Further mapping of late adenovirus genes by cell-free translation of RNA selected by hybridization to specific DNA fragments

From Recoding to Peptides for MHC Class I Immune Display: Enriching Viral Expression, Virus Vulnerability and Virus Evasion

Many viruses, especially RNA viruses, utilize programmed ribosomal frameshifting and/or stop codon readthrough in their expression, and in the decoding of a few a UGA is dynamically redefined to specify selenocysteine. This recoding can effectively increase viral coding capacity and generate a set ratio of products with the same N-terminal domain(s) but different C-terminal domains. Recoding can also be regulatory or generate a product with the non-universal 21st directly encoded amino acid. Selection for translation speed in the expression of many viruses at the expense of fidelity creates host immune defensive opportunities. In contrast to host opportunism, certain viruses, including some persistent viruses, utilize recoding or adventitious frameshifting as part of their strategy to evade an immune response or specific drugs. Several instances of recoding in small intensively studied viruses escaped detection for many years and their identification resolved dilemmas. The fundamental importance of ribosome ratcheting is consistent with the initial strong view of invariant triplet decoding which however did not foresee the possibility of transitory anticodon:codon dissociation. Deep level dynamics and structural understanding of recoding is underway, and a high level structure relevant to the frameshifting required for expression of the SARS CoV-2 genome has just been determined.

Distribution of viral RNA molecules during the adenovirus type 5 infectious cycle in HeLa cells

Viral RNA was localized ultrastructurally by in situ hybridization with a biotinylated viral DNA probe and colloidal gold label in HeLa cells during infection with adenovirus type 5. Transcription was monitored by high-resolution autoradiography after short pulses with tritiated uridine. At the earliest stage of virus-induced nuclear transformation, viral RNA was restricted to the small compact fibrillar "early replicative sites" which we had previously demonstrated to be the site of viral DNA replication (Puvion-Dutilleul and Puvion, 1990b). Protease-DNase-treated sections revealed that these fibrillar masses rapidly enlarged and gave rise to a juxtaposed loose fibrillogranular structure devoid of viral RNA. Subsequently, the function of the compact fibrillar zones changed to become the sites of accumulation of single-stranded (ss) viral DNA molecules, and the contiguous new fibrillogranular zones (previously named the peripheral replicative zones, Puvion-Dutilleul and Puvion, 1990a) became not only the centers of replicating viral double-stranded DNA but also the only sites of viral RNA molecules including the elongating RNA transcripts. Pulse-chase experiments revealed an unexpected accumulation of RNA molecules in these extranucleolar regions of infected nuclei.

Isolation and characterization of temperature-sensitive mutants of adenovirus type 7

Fifty temperature-sensitive mutants, which replicate at 32 degrees C but not at 39.5 degrees C, were isolated after mutagenesis of the vaccine strain of adenovirus type 7 with hydroxylamine (mutation frequency of 9.0%) or nitrous acid (mutation frequency of 3.8%). Intratypic complementation analyses separated 46 of these mutants into seven groups. Intertypic complementation tests with temperature-sensitive mutants of adenovirus type 5 showed that the mutant in complementation group A failed to complement H5ts125 (a DNA-binding protein mutant), that mutants in group B and C did not complement adenovirus type 5 hexon mutants, and that none of the mutants was defective in fiber production. Further phenotypic characterization showed that at the nonpermissive temperature the mutant in group A failed to make immunologically reactive DNA-binding protein, mutants in groups B and C were defective in transport of trimeric hexons to the nucleus, mutants in groups D, E, and F assembled empty capsids, and mutants in group G assembled DNA-containing capsids as well as empty capsids. The mutants of the complementation groups were physically mapped by marker rescue, and the mutations were localized between the following map coordinates: groups B and C between 50.4 and 60.2 map units (m.u.), groups D and E between 29.6 and 36.7 m.u., and group G between 36.7 and 42.0 m.u. or 44.0 and 47.0 m.u. The mutant in group A proved to be a double mutant.

Restricted changes in the adenovirus DNA-binding protein that lead to extended host range or temperature-sensitive phenotypes

Human adenovirus fails to multiply efficiently in monkey cells owing to a block to late viral gene expression. Ad2hr400 through Ad2hr403 are a set of host range (hr) mutants which were selected for their ability to readily grow in these cells at 37 degrees C. The mutations responsible for this extended host range have previously been mapped to the 5' portion of the gene encoding the 72-kilodalton DNA-binding protein (DBP). DNA sequence analyses indicate that all four hr mutants contain the same alteration at coding triplet 130, which changes a histidine codon to a tyrosine codon. These results extend those of Anderson et al. (J. Virol. 48:31-39, 1983), which suggested that only this change in the DBP amino acid sequence can expand adenovirus host range to monkey cells. The hr phenotype does not appear to require phosphorylation of this tyrosine residue, since no phosphotyrosine was detected in DBP isolated from Ad2hr400-infected monkey cells. The hr mutants Ad2hr400 through Ad2hr403, however, are cold sensitive for growth in monkey cells. The mutant Ad2ts400, which was derived from Ad2hr400, represents a second class of hr mutants which can grow efficiently in monkey cells at 32.5 degrees C. The cold-resistant hr mutation of Ad2ts400 has previously been mapped to the 5' region of the DBP gene (map units 63.6 through 66). DNA sequence analysis of this region shows that this mutant contains the original hr alteration at coding triplet 130 as well as a second alteration at coding triplet 148, which changes an alanine codon to a valine codon. We suspect that the alterations at amino acids 130 and 148 change the structure of the amino-terminal domain of the DBP, allowing it to better interact with monkey cell components required for late viral gene expression. Ad2ts400 also contains a temperature-sensitive mutation which has previously been mapped to the 3' portion of the DBP gene (map units 61.3 through 63.6). Sequence analysis of this region indicates that the DBP coding triplet 413 has been altered. This change from a serine codon to a proline codon is the same alteration reported in the previously sequenced DBP mutants Ad5ts125 (W. Kruijer et al., Nucleic Acids Res. 9:4439-4457, 1981) and Ad5ts107 (W. Kruijer et al., Virology 124:425-433, 1983). Thus it appears that only a very limited number of changes in either the 5' or the 3' portion of the DBP gene can give rise to the hr or temperature-sensitive phenotypes, respectively.

E1a regions of the human adenoviruses and of the highly oncogenic simian adenovirus 7 are closely related

Simian adenovirus 7 (SA7) is a highly oncogenic virus, capable of causing tumors in hamsters upon the direct injection of viral DNA. We determined the transcriptional organization of the transforming region and compared it with that of the human adenoviruses. This analysis demonstrated that there are two independently promoted transcription units similar to the E1a and E1b regions of the human adenoviruses. The nucleotide sequence of the SA7 E1a region demonstrated considerable homology with the human adenoviruses, both in the sequences that regulate E1a expression and in the encoded polypeptides. The amino acid homology was reflected in the ability of SA7 to complement the growth of human adenoviruses mutant in the E1a region. Furthermore, we found two regions of amino acid homology unique to SA7 and the highly oncogenic human adenovirus 12.

DNA sequence of the early E3 transcription unit of adenovirus 5

The DNA sequence of the early E3 transcription unit of adenovirus 5 (Ad5) has been determined and it has been compared to Ad2, as published previously [J. Hérissé, G. Courtois, and F. Galibert (1980), Nucl. Acids Res. 8, 2173-2192; J. Hérissé and F. Galibert (1981), Nucl. Acids Res. 9, 1229-1240]. The E3 regions of Ad5 and Ad2 are quite homologous despite being nonessential for Ad growth in cultured cells. The major differences are "gaps" that exist either in Ad5 or Ad2 in intergenic regions. The conservation of sequences suggests that E3 plays a beneficial role in natural infection of humans. E3 appears to encode about seven to nine proteins; based on sequence, seven of these may be membrane proteins. Thus, E3 may be a transcription unit devoted to the synthesis of membrane proteins. The E3 genes lie essentially one after the other along the genome, and which gene is expressed from a given primary transcript is determined by the choice of the 3' end site and the 5' and 3' splice sites. Almost all E3 mRNAs contain nonfunctional AUGs that are 5' to the initiation codon. Codon usage is nonrandom. Although the CG dinucleotide frequency is low, CG clusters exist in the promoter and other regions.

Accumulation of early and intermediate mRNA species during subgroup C adenovirus productive infections

The cytoplasmic, poly(A)-containing RNA species complementary to all regions of the adenovirus type 2 (Ad2) genome expressed before the onset of viral DNA synthesis have been examined by "Northern" blotting. HeLa cells infected with low multiplicities of Ad2 were harvested at 2-hr intervals until late in the infectious cycle to establish the temporal patterns of expression of each viral gene. Under these conditions, such late mRNA products as those of the L3 and L5 families were not detected until 14 hr after infection. Although individual mRNA species complementary to several genes showed different patterns of expression, the order of appearance in the cytoplasm of substantial concentrations of adenoviral mRNA species was E1A, E3, and E4 (4 to 6 hr), E2A and E2B (8 hr), 3.7- and 4.1-kb L1 mRNA species (10-12 hr), IX and IVa2 mRNAs (12 hr), and those encoded in the major late transcriptional unit, such as members of the L3 and L5 families (14 hr). The mRNA species encoding polypeptides IX and IVa2 were not produced when viral DNA synthesis was blocked, whereas the larger L1 mRNA species was made under these conditions. Two E2B mRNA species, some 5.0 and 7 kb, were observed at low concentrations at 8 hr after infection and their concentration increased until 24 hr after infection, as did that of the E2A mRNA species: the products of the E2 transcription unit appeared to be expressed coordinately and at a constant ratio throughout infection. Few of the early mRNA species decreased in concentration after the onset of the late phase of infection. Examination of the viral mRNA produced when protein synthesis was inhibited by 10 microM anisomycin added 3 hr after infection suggested that processing of certain viral, early transcripts was altered in the presence of the drug.

Morphogenesis of human adenovirus type 2: sequence of entry of proteins into previral and viral particles

The initial steps of adenovirus capsid morphogenesis and the sequence of entry of structural and nonstructural proteins into assembly-intermediate (IM) particles were investigated by pulse-chase labeling, temperature shifts, and cycloheximide inhibition of particle formation. The experiments were performed on wild-type and two assembly-defective, temperature-sensitive mutants, H2 ts 112 and H2 ts 107. The sequence of events in the adenovirus assembly can be schematized as follows. (i) Hexons, pentons, and protein IX assembled with scaffolding proteins 100K, PVIII, and PVII, precursor to the major core protein, to form a previral particle banding at a density of 1.285 in CsCl; (ii) additional incorporation of maturation and/or stabilization proteins IIIa, 50K, 39K, 28K, and PVI led to 1.295 IM; (iii) exit of 100K, 39K, and 28K, and entry of viral DNA gave rise to 1.370 IM; (iv) dephosphorylation and/or exit of 50K and exchange with core protein V and processing of precursors to VII, VI, VIII, and DNA-terminal protein resulted in formation of infectious 1.345 virion. The polypeptide composition of the new class of assembly-intermediate particles elicited by H2 ts 107 (1.285 IM), suggested that 100K, PVIII, and also PVII might serve as scaffold components for adenovirus capsid building.

Analysis of Ad5 hexon and 100K ts mutants using conformation-specific monoclonal antibodies

Adenovirus type 5 ts mutants deficient in hexon metabolism were investigated using conformation-specific monoclonal antibodies directed against hexon capsomeres and the viral 100K protein. The ts mutants map either in the hexon structural gene or in the gene encoding the 100K protein, a major, late nonstructural protein. All of the mutants examined (ts1, ts2, ts3, ts4, ts17, and ts20 of J. F. Williams, M. Gharpure, S. Ustacelebi, and S. McDonald (1971). J. Gen. Virol. 11, 95-101) were unable to produce the capsomeric form of hexon (a trimer of three hexon monomers) at the nonpermissive temperature. However, all of the mutants retained the ability to produce a complex of 100K and hexon which has been demonstrated to play a major role in the assembly of hexon trimers. The mutants accumulated nontrimerized hexon in this ts complex in the perinuclear region of the cell. Several of the mutants (ts1, ts2, ts3) were found to successfully assemble hexon synthesized at the nonpermissive temperature upon shift down to the permissive temperature, even in the presence of a protein synthesis inhibitor. The mutant, ts2, which maps in the hexon structural gene, was found to be dependent on protein synthesis for transport of hexon trimers into the nucleus during temperature shift down, while the 100K ts mutants, ts1 and ts3, were independent of protein synthesis for both hexon assembly and transport.

Proteins encoded near the adenovirus late messenger RNA leader segments

Small fragments of adenovirus 2 DNA cloned into the single-strand phage M13 were used to select adenoviral messenger RNAs transcribed from the R-strand between map positions 16 and 30. Cell-free translation of these mRNAs produced proteins of 13.5K, 13.6K, and 11.5K, respectively encoded between the first and second segments of the tripartite major late leader, within the "i"-leader segment, and immediately preceding the third leader segment. Partial sequence analysis of the 13.6K protein is consistent with the hypothesis that it is encoded within the i-leader segment.

Specific complex of the late nonstructural 100,000-dalton protein with newly synthesized hexon in adenovirus type 2-infected cells

Analysis of cellular extracts of HeLa cells infected with adenovirus type 2 (Ad2) by immunoprecipitation with antiserum against the late nonstructural 100,000-dalton (100K) protein revealed the presence of a specific complex between the 100K protein and newly synthesized hexon molecules. Serological analysis of the hexon molecule in the 100K/hexon complex with antibodies specific for hexon monomers or trimers showed that only monomeric hexon molecules were associated with the 100K protein. By immunofluorescence microscopy this monomeric hexon was primarily found in the cytoplasm, whereas the trimeric form was mainly confined to the nucleus of infected cells. We conclude that in the cytoplasm of Ad2-infected cells newly synthesized, monomeric hexon molecules can interact with the 100K protein. This suggests that the 100K protein may play some role either in trimerization of newly synthesized, monomeric hexon molecules and/or in its transport from the cytoplasm into the nucleus.

Nucleotide sequence of the gene encoding adenovirus type 2 DNA binding protein

We have determined the nucleotide sequence of the gene encoding adenovirus type 2 (Ad2) DNA binding protein (DBP). From the nucleotide sequence the complete amino acid sequence of Ad2 DBP has been deduced. A comparison of the amino acid sequences of Ad2 and Ad5 DBP, both 529 residues long, reveals that the C-terminal 354 residues of both sequences are identical. Within the N-terminal 175 amino acid residues Ad2 and Ad5 show nine differences. The site of mutation in Ad2 ND1ts23, a mutant with a temperature-sensitive DNA replication, was mapped at the nucleotide level. A single nucleotide alteration in the DBP gene, resulting in a leucine leads to phenylalanine substitution at position 282 in the amino acid sequence is responsible for the temperature-sensitive character of this mutant. Previously, we localized the mutation of another DBP mutant with a temperature-sensitive DNA replication (H5ts125) at position 413 in the amino acid sequence of the DBP molecule (Nucleic Acids Res. 9 (1981) 4439-4457). These mapping data are discussed in relation to the structure and function of the DBP molecule.

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.

Expression of the gene encoding the adenovirus DNA terminal protein precursor in productively infected and transformed cells

The major product of in vitro translation of early RNA prepared from H5ts125-infected cells and selected by hybridization to adenoviral DNA fragments spanning the region from 14.7 to 31.5 map units had been shown to be identical to the 87-kilodalton terminal protein precursor. A 72- to 75-kilodalton polypeptide whose rRNA can be selected by DNA from this same region and made in the presence of anisomycin was indistinguishable from the 72-kilodalton single-stranded DNA-binding protein encoded by the region from 60.1 to 66.6 map units. The accumulation of cytoplasmic RNA sequences complementary to these l-strand genes under various conditions of infection and in certain lines of transformed cells has been investigated by solution hybridization of cytoplasmic RNA to the separated strands of restriction endonuclease fragments of adenoviral DNA. During the early phase, RNA sequences complementary to the region from 11.6 to 36.7 map units were present at a concentration of 10 to 60 copies per cell, regardless of the nature of the block used to inhibit viral DNA synthesis. By 24 h after infection in the absence of any such block, sequences complementary to the regions from 11.6 to 18.2 map units (IVa2) and from 18.6 to 36.7 map units (E2B) accumulated to concentrations of 4,800 and 280 copies per cell, respectively. The ratio of cytoplasmic E2A RNA sequences to E2B RNA sequences remained close to 10:1 throughout the time period investigated. Of the transformed cell lines which retained E2B DNA sequences that were examined, only the T2C4 line expressed these sequences in cytoplasmic RNA. The implications of these observations for regulation of expression of the adenoviral early l-strand genes are discussed.

Late nonstructural 100,000- and 33,000-dalton proteins of adenovirus type 2. II. Immunological and protein chemical analysis

For an immunological analysis of the late adenovirus type 2 nonstructural 100,000-dalton (100K) and 33K proteins, we prepared antisera against sodium dodecyl sulfate-denatured, gel-purified 100K and 33K proteins. These antisera were tested for potential cross-reactivity, since according to a previous report (Axelrod, Virology 87:366--383, 1978) these two proteins exhibit extensive amino acid homologies. However, immunoprecipitations of 100K and 33K proteins, as well as a sensitive immune replica technique, did not reveal any immunological relationship between these proteins. Therefore, using fingerprint peptide analysis, we investigated the structural relationship between 100K and 33K proteins labeled with a 14C-amino acid mixture or with [14C]proline after digestion with trypsin. We detected only minor, if any, amino acid homologies, indicating that the 100K and 33K proteins are not structurally related.

Characterization of two temperature-sensitive mutants of type 5 adenovirus with mutations in the 100,000-dalton protein gene

Complementation analysis assigned the mutations of strains H5ts115 and H5ts116, two hexon-minus mutants, to the 100,000-dalton (100K) protein gene. Heterotypic marker rescue (i.e., type 5 adenovirus [Ad5] temperature-sensitive mutants DNA X EcoRI restriction fragments of Ad2 DNA) confirmed the results of previous marker rescue mapping studies, and the heterotypic recombinants yielded unique hybrid (Ad5-Ad2) 100K proteins which were intermediate in size between Ad5 and Ad2 proteins and appeared to be as functionally active as the wild-type 100K protein. Phenotypic characterization of these mutants showed that both the hexon polypeptides and the 100K polypeptides were unstable at the nonpermissive temperature, whereas fiber and penton were not degraded, and that the 100K protein made at 39.5 degrees C could not be utilized after a shift to the permissive temperature (32 degrees C). The role of the 100K protein in the assembly of the hexon trimer was also examined by in vitro protein synthesis. Normally, hexon polypeptides synthesized during an in vitro reaction are assembled into immunoreactive hexons. However, this assembly was inhibited by preincubation of the cell extract with anti-100K immunoglobulin G; neither anti-fiber immunoglobulin G nor normal rabbit immunoglobulin G inhibited hexon assembly. It is postulated that an interaction between the 100K protein and hexon polypeptides is required for effective assembly of hexon trimers.

Late nonstructural 100,000- and 33,000-dalton proteins of adenovirus type 2. I. Subcellular localization during the course of infection

We analyzed the subcellular locations of the late adenovirus type 2 nonstructural 100,000-dalton (100K) and 33K proteins in adenovirus type 2-infected HeLa cells both by biochemical cell fractionation and by immunofluorescence microscopy, using specific antisera against purified sodium dodecyl sulfate-denatured 100K and 33K polypeptides. Both methods showed that the 100K protein was present in the cytoplasm as well as in the nuclei of infected cells and that it accumulated in the nuclei during the course of infection. Phosphorylated 100K protein also was found both in the cytoplasm and in nuclei. However, the nuclear 100K protein pool was phosphorylated to a higher degree than the cytoplasmic pool. In all experiments the 33K protein, which also is a phosphoprotein, was present exclusively in the nuclei of infected cells. The 100K and 33K proteins were associated with different nuclear substructures; this was demonstrated serologically by an analysis of infected cells in which double color immunofluorescence microscopy was used. In these experiments antibodies against the 100K protein decorated different nuclear structures than antibodies against the 33K protein.

Controls of RNA splicing and termination in the major late adenovirus transcription unit

The major late adenovirus promoter is active early after infection, selectively producing messenger RNAs coding for polypeptides with molecular weights of 55,000, 52,000 and 14,000. This selective expression suggests that a differential splicing pattern occurs at the transition from early to late viral gene expression. Activation of the late promoter and splicing of the 55, 52K mRNAs does not require newly synthesized virus polypeptides.

Identification and mapping of two polypeptides encoded within the herpes simplex virus type 1 thymidine kinase gene sequences

mRNA's homologous to the herpes simplex virus type 1 DNA restriction endonuclease fragment BamHI p, which contains the thymidine kinase gene, have been identified and mapped by hybrid-arrested translation and mRNA selection. Such mRNA's, when translated in vitro, directed the synthesis of polypeptides of apparent molecular weights 43,000 (VI43) and 39,000 (VI39). mRNA for enzymatically active thymidine kinase was enriched by more than 20-fold after selection. Mapping was carried out with restriction endonuclease fragments of BamHI p, and locations of the 5' and 3' termini of VI43 mRNA were deduced. Analysis of nucleotide sequences around the 5' terminus revealed several consensus sequences commonly found at the start of eucaryotic mRNA's and which are presumably involved in initiation of transcription by RNA polymerase II. Translation of mRNA's for VI43, VI39, and the thymidine kinase enzyme was arrested only by a 1,170-base-pair region of BamHI p. Since this region is insufficient for adjacent genes, coding sequences for VI43 and VI39 must overlap; the possible relationship of these two polypeptides is discussed. A virus-induced product equivalent to VI39 was detected in infected cells.

Gene and mRNA for precursor polypeptide VI from adenovirus type 2

We present a 1,040-base-pair-long sequences of adenoviruses type 2 DNA which encodes the complete gene for precursor polypeptide VI (pVI). pVI consists of 250 amino acids amounting to a molecular weight of 26,990. The proteolytic cleavage maturing pVI to virion polypeptide VI removes 33 amino acids from the amino-terminal end of the polypeptide, thus giving the mature polypeptide VI a molecular weight of 23,400. The UAA stop codon terminating pVI translation is separated by 84 nucleotides from the initiator triplet for the hexon gene. Both polypeptides are encoded by the same translational reading frame, suggesting the evolution of pVI and hexon as separate proteins by the introduction of a termination codon and selection of a new splice acceptor site in an ancestral fused polypeptide chain. The splice site where the common tripartite leader is attached to the pVI mRNA precedes the initiator codon for pVI translation by one nucleotide and forms, together with other late splice acceptor sites, a late adenovirus consensus acceptor site. We also demonstrate that the 3' end of the mRNA's belonging to the L2 3'-cotermination family is located only 31 nucleotides upstream from the splice junction of the pVI mRNA. Furthermore, we show that four novel polypeptides of molecular weights 80,000, 39,000, 36,000, and 10,500 are encoded by region L2.

Mapping of adenovirus 12 mRNA's transcribed from the transforming region

Adenovirus 12 mRNA's transcribed from the transforming region were analyzed and mapped on viral DNA by the nuclease S1 gel and diazobenzyloxymethyl paper blot techniques in cells transformed of adenovirus 12 DNA and in cells early and late after lytic infection with adenovirus 12. Two initiation sites of mRNA transcription and two kinds of splicing were found in each of early regions 1A and 1B. For early region 1A mRNA's, four species were found in lytically infected cells. Three of them were commonly found in cells transformed by either HindIII-G or EcoRI-C. Cells transformed by HindIII-G contained two additional 1A transcripts, which could be the 3' portions of chimeric mRNA's of cellular-viral or viral-viral sequences. Transcription in the 1B region diverged among the above cell lines. Early after lytic infection, no appreciable amount of 1B mRNA was detected, whereas two species of mRNA's, one corresponding to protein IX mRNA and another having splicing, were found at the late stage. In cells transformed by EcoRI-C, a distinct mRNA species with splicing was observed. Cells transformed by HindIII-G contained a transcript from the leftmost part of the 1B sequence at the 5' portion of chimeric mRNA species, suggesting the presence of tandem integration of viral DNA in the cells. Other mRNA species in the 1A and 1B regions were also detected in both transformed cell lines. The results are discussed in relation to the nucleotide sequence of the HindIII-G fragment of adenovirus 12 DNA.

Transcription and RNA processing by the DNA tumour viruses

Messenger RNA synthesis by the DNA tumour viruses proceeds by a complex but versatile series of transcription and RNA processing steps. The major mechanistic features of this pathway are probably very similar to those used by the animal cell host itself. The viruses have, however, evolved intricate arrangements of protein coding sequences and sites for RNA initiation, polyadenylation and splicing which allow them to use their genetic information to maximum advantage.

Expression of unselected adenovirus genes in human cells co-transformed with the HSV-1 tk gene and adenovirus 2 DNA

We have introduced adenovirus 2 genes into high molecular weight DNA of permissive human cells by co-transformation of tk- human 143 cells with Ad2 restriction enzyme fragments and a cloned Bam HI fragment that carries the HSV-1 thymidine kinase gene. Tk+ cells were isolated after selection and maintenance in HAT medium. Several co-transformed lines are able to complement the growth of Ad5 dl312 (delta 1.2--3.7) and Ad5 dl434 (delta 2.6--8.7), deletion mutants that lack sequences from the left end of the viral genome. The amount and arrangement of viral sequences in the co-transformed cell lines have been analyzed by restriction endonuclease digestion and filter hybridization. Most of the cell lines contain a single insertion of the HSV-1 tk fragment and a single insert of adenoviral DNA. However, one line (B1) contains at least four different insertions, two of which are present in multiple copies. The adenoviral DNA in all cell lines is composed of sequences from the left end of the genome and extends for varying lengths in different lines. Two cell lines that complement deletion mutants efficiently synthesize both early region 1a and 1b mRNAs. The B1 line synthesizes low levels of 1a mRNA, higher levels of 1b mRNA and a unique mRNA that maps to the right of the 1b gene family. When grown continuously in HAT medium, some cell lines are quite stable while others are fairly unstable. Some tk+ subclones support the growth of viral mutants as well as the parental line while others give reduced levels of complementation. For all tk+ subclones examined, the alteration or reduction in viral gene expression is independent of changes in the pattern of integration of viral DNA.

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.

Multiple mRNA species for adenovirus type 2 polypeptides III and pVII

Fractionation of messenger activities isolated from the cytoplasm of HeLa cells late in infection with adenovirus type 2 reveals that viral polypeptides III and pVII are each synthesized from two different-sized mRNA's. the major messenger activity for each protein has the same sedimentation rate as that previously reported by Anderson et al. (Proc. Natl. Acad. Sci. U.S.A. 71:2756-2760, 1974). The minor messenger activities for III and pVII sediment more rapidly and are not aggregates of the major mRNA's for these proteins. The two minor messenger activities cosediment with two polyadenylated RNA species which are labeled late in infection with 32P and whose molecular weights are estimated to be 2.9 x 10(6) and 2.4 x 10(6). Both of these species hybridize to adenovirus type 2 DNA specific for the mRNA family that is 3' coterminal at adenovirus type 2 map position 49.5 and the mRNA family that is 3' coterminal at 62.0. This is consistent with the possibility that these RNAs have 5'-terminal sequences identical to those of the normal mRNA's for III and pVII but are 3' coterminal at map position 62, the normal 3' terminus of the mRNA's for polypeptides II and pVI. These species are not found in polyadenylated RNA isolated from the nucleus, suggesting that the minor mRNA species are cytoplasmic RNAs.

Nucleotide sequence of the EcoRI D fragment of adenovirus 2 genome

The entire nucleotide sequence of the Ad. 2 EcoRI D fragment has been determined using the Maxam and Gilbert method. This sequence of 2678 bp contains informations relative to late mRNAs ending at position 78 and for which an AATAAA sequence corresponding to their 3' ends is found at residue number 833. Position of the PVIII mRNA is determined thus allowing deduction of the probable amino acid sequence of the PVIII protein. The position and the sequence of the first leader of early 3 mRNAs is determined as well as the sequence and position of the second early leader of region 3 mRNAs, which also correspond to the "y" leader of the fiber mRNA. Following the localization of an open reading frame in which an ATG could initiate protein synthesis it can be predicted that 3a, b, c mRNAs code for the 16K early protein and the probable amino acid sequence of this protein can be deduced. The CAGTTT sequence frequently present at the 5' end of a leader or of a mRNA body as well as the GGTGAG sequence which is found at the 3' end of several leaders were used to postulate the position of various early mRNAs of region 3 and to suggest the existence of an additional splicing event during the processing of mRNAs 3a, b and c. They were also used to predict the position of the additional "x" late leaders. The imbrication of information concerning (i) the family of late mRNAs ending at position 78, (ii) the position of the "x" leader and the "y" leader and (iii) the beginning of early region 3 is also depicted.

The intervening sequence in the 26S rRNA coding region of T. thermophila is transcribed within the largest stable precursor for rRNA

We studied the transcription of the intervening sequence in the 26S rRNA coding region of the extrachromosomal rDNA molecules in the macronucleus of T. thermophila by hybridization of purified nuclear rRNA precursors or cytoplasmic 26S rRNA to purified native rDNA or specific rDNA restriction fragments. Examination of R loop hybrids in the electron microscope and analyses of S1-protected rDNA fragments in alkaline agarose gels showed that mature 26S rRNA, nuclear pre-26S rRNA and a fraction of the pre-rRNA molecules containing both the sequences for 17S and 26S rRNA all lack the region corresponding to the intervening sequence. The rest of the pre-rRNA molecules, however, hybridize in a colinear fashion to the whole coding region, and thus must contain the intervening sequence. We can conclude from these results that the intervening sequence is transcribed within the primary transcription product of the rDNA, and that the post-transcriptional removal of the intervening RNA sequence is a very early processing event in the organism.