Relationship of mRNA from Productively Infected Cells to the Complementary Strands of Adenovirus Type 2 DNA

The complementary strands of adenovirus type 2 (Ad2) DNA were separated by buoyant density gradient centrifugation with poly (U, G). The complementary strand DNA was shown to remain intact through the course of strand separation. The l-strand of Ad2 DNA, appearing in the less dense complex with poly (U, G) in neutral CsCl density gradients, was shown to have a buoyant density in alkaline (pH 12.5) CsCl density gradients which is 2 to 3 mg per ml greater than that of its complement (h-strand). Renaturation of purified complementary strand DNA was observed only in mixtures of h- and l-strand DNA, and then with the second-order reaction rate expected for Ad2 DNA. Hybridization of the complementary strands of Ad2 DNA with cytoplasmic mRNA isolated from infected HeLa cells was performed in liquid phase and analyzed by hydroxylapatite chromatography. Before viral DNA synthesis (6 h after infection), 13 to 18% of the h-strand and 30 to 35% of the l-strand were represented in viral mRNA. Late (18 h) after infection the mRNA represented 20 to 25% and 63 to 68% of the h- and l-strands, respectively. Most, if not all sequences present in viral mRNA before viral DNA synthesis were also present in the cytoplasm late in infection.     

mRNA from the transforming segment of the adenovirus 2 genome in productively infected and transformed cells.

We have identified two mRNA species transcribed from the adenovirus 2 genome section (HindIII-G fragment) believed to harbor genes for initiation and maintenance of cell transformation. The HindIII-G fragment occupies the left 7.5% of the genome and is transcribed from left to right [poly(U:G) r strand]. Poly(A)-terminated labeled mRNA was isolated from polyribosomes of adenovirus 2 early infected KB cells and from the transformed cell line 8617, hybridization purified using the HindIII-G fragment, and electrophoresed on formamide-polyacrylamide gels. Viral mRNA's of 24S (1.2 X 10(6) daltons) and 14S (4.5 X 10(5) daltons) were isolated from early infected cells and of 22S (1.0 X 10(6) daltons) and 14S from 8617 cells. Hybridization competition indicated that HindIII-G-specific mRNA was present in the polysomes at one-sixth the concentration late after infection as compared with early, indicating that the proteins coded by the transforming segment may be synthesized at reduced amounts during late stages. Only 1/10 the amount of RNA labeled late annealed to the G fragment as compared with that labeled early (per weight of RNA). Thus, synthesis of transforming gene mRNA is probably "turned off" late after infection. Both 24S (22S) and 14S mRNA's from infected and 8617 cells were complementary to the Hpa I-E fragment (left 4.1% of genome). The Hpa I-E fragment is too small to encode 24S and 14S species, which implies that the 5'-terminal regions of both species are coded by the same DNA sequences.     

Carcinogenic purine N-oxide ester modifies covalently all common bases in polynucleotides

The carcinogen 1-methyl-3-hydroxyxanthine after esterification binds covalently to polynucleotides, RNA and DNA. All four ribopolynucleotides and poly(dT) are targets. Depending on reaction conditions, covalent binding is greatest to poly(A) followed by poly(U), poly(dT), poly(G), poly(C), RNA and DNA. Maximal covalent modification of DNA is one moiety per 360 nucleotides. All modified polynucleotides, RNA and DNA, except poly guanylic acid have been enzymatically digested and the major adducts characterized as nucleosides.     

Complementary strand-specific sequences from unique fragments of adenovirus type 2 DNA for hybridization-mapping experiments

Separation of the complementary strands of adenovirus type 2 DNA by poly(U,G)-CsCl density gradient centrifugation permitted studies of Ad2³ DNA renaturation with independently variable concentrations of each complementary strand. Single-stranded DNA was isolated by hydroxylapatite chromatography following exhaustive incubation under such conditions, and was found to selectively represent sequences of the complement present in excess during the incubation. This result was exploited in a general method for isolation of complementary strand-specific sequences of radioactively labeled Ad2 DNA or restriction enzyme fragments of Ad2 DNA. Liquid phase saturation-hybridization experiments were carried out with labeled DNA representing each complementary strand of the six endo R.EcoRI cleavage fragments of Ad2 DNA and unlabeled messenger RNA prepared from HeLa cells late after productive infections with Ad2. The results were combined with the known endo R.EcoRI cleavage map of Ad2 DNA to construct a low-resolution map showing physically separated regions, on both complementary strands of Ad2 DNA, represented in mRNA late after infection.     

Electrophoretic strand separation of long DNAs with poly (U,G) in agarose gels.

We have found that binding of poly(U,G) to single-stranded DNA decreases its mobility in 0.3% agarose gels. Differential binding to the complementary strands of denatured duplex DNA provides a simple method for strand separation. The method is shown to work with bacteriophage lambda DNA, adenovirus DNA and mtDNA for Tetrahymena pyriformis. In all cases the strand that binds more poly(U,G) in CsCl gradients also binds more in gels. The separated strands can be directly blotted from the gel onto nitrocellulose filters and used for hybridization experiments.     

Ribonuclease H: a Ubiquitous Activity in Virions of Ribonucleic Acid Tumor Viruses

Ten ribonucleic acid (RNA) tumor viruses grown in five different host cell species and three non-oncogenic viruses from three different virus groups have been examined for ribonuclease H content. Three different substrates were used to assay ribonuclease H: calf thymus [(3)H]RNA-deoxyribonucleic acid (DNA) hybrid prepared with denatured calf thymus DNA and Escherichia coli DNA-directed RNA polymerase, (3)H-polydenylic acid [(3)H-poly(A)] complexed to polydeoxythymidylic acid [poly(dT)], and (3)H-polyuridylic acid [(3)H-poly(U)] complexed to polydeoxyadenylic acid [poly(dA)]. All ten RNA tumor viruses contained ribonuclease H activity which degraded the RNA of both the calf thymus hybrid and poly(A)-poly(dT), whereas only the ribonuclease H in the Moloney strain of murine sarcoma-leukemia virus and in RD-feline leukemia virus hydrolyzed the RNA strand of poly(U)-poly(dA). No appreciable ribonuclease H activity was detected in influenza, Sendai, or vesicular stomatitis virus. The ribonuclease H and RNA-directed DNA polymerase activities in Moloney murine sarcoma-leukemia virus were inseparable by phosphocellulose chromatography or glycerol gradient centrifugation, but appeared to be partially separated by diethylaminoethyl-cellulose chromatography.     

Isolation and Characterization of Adenovirus Messenger Ribonucleic Acid in Productive Infection

Messenger ribonucleic acid (mRNA) from cells productively infected with adenovirus type 2 was isolated by affinity chromatography on polyuridylic acid [poly (U)] bound to Sepharose. At least 90% of the polyadenylic acid [poly (A)]-containing polysomal mRNA was retained by the poly (U) Sepharose and thus separated from more than 95% of the ribosomal RNA and transfer RNA. In these experiments, 65% of the early (3 to 5 hr postinfection) and 85% of the late (14 to 16 hr postinfection) virus-specific RNA was retained by the poly (U) Sepharose. Early in the infection 18%, and late in the infection more than 95%, of the poly (A)-containing fraction, eluted from the poly (U) Sepharose with 90% formamide, was adenovirus-specific, as shown by exhaustive hybridization. Different patterns, containing several distinct species of viral mRNA, were detected early and late in the infectious cycle. No distinct viral mRNA lacking poly (A) was discovered.     

Hybridization maps of early and late messenger RNA sequences on the adenovirus type 2 genome.

Specific fragments of adenovirus type 2 DNA, generated by cleavage with restriction endonucleases endoR.EcoRI, endoR.HpaI and endoR.HindIII were used in hybridization-mapping experiments. The complementary strands of individual cleavage fragments were separated by the method of Tibbetts &; Pettersson (1974). Liquid hybridizations were performed with ³²P-labeled separated strands of cleavage fragments and messenger RNA extracted from cells early and late after adenovirus infection. The fraction of each fragment strand which was represented in “early” and “late” messenger RNA was determined by chromatography on hydroxylapatite. Early messenger RNA was found to be derived from four widely separated regions, two on the 1- and two on the h-strand (h- and l- refer to the strand with heavy and light buoyant density in CsCl when complexed with poly(U, G)). Messenger RNA, present exclusively late after infection, is derived from several locations, predominantly from the l-strand with a major block of continuous sequences extending between positions 0.25 and 0.65 on the unit map of the adenovirus type 2 genome.     

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.     

A method for isolation of oligo(uridylic acid)-containing messenger ribonucleic acid from HeLa cells

When cytoplasmic polyadenylated ribonucleic acid [poly(A+)RNA] from HeLa cells was treated with ribonuclease H (RNase H) and oligodeoxythymidylate [oligo(dT)] to remove its 3'-poly(A) tail, an increased binding to poly(A)-agarose was observed. The bound material, which comprised 4-6% of the initial RNA, contained 65-80% of the oligo(uridylic acid) [oligo(U)] sequences generated by RNase T1 digestion. Oligo(U) isolated from the bound fraction was shown to be 83% U and to have a U/G ratio of 33. In contrast, oligo(U) from the unbound material was 77% U and had a U/G ratio of 13, suggesting that it is shorter and less U rich than the oligo(U) in the bound fraction. On sucrose gradients, oligo(U+)RNA consistently sedimented with a larger s value than oligo(U-) RNA. The oligo(U) content of oligo(U+) RNA suggests one oligo(U) tract of 33 nucleotides per RNA molecule of 2000-3000 residues.     

Identification of the "sense" -strand of T7 DNA through heteroduplex directed in vitro enzyme synthesis

Summary Enzyme synthesisin vitro directed by T7 heteroduplex DNA is observed when the H strand [the strand assuming the higher density in combination with poly(G,U)], carries the wild allele. This is true for enzyme synthesis mediated byE. coli RNA polymerase or by T7 phage RNA polymerase. Experiments of Wetekam (accompanying paper) using heteroduplexes with markers in thegal operon ofE. coli gave analogous results.     

Location of sequences on the adenovirus genome coding for the 5.5S RNA.

The origin of a low molecular weight virus-associated RNA (VA-RNA) was mapped by hybridization of VA-RNA to specific fragments of adenovirus type 2 DNA, obtained after cleavage with three different restriction endonucleases. VA-RNA was found to hybridize exculsively to the l-strand [strand with low buoyant density in CsCl when complexed with poly(U,G)] of a segment of the viral DNA which is located between positions 0.27 and 0.32 on the unit map of the adenovirus type 2 genome.     

RNA-binding properties of a translational activator, the adenovirus L4 100-kilodalton protein.

The adenovirus L4 100-kDa nonstructural protein (100K protein) is required for efficient initiation of translation of viral late mRNA species during the late mRNA species during the late phase of infection (B. W. Hayes, G. C. Telling, M. M. Myat, J. F. Williams, and S. J. Flint, J. Virol. 64:2732-2742, 1990). The RNA-binding properties of this protein were analyzed in an immunoprecipitation assay with the 100K-specific monoclonal antibody 2100K-1 (C. L. Cepko and P. A. Sharp, Virology 129:137-154, 1983). Coprecipitation of the 100K protein and 3H-infected cell RNA was demonstrated. The RNA-binding activity of the 100K protein was inhibited by single-stranded DNA but not by double-stranded DNA, double-stranded RNA, or tRNA. Competition assays were used to investigate the specificity with which the 100K protein binds to RNA in vitro. Although the protein exhibited a strong preference for the ribohomopolymer poly(U) or poly(G), no specific binding to viral mRNA species could be detected; uninfected or adenovirus type 5-infected HeLa cell poly(A)-containing and poly(A)-lacking RNAs were all effective inhibitors of binding of the protein to viral late mRNA. Similar results were obtained when the binding of the 100K protein to a single, in vitro-synthesized L2 mRNA was assessed. The poly(U)-binding activity of the 100K protein was used to compare the RNA-binding properties of the 100K protein prepared from cells infected by adenovirus type 5 and the H5ts1 mutant (B. W. Hayes, G. C. Telling, M. M. Myat, J. F. Williams, and S. J. Flint, J. Virol. 64:2732-2742, 1990). A temperature-dependent decrease in H5ts1 100K protein binding was observed, correlating with the impaired translational function of this protein in vivo. By contrast, wild-type 100K protein RNA binding was unaffected by temperature. These data suggest that the 100K protein acts to increase the translational efficiency of viral late mRNA species by a mechanism that involves binding to RNA.     

Stability of triple helices containing RNA and DNA strands: experimental and molecular modeling studies.

UV-absorption spectrophotometry and molecular modeling have been used to study the influence of the chemical nature of sugars (ribose or deoxyribose) on triple helix stability. For the Pyrimidine.purine* Pyrimidine motif, all eight combinations were tested with each of the three strands composed of either DNA or RNA. The chemical nature of sugars has a dramatic influence on triple helix stability. For each double helix composition, a more stable triple helix was formed when the third strand was RNA rather than DNA. No stable triple helix was detected when the polypurine sequence was made of RNA with a third strand made of DNA. Energy minimization studies using the JUMNA program suggested that interactions between the 2'-hydroxyl group of the third strand and the phosphates of the polypurine strand play an important role in determining the relative stabilities of triple-helical structures in which the polypyrimidine third strand is oriented parallel to the polypurine sequence. These interactions are not allowed when the third strand adopts an antiparallel orientation with respect to the target polypurine sequence, as observed when the third strand contains G and A or G and T/U. We show by footprinting and gel retardation experiments that an oligoribonucleotide containing G and A or G and U fails to bind double helical DNA, while the corresponding DNA oligomers form stable triple-helical complexes.     

Interactions of nuclear estrogen receptor with DNA and RNA

The interaction of the nuclear estrogen receptor from hen oviduct with nucleic acids were studied by competition assay using DNa-cellulose centrifugation. We demonstrated that the estradiol-receptor complex binds similarly well to poly(A) RNA and denatured DNA. The estrogen receptor was found to interact more strongly with poly(G), poly(U) than with poly(A), poly(C). The receptor complex binds similarly to poly(A) and poly(dA), and to poly(U) and poly(dU). However, the receptor complex shows stronger binding to poly(G) than to poly(dG) and to poly(C) than to poly(dC). Studies with heteropolyribonucleotides indicated that poly(U1G1) is more effective in competing for the estrogen receptor, and poly(AC) and poly(AUG) are moderately effective, whereas poly(ACU) is least effective. GMP and dGMP showed some competition for the nuclear receptor at 300-fold higher nucleotide concentrations than that of the synthetic poly(G). Observations that the nuclear estrogen receptor binds to poly(A) RNA and interacts selectively with polyribonucleotides suggest that the estrogen receptor-RNA interaction may play a role for the function of estrogens in gene regulation.