Loop structures in hybrids of early RNA and the separated strands of adenovirus DNA

Role of circular RNAs in colorectal tumor microenvironment

Circular RNAs (circRNAs) are a class of endogenous noncoding RNA, which were previously considered as a byproduct of RNA splicing error. Numerous studies have demonstrated the altered expression of circRNAs in organ tissues during pathological conditions and their involvements in disease pathogenesis and progression, including cancers. In colorectal cancer (CRC), multiple circRNAs have been identified and characterized as "oncogenic", given their involvements in the downregulation of tumor suppressor genes and induction of tumor initiation, progression, invasion, and metastasis. Additionally, other circRNAs have been identified in CRC and characterized as "tumor suppressive" based on their ability of inhibiting the expression of oncogenic genes and suppressing tumor growth and proliferation. circRNAs could serve as potential diagnostic and prognostic biomarkers, and therapeutic targets or vectors to be utilized in cancer therapies. This review briefly describes the dynamic changes of the tumor microenvironment inducing immunosuppression and tumorigenesis, and outlines the biogenesis and characteristics of circRNAs and recent findings indicating their roles and functions in the CRC tumor microenvironment. It also discusses strategies and technologies, which could be employed in the future to overcome current cancer therapy challenges associated with circRNAs.

Splicing heterogeneity: separating signal from noise

Single-cell analyses have revealed a tremendous variety among cells in the abundance and chemical composition of RNA. Much of this heterogeneity is due to alternative splicing by the spliceosome. Little is known about how many of the resulting isoforms are biologically functional or just provide noise with little to no impact. The dynamic nature of the spliceosome provides numerous opportunities for regulation but is also the source of stochastic fluctuations. We discuss possible origins of splicing stochasticity, the experimental approaches for studying heterogeneity in isoforms, and the potential biological significance of noisy splicing in development and disease.

Adenovirus vector library: an approach to the discovery of gene and protein function

A method was developed to generate a complex cDNA expression library within an adenovirus type 5 (Ad5)-based vector backbone, termed AdLibrary. Construction of the AdLibrary entailed the conversion of an Ad5 genome-containing cosmid to infectious virus particles. The Ad5 genome was modified by replacing the E1A and E1B genes with a Rous sarcoma virus-driven expression cassette. Conversion was accomplished by liberating the viral genome by restriction enzyme digestion and transfection in HEK 293 cells, which support the growth of E1A/E1B-deficient virus. A test AdLibrary demonstrated the possibility of converting and identifying a marker gene present at a frequency of 1/105 in the cosmid library. To demonstrate the utility of this technology, an AdLibrary was used to isolate a viral gene by its biological function. Virus growth was selected for with an AdLibrary on A549 cells, which do not complement for E1A/E1B function. The AdLibrary was generated with cDNAs derived from HeLa cells productively infected with Ad5. A cDNA corresponding to Ad5 E1A 13S was selected and isolated from the AdLibrary using this strategy. Since multiple genes are assayed simultaneously, this technology should expedite the discovery of genes affecting defined biological activities. This AdLibrary approach provides an opportunity to exploit the efficient gene delivery capabilities of adenovirus vectors for the rapid discovery of gene and protein function.

Gene product of region E4 of adenovirus type 5 modulates accumulation of certain viral polypeptides

An adenovirus type 5 mutant, designated H5ilE4I, was constructed in which region E4 was replaced by a cloned cDNA. The cDNA was a copy of an mRNA which exclusively contains open translational reading frames 6 and 7. The phenotype of the mutant was compared with that of the previously characterized E4 mutant H2dl808 and wild-type adenovirus 5. Although the H5ilE4I mutant lacked at least five E4 genes, it was nondefective for growth in HeLa cells. The defects in viral DNA replication, late protein synthesis, and shutoff of host cell protein synthesis associated with the phenotype of the H2dl808 mutant were not observed in HeLa cells infected with the H5ilE4I mutant. However, differences were observed regarding the time of onset of viral DNA replication and the accumulation of the hexon polypeptide as well as the 72-kilodalton adenovirus-specific DNA-binding protein. The results thus indicate that open reading frame 6 or 7 or both contain all genetic information required for viral replication in tissue culture cells, whereas another E4 gene modulates the accumulation of certain viral polypeptides. The early onset of viral DNA replication in H5ilE4I-infected cells may be an indirect effect of the enhanced expression of the 72-kilodalton DNA-binding protein.

Adenovirus transcriptional complexes contain EIa encoded tumour antigens physically bound to cellular proteins

Adenovirus type 12 transcriptional complexes were isolated from cells during the early phase of infection. Sedimentation analysis identified a fast sedimenting complex type I and a slow sedimenting complex type II. Both complexes made virus specific RNA complementary to all the early genes and both contained viral DNA, which in type II but not in type I had nucleosome like configuration. Analysis of the proteins of the complexes with antiserum against Ad 12 EIa-beta-galactosidase fusion protein expressed in E. coli demonstrated the following: (a) type I complex contained EIa 45 K protein, which co-precipitated with cellular proteins of mol. wt. 42, 58, and 60 K, (b) type II complex contained EIa 47 K protein, which co-precipitated with major cellular proteins of 35, 40-46 K and minor proteins of 58, 60, 68, 76, 86, and 120-150 K. Association of EIa specific and cellular proteins to transcriptional complexes was sensitive to both 1 M NaCl and DNAse I indicating the DNA binding nature of these proteins. Treatment of transcriptional complexes with 1 M NaCl or DNase I released EIa proteins, which still remained strongly bound to cellular proteins. These findings suggested that EIa proteins bind to viral DNA and that this binding is probably mediated by cellular proteins.

Identification of adenovirus type 2 early region 1B proteins that share the same amino terminus as do the 495R and 155R proteins

Adenovirus type 2 early region 1B (E1B) proteins synthesized in vitro were fractionated chromatographically and characterized by peptide and sequence analysis and by reaction with peptide-specific antisera targeted to either the N or C terminus of either of two overlapping E1B reading frames (175 or 495 codons). In addition to the previously identified E1B-495R, E1B-175R, and E1B-155R species, two other E1B proteins of similar electrophoretic mobility to the 175R protein were identified. E1B-82R is an abundant product in vitro and in vivo that has the same N terminus as that of the 495R and 155R proteins but a different C terminus. The structure of 82R is predicted by the structure of the abundant 13S (1.02-kilobase) E1B mRNA. E1B-168R is a novel minor species consisting of the 24 amino-terminal residues of the 495R protein fused to the entire polypeptide IX sequence. An additional, minor 16,000-molecular-weight polypeptide was detected that may correspond to a predicted 92R E1B protein, but definitive identification was not possible. These observations establish that the leftmost portion (78 codons) of the 495-codon reading frame, which overlaps the right half of the 175-codon reading frame, is expressed as an abundant protein that does not contain other 495R sequences. This region, which may participate in the regulation of region E1A expression, may thus constitute a functional domain distinct from the rightward portion of the 495R protein.

Synthesis of the Ad2+ND5-specified 42K protein is regulated posttranscriptionally in abortively infected monkey cells

In abortive infections of monkey cells by Ad2+ND5, the synthesis of the simian virus 40-specific 42,000-molecular-weight (42K) protein was reduced approximately 10-fold compared with a productive coinfection by Ad2+ND5 plus Ad2hr400 and about 20-fold compared with productive infections by Ad2+ND5 plus simian virus 40 or by Ad2+ND2 alone. However, the level of Ad2+ND5-specific mRNA was depressed twofold or less in abortive infections compared with productive infections. Moreover, the 42K mRNA isolated from abortive Ad2+ND5 infections translated in vitro with the same efficiency as the mRNA isolated from productive coinfections. This is analogous to the block to synthesis of the adenovirus fiber polypeptide in monkey cells (Anderson and Klessig, J. Mol. Appl. Genet. 2:31-43, 1983). Also like fiber protein, the increased level of the 42K protein found in productive infections was due to enhanced synthesis, not increased stability of the protein. Our results suggest that the synthesis of the Ad2+ND5-specified 42K protein and the adenovirus fiber protein are regulated in similar posttranscriptional manners.

Nuclei of adenovirus 2-infected cells contain an RNA species that corresponds to an intron excised intact from mRNA precursors

We used Northern and S1 nuclease analyses to identify a nuclear RNA species of the structure predicted for an intron excised from the precursor of adenovirus 2 E2A early mRNA. The structure of this excised intron demonstrated that the splicing of E2A mRNA can involve the removal of the intron sequences as single intact molecules. The concentration of the excised intron is 30 copies per nuclei, comparable to the levels of E2A polyadenylated splicing precursors, but 30-fold less than nuclear E2A mRNA. Late in infection, when the production of E2A early mRNA is dramatically elevated (Goldenberg et al., J. Virol. 38:932-939, 1981), the excess intron was not detected, indicating that either its stability or the mechanism of splicing is altered. We also identified a spliced nonpolyadenylated E2A nuclear RNA species with a structure similar to the mRNA, indicating that splicing may normally occur in the absence of polyadenylation.

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.

Nuclei of adenovirus 2-infected cells contain an RNA species that corresponds to an intron excised intact from mRNA precursors

We used Northern and S1 nuclease analyses to identify a nuclear RNA species of the structure predicted for an intron excised from the precursor of adenovirus 2 E2A early mRNA. The structure of this excised intron demonstrated that the splicing of E2A mRNA can involve the removal of the intron sequences as single intact molecules. The concentration of the excised intron is 30 copies per nuclei, comparable to the levels of E2A polyadenylated splicing precursors, but 30-fold less than nuclear E2A mRNA. Late in infection, when the production of E2A early mRNA is dramatically elevated (Goldenberg et al., J. Virol. 38:932-939, 1981), the excess intron was not detected, indicating that either its stability or the mechanism of splicing is altered. We also identified a spliced nonpolyadenylated E2A nuclear RNA species with a structure similar to the mRNA, indicating that splicing may normally occur in the absence of polyadenylation.

Introduction, stable integration, and controlled expression of a chimeric adenovirus gene whose product is toxic to the recipient human cell

The DNA-binding protein (DBP) encoded by human adenoviruses is a multifunctional polypeptide which plays a central role in regulating the expression of the viral genes. To gain a better understanding of the relationships between the various functions provided by DBP, an extensive collection of DBP mutants is essential. To this end we have constructed several permissive human cell lines which contain and express the DBP gene at high levels to allow propagation of otherwise lethal, nonrecoverable mutants of DBP. Because DBP is toxic to human cells, cell lines were constructed by using a vector in which the DBP gene is under the control of the dexamethasone-inducible promoter of the mouse mammary tumor virus. The low basal levels of DBP synthesis in the absence of dexamethasone allows isolation and propagation of these cells. Addition of dexamethasone enhances DBP production 50- to 200-fold, and within 8 h its synthesis from the single integrated copy of the chimeric gene is 5 to 15% of that observed during peak DBP synthesis in infected human cells in which hundreds of copies of the DBP gene serve as templates. At the nonpermissive temperature, adenovirus mutants with ts lesions in the DBP gene replicate their DNAs, express their late genes, and form infectious viral particles in these DBP+ cell lines but not in the parental HeLa cells.

Introduction, stable integration, and controlled expression of a chimeric adenovirus gene whose product is toxic to the recipient human cell

The DNA-binding protein (DBP) encoded by human adenoviruses is a multifunctional polypeptide which plays a central role in regulating the expression of the viral genes. To gain a better understanding of the relationships between the various functions provided by DBP, an extensive collection of DBP mutants is essential. To this end we have constructed several permissive human cell lines which contain and express the DBP gene at high levels to allow propagation of otherwise lethal, nonrecoverable mutants of DBP. Because DBP is toxic to human cells, cell lines were constructed by using a vector in which the DBP gene is under the control of the dexamethasone-inducible promoter of the mouse mammary tumor virus. The low basal levels of DBP synthesis in the absence of dexamethasone allows isolation and propagation of these cells. Addition of dexamethasone enhances DBP production 50- to 200-fold, and within 8 h its synthesis from the single integrated copy of the chimeric gene is 5 to 15% of that observed during peak DBP synthesis in infected human cells in which hundreds of copies of the DBP gene serve as templates. At the nonpermissive temperature, adenovirus mutants with ts lesions in the DBP gene replicate their DNAs, express their late genes, and form infectious viral particles in these DBP+ cell lines but not in the parental HeLa cells.

Splicing in adenovirus and other animal viruses

Splicing provides viruses with great genetic versatility. It is still too early to say whether this versatility is derived from ingeneous mechanisms evolved by necessity by the viruses, or whether the viruses indeed mimic cellular mechanisms. In any event, it is unlikely that cells will provide a single genomic cluster of genes that utilize splicing in such diverse ways as adenovirus, or the other viruses discussed here. And we may speculate that when the full role of splicing in adenovirus gene expression program is known, its import will continue to be a source of amazement!

Characterization of the major mRNAs from adenovirus 2 early region 4 by cDNA cloning and sequencing

The sequences at the splice junctions of many early region 4 (E4) mRNAs from adenovirus 2 (Ad2) were determined by analysis of cDNA clones. The cDNAs were synthesized from poly(A)+ mRNA isolated from HeLa cells early during Ad2 infection. A standard library was constructed, in pBR322, from double stranded cDNAs initiated by oligo-dT priming. Approximately 1% of total recombinants contained E4 sequences, however among eighty clones analyzed in detail, only four contained the 5' leader sequence. A second library was prepared using a new method that led to a greatly increased representation of desired clones. This method employed oligo-dT to prime the synthesis of the first strand and an oligonucleotide ligated to pBR322, whose sequence was present in the 5' leader, to prime the synthesis of the second strand. With this method the percentage of recombinants containing E4 sequences ranged between 15 and 50% of the total colonies. Virtually all of these E4 cDNA clones contained the 5' leader sequence and several hundred were analyzed by comparing the results from single channel dideoxy sequencing reactions. Nine unique sequence patterns were identified and representative clones were completely sequenced.

The adenovirus-2 EIIa early gene promoter: sequences required for efficient in vitro and in vivo transcription

A series of deletion mutants extending from -250 toward the capsite has been constructed in the early promoter region of the adenovirus 2 EIIa gene and tested both in vitro, and in vivo after transfection of HeLa cells, for the ability to act as a template for transcription. A region between positions -94 and -63 upstream from the major EIIa early cap site is essential both in vivo and in vitro for efficient promoter function. By cotransfection of the EIIa deletion mutants with the EIa transcription unit it has been possible to demonstrate that deletion to position -94 does not affect induction of transcription of the EIIa early gene by the EIa transcription unit, but deletion to position -63 results in loss of detectable levels of EIIa early specific RNA. Thus, sequences upstream from position -94 of the EIIa early gene are not involved in the induction of the EIIa early gene by the EIa transcription unit.

Identification of adenovirus genes that require template replication for expression

The relationship between adenovirus type 2 DNA replication and expression of intermediate stage viral genes was investigated. The 1.03-kilobase mRNA from early region 1b (E1b) and the mRNAs coding for proteins IX and IVa2 were first detected between 6 and 8 h postinfection. Inhibition of viral DNA replication with hydroxyurea prevented expression of the IX and IVa2 mRNAs, but not of the E1b mRNA. Pulse-labeling experiments demonstrated that the block of IX and IVa2 expression in hydroxyurea-treated cells was at the level of transcription. By a series of superinfection experiments, it was determined that the viral and cellular factors present during the late stage of adenovirus infection are insufficient to activate IX gene expression. The viral DNA template must first replicate before IX transcription can begin.

Identification of human adenovirus early region 1 products by using antisera against synthetic peptides corresponding to the predicted carboxy termini

Synthetic peptides were prepared which corresponded to the carboxy termini of the human adenovirus type 5 early region 1B (E1B) 58,000-molecular-weight (58K) protein (Tyr-Ser-Asp-Glu-Asp-Thr-Asp) and of the E1A gene products (Tyr-Gly-Lys-Arg-Pro-Arg-Pro). Antisera raised against these peptides precipitated polypeptides from adenovirus type 5-infected KB cells; serum raised against the 58K carboxy terminus was active against the E1B 58K phosphoprotein, whereas serum raised against the E1A peptide immunoprecipitated four major and at least two minor polypeptides. These latter proteins migrated with apparent molecular weights of 52K, 50K, 48.5K, 45K, 37.5K, and 35K, and all were phosphoproteins. By using tryptic phosphopeptide analysis, the four major species (52K, 50K, 48.5K, and 45K) were found to be related, as would be expected if all were products of the E1A region. The ability of the antipeptide sera to precipitate these viral proteins thus confirmed that the previously proposed sequence of E1 DNA and mRNA and the reading frame of the mRNA are correct. Immunofluorescent-antibody staining with the antipeptide sera indicated that the 58K E1B protein was localized both in the nucleus and in the cytoplasm, especially in the perinuclear region. The E1A-specific serum also stained both discrete patches in the nucleus and diffuse areas of the cytoplasm. These data suggest that both the 58K protein and the E1A proteins may function in or around the nucleus. These highly specific antipeptide sera should allow for a more complete identification and characterization of these important viral proteins.

Accurate and efficient in vitro splicing of purified precursor RNAs specified by early region 2 of the adenovirus 2 genome

Polyadenylated and deproteinized nuclear RNA precursors encoded by early region 2 of the adenovirus 2 genome are spliced in vitro by nuclear extracts prepared from MOPC-315 mouse myeloma cells. The in vitro reaction excises sequences from two introns and attaches 5' sequences to the mRNA body. The nucleotide sequence across the splice junctions in the E2 RNAs processed in vitro was investigated by performing primer extensions in the presence of dideoxynucleotides and direct sequencing on polyacrylamide gels. We conclude that the in vitro splicing reaction is accurate and has the same precision as that of in vivo E2 cytoplasmic mRNA prepared from Ad2 infected cells. The efficiency of in vitro splicing by the nuclear extracts is very high. Approximately 80% of E2 RNA precursor, on a molar basis, are spliced in vitro to a mature RNA. These findings provide evidence that a nuclear extract prepared from MOPC-315 mouse myeloma cells is capable of accurate and efficient splicing of E2 RNA precursors.

Transcription of adenovirus 5 early region 1b is elevated in permissive cells infected by a mutant with an upstream deletion

Early region 1b (E1b) of adenovirus 5 consists of a single transcription unit that lies from 1,702 to 4,070 nucleotides from the conventional left end of the genome. The effect of mutations that map upstream of E1b on the production of E1b mRNA was examined in vivo with mutants defective in gene functions from the neighboring early region 1a (E1a) transcription unit (499 to 1,632 nucleotides from the left end). These host range mutants replicate in the adenovirus 5-transformed human cell line 293. E1b mRNA accumulation was assayed by DNA-RNA hybridization late after productive infection when the E1b transcripts are abundant in the cytoplasm. Cells infected by wild-type virus, mutant dl311, or mutant hr1. The elevated levels of E1b mRNA were also detected in steady-state nuclear RNA, pulse-labeled polyadenylated nuclear RNA, and pulse-labeled total nuclear RNA. These data indicate that E1b transcription was elevated in human 293 cells infected with dl312. There was no evidence of increases in genomic DNA in dl312-infected cells, suggesting that the rate of transcription may be elevated. When mixed infections with a 10-fold excess of either dl312 or wild-type virus were performed, the phenotype was that of the more abundant genome. This result suggests that the respective phenotypes were cis dominant. The increased rate of transcription can be attributed to cis-active regulatory effects of the deletion of nucleotides 448 to 1,349 in mutant dl312 DNA.

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.

Variety in the level of gene control in eukaryotic cells

In light of present progress in the understanding of how messenger RNA is constructed in eukaryotic cells, the levels of gene control are discussed. Transcriptional control, assessed by the rate of synthesis of specific nuclear RNA, is strongly indicated to be the most frequent level of control. Definition of eukaryotic transcription units as simple (encoding one protein) and complex (encoding two or more proteins) affords a framework in which to discuss control at the level of RNA processing for which several examples also are known. Finally, differential stability of cytoplasmic mRNAs and differential translation, both well established, are briefly described.

Synthesis of human adenovirus early RNA species is similar in productive and abortive infections of monkey and human cells

Northern (RNA) blot analysis has been used to show that synthesis of early mRNA species is similar in monkey cells productively or abortively infected with human adenovirus. mRNA species from all five major early regions (1A, 1B, 2, 3, 4) are identical in size and comparable in abundance whether isolated from monkey cells infected with adenovirus type 2 or with the host range mutant Ad2hr400 or coinfected with adenovirus type 2 plus simian virus 40. The mRNA species isolated from monkey cells are identical in size to those isolated from human cells. Production of virus-associated RNA is also identical in productive and abortive infections of monkey cells. Synthesis of virus-associated RNA is, however, significantly greater in HeLa cells than in CV1 cells at late times after infection regardless of which virus is used in the infection.

Specific in vitro initiation of transcription on the adenovirus type 2 early and late EII transcription units

Three transcription units are present in the adenovirus type 2 region EII. Transcription units EIIaE and EIIaL encode the mRNA for the 72,000-dalton DNA binding protein, early and late in the lytic cycle, respectively, and transcription unit EIIb encodes the mRNA for the protein that binds to the 5' termini of adenovirus DNA. By using a cell-free transcription system in the presence of purified RNA polymerase B (or II), we have obtained specific initiation of transcription from both the EIIaE promoter, which does not contain a T-A-T-A box, and the EIIaL promoter, which does. In addition, we have identified a new EII T-A-T-A box promoter that is located close to the early non-T-A-T-A box promoter and is used both in vivo and in vitro.

Transformation-defective mutant of adenovirus type 5 containing a single altered E1a mRNA species

A mutant of adenovirus type 5 containing an octanucleotide insert in region E1a of the viral genome was constructed. The insert was present in only one (13s) of the three overlapping mRNA's synthesized from this region. The insert was within the sequences removed by RNA splicing during the production of the other two nRNA's. The insertion resulted in a shift in the translational reading frame of the 13s mRNA and the probable premature termination of translation. The mutant was defective for viral DNA replication in HeLa cells and the transformation of rat embryo and baby rat kidney cells, indicating that a product encoded by the 13s nRNA is required for these two processes. Other early regions of the genome were expressed in HeLa cells infected by this mutant although in some cases the expression was decreased as compared with wild-type-infected cells.

Structure and organization of the gene coding for the DNA binding protein of adenovirus type 5

We have determined the nucleotide sequence of a region of adenovirus type 5 (Ad5) DNA located between map positions 61.7 and 71.4, which covers the gene form the 72 kD DNA binding protein (DBP) and the sequence encoding the amino-terminal part of the 100 kD protein. Sequence analysis of cDNA copies of DBP mRNA revealed the existence of two abundant species of spliced mRNA molecules. One species consists of two short leader sequences from positions 75.2 (67 and 68 nucleotides long) and 68.8 (77 nucleotides long), respectively, and the main body of the RNA molecules. The other species contains only the leader sequence from position 75.2 and the main body. The amino acid sequence of DBP is encoded entirely by a long open reading frame of 1587 nucleotides in the main body of DBP mRNA. From the nucleotide sequence of the DBP gene it can be derived that DBP contains 529 amino acid residues and has an actual molecular weight of 59,049 daltons. The sites of mutation in the mutants H5hr404 and H5ts125 were determined at the nucleotide level. Single nucleotide alterations were detected in H5hr404 and H5ts125 in the sequences corresponding to the amino-terminal part and the carboxy-terminal part of DBP, respectively. The implications of these mutations are discussed.

In vitro splicing of purified precursor RNAs specified by early region 2 of the adenovirus 2 genome

Early region 2 of the adenovirus 2 genome (map position 61-75) specifies two poly(A)+ nuclear RNAs (28S and 23S) that appear to be precursors of the 20S cytoplasmic mRNA [Goldenberg, C. J. & Raskas, H. J. (1979) Cell 16, 131-138]. Splicing of these nuclear RNAs in vitro has been obtained with a whole cell extract prepared from MOPC-315 mouse myeloma cells. The in vitro reaction excises sequences from two introns and attaches 5' sequences to the mRNA body. The splicing reaction was demonstrated by two procedures: (i) hybridization of pulse-labeled RNA fractionated by size and (ii) annealing of RNAs with radioactive DNA probes followed by nuclease digestion. The first procedure provided evidence that sequences from the large 2300-nucleotide intron (74.6-68.8) were excised and 5' transcripts were spliced to the mRNA body. Utilizing both S1 and Exo VII nucleases, the second procedure demonstrated excision of sequences from the smaller 720-nucleotide intron (68.5-66.3), the splicing of sequences from the second leader (68.8) to the mRNA body, and the formation of an mRNA body of 1700 nucleotides, the size found in vivo. These findings provide evidence that an in vitro system that splices viral RNAs to yield products comparable to those found in vivo is now available.

Coordinate regulation of two cytoplasmic RNA species transcribed from early region 2 of the adenovirus 2 genome

Early region 2 (E2) of the adenovirus 2 genome specifies a 72,000-dalton DNA-binding protein that is required for viral DNA replication. Electron microscopy studies have detected two major forms of 20S E2 mRNA, one species with a 5' leader from map position 75 and a second form having a leader from position 72 (Chow et al., J. Mol. Biol. 134:265-303, 1979). Only the species with a leader from position 75 was detected at early times; however, both forms were found at late times. We have analyzed the temporal regulation of E2 expression by documenting mRNA accumulation in the cytoplasm. Kinetic studies of pulse-labeled RNAs demonstrated a peak of E2 cytoplasmic RNa synthesis at 10 to 12 h, coinciding with the time of maximal synthesis of the 72,000-dalton DNA binding protein and viral DNA. To estimate the relative abundances of the two major E2 RNA species at various times during infection, total E2 cytoplasmic and polysomal 20S RNAs were isolated by hybridization-selection with specific DNA probes. The leader sequences in the selected RNAs were then quantitated by further RNA-DNA hybridization. We found that the elevated accumulation rate for E2 cytoplasmic RNA at late times reflected an increase in formation of both major species. Moreover, for all time points examined 66% of the mRNA species had a 5' end from map position 75, and 33% had a 5' terminus from position 72. Continuous labeling experiments provided evidence that both RNA forms have comparable half-lives. The results suggest that the two major species encoded by E2 are regulated in a coordinate fashion late in infection.

A small nuclear ribonucleoprotein is required for splicing of adenoviral early RNA sequences

The size and structure of viral RNA species synthesized in nuclei isolated during the early phase of productive infection by adenovirus type 2 have been examined by electrophoresis in denaturing polyacrylamide cells and the nuclease S1 assay. The major products of transcription in vitro of early regions 1 and 2 in the adenoviral genome are processed RNA molecules that appear to be correctly spliced in isolated nuclei. Splicing of adenoviral RNA molecules is inhibited when nuclei are preincubated with antibodies from systemic lupus erythematosus patients that immunoprecipitate small nuclear ribonucleoprotein particles. The specificity of these antibodies suggests that ribonucleoprotein particles containing U1 RNA are required for splicing of the adenoviral RNA sequences we have examined.

The sequence of the 3' non-coding region of the hexon mRNA discloses a novel adenovirus gene

We report the sequence of a 1164 nucleotide long DNA segment, located between map positions 59.5 and 62.8 on the adenovirus type 2 genome. The sequence comprises the 701 nucleotides long 3' non-coding region of the hexon mRNA as well as several important processing signals. The sequence revealed unexpectedly that the 3' non-coding region of the hexon mRNA contains a 609 nucleotide long uninterrupted translational reading frame following a potential initiator AUG. A late 14S mRNA, corresponding to the open reading frame, could be identified by S1 nuclease mapping and electronmicroscopy. The mRNA shares a poly(A) addition site with the hexon and pVI mRNAs, and carries a leader sequence which is related, and probably identical, to the tripartite leader, found in late adenovirus mRNAs. The junction between the leader and the body of this novel mRNA is located within the coding part of the hexon gene.

Cloning of a DNA fragment from the left-hand terminus of the adenovirus type 2 genome and its use in site-directed mutagenesis

The HpaI E fragment (0-4.5 map units) of adenovirus type 2 (Ad2) DNA was cloned in the plasmid vector pBR322. Excision of the viral insert with PstI and XbaI generated a fragment which comigrated with Ad2 XbaI-E (0-3.8 map units), and this fragment was ligated to the 3.8-100 fragment generated by XbaI cleavage of the DNA of the Ad5 mutant, dl309 (N. Jones and T. Shenk, Cell 17:683-689, 1979). Transfection with the ligation products resulted in the production of progeny virus which was able to replicate on both HeLa and line 293 cells, demonstrating the biological activity of the sequences rescued from the plasmid. Small deletions were introduced around the SmaI site (map position 2.8) within the cloned viral insert, and the altered DNA sequences were reintroduced into progeny virus as described above. The mutant viruses grew well on line 293 cells but plaqued with greatly reduced efficiency on HeLa cells, exhibiting a host range phenotype similar to previously described mutants with lesions located within this region of the genome. When plasmid-derived left-end fragments containing pBR322 DNA sequences to the left of map position 0 were ligated to the 3.8-100 fragment of dl309 DNA, the infectivity of the ligation products was not reduced. However, all progeny viruses examined yielded normal-size restriction enzyme fragments from their left-hand ends, indicating that the bulk of the pBR322 DNA sequences are removed either prior to or as a consequence of the replication of the transfecting DNA molecules.

Nucleotide sequence analysis of a region of adenovirus 5 DNA encoding a hitherto unidentified gene

The nucleotide sequence of a region located on the adenovirus type 5 genome between coordinates 59.9 and 62.5 has been determined. This region comprises the 3'-termini of mRNAs coding for the hexon and the DNA binding protein. The sequence reveals the presence of an open reading frame in r-strand transcripts downstream from the hexon termination codon. The protein predicted from this region has a MW of 23,068 daltons. Based on the characteristics of the mutant Ad2ts1, which maps between coordinates 59.9 and 69.9, it is probable that the predicted protein is involved in processing of late proteins.

Regulation of integrated adenovirus sequences during adenovirus infection of transformed cells

A human cell line (293) transformed by adenovirus type 5 encodes mRNA's and proteins from the early region 1 (E1) of the viral genome. These products correspond to those synthesized early after adenovirus infection of normal cells. This pattern of expression is different from that observed at later times in the lytic cycle. We have determined whether integrated sequences can undergo the early-late transition during infection of transformed cells. Cultures of 293 cells were infected with mutants of adenovirus type 5 that have deletions in EI genes. In such infections, the integrated sequence complements the deletion mutants so that viral DNA replication, late mRNA and protein synthesis, and viral assembly occur. Because the infecting genomes lack EI sequences, the products synthesized from the integrated DNA could be analyzed. In contrast to the early-late transition that occurs with EI DNA in free viral genomes, the pattern of mRNAs and proteins made from the integrated sequences was restricted to the early pattern. Assuming that the viral sequences in 293 cells have not become altered during the history of the cells, our results suggest that regulation of integrated adenovirus genes may not be determined exclusively by nucleotide sequence recognition. Apparently, during infection certain factors prevent the integrated viral genes from responding to the regulatory signals which control late expression from free EI DNA. The distinction between integrated and free viral sequences might reflect the different fates of viral and host transcripts during the lytic cycle of adenovirus.

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.

A mutant immunoglobulin light chain is formed by aberrant DNA- and RNA-splicing events

A mutant immunoglobulin gene has been formed by an abnormal (non V/J) recombination event such that abnormal RNA splicing is required to form a mutant light chain. The structure of the gene suggests that the small palindrome thought to be involved in V/J joining also provides the basis for this abnormal DNA recombination and that the absence of a J segment and RNA splice signal allows an abnormal RNA splicing reaction to occur.

Predicted structure of two adenovirus tumor antigens

Early adenovirus type 2(Ad2) mRNA sequences have been cloned by using the pBR322 plasmid as a vector. Two clones that include sequences from region E1B were identified and their DNAs were characterized by hybridization, restriction enzyme cleavage, and DNA sequence analysis. The results showed that the clones were derived from two different spliced mRNAs. By combining our results with the established DNA sequence for region E1B of the closely related adenovirus type 5[Maat, J., van Beveren, C.P. & van Ormondt, H. (1980) Gene, in press] it was possible to deduce the structure of a 13S and a 22S mRNA. The two mRNAs differ from each other by the size of their intervening sequences. If translation starts at the first AUG following the cap, the 22S mRNA encodes a Mr 67,000 polypeptide that is terminated by a UGA stop codon located immediately before the splice, whereas the 13S mRNA encodes a Mr 20,000 polypeptide that is translated in different reading frames before and after the splice. The Mr 20,000 and 67,000 polypeptides correspond in molecular weight to two proteins that invariably are precipitated from infected cell extracts by antisera from animals carrying adenovirus-induced tumors.

Regulation of early adenovirus transcription: a protein product of early region 2 specifically represses region 4 transcription

An aspect of the regulation of early adenovirus gene expression has been studied by measuring the rates of transcription of several viral transcription units during infection by wild-type (WT) adenovirus type 5 and a temperature-sensitive mutant, H5ts125. It has previously been shown that two transcription units (regions 2 and 4) are subject to negative control. During the course of early infection, transcription of regions 2 and 4 increased to a maximal rate and then declined. The decline from each of these transcription units appeared to be a specific shutoff of transcription, because the transcription of another early transcription unit (region 1A) remained constant during early infection and, in the absence of protein synthesis, the apparent shutoff of region 2 and region 4 transcription did not occur. At the nonpermissive temperature for the mutant, the kinetics of transcription of early region 2 were identical to the kinetics of transcription of WT. Thus, the repression of transcription of region 2 occurred in H5ts125-infected cells as well as in WT-infected cells. Region 4 transcription, however, was not repressed during H5ts125 infection at the nonpermissive temperature. After a maximal rate of transcription was reached, this rate was maintained throughout the course of the experiment. Furthermore, the repression of region 4 transcription appears to be the result of a block of initiation of transcription rather than the result of an inducement of premature termination of transcription. Therefore, it can be concluded that a product of the adenovirus region 2 gene, which is the site of the mutation for H5ts125, is responsible for the specific shutoff of region 4 transcription.