences between nuclear and cytoplasmic virus-specific RNA species can be detected by hybridization competition experiment with viral DNA.     

The E1B 19-kilodalton protein is not essential for transformation of rodent cells in vitro by adenovirus type 5.

The newly constructed adenovirus type 5 mutant in1 carries a single AT base pair insertion immediately after nucleotide position 1715 in the E1B gene sequence which destroys the proximal AUG normally present in E1B messages and prevents production of intact E1B 19-kDa protein in infected cells. We have used in1, variants of in1 containing mutant alleles of viral genes known to enhance transformation frequency, and adenovirus type 5 mutant dl337 (S. Pilder, J. Logan, and T. Shenk, J. Virol. 52:664-671, 1984), in which the sequence between nucleotides 1770 and 1916 within the 19-kDa reading frame is deleted, to test the generally accepted hypothesis that this E1B protein is essential for the transformation of rodent cells and maintenance of the transformed phenotype. We find that these mutants transform rat embryo cells, rat kidney and mouse kidney primary cells, and cells of the 3Y1 rat line with decreased frequencies only when virus is added to these various cells at high input multiplicities of infection. In contrast, when lower doses of virus are used, the mutants transform with wild-type frequencies. Cells infected with higher doses of mutant virus show increased levels of DNA degradation and cell killing compared with those of cells infected with the same levels of wild-type virus, and these effects most likely contribute to the decreased transformation frequencies observed. On the basis of these results and the results of phenotypic analyses of numerous transformants, we propose that the E1B 19-kDa protein is not required for induction and/or maintenance of transformed-cell characteristics in rodent cells infected with adenovirus type 5.     

Transduction of the mammary epithelium with adenovirus vectors in vivo

Because the mammary parenchyma is accessible from the exterior of an animal through the mammary duct, adenovirus transduction holds promise for the short-term delivery of genes to the mammary epithelium for both research and therapeutic purposes. To optimize the procedure and evaluate its efficacy, an adenovirus vector (human adenovirus type 5) encoding a green fluorescent protein (GFP) reporter and deleted of E1 and E3 was injected intraductally into the mouse mammary gland. We evaluated induction of inflammation (by intraductal injection of [(14)C]sucrose and histological examination), efficiency of transduction, and maintenance of normal function in transduced cells. We found that transduction of the total epithelium in the proximal portion of the third mammary gland varied from 7% to 25% at a dose of 2 x 10(6) PFU of adenovirus injected into day 17 pregnant mice. Transduction was maintained for at least 7 days with minimal inflammatory response; however, significant mastitis was observed 12 days after transduction. Adenovirus transduction could also be used in the virgin animal with little mastitis 3 days after transduction. Transduced mammary epithelial cells maintained normal morphology and function. Our results demonstrate that intraductal injection of adenovirus vectors provides a versatile and noninvasive method of investigating genes of interest in mouse mammary epithelial cells.     

A size analysis of the adenovirus replicon

The linear double-stranded genome of adenovirus DNA replicates semiconservatively from two origins of replication at either of the two molecular ends. Using an in vitro replication system which is able to initiate de novo DNA synthesis we have mapped the origin of DNA replication within the terminal 19 bp of the viral genome. Our conclusions are based on the use of different natural DNA templates, i.e., adenovirus type 2 and mouse adenovirus Fl DNA. In addition, we have employed linearized plasmid DNA templates which contain cloned terminal restriction enzyme fragments as well as chemically synthesized adenovirus termini of different length.     

Chromosomal damage induced by human adenovirus type 12 requires expression of the E1B 55-kilodalton viral protein.

Infection of human embryonic kidney cells with adenovirus type 12 results in the induction of damage at specific (17q21-22, 1p36, 1q21, and 1q42-43) and random sites in the cellular chromosomes. A previous study by Durnam et al. (D. M. Durnam, P. P. Smith, J. C. Menninger, and J. K. McDougall, Cancer Cells 4:349-354, 1986) indicated that the expression of viral early region 1 (E1) is sufficient for the induction of damage at band 17q21-22. In the present report we used an adenovirus type 12-adenovirus type 5 recombinant with E1A hybrid sequences as well as viruses with mutations in the adenovirus type 12 E1B genes to map adenovirus type 12 E1 functions involved in the induction of genetic damage. Our results show that the expression of the E1A proteins is not sufficient for this effect. On the other hand, mutations within the E1B 55-kilodalton protein but not the E1B 19-kilodalton protein affect the ability of the virus to induce both specific and random chromosomal damage.