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.     

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.     

Transcription of the Agrobacterium Ti plasmid in the bacterium and in Crown Gall tumors

Regions of the Agrobacterium tumefaciens tumor-inducing (Ti) plasmid which are transcribed in the bacterium or in two tobacco Crown Gall tumors were localized. Complementary DNA (cDNA) probes made to bacterial or tumor RNA were hybridized to blots of the Ti-plasmid or cloned “T”-DNA restriction endonuclease fragments digested with various restriction endonucleases. Extensive regions of the Ti plasmid are transcribed in the bacterium grown in minimal or rich medium. An additional region of the plasmid, which has previously been defined genetically as coding for proteins responsible for octopine utilization and conjugative T-plasmid transfer, is transcribed when the bacteria are induced with octopine. This region is transcribed constitutively in a mutant which is constitutive for octopine utilization. Another additional region of the plasmid is transcribed when the bacteria are induced with agropine. All sections of the “T” DNA are weakly transcribed in the bacterium. In contrast to this, specific regions of the “T” DNA are transcribed into both polyadenylated and nonpolyadenylated RNA in the tumors. The selectivity with which regions are transcribed in the tumor may indicate that the “T” DNA has “evolved” for best use in a eucaryotic cell.     

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.     

The small chromatin fragments released by micrococcal nuclease from hepatoma tissue cultured cell nuclei are strongly enriched in coding DNA sequences and are related to an actively transcribed single-stranded DNA fraction

It was shown with the use of specific probes that mild micrococcal nuclease digestion releases from chromatin actively-transcribed genes as small nucleosome oligomers. In the present work we demonstrate that most if not all of the active genes are accessible to the nuclease. It was found that the short released fragments are greatly enriched in transcribed DNA sequences, the most enriched being the dimers of nucleosomes since 35% of their DNA could be hybridized to cytoplasmic RNA. The results of cDNA-DNA hybridizations indicate that the monomers and dimers of nucleosomes contain most of the DNA sequences which encode poly(A⁺) RNAs, however larger released fragments include some transcribed sequences, while the nuclease-resistant chromatin is considerably impoverished in coding sites. These evidences and the finding that about 25% of the DNA from the dimers of nucleosomes are exclusively located in this class of fragments, tend to prove that the active chromatin regions are attacked in a non-random way by micrococcal nuclease. We have previously isolated, without using exogenous nuclease, an actively transcribed genomic fraction amounting to 1.5–2% of the total nuclear DNA, formed of single-stranded DNA. In the present study we show that all or nearly all the single-stranded DNA sequences could be reassociated with the DNA fragments present in the released monomers and dimers of nucleosomes. Our observations confirmed our previous finding that the greatest part of single-stranded DNA selectively originates from the coding strand of genomic DNA.     

Identification of early adenovirus type 2 RNA species transcribed from the left-hand end of the genome.

Unique fragments of adenovirus type 2 DNA generated by cleavage with endonuclease R-Eco RI or endonuclease R-Hsu I (Hin dIII) were used to map cytoplasmic viral RNAs transcribed early in productive infection. Radioactive early viral RNA was first fractionated by polyacrylamide gel electrophoresis. Eluted viral RNAs were then tested for hybrid formation with DNA fragments. The Eco RI DNA fragment (Eco RI-A) which contains the left-hand 58% of the genome hybridized 13S and 11S RNAs. More detailed mapping of these RNAs was achieved by hybridization to the seven Hsu I fragments of Eco RI-A. The early RNA annealed only to Hsu I-G and C, two fragments which comprise the extreme left-hand 17% of the genome. Viral RNA migrating as 13S and 11S annealed to Hsu I-G, and 13S RNA annealed to Hsu I-C. A 13S RNA is transcribed from Eco RI-A late in infection (18 h). Hybridization-inhibition studies with Eco RI-A DNA, early cytoplasmic RNA, and 3H-labeled 13S late RNA demonstrated that this RNA synthesized at late times is an early RNA species which continues to be synthesized in large amounts at 18 h. This 13S RNA synthesized at 18 h hybridized to Hsu I-C but not to Hsu I-G DNA. These results establish that the 13S RNAs transcribed from Hsu I-G and C at early times must be different species.     

Nucleotide sequence of the simian virus 40 Hind II + III restriction fragment J and the total amino acid sequence of the major structural protein VP1.

The HindII + III restriction fragment J (Hind-J) represents 4.58% of the simian virus 40 genome. The information present in Hind-J is expressed as part of the major, late 16-S messenger RNA, which codes for the structural protein VP1. The nucleotide sequence of the 240-base-pairs-long Hind fragment J has been determined by analysis of each oligonucleotide from both strands resulting from T1 or pancreatic RNase digestion of RNA transcribed from the DNA and from RNase digestion of ribo-substituted DNA. Large oligonucleotide blocks which could be constructed mainly on the basis of complementarity were subsequently ordered by partial chemical degradation of terminally labeled DNA. This direct DNA sequencing approach also completely confirmed the results obtained by both aforementioned RNase degradation methods. In the strand with the same polarity as the late mRNA, triplets corresponding to termination codons are present in two of the three reading frames. The one open reading frame connects in phase with the open reading frame of the neighboring HindII/ III fragments K, F and G, which have been published previously and which together with Hind-J span the total VP1 gene. Some features of the primary nucleotide sequence of this VP1 gene and the derived VP1 amino acid sequence are discussed.     

Histone genes of the sea urchin (S. purpuratus) cloned in E. coli: Order,polarity, and strandedness of the five histone-coding and spacer regions

Sea urchin (S. purpuratus) histone DNA of constructed plasmid chimeras cloned in E. coli was cleaved with the restriction endonucleases Eco RI, Hind III, Sal I, Bam I, and Hha I. The resulting fragments were ordered and isolated directly from agarose gels or cloned into other plasmids. Each fragment hybridized to one or another of the five histone mRNAs and elucidated the order of the histone genes in each of the cloned fragments. Some DNA did not hybridize to histone mRNAs and was identified as spacer DNA located between coding regions.Total sea urchin DNA was cleaved with restriction endonucleases, fractionated on agarose gels, and hybridized to histone mRNAs or histone DNA. The results revealed the order of the five histone genes in the histone gene repeat unit and demonstrate that the histone spacer DNAs have little sequence homology to other genes. Exonuclease III digestion of specific linear chimeric histone DNA plasmids followed by hybridization with mRNAs demonstrated the existence of all five histone genes on one strand of DNA and the 5′-3′ polarity of that strand. These results, in conjunction with the data of Wu et al. (1976), allow us to construct a map of coding and spacer sequences in the transcribed strand of the S. purpuratus histone gene repeat unit:

     

A 7.1 kb linear DNA molecule of Theileria parva has scrambled rDNA sequences and open reading frames for mitochondrially encoded proteins.

Theileria parva, an intralymphocytic protozoan parasite of cattle, contains a linear 7.1 kb DNA element with terminal inverted repeat sequences. The molecule is transcribed into low molecular weight RNA, and both DNA strands encode short stretches of unique sequences, usually < 100 nucleotides, which are similar to large (LSU) or small (SSU) ribosomal subunit RNA. Phylogenetically conserved conformational rRNA domains were assembled from the discontinuous rDNA sequences using comparative secondary structure modelling. For example, a minimum of four predicted sequences, two derived from each DNA strand, is required to assemble domain V of LSU rRNA which participates in peptidyl transferase activity. The discontinuities in the identified rRNA domains fall within regions of no known functional significance. Hence, it is likely that the element encodes fragmented rDNA genes and the mature rRNA is unconventional, consisting of several fragments of RNA, primarily held together by intermolecular and intramolecular base pairing. The element also has ORFs for components of the last two mitochondrial electron transport enzyme complexes. The structure of the parasite DNA element, its protein coding capacity and scrambled rDNA gene sequences, are reminiscent of the mitochondrial genome of Chlamydomonas reinhardtii. We propose that the 7.1 kb element is equivalent to the mitochondrial DNA of T. parva, although a number of its features are unusual for this family of extrachromosomal DNA molecules.