Complementation of adenovirus type 5 host range mutants by adenovirus type 12 in coinfected HeLa and BHK-21 cells.

We have studied the ability of adenovirus type 12 (Ad12) to complement the Ad5 transformation-defective host rang (hr) mutants during infection of human cells (HeLa) or hamster cells (BHK-21). The group I mutant hr3 (mapped within 1.3 to 3.7 map units), which is incapable of synthesizing viral DNA, was complemented for both DNA synthesis and infectious virus production in nonpermissive HeLa cells during coinfection with Ad12. Similarly, the group II mutant hr6 (6.1 to 9.4 map units), which does synthesize DNA, was also shown to be complemented for virus production. When the host cells were BHK-21, an established hamster cell line that is permissive for Ad5 but nonpermissive for Ad12 DNA synthesis and virus production, coinfection with Ad5 and Ad12 did not overcome the block to Ad12 DNA synthesis. Coinfection of BHK-21 cells with Ad12 and either hr3 or hr6 leads to the complementation of only the group I mutant (hr3). The inability of Ad12 to complement hr6 in BHK-21 cells may be due to the failure of Ad12 to express an early gene product from the region corresponding to early region 1B (4.5 to 11 map units) Ad5 where hr6 and the other group II mutations are located.     

Isolation of adenovirus type 5 host range deletion mutants defective for transformation of rat embryo cells.

A series of adenovirus type 5 (Ad5) deletion, insertion and substitution mutants, some of which are defective for transformation of rat cells, have been isolated. The mutants were selected as variants which lack the Xba I endonuclease cleavage site at 4 map units on the viral chromosome. The deletions range in size from 150-2300 bp and are located between 1.5 and 10.5 map units. The mutants can be propagated in 293 cells (Ad5-transformed human embryonic kidney cells), but are defective for growth in HeLa or human embryonic kidney cells. No viral DNA synthesis was observed in mutant virus-infected HeLa cells. All but one of the deletion mutants tested were defective for transformation of rat embryo and rat embryo brain cells.     

Arrangement of integrated viral DNA sequences in cells transformed by adenovirus types 2 and 5.

The organization of the viral DNA sequences in 15 adenovirus-transformed cell lines was analyzed by the Southern blotting procedure. The site of adenovirus integration in the cellular genome was found not to be unique, and the viral DNA sequences involved in integration were not confined to a specific region of the adenovirus genome. Several cell lines showed simple integration patterns that demonstrated the presence of large continuous stretches of viral DNA. In four cell lines, containing sequences from both molecular ends of the viral genome, the left- and right-hand-terminal sequences appeared to be linked to each other.     

Amount of viral DNA in the genome of cells transformed by adenovirus type 2

The number of copies of viral DNA in DNA of cells transformed by adenovirus type 2 has been determined by following the kinetics of reassociation of ³²P-labeled viral DNA in the presence of unlabeled DNA extracted from transformed and control cells. There is close to one copy of adenovirus 2 DNA for every diploid quantity of cell DNA.     

Transformation of rat cells by cyt mutants of adenovirus type 12 and mutants of adenovirus type 5.

Several mutants with much reduced oncogenicity (spontaneous mutants H12 cyt 52 and H12 cyt 70 and UV-induced mutants H12 cyt 61, H12 cyt 62, and H12 cyt 68) of the highly oncogenic adenovirus type 12 (Ad12) were studied for their ability to transform primary baby rat kidney cells. Four of the mutants showed much reduced capacity to transform cells in vitro, while H12 cyt 61 transformed cells as efficiently as the wild-type virus. Viral gene expression in several cell lines established from cultures infected by cyt mutants was studied, and it was found that viral sequences belonging to the left 16% of Ad12 were always transcribed. These results suggest that the function of the transformed state is not defective in the cyt mutants studied. Heterotypic complementation studies showed that the defect(s) in a cyt mutant can be corrected by an Ad7 function. Ad5 dl 313, with a deletion between 3.5 and 10.5 map units, transformed rat cells only at high multiplicity. These results suggest that the region E1B of adenoviruses may be required for efficient transformation of rat cells.     

Reassociation of complementary strand-specific adenovirus type 2 DNA with viral DNA sequences of transformed cells.

Complementary strand-specific adenovirus DNA, either full length or from restriction enzyme cleavage fragments, was used to estimate the fractional representation and abundance of viral sequences in two adenovirus type 2 (Ad2)-transformed rat cell lines, A2F19 and A2T2C4. The reassociation method introduced is based on the linear relationship, after exhaustive hybridization, between the inverted fraction of hybrid DNA and the molar ratio of probe to cellular DNA in the reaction mixture. The amount of viral DNA in A2F19 cells represents 12 to 14% of the viral genome at a level of around seven copies per diploid cell equivalent. For the cell line A2T2C4, the pattern of integrated viral DNA sequences is more complex. With full-length Ad2 DNA strands as a probe, about 56% of the probe was represented in cellular DNA. When each of the four BamHI fragment strands of Ad2 DNA was used as a probe, the fraction of the viral DNA present also amounted to around 56% with one to five copies from different regions of the viral genome. The results demonstrate the advantage of using strand-specific viral DNA as a probe in reassociation analysis with denatured cell DNA. The method should be useful in any system in which complementary strand separation of viral DNA sequences can be achieved.     

Isolation and characterization of herpes simplex virus type 1 host range mutants defective in viral DNA synthesis.

Cell lines were generated by cotransfection of Vero cells with pSV2neo and a plasmid containing the herpes simplex virus type 1 (HSV-1) EcoRI D fragment (coordinates 0.086 to 0.194). One such cell line (S22) contained the genes for alkaline exonuclease and several uncharacterized functions. Three mutant isolates of HSV-1 strain KOS which grew on S22 cells but not on normal Vero cells were isolated and characterized. All three mutants (hr27, hr48, and hr156) were defective in the synthesis of viral DNA and late proteins when grown in nonpermissive Vero cells. Early gene expression in cells infected with these host range mutants appeared to be normal at the nonpermissive condition. The mutations were mapped by marker rescue to a 1.5-kilobase fragment (coordinates 0.145 to 0.155). The mutation of one of these mutants, hr27, was more finely mapped to an 800-base-pair region (coordinates 0.145 to 0.151). This position of these mutations is consistent with the map location of a putative 94-kilodalton polypeptide as determined by sequence analysis (D. McGeoch, personal communication). Complementation studies demonstrated that these mutants formed a new complementation group, designated 1-36. The results presented in this report indicate that the 94-kilodalton gene product affected by these mutations may have a direct role in viral DNA synthesis.     

In vitro synthesis of adenovirus type 5 T antigens. II. Translation of virus-specific RNA from cells transformed by fragments of adenovirus type 5 DNA.

Virus-specific cytoplasmic RNA was isolated from rat cell lines transformed by fragments of adenovirus type 5 DNA, and the RNAs were translated in cell-free systems derived from wheat germ or rabbit reticulocytes. RNA was isolated from cell lines transformed by the following fragments: XhoI-C (leftmost 15.5%), HindIII-G (leftmost 8%), and HpaI-E (leftmost 4.5%). In addition, the adenovirus type 5-transformed human embryonic kidney line 293.C31 was investigated. The products were immunoprecipitated with serum from tumor-bearing hamsters and analyzed by electrophoresis in sodium dodecyl sulfate-polyacrylamide gels. The results show that all transformed cells investigated contain early region 1a-specific RNAs which can be translated into proteins with molecular weights of 34,000 (34K), 36K, 40K, and 42K. Transformed cells that also contain an intact early region 1b synthesized RNA which can be translated into proteins with molecular weights of 19K and 65K. Minor proteins of 15K, 16K, 17.5K, 18K, 25K, and 29K were also observed, but these proteins could not be mapped unambiguously. Cells transformed by the 8% HindIII-G apparently lack RNA encoding the 65K protein, but they do contain RNA coding for the 19K protein.     

Viral DNA sequences and gene products in hamster cells transformed by adenovirus type 2.

Complementary strand-specific adenovirus DNA of full length or from endonuclease BamHI fragments was used as a probe to estimate the fractional representation and abundance of viral sequences in five hamster cell lines (Ad2HE1-5) transformed with UV-inactivated adenovirus type 2. The fraction of the viral genome present in the five transformed cell lines varied from 44% in the Ad2HE5 cell line to 84% in the Ad2HE3 cell line. The number of viral DNA copies per diploid cell equivalent ranged from 1.8 in the Ad2HE1 line to 7.1 in the Ad2HE4 line. In vivo labeling with [35S]methionine followed by immunoprecipitation with an antiserum against adenovirus type 2 early proteins revealed virus-specific polypeptides with molecular weights of 42,000 to 58,000 in extracts from all five hamster cell lines. Several other early viral polypeptides were detected in some of the adenovirus type 2-transformed hamster cell lines.     

Complementation of human adenovirus type 5 ts mutants by human adenovirus type 12.

Temperature-sensitive mutants of type 5 adenovirus belonging to eight complementation groups were complemented in mixed infection by type 12 adenovirus, whereas mutants of 7 other groups were not enhanced. In some crosses, phenotypic mixing took place. No evidence of recombination between type 5 ts mutants and type 12 was found.     

Unique species of mRNA from adenovirus type 7 early region 1 in cells transformed by adenovirus type 7 DNA fragment.

Adenovirus type 7 (Ad7) early region 1 mRNA species transcribed in rat cell lines transformed by the HindIII-I . J fragment (the left 7.8% of the viral genome) and in human KB cells infected with Ad7 were mapped on the viral genome, using S1 nuclease gel and diazobenzyloxymethyl paper hybridization techniques. At the early stage of productive infection, two mRNA's (950 and 840 nucleotides long) with the common 5' and 3' ends but different internal splicings were mapped from region 1A (map units 1.4 to 4.3), and one mRNA (2,310 nucleotides long, with the internal splicing between map units 9.9 to 10.1) was mapped from region 1B (map units 4.6 to 11.4). At the late stage, these early spliced mRNA's were also found and at least three additional Ad7 mRNA's were identified: 700-nucleotide-long mRNA in region 1A; and 1,100- and nucleotide-long mRNA's in region 1B. In transformed rat cell lines, two early region 1A mRNA's (950 and 840 nucleotides long) were also transcribed. Surprisingly, in addition, several unique Ad7 mRNA's, not found in productivity infected cells, were identified in all of the transformed cell lines. Their molecular sizes and coding sequences varied in individual cell lines. However, these mRNA's had the 5' end-proximal portion in region 1B and the 3' end-proximal portion in region 1A, these portions being transcribed by extending from region 1B to 1A on viral DNA fragments joined in a tandem array in transformed cells.     

Cellular transformation by adenovirus type 5 is influenced by the viral DNA polymerase.

Early region 2B (E2B) of the group C adenoviruses encodes a number of proteins, including the 140-kilodalton DNA polymerase, which plays a role in the initiation of viral DNA replication. Temperature-sensitive (ts) mutants with mutations mapping to E2B are conditionally defective for both DNA replication in human cells and transformation of rat cells. Nucleotide sequence analysis shows that the E2B mutant ts36 possesses a single point mutation specific to the viral DNA polymerase; this transition of a C to a T at position 7623 changes leucine residue 249 in the polymerase to a phenylalanine. A wild-type (ts+) revertant possesses a codon specifying the original leucine at position 249. Phenotypic analysis of revertant and wild-type viruses derived by marker rescue from ts36 shows that these variants are wild type for both viral DNA replication and transformation. Thus, the single point mutation in the polymerase gene of ts36 is responsible for both defects.     

Production of growth factors by type 5 adenovirus transformed rat embryo cells

Transformation of Sprague-Dawley rat embryo (RE) cells and a cloned Fischer rat embryo cell line (CREF) with wild-type (Ad5) or a temperature-sensitive DNA-minus mutant (H5ts125) of type 5 adenovirus results in a reduction in binding of epidermal growth factor (EGF) to cell surface receptors. A reduction in EGF binding is also seen in a Syrian hamster embryo cell line transformed by a hexon mutant of Ad5. In contrast, a human embryonic kidney cell line (293) transformed by sheared Ad5 DNA or transfected clones of KB cells expressing the E1 transforming region of Ad5 do not show a decrease in receptor binding. When cocultivated, the adenovirus transformed rat cells were able to induce the growth in agar of normal CREF cells. Medium from Ad5 transformed RE cells stimulated the growth in agar of CREF cells and also inhibited [125I]-EGF binding in CREF cells. When fractionated by gel filtration, two peaks of [125I]-EGF inhibiting activities were obtained with apparent molecular weights of 35,000 and 16,000. These results provide the first evidence that cells transformed by an adenovirus can produce a growth factor(s) that inhibits EGF-receptor binding and induces anchorage-independent growth of normal cells.     

Transforming DNA sequences in rat cells transformed by DNA fragments of highly oncogenic human adenovirus type 12.

Rat cell lines tranformed by viral DNA fragments, EcoRI-C and HindIII-G, of adenovirus type 12 DNA were analyzed for the viral transforming DNA sequences present in cell DNAs. Cell lines transformed by the EcoRI-C fragment of adenovirus type 12 DNA (leftmost 16.5% of the viral genome) contain most of the HindIII-G sequences of the HindIII-G fragment, but at a different frequency depending on the portions of the fragment. The sequence of the AccI-H fragment of adenovirus type 12 DNA (the left part of the HindIII-G; leftmost 4.5% of the viral genome) was detected dominantly in cells transformed by the HindIII-G fragment Southern blot analysis showed that viral DNA sequences are present at multiple integration sites in high-molecular-weight cell DNA from cells transformed by the EcoRI-C or HindIII-G fragment of adenovirus type 12 DNA. These results suggest that most of the HindIII-G sequences in cells transformed by the HindIII-G fragment are present as fragmented forms.     

Transformation with specific fragments of adenovirus DNAs. II. Analysis of the viral DNA sequences present in cells transformed with a 7% fragment of adenovirus 5 DNA

Five clones of rat kidney cells transformed by a small restriction endonuclease fragment of adenovirus 5 (Ad5) DNA (fragment HsuI G, which represents the left terminal 7% of the adenovirus genome) were analyzed with respect to the viral DNA sequences present in the cellular DNAs. In these analyses, the kinetics of renaturation of 32P-labeled specific fragments of Ad5 DNA was measured in the presence of a large amount of DNA extracted either from each of the transformed cell lines or from untransformed cells. The fragments were produced by digestion of 32P-labeled adenovirus 5 DNA with endo R.HsuI, or by digestion of 32P-labeled fragment HsuI G of adeno 5 DNA with endo R.HpaI. All five transformed lines were found to contain DNA sequences homologous to 75--80% of Ad5 fragment HsuI G only. Clones II and V contained approximately 48 copies per quantity of diploid cell DNA, clone VI about 35 copies, clone IV 22 copies and clone III 5--10 copies. These results indicate that a viral DNA segment as small as 5.5% of the Ad5 genome, contains sufficient information for the maintenance of transformation.     

Intracellular forms of adenovirus DNA. V. Viral DNA sequences in hamster cells abortively infected and transformed with human adenovirus type 12.

The persistence of viral DNA in BHK-21 cells abortively infected with human adenovirus type 12 has been investigated using reassociation kinetics. No indication of an increase in the amount of viral DNA per cell has been found. On the contrary, the amount of intracellular viral DNA sequences decreases rapidly after infection. Thus, free adenovirus type 12 DNA does not replicate in BHK-21 cells. The influence of the multiplicity of infection on the amount of persisting adenovirus type 12 DNA has also been explored. The viral DNA sequences persisting in four lines of hamster cells transformed in vitro by adenovirus type 12 at various multiplicities of infection have been quantitated and mapped by reassociation kinetics experiments using restriction endonuclease fragments of 3H-labeled adenovirus type 12 DNA. All the EcoRI restriction nuclease fragments of the adenovirus type 12 genome are represented in each of the four cell lines. Individual fragments of the viral genome are represented in multiple copies in non-equimolar amounts.     

Synthesis of defective viral DNA in HeLa cells infected with adenovirus type 3.

Virus-specific DNA fragments that are shorter than the full-length viral genomes have been isolated from HeLa cells productively infected with adenovirus type 3. A number of predominant size classes could be detected by gel electrophoresis and hybridization, and the array of sizes was similar or identical to the selection in DNA purified from incomplete particles of this serotype (E. Daniell, J. Virol. 19:685-708, 1976). A large fraction of these short DNA molecules contained long inverted terminal repetitions, as did DNA molecules from incomplete particles. Restriction analysis showed that these subgenomic molecules consist of sequences from the two molecular ends of the normal genome. These results suggest that the predominance of left-hand end fragments seen in packaged incomplete DNAs results from selective packaging, whereas the predominance of certain size classes of intracellular viral DNA is a function of prepackaging events. The incomplete DNAs were generated at all times during viral DNA replication, and the yield relative to complete DNA did not seem to vary significantly with time or multiplicity of infection or when the virus was propagated on different human cell types.