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.     

Transforming DNA sequences in rat cells transformed by DNA fragments of highly oncogenic human adenovirus type 12.

Rat cell lines tranformed by viral DNA fragments, EcoRI-C and HindIII-G, of adenovirus type 12 DNA were analyzed for the viral transforming DNA sequences present in cell DNAs. Cell lines transformed by the EcoRI-C fragment of adenovirus type 12 DNA (leftmost 16.5% of the viral genome) contain most of the HindIII-G sequences of the HindIII-G fragment, but at a different frequency depending on the portions of the fragment. The sequence of the AccI-H fragment of adenovirus type 12 DNA (the left part of the HindIII-G; leftmost 4.5% of the viral genome) was detected dominantly in cells transformed by the HindIII-G fragment Southern blot analysis showed that viral DNA sequences are present at multiple integration sites in high-molecular-weight cell DNA from cells transformed by the EcoRI-C or HindIII-G fragment of adenovirus type 12 DNA. These results suggest that most of the HindIII-G sequences in cells transformed by the HindIII-G fragment are present as fragmented forms.     

Unique species of mRNA from adenovirus type 7 early region 1 in cells transformed by adenovirus type 7 DNA fragment.

Adenovirus type 7 (Ad7) early region 1 mRNA species transcribed in rat cell lines transformed by the HindIII-I . J fragment (the left 7.8% of the viral genome) and in human KB cells infected with Ad7 were mapped on the viral genome, using S1 nuclease gel and diazobenzyloxymethyl paper hybridization techniques. At the early stage of productive infection, two mRNA's (950 and 840 nucleotides long) with the common 5' and 3' ends but different internal splicings were mapped from region 1A (map units 1.4 to 4.3), and one mRNA (2,310 nucleotides long, with the internal splicing between map units 9.9 to 10.1) was mapped from region 1B (map units 4.6 to 11.4). At the late stage, these early spliced mRNA's were also found and at least three additional Ad7 mRNA's were identified: 700-nucleotide-long mRNA in region 1A; and 1,100- and nucleotide-long mRNA's in region 1B. In transformed rat cell lines, two early region 1A mRNA's (950 and 840 nucleotides long) were also transcribed. Surprisingly, in addition, several unique Ad7 mRNA's, not found in productivity infected cells, were identified in all of the transformed cell lines. Their molecular sizes and coding sequences varied in individual cell lines. However, these mRNA's had the 5' end-proximal portion in region 1B and the 3' end-proximal portion in region 1A, these portions being transcribed by extending from region 1B to 1A on viral DNA fragments joined in a tandem array in transformed cells.     

Integration and transcription of group C human adenovirus sequences in the DNA of five lines of transformed rat cells

We have used the Southern blotting technique to analyze the integration patterns of human adenovirus sequences in the DNA of four rat cell lines, F17, 8617, T2C4 and F4, which were transformed by Ad-2 virus, and 5RK clone 6, which was transformed by Ad-5 HindIII-G fragment. We have also analyzed the Ad-specific messenger RNAs synthesized in these cell lines, in 293 cells (an Ad-5 transformed human cell line), and in Ad-2 early infected human KB cells, using the RNA geltransfer hybridization technique. We were interested in whether the Ad sequences are integrated, what the integration patterns are, whether the transforming region is present in an intact form, and whether the transforming region and other early regions are expressed at the mRNA level.Our results show that the integration patterns of Ad sequences range from simple to quite complex. Cells from line 8617 contain a single copy of right-end sequences flanked by left-end sequences. T2C4 cells have four different left-end sequences and two different right-end sequences. 5RK cells contain multiple different pieces of left-end sequences. In agreement with the results of Sambrook et al. (1979a,b), F17 cells contain a single copy of the left 17% of the genome, and F4 cells contain multiple copies of the right 5% of the genome fused to the left ~ 68% of the genome. The complete Ad genome is not present in any of the cell lines, and different regions may not be equimolar. There are no specific sites on the cellular or viral genome at which integration occurs. In 8617, F17 and F4 cells the Ad-2 sequences appear to be located close together on a single chromosome, suggesting that the Ad sequences in these cells arose from a single integration event. F17, 8617, T2C4, F4, and probably 5RK, cells all have an intact early region E1a (map position 1·3–4·6); F17, 8617, T2C4 and F4 cells also have E1b (m.p. 4·6–11·2) intact. E1a and E1b are the regions responsible for transformation. 8617 cells also have an intact early region E4 (m.p. 99-91·5) and T2C4 cells have an intact early region E3 (m.p. 76–86).Ad-2 early infected KB cells were shown to synthesize major E1a-specific mRNAs of 13 S, 12 S and 9 S, and major E1b-specific mRNAs of 22 S and 13 S. All the transformed cells synthesize the E1a 13 S and E1a 12 S mRNAs, and all cells except 5RK synthesize the E1b 22 S and E1b 13 S mRNAs. Early infected KB cells synthesize E3-specific mRNAs of 26 S, 24 S, 22 S, 19 S, 12 S and 9 S: T2C4 cells synthesize the major 22 S and 19 S RNA species, and possibly the less pronounced E3 mRNAs. Early infected cells and 8617 cells synthesize E4-specific mRNAs of 19 S, 17 S, 14 S, 12 S, 11 S, 9 S and 8 S. 8617 cells also synthesize E4 mRNAs of about 23 to 24 S and 21 S. F4 cells synthesize 24 S and 19 S hybrid mRNAs that contain both E4 and E1a sequences: these RNAs arise because F4 cells contain a portion of the E4 region fused to the left end (m.p. 0) of the genome.Our results, as well as those from other laboratories, are consistent with the idea that the transformed phenotype of Ad transformed cells is maintained by expression of Ad genes in E1a and E1b.     

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.     

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

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

Characterization of the mRNA''s for the polyoma virus capsid proteins VP1, VP2, and VP3.

Polyadenylated cytoplasmic RNA from polyoma virus-infected cells can be translated in the wheat germ system to yield all there polyoma virus capsid proteins, VP1, VP2, and VP3. The translation products of RNA selected from total cytoplasmic RNA of infected cells by hybridization to polyoma virus DNA showed a high degree of enrichment for VP1, VP2, and VP3. The identity of the in vitro products with authentic virion proteins was established in two ways. First, tryptic peptide maps of the in vitro products were found to be essentially identical to those of their in vivo counterparts. Second, the mobilities of the in vitro products on two-dimensional gels were the same as those of viral proteins labeled in vivo. VP1, VP2, and vp3 were all labeled with [35S] formylmethionine when they were synthesized in the presence of [35S] formylmethionyl-tRNAfmet. We determined the sizes of the polyadenylated mRNA's for VP1, VP2, and VP3 by fractionation on gels. The sizes of the major mRNA species for the capsid proteins are as follows: VP2, 8.5 X 10(5) daltons; VP3, 7.4 X 10(5) daltons; and VP1, 4.6 X 10(5) daltons. We conclude that all three viral capsid proteins are synthesized independently in vitro, that all three viral capsid proteins are virally coded, and that each of the capsid proteins has a discrete mRNA.     

The nucleotide sequence of the transforming HindIII-G fragment of adenovirus type 5 DNA. The region between map positions 4.5 (HpaI site) and 8.0 (HindIII site).

The nucleotide sequence of the region between map positions 4.5 (HpaI-site) and 8.0 (HindIII-site) of adenovirus type 5 (Ad5) DNA has been determined. This stretch of DNA is part of the transforming HindIII-G fragment, which is 2809 nucleotides long. The sequenced segment was found to have a long open reading frame for protein biosynthesis, starting 23 nucleotides from the HpaI site and extending all the way to the HindIII-G site, which could code for a protein of at least 44 000 daltons. The possible correlation beteen the coding capacity of the HindIII-G fragment and the "transforming" proteins specified by it will be discussed in the light of the recent data on the splicing of early mRNAs.     

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

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

Multiple mRNA species for adenovirus type 2 polypeptides III and pVII.

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

Ability of nonpermissive mouse cells to express a simian virus 40 late function(s)

Mouse cells are fully nonpermissive for simian virus 40 (SV40). Infection does not lead to detectable virus replication. In this report, it was shown, first, that spliced 16S and 19S SV40 late mRNA were present in cytoplasmic and polysomal polyadenylated acid+ RNA preparations from SV40-infected baby mouse kidney cells. The 16S and 19S SV40 late mRNA's produced in infected baby mouse kidney cells were identical to or similar to the 16S and 19S SV40 late mRNA's produced in permissive monkey cells as judged by their S1 mapping patterns performed with the late strand of HpaII-BamHI fragment B and by their sedimentation patterns in a sucrose gradient. It was also shown that the 16S late mRNA from infected baby mouse kidney cells could be translated into a polypeptide which was identical to or similar to virion protein VP1 in every aspect examined, including the patter of peptide mapping by limited proteolysis. Second, we reported that mouse kidney cells produced detectable, although low, levels of SV40 virion protein VP1, as shown by the sodium dodecyl sulfate-polyacrylamide gel autoradiogram of [35S]methionine-labeled proteins immunoprecipitated by a rabbit antiserum directed against SV40 virion proteins. Third, it was reported that infected baby mouse kidney cells produced late mRNA's either (i) when the infection was done at a restrictive temperature with the nonleaky tsA58 mutant or (ii) in cells treated with 100 microgram of cycloheximide per ml, in which large T antigen synthesis was inhibited by more than 99.9%. This suggested that large T antigen was not required for the synthesis of late mRNA in mouse cells.     

Comparison of viral RNA sequences in adenovirus 2-transformed and lytically infected cells

The complementary strands of fragments of ³²P-labelled adenovirus 2 DNA generated by cleavage with restriction endonucleases EcoRI or Hpa1 were separated by electrophoresis. Saturation hybridization reactions were performed between these fragment strands and unlabelled RNA extracted from the cytoplasm of adenovirus 2-transformed rat embryo cells or from human cells early after adenovirus 2 infection. The fraction of each fragment strand complementary to RNA from these sources was measured by chromatography on hydroxylapatite. Maps of the viral DNA sequences complementary to messenger RNA in different lines of transformed cells and early during lytic infection of human cells were constructed.Five lines of adenovirus 2-transformed cells were examined. All contained the same RNA sequences, complementary to about 10% of the light strand of EcoRI fragment A. DNA sequences coding for this RNA were more precisely located using Hpa1 fragments E and C and mapped at the left-hand end of the genome. Thus any viral function expressed in all adenovirus 2-transformed cells, tumour antigen, for example, must be coded by this region of the viral genome. Two lines, F17 and F18, express only these sequences; two others, 8617 and REM, also contain mRNA complementary to about 7% of the heavy strand of the right-hand end of adenovirus 2 DNA; a fifth line, T2C4, contains these and many additional viral RNA sequences in its cytoplasm.The viral RNA sequences found in all lines of transformed cells are also present in the cytoplasm of human cells during the early phase of a lytic adenovirus infection. The additional cytoplasmic sequences in the 8617 and REM cell lines also correspond to “early” RNA sequences.     

Herpes simplex virus type 1 HindIII fragment L encodes spliced and complementary mRNA species.

We have used DNA bound to cellulose to isolate and translate in vitro herpes simplex virus type 1 (HSV-1) mRNA's encoded by HindIII fragment L (mapping between 0.592 and 0.647), and 8.450-base-pair (8.45-kb) portion of the long unique region of the viral genome. Readily detectable, late mRNA's 2.7 and 1.9 kb in size encoding 69,000- and 58,000-dalton polypeptides, respectively, were isolated. A very minor late mRNA family composed of two colinear forms, one 2.6 kb and one 2.8 kb, was isolated and found to encode only an 85,000-dalton polypeptide. A major early mRNA, 1.8 kb in size encoding a 64,000-dalton polypeptide, was also isolated. High-resolution mapping of these mRNA's by using S1 nuclease and exonuclease VII digestion of hybrids between them and 5' and 3' end-labeled DNA fragments from the region indicated that the major early mRNA contained no detectable splices, and about half of its 3' end was complementary to the 3' region of the very minor 2.6- to 2.8-kb mRNA's encoded on the opposite strand. These mRNA's also contained no detectable splices. The major late 2.7-kb mRNA was found to be a family made up of members with no detectable splices and members with variable-length (100 to 300 bases) segments spliced out very near (ca. 50 to 100 bases) the 5' end.