Ordered processing of Escherichia coli 23S rRNA in vitro.

In an RNase III-deficient strain of E. coli 23S pre-rRNA accumulates unprocessed in 50S ribosomes and in polysomes. These ribosomes provide a substrate for the analysis of rRNA maturation in vitro. S1 nuclease protection analysis of the products obtained in in vitro processing reactions demonstrates that 23S rRNA processing is ordered. The double stranded stem of 23S rRNA is cleaved by RNase III in vitro to two intermediate RNAs at the 5' end and one at the 3' end. Mature termini are then produced by other enzyme(s) in a soluble protein fraction from wild-type cells. The nature of the reaction at the 5' end is not clear, but the reaction at the 3' end is exonucleolytic, producing three heterogeneous mature termini. The two reactions are coordinated; 3' end maturation progresses concurrently with cleavages at the 5' end. Two results suggest a possible link between final maturation and translation: in vitro, mature termini are formed efficiently in the presence of additives required for protein synthesis; and all the processing intermediates detected from in vitro reactions are also found in polysomes from wild-type cells.     

Escherichia coli 23S ribosomal RNA truncated at its 5'' terminus.

In a strain of E. coli deficient in RNase III (ABL1), 23S rRNA has been shown to be present in incompletely processed form with extra nucleotides at both the 5' and 3' ends (King et al., 1984, Proc. Natl. Acad. Sci. U.S. 81, 185-188). RNA molecules with four different termini at the 5' end are observed in vivo, and are all found in polysomes. The shortest of these ("C3") is four nucleotides shorter than the accepted mature terminus. In growing cells of both wild-type and mutant strains up to 10% of the 23S rRNA chains contain the 5' C3 terminus. In stationary phase cells, the proportion of C3 termini remains the same in the wild-type cells; but C3 becomes the dominant terminus in the mutant. Species C3 is also one of the 5' termini of 23S rRNA generated in vitro from larger precursors by the action of purified RNase III. We therefore suggest that some form of RNase III may still exist in the mutant; and since no cleavage is detectable at any other RNase III-specific site, the remaining enzyme would have a particular affinity for the C3 cleavage site, especially in stationary phase cells. We raise the question whether the C3 terminus has a special role in cellular metabolism.     

Mini-III, an unusual member of the RNase III family of enzymes, catalyses 23S ribosomal RNA maturation in B. subtilis

The late steps of both 16S and 5S ribosomal RNA maturation in the Gram-positive bacterium Bacillus subtilis have been shown to be catalysed by ribonucleases that are not present in the Gram-negative paradigm, Escherichia coli. Here we present evidence that final maturation of the 5' and 3' extremities of B. subtilis 23S rRNA is also performed by an enzyme that is absent from the Proteobacteria. Mini-III contains an RNase III-like catalytic domain, but curiously lacks the double-stranded RNA binding domain typical of RNase III itself, Dicer, Drosha and other well-known members of this family of enzymes. Cells lacking Mini-III accumulate precursors and alternatively matured forms of 23S rRNA. We show that Mini-III functions much more efficiently on precursor 50S ribosomal subunits than naked pre-23S rRNA in vitro, suggesting that maturation occurs primarily on assembled subunits in vivo. Lastly, we provide a model for how Mini-III recognizes and cleaves double-stranded RNA, despite lacking three of the four RNA binding motifs of RNase III.     

The ordered processing of intervening sequences in 23S rRNA of Rhodobacter sphaeroides requires RNase J

The essential processing of ribosomal rRNA precursors requires concerted and sequential cleavages by different endo- and exoribonucleases. Despite long lasting investigations of these processes the exact order of steps remained elusive. Many bacteria perform additional rRNA processing steps by removing intervening sequences within the 23S rRNA. This leads to disintegration of the 23S rRNA and discontinuously assembled fragments within the ribosomes. The maturation of these fragments also requires successive cleavage events by different RNases. Our study reveals that the 5'-to-3' exoribonuclease RNase J is responsible for the final 5'-end maturation of all three 23S rRNA fragments in the α-proteobacterium Rhodobacter sphaeroides. Additionally the results show that 5'- and 3'-processing steps are closely coupled: mature 5'-ends are a strict prerequisite for the final 3'-trimming of the 23S rRNA fragments.     

Partial purification and properties of a ribosomal RNA maturation endonuclease from Bacillus subtilis.

Data are presented on the partial purification and properties of a 5 S ribosomal RNA maturation nuclease, termed RNase M5, from Bacillus subtillis 168. RNase M5 specifically cleaves 21 and 42 nucleotides, respectively, from the 5' and 3' termini of a 5 S rRNA precursor to yield the mature (116 nucleotides) 5 S rRNA. The cleavage is endonucleolytic with the formation of 5'-phosphoryl and 3'-hydroxyl groups. Enzyme action requires divalent cations, which may be furnished by either certain metals or by polyamines. The activity is separable into two components both of which are required for activity. It appears that the same nuclease excises the 5'- and 3'-terminal segments since preparations lose the capacity to modify the two termini with an identical first order thermal decay rate. Certain features of the rRNA precursor which may be involved in cognitive interaction with RNase M5 are discussed.     

Location of the initial cleavage sites in mouse pre-rRNA.

The locations of three cleavages that can occur in mouse 45S pre-rRNA were determined by Northern blot hybridization and S1 nuclease mapping techniques. These experiments indicate that an initial cleavage of 45S pre-rRNA can directly generate the mature 5' terminus of 18S rRNA. Initial cleavage of 45S pre-rRNA can also generate the mature 5' terminus of 5.8S rRNA, but in this case cleavage can occur at two different locations, one at the known 5' terminus of 5.8S rRNA and another 6 or 7 nucleotides upstream. This pattern of cleavage results in the formation of cytoplasmic 5.8S rRNA with heterogeneous 5' termini. Further, our results indicate that one pathway for the formation of the mature 5' terminus of 28S rRNA involves initial cleavages within spacer sequences followed by cleavages which generate the mature 5' terminus of 28S rRNA. Comparison of these different patterns of cleavage for mouse pre-rRNA with that for Escherichia coli pre-rRNA implies that there are fundamental differences in the two processing mechanisms. Further, several possible cleavage signals have been identified by comparing the cleavage sites with the primary and secondary structure of mouse rRNA (see W. E. Goldman, G. Goldberg, L. H. Bowman, D. Steinmetz, and D. Schlessinger, Mol. Cell. Biol. 3:1488-1500, 1983).     

Mode of degradation of precursor-specific ribonucleic acid fragments by Bacillus subtilis.

A precursor of 5S ribosomal ribonucleic acid (rRNA) from Bacillus subtilis was cleaved by ribonuclease (RNase) M5 in cell-free extracts from B. subtilis to yield the mature 5S rRNA plus RNA fragments derived from both termini of the precursor. The released, mature 5S rRNA was stable in these extracts; however, as occurred in vivo, the precursor-specific fragments were rapidly and completely destroyed. Such destruction was not observed in the presence of partially purified RNase M5, so fragment scavenging was not effected by the maturation nuclease itself. The selective destruction of the precursor-specific fragments was shown to occur through a 3'-exonucleolytic process with the release of nucleoside 5'-monophosphates; the responsible activity therefore had the character of RNAse II. Consideration of the primary and probable secondary structures of the precursor-specific fragments and mature 5S rRNA suggested that involvement of 3' termini in tight secondary structure may confer protection against the scavenging activity.     

The ribonucleoprotein substrate for a ribosomal RNA-processing nuclease

The Bacillus subtilis RNase M5 activity, responsible for the endonucleolytic maturation of 5 S rRNA, requires two proteins, alpha and beta. The beta component has been purified to homogeneity and shown to correspond to ribosomal protein BL16. The BL16 protein evidently corresponds functionally to Escherichia coli ribosomal protein EL18, as that latter protein also will complement the B. subtilis alpha protein in the RNase M5 reaction. A filter binding assay for the formation of B. subtilis 5 S rRNA-protein complexes was characterized and used to evaluate the association of BL16 protein with some RNAs. A native precursor of 5 S rRNA, containing extra sequences at both termini of the mature domain, binds the ribosomal protein no better than the mature 5 S rRNA; the precursor sequences do not facilitate that interaction. A model is considered in which the precursor segments facilitate, by refolding, the dissociation of processing products prior to the RNase M5 step. Electrostatic versus nonelectrostatic contributions to the BL16-5 S rRNA complex formation were inspected by analyzing variation in apparent association constants as a function of ionic strength. Electrostatic interactions were seen to contribute approximately 65% to the overall binding energy.     

Involvement of the mature domain in the in vitro maturation of Bacillus subtilis precursor 5S ribosomal RNA.

A precursor of 5S ribosomal RNA from Bacillus subtilis (p5A rRNA, 179 nucleotides in length) is cleaved by RNase M5, a specific maturation endonuclease which releases the mature 5S rRNA (m5, 116 nucleotides) and precursor fragments derived from the 5' (21 nucleotides) and 3' (42 nucleotides) termini of p5A rRNA. Previous results (Meyhack, B., et al. (1978) Proc. Natl. Acad. Sci. U.S.A. 75, 3045) led to the conclusion that recognition elements in potential RNase M5 substrates mainly reside in the mature moiety of the precursor. Limited digestion of p5A rRNA with RNase T1 permitted the isolation of a number of test substrates which contained both precursor-specific segments and were unaltered in the immediate vicinity of the cleavage sites, but which differed in that more or less extensive regions of the mature moiety of the p5A rRNA were deleted. Tests of the capacity of these partial molecules to serve as substrates for RNase M5 indicate clearly that the enzyme recognizes the overall conformation of potential substrates, neglecting only the double-helical "prokaryotic loop" (Fox, G.E., & Woese, C.R. (1975) Nature (London) 256, 505).     

Computer analysis of potential stem structures of rRNA operons in various procaryote genomes

The processing of 16S rRNA and 23S rRNA by RNase III in E.coli is known to involve stem structures formed by both ends of the rRNA. Indeed, complementary nucleotide sequences are usually found at both ends of 16S rRNA and 23S rRNA. However, whether or not this phenomenon exists in various other bacteria has not yet been adequately studied. We have conducted computer analyses of potential stem structures of rRNA operons in 12 bacterial and 3 archaeal genomes, and compared characteristics of the stem structures among these species. We systematically computed free energy values by exhaustively 'annealing' sequences around the 5' end and sequences around the 3' end of both 16S rRNA and 23S rRNA genes, in order to predict potential stem structures.The results suggest that rRNAs in most species form stem structures at both ends. Some species, such as A.aeolicus, seem to form unusually stable stem structures. On the other hand, some rRNAs, such as rRNAs of D.radiodurans, seem not to form solid stem structures. This suggests that rRNA processing in those species must employ a reliable targeting mechanism other than recognizing stem structures by RNase III.