Characterization of Novikoff hepatoma small RNAs homologous to repetitive DNAs

Three minor small RNA species from Novikoff hepatoma cells, with homology to repetitive DNA sequences, have been identified and characterized. These small RNAs, designated 5.1S, 6S and T3 RNAs, show homology to Alu 1, Alu 2, and Alu 3 sequences, respectively. 6S and T3 RNAs were found both in the nucleus and cytoplasm, whereas 5.1S RNA was not found in the nucleus. Neural tissues were found to contain a 6S-sized BC1 RNA with homology to I.D. sequences [19]; in contrast, the current study shows that Novikoff hepatoma cells contain a 75–80 nucleotide long (T3) RNA, homologous to I.D. sequences. These data suggest that BCl and T3 small RNAs, homologous to I.D. sequences, are expressed in a tissue-specific manner. These results also show that in addition to the abundant 7SL, 4.5S and 4.5S1 RNAs having homology to repetitive DNA, Novikoff hepatoma cells also contain several minor small RNAs with homology to repetitive sequences.     

Properties of dispersed, highly repeated DNA within and near the hamster CAD gene.

Dispersed, highly repeated DNA sequences were found within and near the Syrian hamster gene coding for the multifunctional protein CAD. Most of the repeated sequences were homologous to each other and had similar properties. They hybridized to many cytoplasmic polyadenylated RNAs and to 7S and 4.5S cytoplasmic non-polyadenylated RNAs. Cloned DNA fragments containing repeated sequences were transcribed in vitro by RNA polymerase III. The repeated sequences from Syrian hamsters share many properties with the Alu family of repetitive DNA from humans. The hamster sequences were homologous to total repetitive human DNA but only very weakly homologous to two cloned members of the human Alu family.     

Computer analysis of the sequence relationships among 4.5S RNA molecular species from various sources

Nucleotide sequence homology among 4.5S RNAs from various organisms was examined by computer analysis to evaluate their sequence relationships. Chloroplast 4.5S rRNAs of wheat and tobacco were not significantly related to Escherichia coli 4.5S RNA, but were closely related to the 3'-terminus of bacterial 23S rRNA. Significant sequence homology was found between rat Novikoff hepatoma 4.5S RNAI and mouse and hamster 4.5S RNAs, suggesting that these RNAs are products of a family of genes with diverged sequences. E. coli 4.5S RNA had no significant sequence homology with any rodent 4.5S RNAs as a whole sequence. The E. coli, mouse and hamster 4.5S RNAs, however, were found to share a homologous 14-nucleotide sequence at the center of the molecules, which is known to exist as a conserved sequence in both Alu and Alu-equivalent sequences of mammalian DNAs.     

Cloning and characterization of cDNA copies of the 7S RNAs of HeLa cells

We have cloned cDNA copies of in vitro adenylated 7S RNA of HeLa cells. The most representative clones in the library contain DNA fragments copied from the 7SL and 7SK small RNAs. The two classes of recombinants share no homology. The 7SL RNA contains at the 5' end of the molecule sequences homologous to the Alu sequence family. Hybridization to human genomic DNA shows that the 7SL and 7SK clones are homologous to two different families of repetitive sequences.     

Evolution of secondary structure in the family of 7SL-like RNAs

Primate and rodent genomes are populated with hundreds of thousands copies of Alu and B1 elements dispersed by retroposition, i.e., by genomic reintegration of their reverse transcribed RNAs. These, as well as primate BC200 and rodent 4.5S RNAs, are ancestrally related to the terminal portions of 7SL RNA sequence. The secondary structure of 7SL RNA (an integral component of the signal recognition particle) is conserved from prokaryotes to distant eukaryotic species. Yet only in primates and rodents did this molecule give rise to retroposing Alu and B1 RNAs and to apparently functional BC200 and 4.5S RNAs. To understand this transition and the underlying molecular events, we examined, by comparative analysis, the evolution of RNA structure in this family of molecules derived from 7SL RNA.RNA sequences of different simian (mostly human) and prosimian Alu subfamilies as well as rodent B1 repeats were derived from their genomic consensus sequences taken from the literature and our unpublished results (prosimian and New World Monkey). RNA secondary structures were determined by enzymatic studies (new data on 4.5S RNA are presented) and/or energy minimization analyses followed by phylogenetic comparison. Although, with the exception of 4.5S RNA, all 7SL-derived RNA species maintain the cruciform structure of their progenitor, the details of 7SL RNA folding domains are modified to a different extent in various RNA groups. Novel motifs found in retropositionally active RNAs are conserved among Alu and B1 subfamilies in different genomes. In RNAs that do not proliferate by retroposition these motifs are modified further. This indicates structural adaptation of 7SL-like RNA molecules to novel functions, presumably mediated by specific interactions with proteins; these functions were either useful for the host or served the selfish propagation of RNA templates within the host genome.Abbreviations FAM fossil Alu element - FLAM free left Alu monomer - FRAM free right Alu monomer - L-Alu left Alu subunit - R-Alu right Alu subunit Correspondence to: D. LabudaDedicated to Dr. Robert Cedergren on the occasion of his 25th anniversary at the University of Montreal     

Nucleotide sequence of 7 S RNA. Homology to Alu DNA and La 4.5 S RNA

7 S RNA, a component of normal higher eukaryotic cells and several oncornaviruses, was shown to be conserved in evolution (Erikson, E., Erikson, R. L., Henry, B., and Pace, N. R. (1973) Virology 53, 40-46). Recently, 7 S RNA was shown to be partially complementary to Alu family DNA sequences (Weiner, A. (1980) Cell 22, 209-218). In the present study the nucleotide sequence of Novikoff hepatoma 7 S RNA was determined to be: (formula, see text) Comparison of 7 S RNA, Alu and B1 family DNA, and La 4.5 S RNA sequences for homologies showed that 1) one-third of 7 S RNA, mainly the 5'-end, was homologous to Alu and B1 family sequences; 2) one 300-nucleotide long Alu family sequence contained two binding sites for 7 S RNA; and 3) the 5'-ends of 7 S RNA and La 4.5 S RNA also had extensive (60%) homologies. A model for the secondary structure of 7 S RNA based on maximal base pairing and preferential nuclease cleavage sites is also presented.     

Characterization of rat ribosomal DNA. The highly repetitive sequences that flank the ribosomal RNA transcription unit are homologous and contain RNA polymerase III transcription initiation sites

The non-transcribed spacers (NTS) of the ribosomal genes of a number of organisms have been studied and were found to contain repetitive sequences. In these studies with plasmid subclones of NTS, designated p3.4, p2.6 and p1.7, which come from both 5' and 3' flanking regions of the rat ribosomal genes, respectively, it has been determined that these sequences are found elsewhere within the genome. Southern hybridization analysis has demonstrated that the 5' and 3' NTS subclones cross-hybridize, and that the cross-hybridizing regions are synonymous with the highly repetitive regions. Sequences homologous to the rat NTS were specifically localized to both 5' and 3' flanking regions as well as to a number of the introns of cloned genes including rat serum albumin, rat alpha-fetoprotein, rat casein and human serum albumin. No hybridization was detected of the 5' NTS subclone to the human Alu sequence clone, Blur 8, or to the rodent equivalent, a clone containing Chinese hamster ovary type I and II Alu sequences. However, as reported for type II Alu sequences, the subcloned rat NTS sequences contain RNA polymerase III initiation sites and also hybridize to a number of small RNAs, but not 4.5 S or 7 S RNA. Sequence analysis of two distinct repetitive regions in p1.7 has revealed a region of alternating purine-pyrimidine nucleotides, potentially of Z DNA, and stretches of repetitive sequences. The possible roles for these repetitive sequences in recombination and in maintaining a hierarchical structure for the ribosomal genes are discussed.     

Sequence organization of variant mouse 4.5 S RNA genes and pseudogenes.

The rodent 4.5 S RNA is an RNA polymerase III product with a sequence related to the Alu family of interspersed repeated DNA. A previous study identified a tandem array of 4.2-kb repeating units that contain the 4.5 S RNA coding sequence as well as many short repetitive sequences. To understand the genomic organization of this gene family, we have isolated and characterized 4.5 S RNA sequences that are part of the tandem array as well as identified members that are not part of the array. One variant 4.5 S RNA gene family member exhibits length polymorphisms in its minisatellite sites relative to the single previously reported gene. The 4.5 S RNA sequences that are not part of the tandem array possess many of the features of processed pseudogenes and are found adjacent to other interspersed repeated elements. These findings suggest that the mouse 4.5 S RNA can behave as a retroposon, resulting in the accumulation of 4.5 S RNA-like elements at many sites in the genome.     

Human histone genes are interspersed with members of the Alu family and with other transcribed sequences

We have isolated a series of recombinant λCh4A phages containing human histone genes. Histone H2A, H2B, H3 and H4 genes have been found to be clustered, but are not present in any simple repeat pattern. Hybridization of a blot containing phage DNA with S phase polysomal cDNA indicates the presence of additional sequences complementary to HeLa polysomal RNA sequences. Northern blot analysis using these clones as probes has also shown the presence of sequences complementary to non-histone-coding RNAs, some of which accumulate differentially in different stages of the cell cycle. We have also found, by hybridization with appropriate probes, that histone genes are interspersed with several copies of the Alu DNA family; however, not all of the histone genes are associated with an Alu DNA sequence.     

Evolution of mouse B1 repeats: 7SL RNA folding pattern conserved

Summary In a recent report mouse B1 genomic repeats were divided into six families representing different waves of fixation of B1 variants, consistent with the retroposition model of human Alu elements. These data are used to examine the distribution of nucleotide substitutions in individual genomic repeats with respect to family consensus sequences and to compare the minimal energy structures of the corresponding B1 RNAs. By an enzymatic approach the predicted structure of B1 RNAs is experimentally confirmed using as a model sequence an RNA of a young B1 family member transcribed in vitro by T7 RNA polymerase. B1 RNA preserves folding domains of the Alu fragment of 7SL RNA, its progenitor molecule. Our results reveal similarities among 7SL-like retroposons, human Alu, and rodent B1 repeats, and relate the evolutionary conservation of B1 family consensus sequences to selection at the RNA level.     

4.5S RNA is encoded by hundreds of tandemly linked genes, has a short half-life, and is hydrogen bonded in vivo to poly(A)-terminated RNAs in the cytoplasm of cultured mouse cells.

4.5S RNA is a group of RNAs 90 to 94 nucleotides long (length polymorphism due to a varying number of UMP residues at the 3' end) that form hydrogen bonds with poly(A)-terminated RNAs isolated from mouse, hamster, or rat cells (W. R. Jelinek and L. Leinwand, Cell 15:205-214, 1978; F. Harada, N. Kato, and H.-O. Hoshino, Nucleic Acids Res. 7:909-917, 1979). We have cloned a gene that encodes the 4.5S RNA. It is repeated 850 (sigma = 54) times per haploid mouse genome and 690 (sigma = 59) times per haploid rat genome. Most, if not all, of the repeats in both species are arrayed in tandem. The repeat unit is 4,245 base pairs long in mouse DNA (the complete base sequence of one repeat unit is presented) and approximately 5,300 base pairs in rat DNA. This accounts for approximately 3 X 10(6) base pairs of genomic DNA in each species, or 0.1% of the genome. Cultured murine erythroleukemia cells contain 13,000 molecules per cell of the 4.5S RNA, which can be labeled to equilibrium in 90 min by [3H]uridine added to the culture medium. The 4.5S RNA, therefore, has a short half-life. The 4.5S RNA can be cross-linked in vivo by 4'-aminomethyl-4,5',8-trimethylpsoralen to murine erythroleukemia cell poly(A)-terminated cytoplasmic RNA contained in ribonucleoprotein particles.     

Changes in nuclear and polysomal polyadenylated RNA sequences during rat-liver regeneration.

Nuclear and polysomal polyadenylated RNA populations of normal and 16 hour regenerating rat liver have been compared by mRNA-cDNA hybridisations and by unique DNA saturation experiments. It was found that nuclear polyadenylated RNA hybridises to 6.8% of unique DNA in both normal and 16 hour regenerating rat liver. However, cross-hybridisation experiments using cDNA have shown that 10-15% by weight of nuclear polyadenylated RNA sequences are specific to 16 hour regenerating rat-liver. Since both unique DNA and cDNA hybridisation have shown that normal and 16 hour regenerating rat-liver polysomal polyadenylated RNA populations are qualitatively very similar sequences specific to 16 hour regenerating rat-liver nuclear polyadenylated RNA are nucleus confined. Polysomal RNA sequences which were abundant in normal rat-liver have become less abundant in regenerating rat liver.