Transfer RNA Biosynthesis: The Nucleotide Sequence of a Precursor to Serine and Proline Transfer RNAs

The nucleotide sequence of a transfer RNA precursor molecule coded by bacteriophage T4 has been determined. The molecule is a single polynucleotide chain which contains two transfer RNA species that are destined to recognize serine and proline. The 3' -CCA(OH) termini of both mature transfer RNA species are absent in the precursor molecule; these termini must therefore be added enzymatically at a subsequent stage of maturation. Nucleotide residues unique to the precursor are located at both ends of the molecule and between the two transfer RNA sequences.     

Identification of nuclear proteins that specifically bind to RNAs containing 5'' splice sites.

Two polypeptides of 26 and 37 kDa (designated SPP-1 and SPP-2) were identified in in vitro splicing extracts by UV crosslinking to splicing precursor RNAs. Crosslinking of both polypeptides required a functional 5' splice site but was not dependent on sequences at the 3' end of the intron. Centrifugation of extract separated the two polypeptides from major U small nuclear ribonucleoproteins (snRNPs), including U1 snRNPs. Both polypeptides crosslinked to precursor RNAs containing 5' splice sites in the absence of U1 RNA. Complexes containing both polypeptides also contained U1 snRNPs, suggesting that SPP-1 and SPP-2 are a part of the functional spliceosome. We propose that SPP-1 and SPP-2 are factors that participate in the recognition of 5' splice sites.     

Influenza defective interfering viral RNA is formed by internal deletion of genomic RNA.

The 3'- and 5'-terminal nucleotide sequences of the defective interfering (DI) RNAs present in a preparation of DI influenza virus were determined. It was found that all DI RNAs possessed identical terminal sequences for at least the first 13 nucleotides at the 5' end and at least the last 12 nucleotides at the 3' end. The sequence of the DI RNAs is (5')A-G-U-A-G-A-A-A-C-A-A-G-G-...-C-C-U-G-C-U-U-U-C-G-C-U-OH(3'). In addition, the same sequences were present at the 3' and 5' termini of the viral polymerase genes (P1, P2, and P3) from which these DI RNAs originate. These results indicate that DI RNAs of influenzing virus are formed by an internal deletion of the genomic RNA.     

Replication of avocado sunblotch viroid: evidence for a symmetric pathway with two rolling circles and hammerhead ribozyme processing.

The structure of a series of RNAs extracted from avocado infected by the 247-nt avocado sunblotch viroid (ASBVd) was investigated. The identification of multistranded complexes containing circular ASBVd RNAs of (+) and (-) polarity suggests that replication of ASBVd proceeds through a symmetric pathway with two rolling circles where these two circular RNAs are the templates. This is in contrast to the replication of potato spindle tuber viroid and probably of most of its related viroids, which proceeds via an asymmetric pathway where circular (+)-strand and linear multimeric (-)-strand RNAs are the two templates. Linear (+) and (-) ASBVd RNAs of subgenomic length (137 nt and about 148 nt, respectively) and one linear (+)-strand ASBVd RNA of supragenomic length (383-384 nt) were also found in viroid-infected tissue. The two linear (+)-strand RNAs have the same 5'- and 3'-terminal sequences, with the supragenomic species being a fusion product of the monomeric and subgenomic (+)-strand ASBVd RNAs. The 3' termini of these two (+)-strand molecules, which at least in the subgenomic RNA has an extra nontemplate cytidylate residue, could represent sites of either premature termination of the (+)-strands or specific initiation of the (-)-strands. The 5' termini of sub- and supragenomic (+)-strand and the 5' terminus of the subgenomic (-)-strand ASBVd RNA are identical to those produced in the in vitro self-cleavage reactions of (+) and (-) dimeric ASBVd RNAs, respectively. These observations strongly suggest that the hammerhead structures which mediate the in vitro self-cleavage reactions are also operative in vivo.     

Spliced adenovirus-associated virus RNA.

We describe the structure of cytoplasmic RNA species transcribed from the DNA of adenovirus-associated virus, a defective parvovirus. The RNA was hybridized with minus strand template DNA and visualized in the electron microscope. Alternatively, the DNA.RNA duplex molecules were digested with nuclease S1 or Escherichia coli exonuclease VII and analyzed by agarose gel electrophoresis. A set of RNA species was observed with 5' terminal at map positions 5, 13, 19, or 39 and a 3' terminus and poly(A) tail at position 96 (one map unit is equivalent to 1% of genome length). Most of these RNAs are spliced and lack sequences approximately between positions 40 and 49. Some RNA preparations also contained unspliced molecules with 5' and 3' terminal at positions similar to those in the spliced RNA.     

T7 early RNAs and Escherichia coli ribosomal RNAs are cut from large precursor RNAs in vivo by ribonuclease 3

The early region of T7 DNA is transcribed as a single unit in a Ribonuclease III-deficient E. coli strain to produce large molecules essentially identical to those produced in vitro by E. coli RNA polymerase. As with the in vitro RNAs, these molecules are cut by purified RNase III in vitro to produce the messenger RNAs normally observed in vivo. Thus, the normal pathway for producing the T7 early messenger RNAs in vivo appears to involve endonucleolytic cleavage by RNase III. The uninfected RNase III-deficient strain contains several RNAs not observed in the parent strain. Patterns of labeling in vivo suggest that the largest of these RNAs, about 1.8 x 10(6) daltons, may be a precursor to the 16S and 23S ribosomal RNAs. When this large molecule is treated in vitro with purified RNase III, molecules the size of precursor 16S and 23S ribosomal RNAs are released; hybridization competition experiments also indicate that the 1.8 x 10(6) dalton RNA does indeed represent ribosomal RNA. Thus, RNase III cleavage seems to be part of the normal pathway for producing at least the 16S and 23S ribosomal RNAs in vivo. Several smaller molecules are also released from the 1.8 x 10(6) dalton RNA by RNase III, but it is not yet established whether any of these contain 5S RNA sequences.     

Mutants of Escherichia coli Thermosensitive for the Synthesis of Transfer RNA

Using a simple three-step procedure, we have isolated thermosensitive mutants of E. coli that are specifically defective in transfer RNA (tRNA) synthesis. Our procedure was designed to identify mutants that are unable to make su(3) (+) tRNA(Tyr) or grow at the restrictive temperature, yet under the same conditions they retain the ability to make mRNA and protein. The mutants obtained have been analyzed, and they are defective in different steps in the synthesis of functional tRNA at the restrictive temperature. Some of them may fail to modify certain bases in the tRNA. Two mutants are unable to process the 5' end of tRNA precursor molecules. Three are unable to cleave precursor molecules at the 3' end. 11 Mutants can not synthesize any tRNA molecules or tRNA precursors. We speculate that these latter mutants may be defective in RNA polymerase or in an RNA polymerase factor specific for stable RNA synthesis.     

Unpaired terminal nucleotides and 5' monophosphorylation govern 3' polyadenylation by Escherichia coli poly(A) polymerase I

In bacteria, most mRNAs and certain regulatory RNAs are rapidly turned over, whereas mature tRNA and ribosomal RNA are highly stable. The selective susceptibility of unstable Escherichia coli RNAs to 3' polyadenylation by the pcnB gene product, poly(A) polymerase I (PAP I), in vivo is a key factor in their rapid degradation by 3' to 5' exonucleases. Using highly purified His-tagged recombinant PAP I, we show that differential adenylation of RNA substrates by PAP I occurs in vitro and that this capability resides in PAP I itself rather than in any ancillary protein(s). Surprisingly, the efficiency of 3' polyadenylation is affected by substrate structure at both termini; single-strand segments at either the 5' or 3' end of RNA molecules and monophosphorylation at an unpaired 5' terminus dramatically increase the rate and length of 3' poly(A) tail additions by PAP I. Our results provide a mechanistic basis for the susceptibility of certain RNAs to 3' polyadenylation. They also suggest a model of "programmed" RNA decay in which endonucleolytically generated RNA fragments containing single-stranded monophosphorylated 5' termini are targeted for poly(A) addition and further degradation.     

The tRNA processing enzyme RNase T is essential for maturation of 5S RNA.

The maturation of 5S RNA in Escherichia coli is poorly understood. Although it is known that large precursors of 5S RNA accumulate in mutant cells lacking the endoribonuclease-RNase E, almost nothing is known about how the mature 5' and 3' termini of these molecules are generated. We have examined 5S RNA maturation in wild-type and single- or multiple-exoribonuclease-deficient cells by Northern blot and primer-extension analysis. Our results indicate that no mature 5S RNA is made in RNase T-deficient strains. Rather, 5S RNA precursors containing predominantly 2 extra nucleotides at the 3' end accumulate. Apparently, these 5S RNAs are functional inasmuch as mutant cells are viable, growing only slightly slower than wild type. Purified RNase T can remove the extra 3' residues, showing that it is directly involved in the trimming reaction. In contrast, mutations affecting other 3' exoribonucleases have no effect on 5S RNA maturation. Approximately 90% of the 5S RNAs in both wild-type and RNase T- cells contain mature 5' termini, indicating that 5' processing is independent of RNase T action. These data identify the enzyme responsible for generating the mature 3' terminus of 5S RNA molecules and also demonstrate that a completely processed 5S RNA molecule is not essential for cell survival.     

RNase E is required for the maturation of ssrA RNA and normal ssrA RNA peptide-tagging activity

During recent studies of ribonucleolytic "degradosome" complexes of Escherichia coli, we found that degradosomes contain certain RNAs as well as RNase E and other protein components. One of these RNAs is ssrA (for small stable RNA) RNA (also known as tm RNA or 10Sa RNA), which functions as both a tRNA and mRNA to tag the C-terminal ends of truncated proteins with a short peptide and target them for degradation. Here, we show that mature 363-nt ssrA RNA is generated by RNase E cleavage at the CCA-3' terminus of a 457-nt ssrA RNA precursor and that interference with this cleavage in vivo leads to accumulation of the precursor and blockage of SsrA-mediated proteolysis. These results demonstrate that RNase E is required to produce mature ssrA RNA and for normal ssrA RNA peptide-tagging activity. Our findings indicate that RNase E, an enzyme already known to have a central role in RNA processing and decay in E. coli, also has the previously unsuspected ability to affect protein degradation through its role in maturation of the 3' end of ssrA RNA.     

Enhancer-dependent interaction between 5'' and 3'' splice sites in trans.

Splice-site selection and alternative splicing of nuclear pre-mRNAs can be controlled by splicing enhancers that act by promoting the activity of upstream splice sites. Here we show that RNA molecules containing a 3' splice site and enhancer sequence are efficiently spliced in trans to RNA molecules containing normally cis-spliced 5' splice sites or to normally trans-spliced spliced leader RNAs from lower eukaryotes. In addition, we show that this reaction is stimulated by (Ser + Arg)-rich splicing factors that are known to promote protein-protein interactions in the cis-splicing reaction. Thus, splicing enhancers facilitate the assembly of protein complexes on RNAs containing a 3' splice site, and this complex is sufficiently stable to functionally interact with 5' splice sites located on separate RNAs. This trans-splicing is mediated by interactions between (Ser + Arg)-rich splicing factors bound to the enhancer and general splicing factors bound to the 5' and 3' splice sites. These same interactions are likely to play a crucial role in alternative splicing and splice-site selection in cis.