Subcloning of DNA fragments of the simian adenovirus SA7 oncogene in bacteriophage M13

The XmaI/PstI and XmaI DNA fragments of adenovirus SA7 oncogene and the adjacent region (16.7% of the physical map of SA7 left end DNA) were recloned in M13 bacteriophages mp8 and mp9 in order to obtain the singlestranded fragments EIa and EIb from the DNA region of monkey adenovirus SA7 located on the recombinant plasmid pASP carrying the DNA APstI fragment including the adenovirus SA7 oncogene.     

Adenovirus Transformation of Hamster Embryo Cells

Inoculation of hamster embryo cell cultures with human adenovirus type 12 (Ad12) or simian adenovirus (SA7) resulted in the formation of foci of morphologically transformed cells within 12 days. The rapid appearance of well-defined foci was dependent upon the transfer of cells into new plates, with sufficient dilution after virus adsorption, and was independent of virus dose. Dose-response studies showed linearity of focus formation with dilution of Ad12 or SA7. Results averaged from several experiments show plaque-forming unit to focus-forming unit ratios of approximately 1.8 x 10(6) for Ad12 and 2.6 x 10(5) for SA7. Other experiments showed that most of the adenovirus involved in transformation was adsorbed by 3 hr. Cell lines derived from SA7 transformed cells produced tumors within 19 days when inoculated intradermally into young adult hamsters. Such cell-induced tumors histologically resembled SA7 virus-induced hamster tumors. Formation of tumors with SA7 transformed cells was inhibited by prior immunization of test animals with SA7 or Ad12 virus.     

Interaction between the human and simian adenoviruses in human cells: complementation, transcapsidation and formation of defective adeno-adeno hybrids

It was for the first time that complementation between the human and simian adenoviruses in human cells as well as the ability of the human adenovirus Ad2 (HADv2) genome to transform completely into the simian adenovirus SA7(C8) (SADv15) capsid (transcapsidation) was demonstrated. A defective adeno-adeno hybrid (recombinant) between the above viruses is described; the recombinant has the SA7(C8) capsid and Ad2 genome with a 10% insertion of SA7(C8) in the central region. Defective hybrid virions are able to replicate both in human and simian cells by using the SA7(C8) virus as helper. The hybrid virions help the above virus to replicate in human cells: they form a mutually complementing virion pair.     

New data on the type of structural changes in DNA of simian adenovirus SA7 microinjected into mouse zygotes

The structure of the transgene has been analysed in a new series of experiments on the transfer of adenovirus SA7 DNA into the mice zygotes by microinjection technique. The previous data on SA7 DNA elimination from the genomes of different organs (sceletal muscles, heart, tail) have been confirmed and detailed for the F0 and F1 generations of transgenic animals. The left end of adenoviral genome has been shown to be predominantly transfered after microinjections of SA7 DNA into the mice zygotes.     

Model systems of carcinogenesis in vitro: the interaction of the ras oncogene with immortalized cells

Gene transfer experiments have shown that ras effector functions are sufficient to transform cells from a variety of established lines (e. g., mouse NIH3T3 cells). In contrast, primary cells and early passage rodent cells can be transformed by ras oncogenes only at low frequencies, unless cotransfected with collaborating genes such as adenovirus early region IA (EIA) or myc retroviral oncogene homologue. Primary rat embryo fibroblasts (REF) were chosen as a model for the analysis of multistep cellular transformation. Transfection of REF, immortalized by early region of simian adenovirus SA7 with c-Ha-ras oncogene cannot induce their morphological transformation. This phenomenon is observed only after second transfection with the same oncogene. These different cell lines can be used for further analysis of the mechanisms of carcinogenesis.     

Hybrid of Monkey and Human Adenoviruses

Following joint replication of monkey SA7 adenovirus (C8 strain) and human adenovirus type 2 in green monkey kidney tissue culture, a virus possessing the properties of a hybrid was obtained. It was designated Ad2C8. Ad2C8 preparations contained two types of viral particles: human adenovirus type 2, and hybrid particles. The hybrid virions multiplied in green monkey kidney cells in the presence of human adenovirus types 1, 2, and 3, but not 3 and 7, and acquired the capsid of the helper adenovirus. The hybrid can serve as a helper for human adenoviruses. It can apparently induce T antigen of the C8 virus but, in contrast to the latter, does not induce tumors in hamsters.     

Hybrids of human and monkey adenoviruses (adeno-adeno hybrids) that can reproduce in monkey cells: biological and molecular genetic peculiarities

A highly oncogenic monkey adenovirus SA7(C8) facilitates the reproduction of human adenovirus type 2 (Ad2) in monkey cells. Upon mixed infection of monkey cells with both viruses, these viruses recombine producing defective adeno-adeno hybrids Ad2C8 serologically identical to Ad2 and capable of assisting Ad2 to reproduce in monkey cells. Ad2C8 and Ad2 form an intercomplementary pair inseparable in monkey cells. Unlike oncogenic SA7(C8), Ad2C8 is a nononcogenic virus for hamsters but is able to induce tumor antigens of this virus (T and TSTA). Molecular genetic analysis of 68 clones of adeno-adeno hybrids revealed that the left part of their genome consists of Ad2 DNA, and the right part contains no less than 40% of the viral SA7(C8) genome where E2A, E3, and E4 genes are located. Apparently, the products of these genes contribute to the composition of adenoviral tumor antigens, while the E4 gene is involved in complementation of monkey and human adenoviruses and makes a contribution to host range determination of these viruses.     

Viral infections of the Kenya baboon (Papio cynocephalus) in its natural habitat

Stools, rectal swabs, throat swabs, and tissues were collected from 508 baboons (Papio cynocephalus) in 17 areas of Kenya and Tanzania during 5 field trips between 1961 and 1968. A total of 11 isolations were made: nine agents were recovered from 508 fecal samples and 2 from 468 throat swabs. These isolates were identified as adenovirus serotypes AA153, SA7, SV15 and SV23. SV23 was found only in throat swabs and never from fecal material while AA153, SA7 and SV15 were recovered only from fecal material. One rectal specimen produced 2 serotypes, SV15 and SA7. No isolates were recovered from necropsy samples from 19 animals.     

Hybrids of Human and Monkey Adenoviruses (Adeno-Adeno Hybrids) That Can Reproduce in Monkey Cells: Biological and Molecular Genetic Peculiarities

A highly oncogenic monkey adenovirus SA7(C8) facilitates the reproduction of human adenovirus type 2 (Ad2) in monkey cells. Upon mixed infection of monkey cells with both viruses, these viruses recombine producing defective adeno-adeno hybrids Ad2C8 serologically identical to Ad2 and capable of assisting Ad2 to reproduce in monkey cells. Ad2C8 and Ad2 form an intercomplementary pair inseparable in monkey cells. Unlike oncogenic SA7(C8), Ad2C8 is a nononcogenic virus for hamsters but is able to induce tumor antigens of this virus (T and TSTA). Molecular genetic analysis of 68 clones of adeno-adeno hybrids revealed that the left part of their genome consists of Ad2 DNA, and the right part contains no less than 40% of the viral SA7(C8) genome where E2A, E3, and E4 genes are located. Apparently, the products of these genes contribute to the composition of adenoviral tumor antigens, while the E4 gene is involved in complementation of monkey and human adenoviruses and makes a contribution to host range determination of these viruses.     

Increased integration of viral genome following chemical and viral treatment of hamster embryo cells.

Treatment of hamster embryo cells with diverse classes of chemical carcinogens enhances transformation by a carcinogenic simian adenovirus, SA7. Virus transformed foci selected from plates pretreated with 3-methyl-cholanthrene (MCA), methyl methanesulfonate (MMS) or 7,12-dimethylbenz[a]anthracene (DMBA) and established as cell lines in culture, contained equivalent amounts of SA7 viral genome. However, hamster embryo cultures treated with MMS or nickel sulfate had increased amounts of SA7 DNA integrated into cellular DNA when examined 2--9 days after chemical treatment and viral inoculation. An increased uptake of SA7 DNA was demonstrated in hamster cells treated with MMS during DNA repair synthesis in cells retricted in scheduled DNA synthesis by amino acid deprivation; addition of virus after the repair period did not result in an increased integration of viral DNA. These data suggest that enhancement of viral oncogenesis by chemical carcinogens or mutagens may be related to the formation of additional attachment sites in cellular DNA for insertion of viral DNA, thereby increasing the probability of viral transformation.     

Cytophotometric study of changes in the structure of nuclear chromatin induced by the oncogenic adenovirus SA7 (C8)

Infection of primary murine embryonic cell cultures by adenovirus SA7 (C8) results in an increase in chromatin condensation Average optical density of Feulgen stained nuclei 24 h following virus absorption increased for G0/1, S, and G2 cells by 16.1, 11.3 and 13.1%, respectively. This phenomenon is associated with the stimulation of proliferation, with an increase of the S cell amount by 50% of the control values and a decrease of average cell nuclei areas in all phases of cell cycle.     

Preparation and characteristics of a new transformed cell line G11 by transfection of NIH/3T3 mouse fibroblasts with DNA from the SA7 oncogene of simian adenovirus

Murine fibroblasts NIH 3T3 were transfected with the plasmid pASP containing simian adenovirus oncogene insertion. Focus forming transformants were cloned with a final dilution technique and a new cell line G11 was created as a result. Transformed status of this cell line is evidenced by changes in morphology, specific cytochemical and adhesion properties, ability to grow in semisolid agar and FCS concentration growth independence. Presence of intact integrated E1a-region of adenovirus SA7 oncogene was shown by blot-hybridization technique. Transformed status of G11 cells can be explained by integration of SA7 oncogene, that is evidenced indirectly by the increased resistance to heat shock.     

Viral infections of the captive Kenya baboon (Papio cynocephalus): a five-year epidemiologic study of an outdoor colony.

Rectal swabs, throat swabs, fecal samples, tissues, and sera were collected from 334 adult and infant Kenya baboons (Papio cynocephalus) in captivity at this institution over a 5-year period. A total of 4,893 specimens were collected, resulting in the isolation of 582 viral isolates (11.9%). The month of November yielded the lowest isolation rate, while the month of January produced the highest rate. The most commonly isolated viruses in adults and infants were SV6 and SV23, followed by N125, SV15, and SV17 in that order in adults, and SA7, N125, SV15, V340, and SV17 in that order in infants. Nine serotypes, namely enteroviruses SV19, SV42, SA5, A13, and N203, as well as adenoviruses SV15, SV20, SV31, and SV37, were isolated only from adults. Two adenovirus serotypes, SA7 and V340, were recovered predominantly from infants.     

Biological activity of the intact and cleaved DNA of the simian adenovirus 7.

Only the deproteinized DNA preparations of the simian adenovirus of the type 7 (SA 7) exhibited transforming and tumorigenic activity. The complex of the SA7 DNA with terminal protein (TP) did not exhibit either transforming or tumorigenic activity in cell cultures. In contrast to the transforming potential the infectious titers of the DNA - TP complex for the monkey kidney cells were 30-50 times higher than those of pure DNA. Cleavage of the SA7 DNA by specific endonucleases enhanced the tumorigenic potential of pure DNA, suppressed its infectivity and did not affect the lack of transformation capacity of the DNA - TP complex. The onc-gene was localized in the left terminal fragment with the minimal size 4,3x10(6)D in the case of R.Sal I. The tumorigenic activity was found to decrease with an increase in the size of the DNA fragment containing the onc-gene.     

Oncogene-directed mutagenesis in vivo. Polyalkylating derivatives of short single-stranded polynucleotides, complementary E1-adeno-oncogene, in the normalization of adenovirus-transformed rodent cell lines]

Polyalkylating derivatives of single-stranded polynucleotides (30-200-mers) complementary to the long E1 oncogene sequences of simian adenovirus SA7 cause inherited normalization of SH2 and G11 cells transformed with adenovirus SA7; certain deletions in the integrated proviral E1A oncogene were observed in several cases during this process. The transformed cells are indifferent to reagents noncomplementary to the E1 region. Thus polyalkylating derivatives of single-stranded 30-200-mers act as addressed mutagenes which react in a specific way with the integrated complementary DNA sequences of E1 oncogene in transformed rodent cells and realize oncogene-directed mutagenesis in vivo. During this treatment temporary normalized cells reverting to the initial transformed phenotype are also produced.     

Complementary directed modifications of nucleic acids and oncogene-directed mutagenesis in vivo.

High reactivity of the polyalkylating ss oligomers that were sense or antisense 30-200-mers containing sequences complementary to E1 oncogenes of simian adenovirus SA7 and one alkylating residue -CH2CH2N(C2H5OH) (CH2)3N(Ph-p-CH2OH)CH2CH2Cl per each 25 bases of oligomers was demonstrated in vitro by alkylation of ss DNA of recombinant M 13 mp8E1 and mp9E1 phages with inserted E1 sequences of adenovirus oncogene and then by followed complete and selective elimination of E1 sequences from recombinant ss DNA. Treatment of rodent cell cultures transformed by oncogenic SA7 with polyalkylating oligomers which are complementary to the long region of the minus or plus chains of E1 DNA of SA7 revealed a rather high extent of mutant cell clones formation. The cells formed were normalized; they had lost some properties of the transformed cells. Dividing cell clones inherited the new phenotypic properties: morphology, slower and more limited proliferation, and higher dependence on bovine serum growth factors. Some of the mutant cell DNAs demonstrated different mutations in the E1A sequences of the integrated proviral oncogene. There were exchanges G to C (leu to val) in the 525 and C to A (asp to tyr) in the 555 positions of E1A oncogene. Besides a deletions in the 1057-1477 E1A region or/and a mutation in the 1457-1477 of E1A were observed. Thus the inherited cell normalization observed is performed due to oncogene-directed mutagenesis in vivo.     

Tumour Induction by Simian Adenovirus SA7 DNA Fragments

DNA extracted from simian adenovirus SA7 can induce tumours in hamsters and is infectious in tissue culture^1,2. We now have evidence that fragments of the SA7 genome can initiate tumours in newborn hamsters.     

Integration of foreign genome fragments into cells transformed or cotransformed with fragmented adenoviral DNA

The integration of DNA of highly oncogenic simian adenovirus type 7 (SA7) and non-oncogenic human adenovirus type 6 (Ad6) into the genome of newborn rat kidney cells transformed by fragmented DNA preparations was studied using reassociation kinetics and spot hybridization. Transforming DNA was fragmented with the specific endonuclease SalI (SA7) and BglII (Ad6). In contrast to the cell transformation by intact viral DNA, transformation by fragmented DNA resulted in integration into the cellular genome of not only the lefthand fragment with the oncogene but also of other regions of the viral genome. Additionally integrated fragments were stable and preserved during numerous passages of cells lines, although they were no expressed, at least in the case of the Ad6-transformed cell line. The integration of the fragments of SA7 DNA was accompanied by loss of 25-50% of the mass of each fragment. Adding the linear form of the pBR322 plasmid to the preparation of transforming Ad6 DNA also contributed to its cointegration into the genome of the transformed cell. This technique of cell cotransformation with any foreign DNAs together with the viral oncogens may be used as an equivalent of an integration vector for eukaryotic cells.