Transcription map for adenovirus type 12 DNA.

The regions of the adenovirus type 12 genome which encode l- and r-strand-specific cytoplasmic RNA were mapped by the following procedure. Radioactive, intact, separated complementary strands of the viral genome were hybridized to saturating amounts of unlabeled late cytoplasmic RNA. The segments of each DNA strand complementary to the RNA were then purified by S1 nuclease digestion of the hybrids. The arrangement of the coding regions of each strand was deduced from the pattern of hybridization of these probes to unlabeled viral DNA fragments produced by digestion with EcoRI, BamHI, and HindIII.. The resulting map is similar, if not identical, to that of adenovirus type 2. The subset of the late cytoplasmic RNA sequences which are expressed at early times were located on the map by hybridizing labeled, early cytoplasmic RNA to both unlabeled DNA fragments and unlabeled complementary strands of specific fragments. Early cytoplasmic RNA hybridized to the r-strand to EcoRI-C and BamHI-B and to the l-strand of BamHI-E. Hybridization to BamHI-C was also observed. The relative rates of accumulation of cytoplasmic RNA complementary to individual restriction fragments was measured at both early and late times. Early during infection, most of the viral RNA appearing in the cytoplasm was derived from the molecular ends of the genome. Later (24 to 26 h postinfection) the majority of the newly labeled cytoplasmic RNA was transcribed from DNA sequences mapping between 25 and 60 map units on the genome.     

Selective enrichment of a large size genomic DNA fragment by affinity capture: an approach for genome mapping.

A method to enrich large size DNA fragments obtained by digestion with rare cutting restriction endonucleases was developed and applied for the isolation of a 150 kb SfiI fragment containing the beta-globin gene cluster. The digested DNA is rendered single stranded at the ends by diffusing a strand specific exonuclease into an agarose plug containing DNA. The plug is melted and solution hybridization is then performed with a bridge RNA containing specific sequences from the end of a desired fragment linked to a common probe sequence. The common probe sequence is annealed to a biotinylated RNA and the resulting tripartite hybrid is retained onto a solid matrix containing avidin and specifically released by ribonuclease action. Enrichments of greater than 350 fold have been achieved consistently. Such directed purification of large DNA fragments without cloning can considerably expedite mapping and gene localization in a complex genome and facilitate the construction of sublibraries from defined regions of the genome.     

Cleavage of adeno-associated virus DNA with Sali,Psti and Haeii restriction endonucleases.

Duplex AAV-2 DNA was digested with SalI, PstI or HaeII restriction endonucleases and the cleavage sites were mapped. SalI cleaves AAV DNA at 0.310 map units, PstI at 0.106, 0.422 and 0.914 and the five HaeII sites were mapped at 0.110. 0.156, 0.181, 0.536 and 0.600 map units. These cleavage products will be useful for the isolation of specific regions from the AAV DNA, located outside of the stably transcribed region of the genome, and will also help to map more complex restriction enzyme cleavages.     

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.     

Cleavage of DNA.RNA hybrids by type II restriction enzymes.

The action of a number of restriction enzymes on DNA.RNA hybrids has been examined using hybrids synthesised with RNAs of cucumber mosaic virus as templates. The enzymes EcoRI, HindII, SalI, MspI, HhaI, AluI, TaqI and HaeIII cleaved the DNA strand of the hybrids (and possible also the RNA strand) into specific fragments. For four of these enzymes, HhaI, AluI, TaqI and HaeIII, comparison of the restriction fragments produced with the known sequences of the viral RNAs confirmed that they were recognising and cleaving the DNA strand of the hybrids at their correct recognition sequences. It is likely that the ability to utilise DNA.RNA hybrids as substrates is a general property of Type II restriction enzymes.     

Characterization and biological activity of cloned simian virus 40 DNA fragments

The biological activity of fragments of the SV40 genome was determined by manual microinjection of the fragments into the nuclei of mammalian cells. Fragments of the SV40 A gene (that codes for the T antigens) were obtained either directly by digestion with restriction endonucleases or after cloning into plasmid pBR322. Three different biological activities were studied: expression of T antigen, induction of cell DNA synthesis, and, in a few cases, reactivation of repressed ribosomal RNA genes. By using a number of fragments with deletions in the various portions of the SV40 A gene, we have been able to conclude that: 1) the sequences from 0.65 to 0.51 map units are not needed for the induction of cell DNA synthesis; 2) the sequences from 0.42 to 0.17 map units are not needed for the induction of cell DNA synthesis; and 3) the critical sequences for the induction of cell DNA synthesis, 0.51 to 0.42 map units, are different from those necessary for the reactivation of repressed ribosomal RNA genes (0.39-0.33 map units). These results indicate that the information for these two fundamental processes of cell proliferation resides in two separate and distinct domains of the SV40 A gene.     

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

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