Amount of viral DNA in the genome of cells transformed by adenovirus type 2

Relationship between the Epstein-Barr virus genome and nasopharyngeal carcinoma in Caucasian patients

In order to explore whether undifferentiated nasopharyngeal carcinoma (NPC) shows a regular association with Epstein-Barr virus (EBV), regardless of the geographical and ethnic origin of the patient, a correlated histopathological and nucleic acid hybridization study was performed on biopsies from Caucasian patients with nasopharyngeal carcinomas and from various controls. Among 12 undifferentiated NPCs, 11 were positive for EBV-DNA, with multiple copies of the viral genome per cell. Serological tests showed elevated anti-VCA and anti-EA(DA) titers. Six NPCs with various degrees of squamous differentiation, four malignant lymphomas of the nasopharynx and seven carcinomas located outside the nasopharynx were EBV-DNA negative. These findings further stress the uniqueness and regularity of the association between EBV-DNA and undifferentiated NPC. Clearly, the association extends over geographical barriers and holds true not only in the previously studied, moderate-incidence African ethnic group, but also in the low-incidence Western patients.

14q+ marker chromosome in an EBV-genome-negative lymph node without signs of malignancy in a patient with EBV-genome-positive nasopharyngeal carcinoma

In a patient with an EBV-genome-positive nasopharyngeal carcinoma, an EBV-genome-negative inguinal lymph node without histological evidence of malignant lymphoma or metastatic carcinoma growth was found to contain a 14q+ marker chromosome, identified as an 8;14 translocation, in all cells analyzed. This observation indicates that chromosome aberrations may precede histological signs of malignancy. The possible implication of this finding in relation to the postulated role of the 14q+ marker and lymphoma development is discussed.

The spliced structures of adenovirus 2 fiber message and the other late mRNAs

All late adenovirus 2 messenger RNAs, except perhaps that for peptide IX, are composite molecules with sequences derived from at least two to five or more separate portions of the genome, as determined by electron microscopic analyses of polysomal RNA hybridized to single- or double-stranded DNA. We previously reported that eight different rightward-transcribed mRNAs contain, at their 5' ends, a common three-part leader sequence derived from coordinates 16.6, 19.6 and 26.6, and that a ninth mRNA consists of sequences from 4.6--6.1 linked directly to those from 9.7--11.0 (Chow et al., 1977a; revised coordinates). We now demonstrate that four additional RNA species also have the same tripartite leader joined to messages with 5' ends located at coordinates at 29.1, 30.5, 33.9 and 42.8. The RNA transcript extending from 29.1--39.0 covers most or all of the viral associated (VA) RNA genes (29.0--30.1). The late RNAs can be grouped into several families of transcripts in which two or three mRNAs have the same 3' end and 3' proximal sequences, but differ substantially in length at the 5' end and, therefore, the coordinate at which the leader sequences are attached to the main body of the message. The number of RNA species transcribed from the Ad2 chromosome between coordinates 29 and 50 exceeds the number of identified Ad2 proteins. Several pairs of messages differing in length by a few percent may thus encode the same protein or have a precursor-product relationship. We have also found that a subpopulation of the polysomal mRNAs for the fiber protein, the most distal gene (86.3--91.2) in the rightward transcription unit, has a fourth leader component "y" (78.6--79.1) in addition to the common tripartite leader sequences. Less frequent fiber RNA species have fifth "x" (76.9--77.3) and/or sixth "z" (84.7--85.1) leader segments. Transcripts with x, y or z segments might be processing intermediates, and it is possible to arrange these species into an array suggestive of multiple pathways for the maturation of fiber mRNA. mRNA transcribed at late times from the L strand between coordinates 15.0 and 11.0 has a single component leader located 200 bases from the main body of the gene from coordinate 16.1 to 15.7. This leader originates from a site very close to the first leader component (16.5--16.6) of the R strand messages and suggests the presence of adjacent L and R strand promoters from which transcription diverges. Taken together, these results emphasize the diversity of splicing patterns and the variety of recombined sequences generated during the synthesis of late Ad2 mRNAs.

Adenovirus type 2 late mRNA's: structural evidence for 3'-coterminal species

Adenovirus type 2-infected HeLa cells were labeled with 32PO4 during the period 14 to 17 h postinfection. Viral mRNA's with polyadenylic acid were isolated by polyuridylic acid Sepharose chromatography and fractionated according to size by electrophoresis through an acrylamide-agarose slab gel. Messenger bands were eluted and partially degraded with alkali. RNA fragments from each band that contain polyadenylic acid were isolated by polyuridylic acid Sepharose chromatography and fingerprinted two-dimensionally after T1 RNase digestion. Three bands, with mobilities of approximately 26S, 21S, and 18S, shared two large characteristic T1 oligonucleotides in common in the fingerprints of their 3'-terminal sequences. These oligonucleotides were mapped with a Hpa II restriction fragment of adenovirus type 2 DNA with coordinates 49-50.2. We conclude that the three mRNA's are coterminal in sequence at their 3' ends and overlap at internal positions. Implications for the protein-coding potential of these mRNA's and the mechanisms of adenovirus tyep 2 late RNA processing are discussed.

Studies of the transcription of viral genome in adenovirus 5 transformed cells

Transcription of the human adenovirus 5 genome in transformed rat embryo cells (DFK3) was investigated using two different approaches. Preferential digestion of transcribed viral sequences by DNase I was analysed using kinetics of renaturation of 32P-labeled Ad5 HpaI restriction fragments in the presence of material which was stable after nuclease treatment. The second approach was the hybridization of 32P-labeled nuclear RNA from transformed cells with Ad5 restriction fragments which were attached to a nitrocellulose filter. These two methods gave similar results. It was found that not all integrated regions of the Ad5 genome are active in transformed cells. 2,5 copies of the HpaI-E fragment of Ad5 DNA were found in transformed DFK3 cell line. Nuclear RNA from these cells hybridized to HpaI-E fragment of Ad5 DNA, but only about half of sequences of the integrated HpaI-E fragment was sensitive to DNase I digestion.

Relationship between the Epstein-Barr virus and undifferentiated nasopharyngeal carcinoma: correlated nucleic acid hybridization and histopathological examination

In order to examine critically the closeness of association between Epstein-Barr virus (EBV) DNA and nasopharyngeal carcinoma (NPC) a correlated histopathological and nucleic acid hybridization study was performed on 51 undifferentiated NPC, 4 NPC with some signs of squamous differentiation, 7 nasophayngeal tumors of other histological types and 14 head and neck carcinomas located outside the nasopharynx. All 51 undifferentiated NPCs contained significant numbers of EBV-genome copies per cell. Two of the somewhat differentiated NPCs were also EBV-DNA-positive, whereas 2 were negative. Of the 7 other nasopharyngeal tumors, 1 was EBV-DNA-positive. Histological examination, however, showed that this was a typical Burkitt lymphoma. The other 6 tumors were all EBV-DNA-negative lymphoproliferative malignancies. All 14 had head and neck carcinomas located outside the nasopharynx were EBV-DNA-negative. The sera of undifferentiated NPC patients had elevated antibody titers against the EBV-determined antigens, the EA (D) componet in particular. These findings confirm that there is a regular association between EBV-DNA and undifferentiated NPC.

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

RNA isolated from the cytoplasm of human cells at late times after infection by adenovirus type 2 (Ad2) has been fractionated by hybridization to fragments of Ad2 DNA which were produced by digestion with the restriction endonucleases Hpa I, Eco RI, Bam HI and Hind III. Cell-free translation of these partially purified mRNAs indicates that the genes for the late Ad2 proteins lie within the following intervals on the conventional Ad2 map: 15K (4.4-17.0 map units), IX and IVa2 (7.5-17.0), IIIa (29.1-40.9), III and V (29.1-57.0), pVIII (40.9-57.0), pVI and II (40.9-70.7), 100K (59.0-83.4), pVIII (70.7-83.4) and IV (85.0-100). In addition to the primary hybridization of the late Ad2 mRNAs to the regions indicated above, most late Ad2 mRNAs (except those for 15K, IX and IVa2) exhibited some hybridization to a secondary site between 17.0 and 29.1 map units.

Two adenovirus mRNAs have a common 5' terminal leader sequence encoded at least 10 kb upstream from their main coding regions

The messenger RNAs encoding two late adenovirus serotype 2 (Ad2) proteins, fiber and 100K, were purified by hybridization to restriction endonuclease fragments of Ad2 DNA followed by electrophoresis on polyacrylamide gels containing 98% formamide. The 5' terminal oligonucleotides generated by RNAase T1 digestion of the messengers were selected by dihydroxyboryl-cellulose chromatography. Both mRNAs gave an identical 5'-undecanucleotide with the general structure 7mG5'ppp5'AmC(m)U(C4,U3)G. This undecanucleotide could be removed by mild RNAase treatment from the mRNA after hybridization to DNA fragments containing the main coding sequence of the messenger. In contrast, a small region defined by Bal I-E (14.7-21) protects this undecanucleotide from RNase. A second region contained within both Hind III-B (17-31.5) and Hpa I-F (25.5-27.9), although unable to protect the undecanucleotide, hybridizes to both fiber and 100K mRNAs and protects a similar sequence of 100-150 nucleotides. These observations suggest that both mRNAs contain a long common sequence, complementary to at least two different sites on the Ad2 genome remote from the start of these two genes. The implications of these findings are discussed, and a general mechanism is presented for the biosynthesis of mRNAs from larger precursor molecules, based on intramolecular ligation.

A novel method to map transcripts: evidence for homology between an adenovirus mRNA and discrete multiple regions of the viral genome

A method has been devised which permits mapping of transcripts by a two-step hybridization procedure (sandwich hybridization). RNA extracted from cells infected with an adenovirus-SV40 hybrid (Ad2+ND1) was hybridized to restriction endonuclease fragments of adenovirus type 2 (Ad2) DNA immobilized on nitrocellulose filters. RNAs containing both Ad2 and SV40 sequences formed duplexes through their Ad2 sequences, leaving their SV40 sequences as protruding tails. Annealing with 32P-labeled SV40 DNA caused these tails to become labeled, permitting autoradiographic identification of the sequences of Ad2 DNA which are homologous to the RNA. The high sensitivity of this technique, achieved through the use of 32P-labeled RNA of high specific activity, has led to the observation that hybridization of Ad2+ND1 RNA occurs at several locations on the Ad2 genome, in addition to the expected sites of hybridization proximal to the SV40 insertion.

An amazing sequence arrangement at the 5' ends of adenovirus 2 messenger RNA

The 5' terminal sequences of several adenovirus 2 (Ad2) mRNAs, isolated late in infection, are complementary to sequences within the Ad2 genome which are remote from the DNA from which the main coding sequence of each mRNA is transcribed. This has been observed by forming RNA displacement loops (R loops) between Ad2 DNA and unfractionated polysomal RNA from infected cells. The 5' terminal sequences of mRNAs in R loops, variously located between positions 36 and 92, form complex secondary hybrids with single-stranded DNA from restriction endonuclease fragments containing sequences to the left of position 36 on the Ad2 genome. The structures visualized in the electron microscope show that short sequences coded at map positions 16.6, 19.6 and 26.6 on the R strand are joined to form a leader sequence of 150-200 nucleotides at the 5' end of many late mRNAs. A late mRNA which maps to the left of position 16.6 shows a different pattern of second site hybridization. It contains sequences from 4.9-6.0 linked directly to those from 9.6-10.9. These findings imply a new mechanism for the biosynthesis of Ad2 mRNA in mammalian cells.

Transformation of lymphocytes by Herpesvirus papio

Cotton-topped (CT) or white-lipped (WL) marmoset lymphocytes were transformed in vitro with herpesvirus papio (HVP) into permanently growing lymphoblastoid cell lines (LCL). Five of 9 HVP-transformed CT cell lines contained cells with antigens reacting with antibodies to Epstein-Barr virus (EBV) capsid antigen (VCA) and/or to EBV-induced early antigens (EA). None of 12 WL LCL revealed such antigen-producing cells. Cells from both groups of cultures failed to react with antibodies to the EBV-specified nuclear antigen (EBNA). Exposure of baboon circulating lymphocytes to X-irradiated HVP or EBV-carring cells, or to suspensions of EBV resulted in establishment of LCL which all contained VCA and/or EA-positive, but no EBNA-positive cells. Nuclear antigens were undetectable also with anti-VCA-positive sera from baboons, chimpanzees, or other non-human primates. DNA-complementary RNA (cRNA) filter hybridization with EBV cRNA showed that with one exception transformed CT or WL marmoset cells contained at least 1-2 virus genome equivalents per cell, while at least 12-25 virus genome equivalents per cell were detected in transformed baboon cells. These data need confirmation by DNA-DNA reassociation kinetics.

One predominant 5'-undecanucleotide in adenovirus 2 late messenger RNAs

Oligonucleotides containing the 5' termini of adenovirus 2 mRNA are selectively retained on columns of dihydroxyboryl cellulose. When total late adenovirus 2 mRNA was treated with RNAase T1, a single 5' terminal oligonucleotide was isolated, although in several states of methylation. This oligonucleotide has the general structure m7G5'ppp5' AmCmU(C4,U3)G. Since at least twelve individual species of mRNA must be present late after infection, this finding was unexpected and its significance is discussed.

Reassociation of complementary strand-specific adenovirus type 2 DNA with viral DNA sequences of transformed cells

Complementary strand-specific adenovirus DNA, either full length or from restriction enzyme cleavage fragments, was used to estimate the fractional representation and abundance of viral sequences in two adenovirus type 2 (Ad2)-transformed rat cell lines, A2F19 and A2T2C4. The reassociation method introduced is based on the linear relationship, after exhaustive hybridization, between the inverted fraction of hybrid DNA and the molar ratio of probe to cellular DNA in the reaction mixture. The amount of viral DNA in A2F19 cells represents 12 to 14% of the viral genome at a level of around seven copies per diploid cell equivalent. For the cell line A2T2C4, the pattern of integrated viral DNA sequences is more complex. With full-length Ad2 DNA strands as a probe, about 56% of the probe was represented in cellular DNA. When each of the four BamHI fragment strands of Ad2 DNA was used as a probe, the fraction of the viral DNA present also amounted to around 56% with one to five copies from different regions of the viral genome. The results demonstrate the advantage of using strand-specific viral DNA as a probe in reassociation analysis with denatured cell DNA. The method should be useful in any system in which complementary strand separation of viral DNA sequences can be achieved.

Two "early" mRNA species in adenovirus type 2-transformed rat cells

mRNA isolated from adenovirus 2-infected HeLa cells at early times during the productive cycle and from two lines of adenovirus 2-transformed rat embryo cells (F17 and T2C4) was fractionated on sucrose gradients after disaggregation. Viral mRNA species were identified by hybridization across such gradients with the separated strands of restriction endonuclease fragments of 32P-labeled DNA known to be complementary to adeovirus 2 "early" and adenovirus 2-transformed cell mRNA. mRNA transcribed from the left-hand 14% of the adenovirus 2 genome was found to comprise two species, 16 to 17S and 20 to 21S: the same sized mRNA's were present both at early times during productive infection and in the two transformed rat cell lines. Direct comparison of the sequences present in these two mRNA species by additional saturation hybridizations suggests that they are not related to one another. Three additional regions of the adenovirus 2 genome, all of which are located in the right-hand 40% of the adenovirus 2 genome, are complementary to early mRNA sequences: each of these appears to specify one major mRNA species of about 22S. Thus, five major species of adenovirus type 2 early mRNA have been identified. Two of these, copied from the left-hand 14% of the viral genome, are also present in adenovirus 2-transformed rat cells.

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

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

Visualization and mapping of late nuclear adenovirus RNA

Nuclei of KB cells harvested at late stages of productive infection with adenovirus type 2 (Ad2) harbor RNA molecules which measure up to 13 mum in length, as determined by electron microscopy of denatured RNA. While some of the molecules display features of secondary structure that are characteristic for precursor rRNA, our interest was in those showing almost no intramolecular folding. When hybridized to double stranded viral DNA under conditions which favor RNA:DNA duplex formation, nuclear AD2 RNA displaces the homologous DNA region and generates R loop structures whose size is proportional to the length of the hybridizing RNA. Slowly sedimenting RNA forms small R loops, whereas RNA of high sedimentation velocity generates loops that span a large proportion of the DNA length. Using SV40 sequences within Ad2+ND4 hybrid DNA as a position marker, we oriented many of the R loops on the conventional Ad2 map. Our analysis was restricted to the most abundant sequences of late Ad2 nuclear RNA participating in R loop formation. A small but significant proportion of large RNA generates loops between map positions 0.3 and 0.9. The much more frequent RNA of intermediate size (although larger than mRNA) hybridizes with midpoints near map positions 0.55 and 0.88--that is, near the gene locations for hexon and fiber. Our findings are compatible with the idea that the nuclear RNAs visualized in this study are intermediates in a processing pathway leading to mature forms of late Ad2 mRNA.

Structure of the inverted terminal repetition of adenovirus type 2 DNA

Several secondary structure features involving the ends of single strands of adenovirus type 2 DNA have been studied by electron microscopy by both the gene 32-ethidium bromide technique and a modification of the standard formamide-cytochrome c technique. A duplex stem of length 115 +/- 10 nucleotide pairs due to pairing between the two members of the inverted terminal repetition is observed in the single-stranded circles that form upon annealing single-stranded linear molecules. This duplex stem is shown to lie at the ends of the DNA by using several reference markers: (i) a newly discovered secondary structure feature (a loop of length ca. 500 nucleotides with a 20-nucleotide pair duplex stem) that maps 73% of the full length from the left end of the molecule and (ii) a duplex region due to a hybridized restriction fragment. There is also some secondary structure within each end of linear single strands. There is some variation in the morphology of the end strucures, and we propose that these involve base pairing, as in a tRNA clover leaf, rather than an exact single hairpin-type inverted repeat. These observations are consistent with the hypothesis that there is a foldback structure at the 3' ends of the DNA that functions as a primer for the initiation of replication.

Characterization of single-stranded viral DNA sequences present during replication of adenovirus types 2 and 5

Replication intermediates of adenovirus DNA apparently contain extensive stretches of single-stranded DNA. Such single-stranded viral DNA sequences homologous to different regions of the viral genome present in adenovirus-infected cells during viral DNA replication have therefore been characterized by hybridization to the separated strands of restriction endonuclease fragments of 32P-labeled adenovirus types 2 and 5 DNA. Saturation hybridization experiments with infected cell DNA extracted at late times suggest that all regions of the adenovirus genome are represented in the single-stranded fraction, but at unequal frequencies. This nonuniform representation has been characterized in more detail with self-annealed, total cell DNA extracted 18 hr after adenovirus type 2 infection: the concentration of single-stranded sequences homologous to different regions of the viral genome was determined by comparing the rates of hybridization of 32P-labeled, single-stranded DNA probes with such self-annealed 18 hr DNA to the rates of hybridization of the same probes with equal concentrations of their complements. This approach allows the concentration of single-stranded viral DNA sequences in excess of their complements to be determined. Such sequences can be represented by two concentration gradients across the viral genome: those homologous to the r strand increase in concentration from 27.8-40.9 units toward the right end, whereas sequences homologous to the 1 strand increase from an area 27.8-40.9 units toward the left end. The time course of synthesis of single-stranded viral DNA sequences relative to accumulation of total viral DNA during the productive cycle and their behavior following a shift of H5ts125-infected cells in which viral DNA replication has begun from a permissive to a nonpermissive temperature support the contention that these sequences are indeed generated as adenovirus DNA is replicated. These results are therefore discussed in terms of current models of adenovirus DNA replication.

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

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

The arrangement of simian virus 40 sequences in the DNA of transformed cells

High molecular weight DNA, isolated from eleven cloned lines of rat cells independently transformed by SV40, was cleaved with various restriction endonucleases. The DNA was fractionated by electrophoresis through agarose gels, denatured in situ, transferred directly to sheets of nitrocellulose as described by Southern (1975), and hybridized to SV40 DNA labeled in vitro to high specific activity. The location of viral sequences among the fragments of transformed cell DNA was determined by autoradiography. The DNAs of seven of the cell lines contained viral sequences in fragments of many different sizes. The remaining four cell lines each contain a single insertion of viral DNA at a different chromosomal location. The junctions between viral and cellular sequences map at different places on the viral genome.

Genome structure of incomplete particles of adenovirus

Incomplete particles arising during productive growth of adenovirus were separated from infectious particles by density gradient centrifugation. The DNA contained in particles of low density was characterized by restriction enzyme analysis and by electron microscopy and heteroduplexing techniques. The DNA is heterogeneous in length, ranging in size from 15% of the normal genome to full length. Many individual molecules contain long, inverted terminal repetitions, which consist of the sequences extending from the normal left-hand end of the viral genome inward; the normal right end sequences appear to be missing from these molecules. The region of the genome reiterated in these molecules is that which has been implicated in transformation of rat cells by adenovirus (Gallimore, Sharp, and Sambrook, 1974; Graham, van der Eb, and Heijneker, 1974). A model for adenovirus replication is presented that accounts for the aberrant structures observed.

Mapping of adenovirus messenger RNA by electron microscopy

Late adenovirus messenger RNA was annealed to complementary regions of partially melted viral double-stranded DNA. The RNA. DNA hybrid regions within the DNA molecules were visualized as loops in the electron microscope. Loops occurred at several regions of the DNA, most frequently, however, at a location near the center of the molecule. This hybridization technique appears well suited for an accurate mapping of messenger RNA, as well as for studies of RNA processing.

Location and identification of the genes for adenovirus type 2 early polypeptides

Virus-specific RNA was prepared from cells early after adenovirus type 2 infection and fractionated by hybridization to specific fragments of viral DNA. The viral mRNA was used to program cell-free protein synthesis, and the products were analyzed by electrophoresis. The genes for the early polypeptides of apparent molecular weight 44,000, 15,000, 72,000, 15,500, 19,000, and 11,000 daltons were located, respectively, between positions 0-4.1, 4.1-16.7, 58.5-70.7, 75.9-83.4, 89.7-98.6, and 89.7-98.6 of the conventional adenovirus DNA map. The polypeptide of molecular weight 72,000 daltons was shown to be the single-stranded DNA-binding protein described by others. RNAs from three different adeno-transformed cell lines each program the synthesis in vitro of predominantly the 15K polypeptide, as well as variable amounts of the polypeptide of molecular weight 44,000 daltons. The genes for these two polypeptides are located in the portion of DNA known to be required for transformation of rodent cells by adenovirus.

Detection of virus-specific DNA and RNA base-sequences in individual cells transformed or infected by adenovirus type 2

By means of 3H thymidine-labelled adenovirus 2 DNA, adenovirus-specific DNA sequences have been localized in individual nuclei of adenovirus 2- or 12-infected cells, and adenovirus-specific RNA sequences have been detected in the permissive cells as well as in cells transformed by adenovirus type 2. The ability to detect such specific virus RNA base-sequences in particular, by in situ hybridization, should be useful in studying the transcriptional specificities of tumours and neoplasms.

Termination sites for adenovirus type 2 DNA replication

Termination sites for replication of adenovirus type 2 DNA have been demonstrated at both ends of the viral chromosome by the procedure of Danna and Nathans (1972). Single-stranded DNA from replicating intermediates was also characterized by hybridization with separated strands of viral DNA. The results indicate that both strands are exposed during replication.