Specific nucleotide sequences in HeLa cell inverted repeated DNA: enrichment for sequences found in double-stranded regions of heterogeneous nuclear RNA

Inverted repeat DNA was isolated from HeLa cell nuclei and transcribed in vitro with Escherichia coli RNA polymerase in the presence of [alpha-³²P]nucleoside triphosphates. The RNA products were digested with T₁ ribonuclease and subjected to separation in two dimensions. The pattern of the prominent oligonucleotides was almost indistinguishable from that seen when the double-stranded regions from ³²P-labeled HeLa cell heterogeneous nuclear RNA were fingerprinted in a similar manner. The sequences of several of the largest prominent T₁ ribonuclease-generated oligonucleotides were determined and were found to agree with those isolated from the double-stranded heterogeneous nuclear RNA that migrated to the same positions in the fingerprints. The most prominent component of the inverted repeat DNA appears to be sequences that are transcribed into double-stranded regions in heterogeneous nuclear RNA molecules.     

Ribonucleoprotein organization of polyadenylate sequences in HeLa cell heterogeneous nuclear RNA.

Ribonucleoprotein particles containing heterogeneous nuclear RNA (Pederson, 1974) were isolated from HeLa cells and digested with ribonucleases A and T₁ at high ionic strength. The nuclease-resistant material, comprising 9.4% of the initial acid-insoluble [³H]adenosine radioactivity, was further fractionated by poly(U)-Sepharose chromatography. The bound fraction eluted from the column with 50% formamide and banded in cesium sulfate gradients (without aldehyde fixation) at a buoyant density characteristic of ribonucleoprotein (1.45 g/cm³). Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of this material revealed two Coomassie blue-stained bands. The major polypeptide had a molecular weight of 74,000 a less prominent band had a molecular weight of 86,000. The RNA components contained 74.4 mol % AMP and 17.7 mol % UMP. Polyacrylamide gel electrophoresis of the RNA, labeled with [³H]adenosine, demonstrated the presence of molecules 150 to 200 nucleotides in length (poly(A)), as well as molecules 20 to 30 nucleotides long (oligo(A)). Both poly(A) and oligo(A) sequences have previously been identified in HeLa heterogeneous nuclear RNA. These data demonstrate that both the poly (A) and oligo(A) sequences in HeLa heterogeneous nuclear RNA exist in vivo tightly complexed with specific proteins.     

Nucleotide sequence of nuclear 5S RNA of mouse cells

The nucleotide sequence of nuclear 5S RNA of mouse cells was determined. The 5S RNA is 117 nucleotides long with one mole each of m₃^2,2,7G, Gm, Am and Cm, two moles of Um, and three moles of ψ as modified nucleosides, and it is rich in uridylate residues (about 36 %). The 5′-terminal hexanucleotide-containing cap structure, m₃^2,2,7GpppAm-Um-A-C-U-, is identical with that of U1 RNA. This RNA contains sequences complementary to the terminal sequences of the introns of heterogeneous nuclear RNAs.     

5'-terminal structures of poly(A)+ cytoplasmic messenger RNA and of poly(A)+ and poly(A)- heterogeneous nuclear RNA of cells of the dipteran Drosophila melanogaster.

Structures at the 5′ terminus of poly (A)-containing cytoplasmic RNA and heterogeneous nuclear RNA containing and lacking poly(A) have been examined in RNA extracted from both normal and heat-shocked Drosophila cells. ³²P-labeled RNA was digested with ribonucleases T₂, T₁ and A and the products fractionated by a fingerprinting procedure which separates both unblocked 5′ phosphorylated termini and the blocked, methylated, “capped” termini, known to be present in the messenger RNA of most eukaryotes.Approximately 80% of the 5′-terminal structures recovered from digests of poly(A)-containing Drosophila mRNA are cap structures of the general form m⁷G^5′ppp^5′X(m)pY(m)pZp. With respect to the extent of ribose methylation and the base distribution, the 5′-terminal sequences of Drosophila capped mRNA appear to be intermediate between those of unicellular eukaryotes and those of mammals. Drosophila is the first organism known in which type 0 (no ribose methylations), type 1 (one ribose methylation), and type 2 (two ribose methylations) caps are all present. In contrast to mammalian cells, the caps of Drosophila never contain the doubly methylated nucleoside N⁶,2′-O-dimethyladenosine. Both purines and pyrimidines can be found as the penultimate nucleoside of Drosophila caps and there is a wide variety of X-Y base combinations. The relative frequencies of these different base combinations, and the extent of ribose methylation, vary with the duration of labeling. The large majority of poly(A)-containing cytoplasmic RNA molecules from heat-shocked Drosophila cells are also capped, but these caps are unusual in having almost exclusively purines as the penultimate X base.Greater than 75% of the 5′ termini of heterogeneous nuclear RNA (hnRNA) containing poly(A) and greater than 50% of the termini of hnRNA lacking poly (A) are also capped. Triphosphorylated nucleotides, common as the 5′ nucleotides of mammalian hnRNA, are rare in the poly(A)-containing hnRNA of Drosophila. The frequency of the various type 0 and type 1 cap sequences of cytoplasmic and nuclear poly (A)-containing RNA are almost identical. The caps of hnRNA lacking poly(A) are also quite similar to those of poly-adenylated hnRNA, but are somewhat lower in their content of penultimate pyrimidine nucleosides, suggesting that these two populations of molecules are not identical.     

Sequence analysis and evolution of sea urchin (Lytechinus pictus and Strongylocentrotus purpuratus) histone H4 messenger RNAs

The putative histone H4 (F2a₁) mRNA has been isolated from early blastula Strongylocentrotus purpuratus sea urchin embryos. Nucleotide sequences of oligonucleotides obtained by digestion of this RNA with T₁ ribonuclease have been obtained and many are found to be colinear with the amino acid sequence of histone H4 protein. The sequences obtained from the H4 mRNAs of S. pnrpuratus have been compared with those obtained from Lytechinus pictus (Grunstein & Schedl, 1976). The two mRNAs for this highly conserved protein have undergone considerable divergence of the sort that would be predicted from the degeneracy of the genetic code. 11.5% of the bases have undergone substitution at a rate calculated to be 3 × 10^?9 base changes · codon^?1 · year^?1.     

The putative 15 S precursor of globin mRNA contains a poly(A) sequence

[³H]Uridine or [³H]adenosine pulse-labelled nuclear RNA was isolated from chicken immature red blood cells and separated on denaturing formamide sucrose gradients. RNA of each gradient fraction was hybridized with unlabelled globin DNA complementary to mRNA (cDNA) and subsequently digested by RNAase A and RNAase T₁. The experiments revealed two RNA species with globin coding sequences sedimenting at 9 S and approx. 15 S, the latter probably representing a precursor of 9 S globin mRNA.A poly(A) sequence was demonstrated in this RNA by two different approaches. Nuclear RNA pulse-labelled with [³H]uridine was fractionated by chromatography on poly(U)-Sepharose. Part of the 15 S precursor was found in the poly(A)-containing RNA. In the second approach 15 S RNA pulse-labelled with [³H]adenosine was hybridized with globin cDNA, incubated with RNAase A and RNAase T₁ and subjected to chromatography on hydroxyapatite. The hybrids were isolated and after separation of the strands degraded with DNAase I, RNAase A and RNAase T₁. By this procedure poly(A) sequences of approximately 100 nucleotides could be isolated from the 15 S RNA with globin coding sequences. The poly(A) sequence was completely degraded by RNAase T₂.     

A small nuclear precursor of messenger RNA in the cellular slime mold Dictyostelium discoideum

Previous work (Firtel et al., 1972) showed that messenger RNA from the cellular slime mold Dictyostelium discoideum, like that from mammalian cells, contains a sequence of about 100 adenylic acid residues at the 3′ end. We show here that Dictyostelium nuclei, labeled under a variety of conditions, do not contain material analogous to the large nuclear heterogeneous RNA found in mammalian cells. Rather, the majority of pulse-labeled nuclear RNA that is not a precursor of ribosomal RNA does contain at least one sequence of polyadenylic acid; this RNA, with an average molecular weight of 500,000, appears to be only 20% larger than cytoplasmic messenger RNA.Pulse-labeling experiments show that the nuclear poly(A)-containing RNA is a material precursor of messenger RNA. Whereas previous work showed that over 90% of messenger RNA sequences are transcribed from non-reiterated DNA, we show here that about 25% of nuclear poly (A)-containing RNA is transcribed from reiterated DNA sequences and only 75% from single-copy DNA. We present evidence that a large fraction of the nuclear poly(A)-containing RNA contains, at the 5′ end, a sequence of about 300 nucleotides that is transcribed from repetitive DNA, and which is lost before transport of messenger RNA into the cytoplasm.Based on these and other results, we present a model of arrangement of repetitive and single-copy DNA sequences in the Dictyostelium chromosome.     

Polyadenylic acid-containing RNA and its polyadenylic acid sequences newly synthesized in isolated embryonic cells of Xenopus laevis.

Newly synthesized polyriboadenylic acid [poly(A)]-containing RNA and its poly(A) sequences were isolated and characterized in Xenopus embryonic cells. Upon sedimentation analysis, the poly(A)-containing RNA labeled for 30 min showed a very heterogeneous size distribution ranging from 9 to >40 S. After 5 hr of labeling, the profile became much less heterogeneous and the main component was distributed in the 9–28 S region. The average molecular weight of 6.5–7.0 × 10⁵ daltons was calculated for the 5-hr labeled RNA. This poly(A)-containing RNA, comprising about 10% of the total labeled RNA, was metabolically stable and accumulated linearly for 5 hr. Gel electrophoresis of the RNA revealed the presence of little or no free poly(A) sequences. Most of the poly(A) sequences, which were isolated from 30-min labeled poly(A)-containing RNA migrated as a single discrete component approximately 150 nucleotides long. In contrast, they were slightly smaller (130 nucleotides long) and more heterogeneous, when obtained from the poly(A)-containing RNA labeled for 5 hr. From these results, it may be likely that the embryonic poly(A)-containing RNA is similar in size to the steady-state population of the poly(A)-containing RNA reported to occur in vitellogenic oocytes and cultured kidney cells of the same species.     

Extreme ends of the genome are conserved and rearranged in the defective interfering RNAs of semliki forest virus

We have analyzed Semliki Forest virus defective interfering RNA molecules, generated by serial undiluted passaging of the virus in baby hamster kidney cells. The 42 S RNA genome (about 13 kb ²) has been greatly deleted to generate the DI RNAs, which are heterogeneous both in size (about 2 kb) and sequence content. The DI RNAs offer a system for exploring binding sites for RNA polymerase and encapsidation signals, which must have been conserved in them since they are replicated and packaged. In order to study the structural organization of DI RNAs, and to analyze which regions from the genome have been conserved, we have determined the nucleotide sequences of (1) a 2.3 kb long DI RNA molecule, DI309, (2) 3′-terminal sequences (each about 0.3 kb) of two other DI RNAs, and (3) the nucleotide sequence of 0.4 kb at the extreme 5′ end of the 42 S RNA genome.The DI309 molecule consists of a duplicated region with flanking unique terminal sequences. A 273-nucleotide sequence is present in four copies per molecule. The extreme 5′-terminal nucleotide sequence of the 42 S RNA genome is shown to contain domains that are conserved in the two DI RNAs of known structure: DI309, and the previously sequenced DI301 (Lehtovaara et al., 1981). Here we report which terminal genome sequences are conserved in the DI RNAs, and how they have been modified, rearranged or amplified.     

Reiterated transfer RNA genes of Xenopus laevis

The proportion of the Xenopus laevis genome complementary to “7 S” RNA, unfractionated transfer RNA and some selected aminoacyl-tRNAs, and the sequence complexity of these RNA species, have been determined by following the kinetics of RNA-DNA hybridization on filters under conditions of RNA excess at optimum rate temperature. For hybridization of aminoacyl-labelled tRNAs, conditions for optimum aminoacylation were first determined and, where necessary, aminoacyl-tRNAs were treated with nitrous acid to prevent discharge during annealing. Neither the extent nor rate of hybridization was affected by this treatment.“7 S” RNA, coded for by 580 genes per haploid complement of chromosomes, reacts like a single family of nucleotide sequences, whereas about 43 basic tRNA sequences are coded for by at least 7800 genes. If hybrids are not treated with RNase A, the apparent tDNA redundancy is some 23% greater but no more nucleotide sequences are detectable. Taken together, the results suggest that each tRNA sequence is, on average, 200-fold reiterated.The reiteration varies, however, for different aminoacyl-tRNAs. Thus, hybridization resolves only one valyl-tRNA which is coded for by 240 genes, but at least four leucyl-tRNA sequences can be distinguished by hybridization, each of which is on average 90-fold reiterated. Reiteration also varies for the two methionyl-tRNAs detectable both by hybridization and by reversed phase chromatography: tRNA₁^Met and tRNA₂^Met are 310- and 170-fold reiterated, respectively, and each is kinetically homogeneous. These saturation values are almost exactly additive and are not influenced by the presence of other tRNA species. Thus the results suggest that Xenopus tRNAs are no more heterogeneous than would be predicted by the genetic code, despite the high but variable multiplicity of tRNA cistrons.