Sequence and conformation of 5 S RNA from Chlorella cytoplasmic ribosomes: comparison with other 5 S RNA molecules

The sequence of Chlorella cytoplasmic 5 S RNA has been determined by fingerprinting techniques. Partial digests were fractionated by a two-dimensional acrylamide gel electrophoretic technique, which indicates whether specific fragments are paired in the molecule. In this way, the four main base-paired regions of the molecule were located. The sequence of Chlorella cytoplasmic 5 S RNA is related to, but different from, that of other eukaryotic 5 S RNAs: it shows approximately 60% homology with vertebrate 5 S RNA and 40% homology with yeast 5 S RNA. In some respects the conformation of the molecule in solution is quite different from that of other sequenced 5 S RNAs: in particular, the highly accessible region found around position 40 in all other 5 S RNAs (prokaryotic and eukaryotic) does not exist in this molecule.     

In vitro RNA transcription by the New Jersey serotype of vesicular stomatitis virus. II. Characterization of the leader RNA.

The New Jersey serotype of vesicular stomatitis virus (VSV) was able to synthesize a small RNA (leader RNA) approximately 70 bases in length similar to the leader RNA synthesized in vitro by the genetically distinct Indiana serotype of VSV. Also, the New Jersey leader RNA contained the same 5'-terminal sequence, ppA-C-G, as the Indiana leader RNA and had a very similar base composition, with 42% AMP, 16% CMP, 18.6% GMP, and 23.4% UMP. The 3'-terminal sequence of the VSV New Jersey genome RNA was detemined and found to contain the sequence- Py-G-UOH, again the same as that of the Indiana serotype of VSV. Evidence that the New Jersey leader RNA is transcribed from the 3' end of the genome RNA was obtained from the fact that it can protect the 3'-terminal base of [3H]borohydride-labeled New Jersey genome RNA from RNase digestion. Although the New Jersey and Indiana leader RNAs were similar in many respects, they were unable to form RNase-resistant hybrids when annealed to heterologous genome RNA.     

Role of the 5' leader sequence of alfalfa mosaic virus RNA 3 in replication and translation of the viral RNA.

RNA 3 of alfalfa mosaic virus (AIMV) encodes the movement protein P3 and the viral coat protein which is translated from the subgenomic RNA 4. The 5'-leader sequences of RNA 3 of AIMV strains S, A, and Y differ in length from 314 to 392 nucleotides and contain a variable number of internal control regions of type 2 (ICR2 motifs) each located in a 27 nt repeat. Infectious cDNA clones were used to exchange the leader sequences of the three strains. This revealed that the leader sequence controls the specific ratio in which RNAs 3 and 4 are synthesized for each strain. In addition, it specifies strain specific differences in the kinetics of P3 accumulation in plants. Subsequent deletion analysis revealed that a 5'-sequence of 112 nt containing one ICR2 motif was sufficient for a 10 to 20% level of RNA 3 accumulation in protoplasts and a delayed accumulation in plants. An additional leader sequence of maximally 114 nt, containing two ICR2 motifs, was required to permit wildtype levels of RNA 3 accumulation. The effect of deletions in the leader sequence on P3 synthesis in vitro and in vivo was investigated.     

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.     

High-frequency leader sequence switching during coronavirus defective interfering RNA replication.

A system was developed that exploited defective interfering (DI) RNAs of coronavirus to study the role of free leader RNA in RNA replication. A cDNA copy of mouse hepatitis virus DI RNA was placed downstream of the T7 RNA polymerase promoter to generate DI RNAs capable of extremely efficient replication in the presence of a helper virus. We demonstrated that, in the DI RNA-transfected cells, the leader sequence of these DI RNAs was switched to that of the helper virus during one round of replication. This high-frequency leader sequence exchange was not observed if a nine-nucleotide stretch of sequence (UUUAUAAAC) at the junction between the leader and the remaining DI sequence was deleted. This observation suggests that a free leader RNA generated from the genomic RNA of mouse hepatitis virus may participate in the replication of DI RNA.     

Small RNA molecules related to the Alu family of repetitive DNA sequences.

A rodent 4.5S RNA molecule with extensive homology to the Alu family of interspersed repetitive DNA sequences has been found physically associated with polyadenylated nuclear and cytoplasmic RNAs (W. Jelinek and L. Leinwand, Cell 15:205-214, 1978; S. Haynes et al., Mol. Cell. Biol. 1:573-583, 1981). In this report, we describe a 4.5S RNA molecule in rat cells whose RNase fingerprints are identical to those of the equivalent mouse molecule. We show that the rat 4.5S RNA is part of a small family of RNA molecules, all sharing sequence homology to the Alu family of DNA sequences. These RNAs are synthesized by RNA polymerase III and are developmentally regulated and short-lived in the cytoplasm. Of this family of small RNAs, only the 4.5S RNA is found associated with polyadenylated RNA.     

Coronavirus multiplication strategy. II. Mapping the avian infectious bronchitis virus intracellular RNA species to the genome.

Avian infectious bronchitis virus, a coronavirus, directed the synthesis of six major single-stranded polyadenylated RNA species in infected chicken embryo kidney cells. These RNAs include the intracellular form of the genome (RNA F) and five smaller RNA species (RNAs A, B, C, D, and E). Species A, B, C, and D are subgenomic RNAs and together with the genome form a nested sequence set, with the sequences of each RNA contained within every larger RNA species (D. F. Stern and S. I. T. Kennedy, J. Virol 34:665-674, 1980). In the present paper we show by RNase T1 oligonucleotide fingerprinting that RNA E is also a member of the nested set. Partial alkaline fragmentation of the genome followed by sucrose fractionation, oligodeoxythymidylate-cellulose chromatography, and RNase T1 fingerprinting gave a partial 3'-to-5' oligonucleotide spot order. A comparison of the oligonucleotides of each of the five subgenomic RNAs with this spot order established that all of the RNAs are comprised of nucleotide sequences inward from the 3' end of the genome. This result is discussed in relation to the multiplication strategy both of coronaviruses and of other RNA-containing viruses.     

The S(MK) box is a new SAM-binding RNA for translational regulation of SAM synthetase

We have identified the S(MK) box as a conserved RNA motif in the 5' untranslated leader region of metK (SAM synthetase) genes in lactic acid bacteria, including Enterococcus, Streptococcus and Lactococcus species. This RNA element bound SAM in vitro, and binding of SAM caused an RNA structural rearrangement that resulted in sequestration of the Shine-Dalgarno (SD) sequence. Mutations that disrupted pairing between the SD region and a sequence complementary to the SD blocked SAM binding, whereas compensatory mutations that restored pairing restored SAM binding. The Enterococcus faecalis S(MK) box conferred translational repression of a lacZ reporter when cells were grown under conditions where SAM pools are elevated, and mutations that blocked SAM binding resulted in loss of repression, demonstrating that the S(MK) box is functional in vivo. The S(MK) box therefore represents a new SAM-binding riboswitch distinct from the previously identified S box RNAs.     

Carbon source transport, nucleotide levels, and stable RNA synthesis in a mutant strain of Escherichia coli

We have previously described a temperature-sensitive mutant of Escherichia coli, 2S142 (rel-, met-, rns-, ilv-, ts-) which shows specific inhibition of stable RNA synthesis at 42 degrees C. This mutation mimics a carbon source downshift in that the decay of guanosine 5'-diphosphate, 3'-diphosphate (ppGpp) is inhibited at the restrictive temperature. In this paper we show that the temperature-sensitive lesion in 2S142 does affect the uptake of glucose or alpha-D-methylglucopyranoside (alpha DMG) at 42 degrees C. However, restoration of glucose or alpha DMG uptake by the insertion of a constitutive galactose permease gene or further restriction of glucose uptake by insertion of a ptsG mutation into 2S142 have no effect on rRNA synthesis at 42 degrees C (although ppGpp levels are lowered in both cases). Furthermore, while restriction of uptake at 42 degrees C varies widely from carbon source to carbon source, severe restriction of rRNA synthesis is observed on all carbon sources tested at 42 degrees C. Levels of glycolytic intermediates, adenylate energy charge, ATP levels, and cAMP levels are all unaffected at the restrictive temperature. GTP levels decrease at 42 degrees C in glucose grown cells but that also does not appear to be related to the decrease in rRNA synthesis. These data were interpreted to suggest that the restriction of stable RNA synthesis in 2S142 at 42 degrees C can not be explained on the basis of decreased uptake and/or metabolism of carbon source. "Phantom spot" levels do decrease in 2S142 at 42 degrees C. In fact, "phantom spot" is the only putative regulatory molecule which correlates with restriction of rRNA synthesis on all carbon sources tested.     

Evidence for the Identity of Shared 5′-Terminal Sequences Between Genome RNA and Subgenomic mRNA''s of B77 Avian Sarcoma Virus

The polyribosomal fraction from chicken embryo fibroblasts infected with B77 avian sarcoma virus contained 38S, 28S, and 21S virus-specific RNAs in which sequences identical to the 5'-terminal 101 bases of the 38S genome RNA were present. The only polyadenylic acid-containing RNA species with 5' sequences which was detectable in purified virions had a sedimentation coefficient of 38S. This evidence is consistent with the hypothesis that a leader sequence derived from the 5' terminus of the RNA is spliced to the bodies of the 28S and 21S mRNA's, both of which have been shown previously to be derived from the 3' terminal half of the 38S RNA. The entire 101-base 5' terminal sequence of the genome RNA appeared to be present in the majority of the subgenomic intracellular virus-specific mRNA's, as established by several different methods. First, the extent of hybridization of DNA complementary to the 5'-terminal 101 bases of the genome to polyadenylic acid-containing subgenomic RNA was similar to the extent of its hybridization to 38S RNA from infected cells and from purified virions. Second, the fraction of the total cellular polyadenylic acid-containing RNA with 5' sequences was similar to the fraction of RNA containing sequences identical to the extreme 3' terminus of the genome RNA when calculated by the rate of hybridization of the appropriate complementary DNA probes. This suggests that most intracellular virus-specific RNA molecules contain sequences identical to those present in the 5'-terminal 101 bases of the genome. Third, the size of most of the radioactively labeled DNA complementary to the 5'-terminal 101 bases of the genome remained unchanged after the probe was annealed to either intracellular 38S RNA or to various size classes of subgenomic RNA and the hybrids were digested with S1 nuclease and denatured with alkali. However, after this procedure some DNA fragments of lower molecular weight were present. This was not the case when the DNA complementary to the 5'-terminal 101 bases of the genome was annealed to 38S genome RNA. These results suggest that, although the majority of the intracellular RNA contains the entire 101-base 5'-terminal leader sequence, a small population of virus-specific RNAs exist that contain either a shortened 5' leader sequence or additional splicing in the terminal 101 bases.     

Intracellular vesicular stomatitis virus leader RNAs are found in nucleocapsid structures.

Previous studies demonstrated that cytoplasmic extracts of cells infected with vesicular stomatitis virus contain plus-strand leader RNAs which sediment at 18S on sucrose gradients as a complex with viral N protein. The work presented in this paper demonstrated that these 18S complexes were stable on CsCl density gradients, banding at a buoyant density near that of genome nucleocapsids, and exhibited a morphology in an electron microscope similar to the disk structures found in virus genome nucleocapsids. Minus-strand leader RNAs were also found in 18S complexes on sucrose gradients. Quantitation of intracellular leader RNA suggested that, late in infection, approximately three-quarters of total intracellular leader RNA was encapsidated.     

Structure-function relationship of Rous sarcoma virus leader RNA.

Cells infected by RSV synthesize viral 35S RNA as well as subgenomic 28S and 22S RNAs coding for the Env and Src genes respectively. In addition, at least the 5' 101 nucleotides of the leader are also conserved and we have shown previously that this sequence contains a strong ribosome binding site (J.-L. Darlix et al., J. Virol. 29, 597). We now report the RNA sequence of Rous Sarcoma virus (RSV) leader RNA and propose a folding of this 5' untranslated region which brings the Cap, the initiation codon for Gag and the strong ribosome binding site close to each other. We also show that ribosomes protect a sequence just upstream from initiator Aug of Gag in vitro, and believed to interact with part of the strong ribosome binding site according to the folding proposed for the leader RNA.     

Biochemical research on oogenesis. RNA accumulation during oogenesis of the dogfish Scyliorhinus caniculus

Four biochemical mechanisms have been shown to operate in the oocytes of amphibians and teleosts: (1) amplification of the 28 S and 18 S genes, (2) noncoordinate accumulation of 5 S RNA and 28 S + 18 S RNA, (3) storage of 5 S and transfer RNA made in excess by small oocytes within nucleoprotein particles, (4) expression of different 5 S genes in oocytes and somatic cells. We have tried to extend these observations to another group of vertebrates, i.e., selacians (Chondrichthya). Our data suggest that ribosomal gene amplification is low or absent in the oocytes of the dogfish Scyliorhinus caniculus. However, previtellogenic oocytes of this species accumulate more 5 S RNA than needed for ribosome assembly. Transfer and 5 S RNA present in small oocytes are probably not free in the cell sap. A substantial fraction of these RNAs sediments at 10 S when homogenates of immature ovaries are centrifuged in sucrose density gradients. In contrast to what we observed in amphibians and teleosts, 5 S RNA from ovaries of S. caniculus is identical in sequence to 5 S RNA from liver. Among the four mechanisms mentioned above, the second and probably the third one are used by the oocytes of S. caniculus. Mechanism (4) is absent in this species. No definitive conclusion can be drawn concerning mechanism (1), i.e., ribosomal gene amplification.     

RNA recombination in a coronavirus: recombination between viral genomic RNA and transfected RNA fragments.

Mouse hepatitis virus (MHV), a coronavirus, has been shown to undergo a high frequency of RNA recombination both in tissue culture and in animal infection. So far, RNA recombination has been demonstrated only between genomic RNAs of two coinfecting viruses. To understand the mechanism of RNA recombination and to further explore the potential of RNA recombination, we studied whether recombination could occur between a replicating MHV RNA and transfected RNA fragments. We first used RNA fragments which represented the 5' end of genomic-sense sequences of MHV RNA for transfection. By using polymerase chain reaction amplification with two specific primers, we were able to detect recombinant RNAs which incorporated the transfected fragment into the 5' end of the viral RNA in the infected cells. Surprisingly, even the anti-genomic-sense RNA fragments complementary to the 5' end of MHV genomic RNA could also recombine with the MHV genomic RNAs. This observation suggests that RNA recombination can occur during both positive- and negative-strand RNA synthesis. Furthermore, the recombinant RNAs could be detected in the virion released from the infected cells even after several passages of virus in tissue culture cells, indicating that these recombinant RNAs represented functional virion RNAs. The crossover sites of these recombinants were detected throughout the transfected RNA fragments. However, when an RNA fragment with a nine-nucleotide (CUUUAUAAA) deletion immediately downstream of a pentanucleotide (UCUAA) repeat sequence in the leader RNA was transfected into MHV-infected cells, most of the recombinants between this RNA and the MHV genome contained crossover sites near this pentanucleotide repeat sequence. In contrast, when exogenous RNAs with the intact nine-nucleotide sequence were used in similar experiments, the crossover sites of recombinants in viral genomic RNA could be detected at more-downstream sites. This study demonstrated that recombination can occur between replicating MHV RNAs and RNA fragments which do not replicate, suggesting the potential of RNA recombination for genetic engineering.     

A common conformational feature in several prokaryotic and eukaryotic 5 S RNAs: a highly exposed, single-stranded loop around position 40

Psendomonas fluorescens, yeast and HeLa cells ³²P-labelled 5 S RNAs were submitted to partial hydrolysis with T₁, T₂ or pancreatic ribonucleases; the fragments were separated by two-dimensional acrylamide gel electrophoresis. First splits (obtained when only one cleavage takes place in the molecule) were found to occur essentially around position 40 in the sequence, as already demonstrated for Escherichia coli 5 S RNA. The existence in prokaryotic and eukaryotic 5 S RNAs of this very accessible region is thus proved. Eukaryotic 5 S RNAs also display a very accessible region around position 90 of the sequence.