Presence of cell and virus specific sequences in the same molecules of nuclear RNA from virus transformed cells

Co-transcribed 3' host sequences augment expression of integrated hepatitis B virus DNA

We have previously reported the cloning and structural analysis of integrated hepatitis B virus DNA copies from the human hepatoma cell line PLC/PRF/5. Here we show that the cloned DNA fragments of 10.7 kb and 10.5 kb contain intact coding sequences for HBsAg since Ltk- cells transfected with these DNAs secrete considerable amounts of HBsAg. We show for the 10.7-kb fragment that multiple readthrough messages composed of viral as well as cellular sequences are transcribed. These RNAs differ only in their 3' sequences. Furthermore, the 10.7-kb insert leads to a substantial increase in HBsAg produced compared with HBV DNA and with the 10.5-kb insert. We provide evidence that the different 3' sequences on the HBsAg transcripts account for the augmentation of expression.

The regulated expression of beta-globin genes introduced into mouse erythroleukemia cells

We have introduced a hybrid mouse-human beta-globin gene as well as the intact human beta-globin gene into murine erythroleukemia (MEL) cells and have demonstrated that these genes are appropriately regulated during differentiation of the MEL cell in culture. The addition of chemical inducers to cotransformed cells results in a 5 to 50 fold increase in the level of mRNA transcribed from the exogenous globin gene. S1 nuclease and primer extension analyses demonstrate that these mRNAs initiate and terminate correctly. Nuclear transcription experiments indicate that induction of hybrid mRNA results at least in part from the increase in the rate of globin gene transcription. Furthermore, the induction appears to be specific for globin genes within an erythroid cell. These results permit the study of expression of the globin gene during erythroid differentiation and suggest that the specific induction of the globin gene is an inherent property of DNA sequences within or flanking the beta-globin genes. Moreover, the fact that the human and hybrid globin genes are both inducible in MEL cells suggests that these regulatory sequences are conserved between mouse and human cells.

Stimulation of host centriolar antigen in TC7 cells by simian virus 40: requirement for RNA and protein syntheses and an intact simian virus 40 small-t gene function

Simian virus 40 (SV 40) stimulated a host cell antigen in the centriolar region after infection of African green monkey kidney (AGMK) cells. The addition of puromycin and actinomycin D to cells infected with SV40 within 5 h after infection inhibited the stimulation of the host cell antigen, indicating that de novo protein and RNA syntheses that occurred within the first 5 h after infection were essential for the stimulation. Early viable deletion mutants of SV40 with deletions mapping between 0.54 and 0.59 map units on the SV40 genome, dl2000, dl2001, dl2003, dl2004, dl2005, dl2006, and dl2007, did not stimulate the centriolar antigen above the level of uninfected cells. This indicated that an intact, functional small-t protein was essential for the SV40-mediated stimulation of the host cell antigen. Our studies, using cells infected with nondefective adenovirus-SV40 hybrid viruses that lack the small-t gene region of SV40 (Ad2+ND1, Ad2+ND2, Ad2+ND3, Ad2+ND4, and Ad2+ND5), revealed that the lack of small-t gene function of SV40 could be complemented by a gene function of the adenovirus-SV40 hybrid viruses for the centriolar antigen stimulation. Thus, adenovirus 2 has a gene(s) that is analogous to the small-t gene of SV40 for the stimulation of the host cell antigen in AGMK cells.

Evolutionary variants of simian virus 40 which are impaired in early lytic functions but transform nonpermissive cells

From an undiluted passaged virus stock, two size classes of defective simian virus 40 (SV40) DNA were isolated from which two evolutionary variants were cloned. By means of restriction enzyme and heteroduplex analysis, physical maps of the mutants have been constructed. Both mutants contained the region of SV40 DNA coding for the early proteins plus some adjacent sequences (the region from 0.120 to 0.685 map unit, clockwise, on the standard SV40 DNA map). Furthermore, each mutant contained, in the form of two inverted repeats, four times the sequences from the region 0.625 to 0.685 map unit, clockwise. Some biological properties of the mutant DNA were examined, and we found that the mutant DNA (i) has, as compared with SV40 DNA, an impaired ability to induce T antigen in permissive and nonpermissive cells; (ii) does not complement a thermosensitive A mutant of SV40; (iii) replicates very inefficiently without a helper; and (iv), as an apparent contradiction, transforms nonpermissive baby rat kidney cells as well as SV40 DNA. A hypothetical mechanism for the expression of the mutant DNA that might explain the observed biological properties is presented.

Comparison of polysomal and nuclear poly(A)-containing RNA populations from normal rat liver and Novikoff hepatoma

Polysomal and nuclear poly(A)-containing RNA of normal rat liver and Novikoff hepatoma cells have been compared by cDNA.RNA hybridization kinetics. Homologous hybridization reactions revealed at total kinetic complexity of about 1.6 X 10(10) and 1.38 X 10(10) daltons for liver and Novikoff mRNA respectively. The high abundance component present in liver cannot be detected in Novikoff. It was found from heterologous reactions that about 30% by weight of mRNA sequences are specific to liver. Determination of the nuclear poly(A)-containing RNA complexities revealed that about 5.5% and 4% of the haploid genome is expressed in the liver and Novikoff respectively. In a heterologous reaction, up to 30% of the liver cDNA failed to form hybrids with Novikoff nuclear RNA. Cross hybridizations have further revealed abundance shifts in both nuclear and polysomal RNA populations. Some sequences abundant in liver are less abundant in Novikoff and some rare liver sequences are relatively abundant in Novikoff.

Transcription of the viral genome in cell lines transformed by simian virus 40. I. Mapping of virus-specific nuclear RNAs

Mapping of virus-specific nuclear transcripts was carried out in three lines of rat cells transformed by SV40. Each of these cell lines contained a single copy of integrated viral DNA with identified regions adjacent to cell DNA (1). The main virus-specific nuclear transcript in all of these cell lines was shown to be complementary to the minus strand of the early region in SV40 genome. Each cell nucleus contained approximately 50 copies of these RNAs. Transcripts complementary to both strands of the late region in viral genome were also detectable in all of these cell lines. Its content varied depending on the cell line and was 20-50-fold less than that of the main virus-specific transcript. All the regions of integrated SV40 genome in isolated nuclei of transformed cells were equally sensitive to pancreatic DNase I treatment suggesting that the whole viral genome served as a template for RNA synthesis in these cell lines.

Order of polyadenylic acid addition and splicing events in early adenovirus mRNA formation

A study of the processing of mRNA from two early adenovirus type 2 transcription units (regions 2 and 4 of adenovirus type 2 genome; [J. Flint, Cell 10:153--166, 1977]) revealed that polyadenylic acid [poly(A)] was added in most if not all cases to an unspliced nuclear RNA molecule whose coordinates extended from the apparent initiation site for RNA synthesis to the single poly(A) site in each transcription unit. An intermediate RNA molecule in the processing of the mRNA for the 72,000-M, single-stranded DNA binding protein showed that the first of the two intervening sequences, the one closest to the 5' end of the molecule, was removed first at least in the majority of the processed molecules. Finally, in cells labeled for 10 min and then treated with actinomycin D to stop further RNA synthesis, the majority, if not all, of the poly(A)-terminated nuclear RNA specific for region 2 was successfully processed and transported to the cytoplasm.

Steps in the processing of Ad2 mRNA: poly(A)+ nuclear sequences are conserved and poly(A) addition precedes splicing

The conservation of nuclear Ad2 sequences during nucleocytoplasmic transport has been estimated from the accumulation of 3H-uridine in nuclear and cytoplasmic Ad2-specific RNA from the major late transcription unit. From 10-28% is conserved of the total Ad2 nuclear RNA synthesized from each of five regions of the genome that specify groups of 3' co-terminal mRNAs. The sum of the conservation of all the regions was equivalent to 100%, signifying the conservation of at least a part of each transcript or all of about one fifth to one sixth of the transcripts. The conservation of poly(A)+ Ad2 nuclear RNA is about 4 times greater than of total Ad2 nuclear RNA, approaching 100% conservation of poly(A)+ nuclear sequences. Since each mRNA contains three "spliced" sequences that are probably encoded only once per transcript, these data on conservation of the Ad2 sequences suggest that each transcriptional event from the 16-99 transcription unit gives rise to one of a possible 13-14 mRNA molecules with destruction of the remainder of the transcribed RNA. The portion which is conserved resides next to the region to which which poly(A) is added. Three models for the choice of poly(A) sites were considered: termination at the poly(A) site, cleavage shortly after synthesis of one of the sites before transcription was complete, and cleavage after completion of transcription. The first model was ruled out by the demonstration of equimolar synthesis over the 16-99 region. The second model is strongly supported because 3H-uridine label appears equally rapidly in the time range 2-10 min in each of the five 3' poly(A) addition sites, whereas chain completion before cleavage would lead to a faster appearance of label in the most promoter-distal site. Furthermore, briefly labeled RNA molecules extending from 16 to each of several poly(A) addition sites were the first poly(A)- terminated 3H-uridine-labeled molecules detected, demonstrating that poly(A) addition precedes splicing. The choice of which mRNA emerges from each transcriptional event would appear to depend upon first choosing one of five 3' mRNA ends followed by a 5' splicing event.

Identification of early adenovirus type 2 RNA species transcribed from the left-hand end of the genome

Unique fragments of adenovirus type 2 DNA generated by cleavage with endonuclease R-Eco RI or endonuclease R-Hsu I (Hin dIII) were used to map cytoplasmic viral RNAs transcribed early in productive infection. Radioactive early viral RNA was first fractionated by polyacrylamide gel electrophoresis. Eluted viral RNAs were then tested for hybrid formation with DNA fragments. The Eco RI DNA fragment (Eco RI-A) which contains the left-hand 58% of the genome hybridized 13S and 11S RNAs. More detailed mapping of these RNAs was achieved by hybridization to the seven Hsu I fragments of Eco RI-A. The early RNA annealed only to Hsu I-G and C, two fragments which comprise the extreme left-hand 17% of the genome. Viral RNA migrating as 13S and 11S annealed to Hsu I-G, and 13S RNA annealed to Hsu I-C. A 13S RNA is transcribed from Eco RI-A late in infection (18 h). Hybridization-inhibition studies with Eco RI-A DNA, early cytoplasmic RNA, and 3H-labeled 13S late RNA demonstrated that this RNA synthesized at late times is an early RNA species which continues to be synthesized in large amounts at 18 h. This 13S RNA synthesized at 18 h hybridized to Hsu I-C but not to Hsu I-G DNA. These results establish that the 13S RNAs transcribed from Hsu I-G and C at early times must be different species.

Properties of cells transformed by DNA tumor viruses

Transformation by the papovaviruses, SV40 and polyoma, is reviewed briefly, including factors that affect the frequency of transformation. Virus markers useful in the determination of the etiology of virus-free tumors are described, including viral DNA, viral mRNA, virus-induced antigens, and the rescue of infectious virus. Finally, the evidence that viral genes are involved in the maintenance of transformation is presented.

Simian virus 40 transcription in productively infected and transformed cells

Several independent cell lines transformed by simian virus 40 carry a species of viral RNA of 900,000 to 1,000,000 daltons. A viral RNA species of similar size is found early in the lytic cycle. Late in the viral lytic cycle, two prominent viral RNA species of about 600,000 and 900,000 daltons are seen. The larger late species shares nucleotide sequences with, and is less stable than, the smaller. These RNA species are located in the cytoplasm of the infected cell. The regions of the viral genome coding for these RNA species are mapped by hybridization of lytic RNA species to fragments of the genome produced by cleavage with Haemophilus aegyptius endonuclease.

Control of simian virus 40 gene expression in adenovirus-simian virus 40 hybrid viruses. Synthesis of hybrid adenovirus 2-simian virus 40 RNA molecules in cells infected with a nondefective adenovirus 2-simian virus 40 hybrid virus

The effect of interferon on simian virus 40 (SV40) and adenovirus 2 (Ad2) T antigen synthesis has been examined in cells infected with SV40, with Ad2, and with a nondefective Ad2-SV40 hybrid virus, Ad2(+)ND(4). The induction of SV40 T antigen by SV40 was highly sensitive to interferon, whereas the induction of Ad2 T-antigen by Ad2 was resistant. This difference in interferon sensitivity was also noted in cells simultaneously infected with both viruses. However, the induction of SV40 T antigen by Ad2(+)ND(4), which contains covalently linked SV40 and Ad2 DNAs, was as resistant to interferon as the induction of Ad2 T antigen. This change in the interferon sensitivity of SV40 T antigen synthesis suggests that the expression of at least this portion of the SV40 genetic information in Ad2(+)ND(4) is under Ad2 genetic control. When RNA extracted from Ad2(+)ND(4)-infected cells was examined by means of sequential hybridization with Ad2 DNA, elution, and rehybridization with SV40 DNA, 27% of the SV40-specific RNA was found to be linked to Ad2 RNA. No such linkage was detected in control mixtures of Ad2 and SV40 RNAs. The presence of Ad2 and SV40 nucleotide sequences in the same RNA molecule implies that, in Ad2(+)ND(4) infection, transcription is initiated in the DNA of one virus (Ad2 or SV40) and continues without interruption across the point of junction into the DNA of the other virus. Furthermore, the interferon resistance of Ad2(+)ND(4)-induced SV40 T antigen synthesis suggests that transcription of the genetic information for SV40 T antigen is initiated in a region of Ad2 DNA.

Viruses and evolution

This chapter discusses the role of viruses in nature. Viral transduction of structural and regulatory genes provides a means for information to leave the body of an organism other than through the germ cells. Natural selection acts upon the cell–virus nucleic acid coupling and the rate and direction of the evolution of any species depends upon the number of associated viruses and the extent to and speed with which they allow information to be cycled through the total gene pool of that population. There are three mechanisms by which gene material can be transferred from cell to cell: (1) transformation, (2) transduction, and (3) sexual conjugation. Transformation is the most random and inefficient process; it requires the laws of diffusion and the existing chemistry of the cell membrane, modified in contemporary cells by the development of transport systems, which facilitate membrane penetration. Transduction requires the development of genes for capsomere proteins to encapsidate nucleic acid and a sophistication of the process of membrane evagination to package nucleic acid into free particles, These are relatively modest genetic adaptations. However, true sexual union as it occurs in modern eukaryotes, requires such a high degree of cytological organization that it is inconceivable that it could have operated efficiently during the first billion or so years of cell evolution.

Transcription of simian virus 40. II. Hybridization of RNA extracted from different lines of transformed cells to the separated strands of simian virus 40 DNA

The amount of simian virus 40 (SV40) DNA present in various SV40-transformed mouse cell lines and "revertants" isolated from them was determined. The number of viral DNA copies in the different cell lines ranged from 1.35 to 8.75 copies per diploid quantity of mouse cell DNA and from 2.2 to 14 copies per cell. The revertants had the same number of viral DNA copies per diploid quantity of mouse cell DNA as their parental cell lines. (However, they showed an increased number of viral DNA copies per cell due to their increased amount of DNA.) By using separated strands of SV40 DNA, the extent of each DNA strand transcribed into stable RNA species was determined for the transformed and "revertant" cell lines. From 30 to 80% of the "early" strand and from 0 to 20% of the "late" strand was present as stable RNA species in the cell lines tested. There was no alteration in the pattern of the stable viral RNA species present in three concanavalin A-selected revertants, whereas in a fluorodeoxyuridine-selected revertant there appeared to be less viral-specific RNA present in the cells.

Production of viral mRNA in adenovirus- transformed cells by the post- transcriptional processing of heterogeneous nuclear RNA containing viral and cell sequences

Adenovirus 2-transformed cells contain virus-specific sequences which are covalently linked to cell-specific RNA sequences in heterogeneous nuclear RNA (HnRNA) molecules larger than 45S. Virus sequences are identified by hybridization to viral DNA, and the cell sequences are detected by hybridization to cellular DNA under conditions where hybridization only occurs to reiterated sites in cell DNA. Such large composite viral-cell HnRNA molecules presumably arise through the uninterrupted transcription of host sequences and integrated viral DNA. Adenovirus-specific polysomal RNA from these cells sediments as three discrete species at 16, 20, and 26S. These specific classes of viral mRNA do not contain rapidly hybridizing host-specific RNA sequences. Both virus-specific HnRNA and mRNA contain polyadenylic acid sequences since they bind to polyU columns at levels characteristics of other polyA-terminated HnRNA and mRNA. Thus, the discrete species of virus-specific mRNA in adenovirus 2 transformed cells appear to be derived from high-molecular-weight virus-specific HnRNA through a series of post-transcriptional modifications involving polyA addition. Subsequently the HnRNA is cleaved so that the cell-specific RNA sequences that originate from the reiterated sites in cell DNA do not accompany the adenovirus mRNA to the cytoplasm. These events for the adenovirus-specific mRNA appear, therefore, to be similar to the stages in the biogenesis of the majority of mRNA in eukaryotic cells.

Patterns of simian virus 40 deoxyribonucleic acid transcription. II. In transformed cells

The pattern of simian virus 40 (SV40) deoxyribonucleic acid transcription has been examined in 11 SV40-transformed cell lines. In all cases, substantial regions of the minus strand (35-75%) appeared to be transcribed. In the lines tested, these regions included the "early" gene sequences. The SV40-specific ribonucleic acid from at least two of the transformed cell lines represented significantly greater portions of the minus strand than are represented in "early" lytic ribonucleic acid. Small regions of the plus strand appeared to be transcribed in only two of the transformed cell lines.

Processing of adenovirus RNA before release from isolated nuclei

Nuclei isolated from cultured human cells (KB) infected with adenovirus type-2 were used to study events occurring during the adenosine triphosphate-dependent release of viral RNA. When cells were labeled with [(3)H]uridine for 50 min beginning 18 hr after infection, most nuclear viral messenger RNA was in the form of high molecular weight precursors with sedimentation coefficients greater than 28 S. When nuclei were incubated in the presence of ATP and an ATP-generating system, labeled RNA the size of viral mRNA (10-29 S) was released. Cleavage of viral RNA precursor molecules of high molecular weight occurred during incubation of nuclei. The change in size of viral RNA did not require exogenous ATP and occurred before release of RNA from nuclei. This RNA cleavage seems comparable to processing of mRNA in vivo, for discrete viral species were produced. Cleavage was completed after 10 min of incubation but was not the rate-limiting step in the release reaction, which required about 20 min for completion.

Isolation and characterization of simian virus 40 ribonucleic acid

Deoxyribonucleic acid-ribonucleic acid (RNA) hybridization in formamide was used to isolate simian virus 40-specific RNA. Early in the lytic cycle, a 19S viral RNA species was observed. Late in the lytic cycle, 16S and 19S viral species were found. The 16S and 19S species of viral RNA were localized in the cytoplasm. High-molecular-weight heterogeneous RNA, containing viral sequences, was isolated from the nuclear fraction of infected cells late in the lytic cycle. This RNA may contain non-viral sequences linked to viral sequences. The formamide hybridization technique can be used to isolate intact late lytic viral RNA which is at least 99% pure.

Virus-specific ribonucleic acid in cells producing rous sarcoma virus: detection and characterization

Cells producing Rous sarcoma virus contain virus-specific ribonucleic acid (RNA) which can be identified by hybridization to single-stranded deoxyribonucleic acid (DNA) synthesized with RNA-directed DNA polymerase. Hybridization was detected by either fractionation on hydroxyapatite or hydrolysis with single strand-specific nucleases. Similar results were obtained with both procedures. The hybrids formed between enzymatically synthesized DNA and viral RNA have a high order of thermal stability, with only minor evidence of mismatched nucleotide sequences. Virus-specific RNA is present in both nuclei and cytoplasm of infected cells. This RNA is remarkably heterogeneous in size, including molecules which are probably restricted to the nucleus and which sediment in their native state more rapidly than the viral genome. The nature of the RNA found in cytoplasmic fractions varies from preparation to preparation, but heterogeneous RNA (ca. 4-50S), smaller than the viral genome, is always present in substantial amounts.

The mechanism of viral carcinogenesis by DNA mammalian viruses: RNA transcripts containing viral and highly reiterated cellular base sequences in adenovirus-transformed cells (DNA-RNA hybridization-viral-cell mRNA)

Virus-specific RNA was isolated from cells transformed by human adenovirus 2 and 7 by multiple hybridizations with and elutions from homologous viral DNA; RNA molecules purified by this selection procedure hybridized efficiently with both viral DNA (24-50%) and DNA from untransformed cells (12-27%). Virus-specific RNA isolated in the same manner from cells productively infected with adenoviruses did not hybridize significantly with cellular DNA. These findings suggest that RNA molecules containing covalently-linked viral and cellular sequences are transcribed in cells transformed by human adenoviruses. The high efficiency of hybridization with DNA from untransformed cells implies that viral DNA is integrated adjacent to highly reiterated cellular DNA sequences.

Addition of polyadenylate sequences to virus-specific RNA during adenovirus replication

Adenovirus-specific nuclear and polysomal RNA, both early and late in the infectious cycle, contain a covalently linked region of polyadenylic acid 150-250 nucleotides long. A large proportion of the adenovirus-specific messenger RNA contains poly(A). As revealed by hybridization experiments, the poly(A) is not transcribed from adenovirus DNA. Furthermore, an adenosine analogue, cordycepin, blocks the synthesis of poly(A) and also inhibits the accumulation of adenovirus messenger RNA on polysomes. Addition of poly(A) to viral RNA may involve a host-controlled mechanism that regulates the processing and transport of messenger RNA.