Synthesis of virus-specific ribonucleic acid in KB cells infected with type 2 adenovirus

Cellular splicing and transcription regulatory protein p32 represses adenovirus major late transcription and causes hyperphosphorylation of RNA polymerase II

The cellular protein p32 is a multifunctional protein, which has been shown to interact with a large number of cellular and viral proteins and to regulate several important activities like transcription and RNA splicing. We have previously shown that p32 regulates RNA splicing by binding and inhibiting the essential SR protein ASF/SF2. To determine whether p32 also functions as a regulator of splicing in virus-infected cells, we constructed a recombinant adenovirus expressing p32 under the transcriptional control of an inducible promoter. Much to our surprise the results showed that p32 overexpression effectively blocked mRNA and protein expression from the adenovirus major late transcription unit (MLTU). Interestingly, the p32-mediated inhibition of MLTU transcription was accompanied by an approximately 4.5-fold increase in Ser 5 phosphorylation and an approximately 2-fold increase in Ser 2 phosphorylation of the carboxy-terminal domain (CTD). Further, in p32-overexpressing cells the efficiency of RNA polymerase elongation was reduced approximately twofold, resulting in a decrease in the number of polymerase molecules that reached the end of the major late L1 transcription unit. We further show that p32 stimulates CTD phosphorylation in vitro. The inhibitory effect of p32 on MLTU transcription appears to require the CAAT box element in the major late promoter, suggesting that p32 may become tethered to the MLTU via an interaction with the CAAT box binding transcription factor.

Detection of infectious adenovirus in cell culture by mRNA reverse transcription-PCR

We have developed and evaluated the reverse transcription (RT)-PCR detection of mRNA in cell culture to assay infectious adenoviruses (Ads) by using Ad type 2 (Ad2) and Ad41 as models. Only infectious Ads are detected because they are the only ones able to produce mRNA during replication in cell culture. Three primer sets for RT-PCR amplification of mRNA were evaluated for their sensitivity and specificity: a conserved region of late mRNA transcript encoding a virion structural hexon protein and detecting a wide range of human Ads and two primer sets targeting a region of an early mRNA transcript that specifically detects either Ad2 and Ad5 or Ad40 and Ad41. The mRNAs of infected A549 and Graham 293 cells were recovered from cell lysates with oligo(dT) at different time periods after infection and treated with RNase-free DNase to remove residual contaminating DNA, and then Ad mRNA was detected by RT-PCR assay. The mRNA of Ad2 was detected as early as 6 h after infection at 10(6) infectious units (IU) per cell culture and after longer incubation times at levels as low as 1 to 2 IU per cell culture. The mRNA of Ad41 was detected as soon as 24 h after infection at 10(6) IU per cell culture and at levels as low as 5 IU per cell culture after longer incubation times. To confirm the detection of only infectious viruses, it was shown that no mRNA was detected from Ad2 and Ad41 inactivated by free chlorine or high doses of collimated, monochromatic (254-nm) UV radiation. Detection of Ad2 mRNA exactly coincided with the presence of virus infectivity detected by cytopathogenic effects in cell cultures, but mRNA detection occurred sooner. These results suggest that mRNA detection by RT-PCR assay in inoculated cell cultures is a very sensitive, specific, and rapid method by which to detect infectious Ads in water and other environmental samples.

The structure and function of the adenovirus major late promoter

The adenovirus major late promoter (MLP) has played a pre-eminent role in the analysis of transcription initiation in mammalian cells, and is an outstanding example of the ways in which the study of adenovirus has led to fundamental insights into general cellular processes. The aim of this chapter is to give a comprehensive review of the structure and function of this model mammalian promoter. After a brief description of late transcription in the adenovirus replication cycle, the experimental evidence for the current consensus on the genetic structure of the MLP, including a consideration of non-primate adenovirus MLPs, will be reviewed. Next, the functions of the MLP in the viral life cycle will be examined, and some of the problems that remain to be resolved will be addressed. The review ends with some ideas on how the knowledge of the structure and function of the MLP can be used in designing virus vectors for specific experimental purposes.

A herpesvirus regulatory protein appears to act post-transcriptionally by affecting mRNA processing

Post-transcriptional control mechanisms play an important role in regulating gene expression for a number of viruses, especially in the regulation of late gene products. In this study we have investigated the mode of action of ICP27, an immediate-early regulatory protein of herpes simplex virus 1 (HSV-1) required for late gene expression. Transfection experiments have demonstrated that ICP27 can activate or repress expression depending on the target gene. Here, we show that the regulatory activity of ICP27 is independent of the target gene promoter sequences but, instead, depends on the presence of different mRNA processing signals. The activation function correlated with different polyadenylation sites, whereas the repressor function correlated with the presence of introns either 5' or 3' to the target gene-coding sequences. Poly(A)+ RNA levels were increased by ICP27 in transfections with a target gene having only an AATAAA recognition signal but no G/U box within the usual distance. In contrast, in the presence of ICP27, spliced target mRNAs were decreased 5- to 10-fold in transfections with target genes containing a 5' or 3' intron. These results suggest that this essential HSV-1 regulatory protein acts post-transcriptionally to affect mRNA processing and point to possible interactions between splicing and polyadenylation factors.

Adenovirus inhibition of cellular protein synthesis is prevented by the drug 2-aminopurine

Adenovirus infection results in the suppression of cellular protein synthesis, but the mechanism has not been established. In this report we demonstrate that the shut-off of cellular protein synthesis by adenovirus is prevented in cells by treatment with the drug 2-aminopurine. Treatment with 2-aminopurine is shown to prevent suppression of cellular translation without disrupting the normal viral block in the transport of cellular mRNAs from the nucleus to the cytoplasm. We show that viral suppression of cellular protein synthesis occurs concomitant with activation of the interferon-induced double-stranded RNA-activated inhibitor (DAI), a protein kinase, and phosphorylation of the alpha subunit of eukaryotic initiation factor 2 (eIF-2 alpha), but that prevention of host cell shut-off by 2-aminopurine occurs without a decrease in kinase activity or a dephosphorylation of eIF-2 alpha. Results are presented that indicate that activation of DAI kinase and phosphorylation of eIF-2 alpha may be required but are not sufficient to achieve inhibition of cellular protein synthesis during adenovirus infection. We suggest that other events, in particular the modification of additional initiation factors, are likely involved in viral inhibition of cellular translation.

Regulation of poly(A) site selection in adenovirus

We have investigated the mechanisms involved in the early-to-late RNA-processing switch which regulates the mRNA species generated from the adenovirus major late transcription unit (MLTU). In particular, polyadenylation choice mechanisms were characterized by using a reconstructed adenovirus E1A gene as a site for insertion of MLTU poly(A) regulation signals (L1 and L3). Adenovirus constructs containing the variant poly(A) recognition elements were used to compare E1A poly(A) signal utilization with wild-type MLTU (L1 to L5) utilization. In both early and late stages of infection, either polyadenylation site (L1 or L3) is capable of being utilized when presented as the only operational poly(A) site. In an early infection, a virus which contains multiple elements presented in tandem (L13) uses the first poly(A) site, L1, preferentially (ratio of L1 to L3, 8:1) in both E1A and MLTU loci. Transcription termination is not involved in restricting the utilization of the downstream L3 site. In a late infection, when each of the five MLTU poly(A) sites is used, a switch also occurs for the E1AL13 construct, with utilization of both the L1 and L3 poly(A) sites. The switch from early to late was not the result of altered processing factors in the late infection, as demonstrated by superinfecting the E1AL13 construct into cells which had already entered a late stage of infection. The superinfecting virus gave an L1-only phenotype; therefore, a cis mechanism is involved in adenovirus poly(A) regulation.

In vitro synthesis of late bacteriophage phi 29 RNA

A crude P-100 fraction prepared from Bacillus subtilis 21 min after infection with wild-type phage phi 29 supported the in vitro synthesis of late phi 29 RNA by added RNA polymerase. Synthesis of late RNA was also detected when purified phi 29 DNA was transcribed by RNA polymerase in the presence of an S-150 fraction obtained by lysis of phi 29-infected cells in the presence of 1 M NaCl. Late phi 29 RNA was not synthesized when either the P-100 or the S-150 fraction was prepared from cultures infected with phi 29 having a mutation in gene 4.

Characterization of a temperature-sensitive fiber mutant of type 5 adenovirus and effect of the mutation on virion assembly

A temperature-sensitive, fiber-minus mutant of type 5 adenovirus, H5ts142, was biochemically and genetically characterized. Genetic studies revealed that H5ts142 was a member of one of the three apparent fiber complementation groups which were detected owing to intracistronic complementation. Recombination analyses showed that it occupied a unique locus at the right end of the adenovirus genetic map. At the nonpermissive temperature, the mutant made stable polypeptides, but they were not glycosylated like wild-type fiber polypeptides. Sedimentation studies of extracts of H5ts142-infected cells cultured and labeled at 39.5 degrees C indicated that a limited number of the fiber polypeptides made at the nonpermissive temperature could assemble into a form having a sedimentation value of 6S (i.e., similar to the trimeric wild-type fiber), but that this 6S structure was not immunologically reactive. When H5ts142-infected cells were shifted to the permissive temperature, 32 degrees C, fiber polypeptides synthesized at 39.5 degrees C were as capable of being assembled into virions as fibers synthesized in wild type-infected cells; de novo protein synthesis was not required to allow this virion assembly. In H5ts142-infected cells incubated at 39.5 degrees C, viral proteins accumulated and aggregated into particles having physical characteristics of empty capsids. These particles did not contain DNA or its associated core proteins. However, when the infected culture was shifted to 32 degrees C, DNA appeared to enter the empty particles and complete virions developed. The intermediate particles obtained had the morphology of adenoviruses, but they contained less than unit-length viral genomes as measured by their buoyant density in a CsCl density gradient and the size of their DNA as determined in both neutral and alkaline sucrose gradients. The reduced size of the intermediate particle DNA was demonstrated to be the result of incompletely packaged DNA molecules being fragmented during the preparative procedures. Hybridization of labeled DNA extracted from the intermediate particles to filters containing restriction fragments of the adenovirus genome indicated that the molecular left end of the viral genome preferentially entered these particles.

Herpes simplex virus-induced changes in cellular and adenovirus RNA metabolism in an adenovirus type 5-transformed human cell line

We used the viral transcripts (designated Ad-RNA) that accumulated in the cytoplasm of adenovirus type 5-transformed human embryonic kidney cells (cell line 291-31) as models for cellular RNAs to examine how herpes simplex virus modifies cellular RNA metabolism. Infection of 293-31 cells with herpes simplex virus type 1 strain 17 lead to extensive inhibition of Ad-RNA accumulation by 4 h postinfection. The major part of this inhibition was due to an immediate early or alpha gene function, which reduced the rate of transcription of Ad-RNA within the nuclei of the infected cells. In addition, host polyadenylic acid-containing RNA accumulation and rRNA accumulation were affected, but to a lesser extent and at lower rate than Ad-RNA accumulation. In conjunction with previous data, our experimental data allowed us to propose a general scheme for how herpes simplex virus type 1 alters the metabolism of cellular RNA, the possible mechanisms for these changes, and how they correlate with the regulation of herpes simplex virus gene expression.

Control of adenovirus early gene expression: a class of immediate early products

We have identified the viral mRNAs present in cells in which protein synthesis has been stringently inhibited prior to infection with adenovirus type 2. These species presumably represent the subset of viral mRNAs that are "immediate early" products, requiring only host cell genes of their expression, and they do not include any of the conventionally recognized early mRNAs. Treatment of cells with 100 microM anisomycin inhibits 99.6% of protein synthesis and substantially depresses (by 20--200 fold) the levels of the conventional early mRNAs from regions E1A, E1B, E2, E3 and E4. Also depressed are species encoding an 87K protein (11.6--31.5 map units) and a 13.6K protein (encoded a short distance to the right of 21.5 map units). The only mRNAs not depressed by this treatment are an mRNA for a 13.5K protein encoded between 17.0 and 21.5 map units, and the mRNA for the late 52,55K protein encoded between 29 and 34 map units, which is also present in small amounts at early times. Further proof that production of the mRNA for the immediate early 13.5K protein is independent of E1A gene function is provided by the observation that it can be detected in cells infected with the E1A deletion mutant dl312.

Vero cells injected with adenovirus type 2 mRNA produce authentic viral polypeptide patterns: early mRNA promotes growth of adenovirus-associated virus

Adenovirus type 2 mRNAs were injected via glass capillaries into Vero cells, a line of African green monkey kidney cells permissive for adenovirus growth. Polypeptides synthesized after injection were labeled with 35S-labeled amino acids, precipitated with antiviral sera, and analyzed by polyacrylamide gel electrophoresis. Both early and late viral mRNAs give rise to authentic polypeptides. The in vivo translation of mRNAs can be measured as late as 24 hr after injection. The ability to analyze the protein products of microinjected mRNAs directly should greatly extend the applications of the procedure. Vero cells injected with early mRNA from adenovirus type 2 support the growth of adenovirus-associated virus, a defective virus that is dependent on adenovirus helper functions. This result demonstrates that a measurable biological activity, the ability to overcome the defectiveness of adenovirus-associated virus, resides in early adenovirus mRNA.

Adenovirus DNA template for late transcription is not a replicative intermediate

The relationship between adenovirus replication and late transcription has been investigated using viral replication and transcription complexes isolated from infected HeLa cell nuclei. These two types of complexes extracted from adenovirus type 2-infected cell nuclei did not sediment at the same rate on sucrose gradients. Viral replicative intermediates were quantitatively precipitated by immunoglobulins raised against purified 72,000-dalton DNA-binding protein, whereas viral transcription complexes remained in the supernatant. These results show that late transcription does not occur on active replication complexes or on 72,000-dalton DNA-binding protein-containing replicative intermediates inactive in DNA synthesis. Additional evidence is presented indicating that it is very unlikely that replicative intermediates lacking the 72,000-dalton DNA-binding protein could be the template for late transcription.

Autoregulation of adenovirus type 5 early gene expression II. Effect of temperature-sensitive early mutations on virus RNA accumulation

The kinetics of accumulation of early virus RNA in the cytoplasm of KB cells infected at 40.5 degrees C by wild-type (WT) adenovirus type 5 and a temperature-sensitive "early" mutant, H5ts125 (ts125), were compared by hybridization of unlabeled RNA in solution to the (3)H-labeled l strand of Ad5 DNA HindIII restriction endonuclease fragment A. In the presence of 1-beta-d-arabinofuranosylcytosine, A(l) RNA accumulated in WT-infected cells for 9 h and then decreased in concentration to 6% of the 9-h concentration by 18 h. In ts125-infected cells, A(l) RNA accumulated for 12 h and then remained at the same concentration for at least 6 h thereafter. The concentrations of virus RNA from the four early transcription regions of the genome were measured at 15 h in cells infected at 40.5 degrees C in the presence of 1-beta-d-arabinofuranosylcytosine by: (i) ts125 and WT; (ii) two other ts early mutants, ts107 and ts149; and (iii) a revertant of ts125. The revertant and ts149, a mutant from a different complementation group than ts125, both accumulated all early virus cytoplasmic RNA species in amounts similar to, or less than, WT. However, both ts125 and ts107, independently isolated mutations in the 72,000-molecular-weight (72K) DNA-binding protein gene, accumulated cytoplasmic early RNA in excess of that found in WT infection. This pattern of RNA accumulation with the mutants and WT virus was the same in the nuclei as in the cytoplasm at 40.5 degrees C. At 32 degrees C, however, the abundance of nuclear virus RNA from all four early regions was the same in cells infected by either ts125 or WT. Differences in the relative abundance of nuclear RNA from the four early regions were observed in cells infected at 40.5 and 32 degrees C, but were not dependent upon the infecting virus genotype. These results are consistent with autoregulation of early gene expression by the 72K protein and support the hypothesis that the 72K protein either decreases the rate of early virus transcription or increases the rate of virus RNA degradation in the nucleus.

Transcription of adenovirus RNA in permissive and nonpermissive infections

The mechanism of blocked replication of human adenoviruses in monkey cells was examined. Previous experiments have placed the replicative block at the level of transcription of translation of adenovirus mRNA. Coinfection of the monkey cells with simian virus 40 enhances adenovirus replication in these cells. We compared the adenovirus mRNA transcribed during infection of permissive human cells and enhanced and unenhanced monkey cells. Adenovirus mRNA from enhanced monkey cells appeared to be identical to adenovirus mRNA from human cells. This indicated that simian virus 40 coinfection did not overcome the blocked replication by substituting for a missing adenovirus transcript. Comparison of adenovirus mRNA from enhanced and unenhanced monkey cell infection revealed two types of transcriptional discrepancies. There was a decrease in both the complexity and the relative abundance of several regions of the enhanced adenovirus mRNA. However, neigher of these transcriptional defects was sufficient to totally explain the difference in yield of infectious virus and viral protein seen in these two types of infection.

Macromolecular synthesis in cells infected by frog virus 3. VII. Transcriptional and post-transcriptional regulation of virus gene expression

We have used improved techniques for separating individual species of RNA and protein to study the mechanisms that control gene expression by frog virus 3, a eucaryotic DNA virus. Forty-seven species of viral RNA and 35 viral polypeptide species were resolved by polyacrylamide gel electrophoresis. The relative molar ratios of virus-specific polypeptides synthesized at various times after infection were determined by computer planimetry and were compared with the molar ratios of appropriate-sized viral RNAs to code for each polypeptide. Viral polypeptides were classified according to the time during the growth cycle at which their maximal rate of synthesis occurred - early, 2 to 2.5 h; intermediate, 4 to 4.5 h; and late, 6 to 6.5 h. The viral RNAs, which were assumed to be mRNA's, could not be classified according to time of maximum synthesis; once their synthesis had begun, most of the RNAs continued to be synthesized at the same or higher rates. However, only 10 of the 47 viral RNA bands were plainly visible after electrophoresis of extracts from cells labeled from 1 to 1.5 h after infection; these 10 RNAs were designated "early" RNA. The early pattern of both RNA and polypeptide synthesis was maintained for at least 6 h in the presence of the amino acid analog fluorophenylalanine, which indicates that a functional viral polypeptide was required for "late" transcription and translation. The presumptive mRNA's for late polypeptides did not appear until 2 h after infection, but two of these "late" RNAs became the major products of transcription by 4 h into the infectious cycle. In contrast to the declining rate of synthesis of the early proteins, corresponding early RNA species continued to be synthesized at the same or higher rates throughout the replicative cycle. Although the synthesis of late virus-specific proteins appeared to be regulated at the level of transcription, our results suggest that the synthesis of both early and intermediate proteins was regulated at the post-transcriptional level.

Species identification and genome mapping of cytoplasmic adenovirus type 2 RNAs synthesized late in infection

Adenovirus type 2 cytoplasmic RNAs synthesized late in productive infection were resolved by electrophoresis on formamide gels. Regions of the adenovirus 2 genome specifying RNAs of distinct size were determined by hybridization to specific DNA fragments generated by cleavage with endo R.EcoRI and endo R.SmaI. From these studies 13 distinct viral RNA species were identified. A 26S to 28S size class and a 21S to 23S size class were each found to consist of four distinct RNA species. Three RNA species were identified in a 16S to 18S size class, and a fourth size class, 11S to 13S, was resolved into two components. The SmaI-D region (0.38 to 0.51 on the unit genome) and the EcoRI-F, D region (0.70 to 0.83) of the genome were found to code for multiple transcripts. Three RNAs (28S, 22S, and 18S) are specified by SmaI-D, and four components, 28S, 22S, 18S, and 16S, are encoded by EcoRI-F,D. The RNA represented by each set of multiple transcripts exceeds the coding capacity of the respective region, and the species within each set of RNAs appear to contain common sequences. The relationship between the cytoplasmic RNA species synthesized at late times and early cytoplasmic RNAs was determined by hybridization-inhibition experiments. The multiple transcripts encoded by the EcoRI-D fragment were found to contain sequences that are present in early cytoplasmic RNA. These studies enabled preparation of a map which accounts for transcription of approximately 67% of the r strand of the adenovirus 2 genome.

Transcription of the genome of adenovirus type 12. IV. Maps of stable late RNA from productively infected human cells

From human KB cells productively infected with adenovirus type 12, mRNA and stable nuclear RNA were isolated late (42 h) after infection. Using restriction endonuclease fragments of adenovirus type 12 DNA, mRNA and stable nuclear RNA sequences were mapped on the viral genome. Late after infection, preferentially the r (= rightward) strand is transcribed into stable nuclear RNA, whereas the l (= leftward) strand is expressed only to a minor extent. Adenovirus type 12-specific mRNA originates from the following sections on the viral genome: 0 to 0.11, 0.18 to 0.20, 0.27 to 0.49, 0.56 to 0.63, 0.68 to 0.84, and 0.89 to 0.92 fractional length units on the r strand and 0.11 to 0.16, 0.22 to 0.27, 0.50 to 0.54, 0.62 to 0.66, 0.855 to 0.865, and 0.93 to 1.0 fractional length units on the l strand. Self-complementary viral RNA isolated at 42 h postinfection anneals to 70 to 80% of each strand of the viral genome.

Immunofluorescence study of the adenovirus type 2 single-stranded DNA binding protein in infected and transformed cells

High-titer monospecific antiserum against highly purified adenovirus 2 (Ad2) single-stranded DNA binding protein (DBP) was used to study, by indirect immunofluorescence (IF), the synthesis of DBP in Ad2-infected human cells and adenovirus-transformed rat, hamster, and human cell lines. In infected cells the synthesis of DBP was first detected in the cytoplasm at 2 to 4 h postinfection and reached a maximum intensity at 6 h postinfection. At this time DBP began to accumulate in the nucleus, where it reached maximum intensity at about 14 h postinfection. The cytoplasmic IF was diffuse, whereas nuclear IF appeared as dots that coalesced into large globules as infection progressed. In cells treated with 1-beta-d-arabinofuranosylcytosine to inhibit viral DNA synthesis, strong nuclear IF was observed in the form of dots, but the large fluorescent globules were not observed. The Ad2 (oncogenic group C) anti-DBP serum reacted very strongly by IF with Ad5 (group C)-infected, to a lesser extent with Ad7 and Ad11 (group B)-infected, and weakly with Ad12 and Ad18 (group A)-infected KB cells (treated with 1-beta-d-arabinofuranosylcytosine). These results may indicate that Ad2 DBP is closely related immunologically to DBPs induced early after infection by adenovirus serotypes in oncogenic group C, moderately related to DBPs of serotypes in oncogenic group B, and perhaps distantly related to DBPs of serotypes in oncogenic group A. The following adenovirus-transformed cell lines were examined for DBP synthesis by IF with the Ad2 anti-DBP serum: six rat cell lines (T2C4, F17, 8662, 8638, 8617, and F161) transformed by Ad2 virus, three hamster cell lines transformed by Ad2 virus (Ad2HT1) and Ad2-simian virus 40 hybrid virus (ND1HK1 and ND4HK4), and one rat (5RK) and one human (293-31) cell line transformed by transfection with Ad5 DNA. T2C4 and 8662 appeared weakly positive, whereas Ad2HT1 and ND4HK1 were strongly positive. The other transformed cell lines did not produce DBP detectable by IF. Thus, some but not all transformed cell lines produce DBP, which indicates that DBP is not required for maintenance of cell transformation and that transformed cells can express "nontransforming" viral genes as protein.

Adenovirus type 2 nuclear RNA accumulating during productive infection

The viral-specific nuclear RNA which accumulates early and late during productive infection of HeLa cells by adenovirus-type 2 (Ad2) has been characterized with respect to its size and stability after denaturation by Me2SO. Early nuclear transcripts, under nondenaturing conditions, sediment in the range 28 to 45S, but treatment with Me2SO prior to sedimentation results in a shift to about 20S. Later nuclear RNA accumulates as a composite of two populations of molecules: one with a broad size distribution centering on 45S under nondenaturing conditions and less than 32S after denaturation and a second having a narrow size distribution around 35S which is quite stable to Me2SO. Analysis of late RNA by hybridization to Sma fragments of Ad2 DNA suggests that the 35S RNA species is derived from a limited portion of the left half of the viral genome.

Electron microscopy of late adenovirus type 2 mRNA hybridized to double-stranded viral DNA

R loops were generated with late adenovirus type 2 (Ad2) mRNA in double-stranded viral DNA, and visualized by electron microscopy. Unpaired DNA sequences in Ad2:Ad2+ND4 heteroduplex DNA served as a visual marker for the orientation of R loops with respect to the conventional DNA map. The most abundant classes of late Ad2 mRNA observed by this technique hybridized, in order of R-loop frequency, with midpoints near posit1ons 0.57, 0.88, 0.77, and 0.40 to 0.50 of the DNA map. The R loop at position 0.57, 0.88, 0.77, and 0.40 containing the hexon gene; the one at position 0.88 corresponded to a region containing the fiber gene. The relative frequencies of these two R loops paralleled those of the encoded gene products. The mRNA sizes, calculated from those of the respective R loops, were slightly larger than needed to code for these polypeptides. Using the R-loop technique, two locations at which adjacent mRNA's hybridized to different strands were accurately mapped at positions 0.61 and 0.91 of the DNA. The map positions of late Ad2 mRNA correlated well to published RNA and protein maps.

Transcription of the genome of adenovirus type 12. III. Maps of stable RNA from productively infected human cells and abortively infected and transformed hamster cells

The adenovirus type 12-specific mRNA and the stable nuclear RNA from productively infected KB cells, early postinfection, from abortively infected BHK-21 cells, and from the adenovirus type 12-transformed hamster lines T637 and HA12/7 have been mapped on the genome of adenovirus type 12. The intact separated heavy (H) and light (L) strands of adenovirus type 12 DNA have been used to determine the extent of complementarity of the mRNA or nuclear RNA from different cell lines to each of the strands. More precise map positions have been obtained by the use of the H and L complements of the fragments of adenovirus type 12 DNA which were produced with the EcoRI and BamHI restriction endonucleases. The results of the mapping experiments demonstrate that the mRNA's isolated early from productively and abortively infected and from two lines of transformed cells are derived from the same or similar regions of the adenovirus type 12 genome. The map positions on the adenovirus type 12 genome for the mRNA from the cell lines as indicated correspond to regions located approximately between 0 and 0.1 and 0.74 and 0.88 fractional length units on the L strand and to regions between 0.63 and 0.74 and 0.89 and 1.0 fractional length units on the H strand. The HA12/7 line lacks mRNA complementary to the region between 0.74 and 0.88 fractional length units on the L strand. Similar data are found for the nuclear RNA, except that the regions transcribed are more extensive than those observed in mRNA. The polarity of the H strand has its 3'-end on the right terminus in the EcoRI A fragment, and the L strand has its 3'-end on the left terminus in the EcoRI C fragment. Thus, the H strand is transcribed from right to left (1 = leftward strand); and the L strand is transcribed from left to right (r = rightward strand). The designations H and L refer to the relative heavy and light densities of the two strands in polyuridylic-polyguanylic acid-CsCl density gradients. The EcoRI C-H and D-H complements have been shown to be part of the intact L strand; thus, there is a "reversal in heaviness" on the left terminus of the viral DNA.

Genome expression and mRNA maturation at late stages of productive adenovirus type 2 infection

RNA from adenovirus 2-infected KB cells was annealed in liquid with RNA in vast excess to viral heavy (l) and light (r) 32P-labeled DNA strands. Hybridization kinetics were analyzed by computer to estimate the number of viral RNA abundance classes, their relative concentrations, and the fraction of each DNA strand from which they originated. Early whole cell RNA extracted 5 h postinfection annealed rapidly to 10 to 15% of l and r strands and then slowly to final values of 60 and 40% of l and r strands. By 9 h postinfection the expression of late genes was apparent and whole cell RNA annealed to 20 and 75% of l and r strands. Whole cell RNA extracted between 12 and 36 h postinfection annealed to 7 to 15% and 75 to 90% of l and r strands. Late nuclear RNA hybridized to 10 and 90% of l and r strands, and late polyribosomal RNA hybridized to 20 and 75% of l and r strands. Based upon kinetic analyses, we estimate that mRNA synthesized exclusively during late stages arises from about 6 to 8% and 45 to 49% of l and r strands. This assumes that the early class I mRNA (in low concentration late) originates from 8 to 10% and 6 to 10% of l and r strands and that early class II mRNA (in high concentration late) is derived from 2% and 8 to 13% of l and r strands. Mixing experiments indicated that early mRNA is a subset of RNA extracted from polyribosomes late after infection and that late nuclear RNA contains sequences complementary to early l strand class I nRNA. RNA-RNA hybrids were isolated from late mRNA containing sequences from 60% of l and r strands, but it is not known when these were synthesized, and therefore whether complementary RNA transcripts are synthesized late after infection, as they are known to be synthesized early. These results demonstrate that portions of the genome are transcribed into RNA sequences that remain confined to the nucleus and are not exported to polyribosomes as mRNA.

Adenovirus type 12-specific RNA sequences during productive infection of KB cells

The complementary strands of adenovirus type 12 DNA were separated, and virus-specific RNA was analyzed by saturation hybridization in solution. Late during infection whole cell RNA hybridized to 75% of the light (1) strand and 15% of the heavy (H) strand, whereas cytoplasmic RNA hybridized to 65% of the 1 strand and 15% of the h strand. Late nuclear RNA hybridized to about 90% of the 1 strand and at least 36% of the h strand. Double-stranded RNA was isolated from infected cells late after infection, which annealed to greater than 30% of each of the two complementary DNA strands. Early whole cell RNA hybridized to 45 to 50% of the 1 strand and 15% of the h strand, whereas early cytoplasmic RNA hybridized to about 15% of each of the complementary strands. All early cytoplasmic sequences were present in the cytoplasm at late times.

Synthesis of the adenovirus-coded DNA binding protein in infected cells

Synthesis of the 75K (75K indicates a moleculatr weight of 70,000 to 75,000) DNA binding protein, an early virus-coded protein in adenovirus 2-infected KB cells, and its regulation were studied by using a radioimmune precipitation inhibition assay. The protein was first detected at 4 h postinfection and accumulated at an expoential rate. An arrest of further synthesis (accumulation) was observed at 10 to 11 h postinfection, coinciding with the onset of synthesis of late virion proteins. In contrast, when the infected cells were treated with 25 mug of arabinosyl cytosine per ml to block viral DNA replication, the synthesis of 75K protein did not cease but continue for up to 36 h postinfection. The synthesis of 75K protein in cells after release from a cycloheximide block (2 to 9 h postinfection) was analyzed. Increased amounts of early adenovirus-specific mRNA accumulate in infected cells during a cycloheximide block (Parsons and Green, 1971). However, cycloheximide treatment did not produce increased levels of 75K protein, and an abrupt arrest of 75K protein formation was again observed at the time of synthesis of late virion proteins. Partition of the 75K protein between the nuclear and cytoplasmic fractions during the course of infection was studied. The 75K protein appeared first in the cytoplasm and then in the nucleus after a slight lag. Accumulation of the 75K protein continued both in the cytoplasm and nucleus, with higher levels being found in the cytoplasm.

Viral transcription in KB cells infected by temperature-sensitive "early" mutants of adenovirus type 5

RNA:DNA hybridization was used to study the synthesis of viral RNA in two DNA-minus, temperature-sensitive mutants of type 5 adenovirus (H5ts125 and H5ts149) belonging to two different, non-overlapping complementation groups. Hybridization competition analysis showed that both mutants transcribed all early gene sequences at the restrictive temperature (41 C). In mutant-infected cells at 41 C, the rate of viral transcription was similar to the rate of early RNA synthesis in wild-type virus infection and was dependent on the multiplicity of infection; little or no late transcription was detected. The shutoff of class I early RNA transcription was shown to be a late function during wild-type virus infection and did not occur at 41 C in mutant-infected cells. When mutant-infected cells were incubated at the permissive temperature (32 C) for 25 h and then shifted to 41 C, the rate of viral DNA synthesis decreased rapidly for H5ts125 and slowly for H5ts149. However, the rate of viral transcription remained unchanged in H5ts125-infected cells for at least 3 h after the temperature shift; although the synthesis of viral DNA had stopped by this time, the synthesis of late viral RNA sequences continued.

Viral RNA synthesis and levels of DNA-dependent RNA polymerases during replication of adenovirus 2

The rates of RNA synthesis in cultured human KB cells infected by adenovirus 2 were estimated by measuring the endogenous RNA polymerase activities in isolated nuclei. The fungal toxin alpha-amanitin was used to determine the relative and absolute levels of RNA polymerases I, II, and III in nuclei isolated during the course of infection. Whereas the level of endogenous RNA polymerase I activity in nuclei from infected cells remained constant relative to the level in nuclei from mock-infected cells, the endogenous RNA polymerase II and III activities each increased about 10-fold. These increases in endogenous RNA polymerase activities were accompanied by concomitant increases in the rates of synthesis in isolated nuclei of viral mRNA precursor, which was quantitated by electrophoretic analysis on polyacrylamide gels. The cellular RNA polymerase levels were measured with exogenous templates after solubilization and chromatographic resolution of the enzymes on DEAE-Sephadex, using procedures in which no losses of activity were apparent. In contrast to the endogenous RNA polymerase activities in isolated nuclei, the cellular levels of the solubilized class I, II, and III RNA polymerases remained constant throughout the course of the infection. Furthermore, no differences were detected in the chromatographic properties of the RNA polymerases obtained from infected or control mock-infected cells. These observations suggest that the increases in endogenous RNA polymerase activities in isolated nuclei are not due to variations in the cellular concentrations of the enzymes. Instead, it is likely that the increased endogenous enzyme activities result from either the large amounts of viral DNA template available as a consequence of viral replication of from replication or from functional modifications of the RNA polymerases or from a combination of these effects.

Transcription of the genome of adenovirus type 12. Viral mRNA in productively infected KB cells

In human KB cells productively infected with adenovirus type 12, viral DNA replication starts between 12 and 14h postinfection. Virus-specific, polysome-associated mRNA was investigated early (6-8h) and late (26-28h) after infection. Most of the viral mRNA was polyadenylated and accounted for 0.46% and 24.1% of the mRNA synthesized early and late postinfection, respectively. The viral-specific mRNA isolated both early and late after infection falls into several distinct size-classes, ranging in molecular weights between 0.3X10(6) and 1.5X10(6) for the early RNA and between 0.6X10(6) and 2.3X10(6) for the RNA synthesized late in the infection.

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.

Analysis of early adenovirus 2 RNA using Eco R-R1 viral DNA fragments

Adenovirus 2 RNA synthesized early in productive infection was analyzed by RNA-DNA hybridization. Hybridization experiments were performed with adenovirus 2 DNA and wit, the six adenovirus 2 DNA fragments generated 0y digestion with the restriction endonuclease Eco R.R1. Duplex formation between RNA and -32P-labeled viral DNA was assayed by S(1) nuclease digestion. RNA from the cytoplasm annealed 12 percent of the total viral DNA and the following percentage of each of the R.R1 fragments: 6 percent of R1-A, 24 percent of R1-B, 0 percent of R1-F, 40 percent of R1-D, 13 percent of R1-E, and 22 percent of R1-C. The early cytoplasmic RNA is composed of two sequence classes: class I, present in greatly reduced quantities at late times in infection (18 h), and class II, which remains at high concentrations at 18 h. In hybridization-inhibition experiments, hybridization of class II RNA is inhibited by late cytoplasmic RNA, whereas hybridization of class I RNA is not blocked by late cytoplasmic RNA (J. J. Lucas and H. S. Ginsberg, 1971; E.A. Craig and H. J. Raskas, 1971). To determine the location of class I and II sequences on the genome, membrane bound DNA fragments were used in hybridization-inhibition experiments. These studies demonstrated that the early cytoplasmic transcripts of R1-D belong to class II, whereas R1-C transcripts are class I sequences. The cytoplasmic RNAs transcribed from fragments A and B contain both class I and class II sequences. Analysis of cytoplasmic RNA fractionated by size demonstrated that the class I sequences include a 19 S RNA transcribed from R1-B and class II sequences include a 20S RNA derived from R1-D. Nuclear RNA purified from cultures early in infection was annealed with -32P-labeled R1 fragments. With all six fragments the nuclear RNA annealed as much or more of the DNA than did cytoplasmic RNA. Eco R1-F annealed at least 25 percent with early nuclear RNA, whereas no sequences homologous to R1-F were detected in early cytoplasmic RNA. When cultures were labeled from 2 to 6 h after infection, at least 5 percent of the -3H-labeled early nuclear viral RNA annealed to Eco R1-F. Some of these nuclear transcripts from R1-F appear to be covalently linked to sequences transcribed from a contiguous region of the genome (Eco R1-B). 8.4 percent of the RNA selected by hybridization of R1-F reannealed to R1-B, whereas no more than 1.5 percent reannealed to R1 fragments A, D, E, or C.

Sequence relationships between adenovirus 2 early RNA and viral RNA size classes synthesized at 18 hours after infection

Synthesis of cytoplasmic viral RNA was studied during infection of cultured human (KB) cells with adenovirus 2. At 6 h, before viral DNA synthesis began 5% of the poly(A)-containing RNA hybridized to viral DNA; by 12 h and at later times more than 80% was virus specified. At 18 h after infection, four major size classes of cytoplasmic viral RNA were identified among the poly(A)-containing molecules. These size classes migrated as 27S, 24S, 19S, and 12 to 15S in polyacrylamide gels. The three larger size classes could also be identified in denaturing formamide gels. Hybridization of the 27S, 24S, and 19S viral RNAs was not inhibited by RNA harvested from cells at early times in infection. Therefore, these three major RNAs must code for late viral proteins. Hybridization of the 12 to 15S RNA was partially inhibited by RNA from cultures harvested at early times, suggesting that in this size class some of the RNA labeled at 18 h codes for early viral proteins.

Transcription of the genome of adenovirus type 12. I. Viral mRNA in abortively infected and transformed cells

In baby hamster kidney (BKH-21) cells abortively infected with adenovirus type 12, polysome-associated, virus-specific RNA could be detected starting 5 to 7 h after infection. The amount of this RNA reached a maximum between 10 to 12 h after infection and continued to be synthesized at a reduced level until late in infection (48 to 50 h.). In BHK-21 cells transformed by adenovirus type 12 (HB cells), 0.26% of the polysome-associated mRNA was virus specific. The size of the virus-specific mRNA isolated from polysomes of BHK-21 cells abortively infected with, or transformed by adenovirus type 12 was determined by electrophoresis in polyacrylamide gels in 98% formamide, i.e., under conditions which eliminated secondary structure or aggregation of RNA. In abortively infected hamster cells viral mRNA size classes of molecular weights 0.9 times 10-6 and 0.65 times 10-6 to 0.67 times 10-6 were predominant. A minor fraction of 1.5 times 10-6 daltons was consistently found and increased with time after infection. Late after infection (24 to 26 h), viral mRNA of 1.9 times 10-6 daltons was also observed. The size distribution of adenovirus type 12-specific mRNA from transformed hamster cells (HB line) was very similar to that in abortively infected cells, except that the relative amount of the viral mRNA fraction of 1.5 times 10-6 daltons was much higher. It is uncertain whether the viral mRNA of high-molecular-weight represents mixed transcripts derived from integrated viral genomes and adjacent host genes.