The nucleotide sequence of a precursor to the glycine- and threonine-specific transfer ribonucleic acids of Escherichia coli.

The primary nucleotide sequence of an Escherichia coli tRNA precursor molecule has been determined. This precursor RNA, specified by the transducing phage lambdah80dglyTsuA36 thrT tyrT, accumulates in a mutant strain temperature-sensitive for RNase P activity. The 170-nucleotide precursor RNA is processed by E. coli extracts to form mature tRNA Gly 2 suA36 and tRNA Thr ACU/C. The sequence of the precursor is pG-U-U-C-C-A-G-G-A-U-G-C-G-G-G-C-A-U-C-G-U-A-U-A-A-U-G-G-C-U-A-U-U-A-C-C-U-C-A-G-C-C-U-N-C-U-A-A-G-C-U-G-A-U-G-A-U-G-C-G-G-G-T-psi-C-G-A-U-U-C-C-C-G-C-U-G-C-C-C-G-C-U-C-C-A-A-G-A-U-G-U-G-C-U-G-A-U-A-U-A-G-C-U-C-A-G-D-D-G-G-D-A-G-A-G-C-G-C-A-C-C-C-U-U-G-G-U-mt6A-A-G-G-G-U-G-A-G-m7G-U-C-G-G-C-A-G-T-psi-C-G-A-A-U-C-U-G-C-C-U-A-U-C-A-G-C-A-C-C-A-C-U-UOH(tRNA sequences are italicized). It contains the entire primary nucleotide sequences of tRNA Gly2 suA36 and tRNA Thr ACU/C, including the common 3'-terminal sequence, CCA. Nineteen additional nucleotides are present, with 10 at the 5' end, 3 at the 3' end, and the remaining 6 in the inter-tRNA spacer region. RNase P cleaves the precursor specifically at the 5' ends of the mature tRNA sequences.     

Interplay among processing and degradative enzymes and a precursor ribonucleic acid in the selective maturation and maintenance of ribonucleic acid molecules

In order to understand why the first tRNA (tRNAGln) in the T4 tRNA gene cluster is not produced when T4 infects an RNase III- mutant of Escherichia coli, RNA metabolism was analyzed in RNase III- RNase P- (rnc, rnp) cells infected with bacteriophage T4. After such an infection a new dimeric precursor RNA molecule of tRNAGln and tRNALeu has been identified and analyzed. This molecule is structurally very similar to K band RNA that accumulates in rnc+ rnp strains. It is four nucleotides shorter than K RNA at the 5' end. This molecule like K RNA contains two RNase P processing sites at the 5' ends of each tRNA. Both sites are accessible to RNase P. However, while in the K RNA the site at the 5' end of tRNALeu (the site in the middle of the substrate) is more efficiently cleaved than the other site, this differential is even increased in the Ks (K like) molecule. This difference is sufficiently large that in vivo in the RNase III- strain the smaller precursor of tRNAGln is degraded rather than being matured to tRNAGln by RNase P. This information contributes to the elucidation of the key role of RNase III in the processing of T4 tRNA. It shows the dependence of RNase P activity at the 5' end of tRNAGln on a correct and specific cleavage by RNase III at a position six nucleotides proximal to the RNase P site, and it explains why in the absence of RNase III the first tRNA in the T4 tRNA cluster, tRNAGln, does not accumulate.     

RNA processing in prokaryotic cells

RNA processing in Escherichia coli and some of its phages is reviewed here, with primary emphasis on rRNA and tRNA processing. Three enzymes, RNase III, RNase E and RNase P are responsible for most of the primary endonucleolytic RNA processing events. The first two are proteins, while RNase P is a ribozyme. These three enzymes have unique functions and in their absence, the cleavage events they catalyze are not performed. On the other hand a relatively large number of exonucleases participate in the trimming of the 3′ ends of tRNA precursor molecules and they can substitute for each other. Primary processing is the first event that happens to the nascent RNA molecule, while in secondary RNA processing, the substrate is a product of a primary processing event. Although most RNA processing occurs in RNP particles, it seems that only in secondary RNA processing is the RNP particle required for the reaction. Bacteria and especially bacteriophages contain self-splicing introns which in cases were probably acquired from other species.     

Non-ribosomal nucleotide sequences in 7-S RNA, the immediate precursor of 5.8-S ribosomal RNA in yeast.

The topography and the length of the non-ribosomal sequences present in 7-S RNA, the immediate precursor of 5.8-S ribosomal RNA, from the yeast Saccharomyces carlsbergensis were determined by analyzing the nucleotide sequences of the products obtained after complete digestion of 7-S RNA with RNase T1. The results show that 7-S RNA contains approximately 150 non-ribosomal nucleotides. The majority (90%) of the 7-S RNA molecules was found to have the same 5'-terminal pentadecanucleotide sequence as mature 5.8-S rRNA. The remaining 10% exhibited 5'-terminal sequences identical to those of 5.9-S RNA, which has the same primary structure as 5.8-S rRNA except for a slight extension at the 5' end [Rubin, G.M. (1974) Eur. J. Biochem. 41, 197--202]. These data show that the non-ribosomal nucleotides present in 7-S RNA are all located 3'-distal to the mature 5.8-S rRNA sequence. Moreover, it can be concluded that 5.9-S RNA is a stable rRNA rather than a precursor of 5.8-S rRNA. The 3'-terminal sequence of 5.8-S rRNA (U-C-A-U-U-UOH) is recovered in a much longer oligonucleotide in the T1 RNase digest of 7-S RNA having the sequence U-C-A-U-U-U-(C-C-U-U-C-U-C)-A-A-A-C-A-(U-U-C-U)-Gp. The sequences enclosed in brackets are likely to be correct but could not be established with absolute certainty. The arrow indicates the bond cleaved during processing. The octanucleotide sequence -A-A-A-C-A-U-U-C- located near the cleavage site shows a remarkable similarity to the 5'-terminal octanucleotide sequence of 7-S RNA (-A-A-A-C-U-U-U-C-). We suggest that these sequences may be involved in determining the specificity of the cleavages resulting in the formation of the two termini of 5.8-S rRNA.     

5S ribosomal RNA is contained within a 25 S ribosomal RNA that accumulates in mutants of Escherichia coli defective in processing of ribosomal RNA.

A temperature-sensitive mutant strain of Escherichia coli defective in two RNA processing enzymes, RNase III and RNase E (rnc. rne), fails to produce normal levels of 23 S and 5 S rRNA at the non-permissive temperature. Instead, a molecule larger than 23 S is produced. This molecule, designated 25 S rRNA, can be processed in vitro to produce p5 rRNA. These findings further our understanding of the overall processing events of ribosomal RNA which take place in the bacterial cell.     

A conditional lethal mutant of Escherichia coli which affects the processing of ribosomal RNA.

A temperature-sensitive mutant strain was isolated from an RNase III-(rnc) strain of Escherichia coli. At the permissive temperature it behaves like the parental strain, but at the nonpermissive temperature it fails to produce normal levels of 23 S and 5 S rRNA, while instead the 25 S rRNA species becomes very prominent. (The 25 S molecule appears in rnc cells and contains 23 S rRNA sequences). When an rnc+ mutation was introduced to such a strain, or when the rnc mutation was replaced by an rnc+ allele, the strain remained temperature-sensitive. At the permissive temperature such strains synthesized rRNA like any other E. coli strain, but at the nonpermissive temperature they remained unable to synthesize normal levels of 5 S rRNA, and instead a larger molecule was accumulated. The simplest interpretation of theses findings is that the mutant strain contains a temperature-sensitive processing endoribonuclease, RNase E, which normally introduces a cut in the growing rRNA chain somewhere between the 23 S and the 5 S rRNA cistrons. These findings help also to explain the nature and origin of the various rRNA species observed in RNase III- cells and add to our understanding of processing of ribosomal RNA in normal cells of Escherichia coli.     

RNase G of Escherichia coli exhibits only limited functional overlap with its essential homologue,RNase E

RNase G (rng) is an E. coli endoribonuclease that is homologous to the catalytic domain of RNase E (rne), an essential protein that is a major participant in tRNA maturation, mRNA decay, rRNA processing and M1 RNA processing. We demonstrate here that whereas RNase G inefficiently participates in the degradation of mRNAs and the processing of 9S rRNA, it is not involved in either tRNA or M1 RNA processing. This conclusion is supported by the fact that inactivation of RNase G alone does not affect 9S rRNA processing and only leads to minor changes in mRNA half-lives. However, in rng rne double mutants mRNA decay and 9S rRNA processing are more defective than in either single mutant. Conversely, increasing RNase G levels in an rne-1 rng::cat double mutant, proportionally increased the extent of 9S rRNA processing and decreased the half-lives of specific mRNAs. In contrast, variations in the amount of RNase G did not alter tRNA processing under any circumstances. Thus, the failure of RNase G to complement rne mutations, even when overproduced at high levels, apparently results from its inability to substitute for RNase E in the maturation of tRNAs.     

A site in a tRNA precursor that can be processed by the whole RNase P enzyme but not by the RNA alone

A precursor molecule for 10 Sb RNA, the RNA moiety of the RNA processing enzyme RNase P, was purified, characterized for enzymatic activity, and compared to 10 Sb RNA and to RNase P. In these studies the K RNA, a dimeric precursor of tRNAGln-tRNALeu, coded by bacteriophage T4, was used as a substrate. This precursor contains two RNase P cleavage sites, one at each 5' end of the two tRNAs. The precursor 10 Sb and 10 Sb RNAs have the capacity to cleave the precursor tRNA molecule but only at the 5' end of tRNALeu, not at the 5' end of tRNAGln. Even when a substrate was prepared that contained only one site for RNase P (the one next to tRNAGln), this substrate was not cleaved by the RNA alone while the whole enzyme was effective in processing this substrate. The possible function of the protein of RNase P in the enzymatic reaction is discussed.     

The role of 5-S RNA in temperature-sensitive ribosomal RNA maturation.

The synthesis of 5-S RNA was found to be unchanged at both the permissive (33.5 degrees C) and non-permissive (38.5 degrees C) temperatures in a temperature-sensitive Baby Hamster Kidney cell line (BHK 21 ts 422 E) as measured relative to synthesis of 18-S rRNA. The 5-S RNA is shown to be associated with nucleolar ribonucleoprotein particles even though rRNA processing does not yield a functional 28-S rRNA at the non-permissive temperature. The amount of 5-S RNA found associated with the 80-S ribonucleoprotein particles was the same at the permissive and non-permissive temperatures, indicating that an aberrant 5-S RNA contribution to rRNA processing is not a primary cause for the temperature-sensitive lesion of rRNA maturation in this mutant cell line. The amount of 5-S RNA in nucleolar 80-S RNA particles indicated that the association of 5-S RNA with the rRNA precursor particle occurs before the cleavage step at which 32-S precursor RNA is produced.