Identification and analysis of the rnc gene for RNase III in Rhodobacter capsulatus.

The large subunit ribosomal RNA of the purple bacterium Rhodobacter capsulatus shows fragmentation into pieces of 14 and 16S, both fragments forming the functional equivalent of intact 23S rRNA. An RNA-processing step removes an extra stem-loop structure from the 23S rRNA [Kordes, E., Jock, S., Fritsch, J., Bosch, F. and Klug, G. (1994) J. Bacteriol., 176, 1121-1127]. Taking advantage of the fragmentation deficient mutant strain Fm65, we used genetic complementation to find the mutated gene responsible for this aberration. It was identified as the Rhodobacter homologue to mc from Escherichia coli encoding endoribonuclease III (RNase III). The predicted protein has 226 amino acids with a molecular weight of 25.5 kDa. It shares high homology with other known RNase III enzymes over the full length. In particular it shows the double-stranded RNA-binding domain (dsRBD) motif essential for binding of dsRNA substrates. The Fm65 mutant has a frame shift mutation resulting in complete loss of the dsRBD rendering the enzyme inactive. The cloned Rhodobacter enzyme can substitute RNase III activity in an RNase III deficient E. coli strain. Contrary to E. coli, the Rhodobacter mc is in one operon together with the lep gene encoding the leader peptidase.     

Cloning the gene for ribonuclease E, an RNA processing enzyme

A transducing bacteriophage lambda Ch25rne+, which codes for ribonuclease E of E. coli, has been isolated. To achieve this a random library of Escherichia coli HindIII fragments was cloned in the lambda Charon 25 vector (prepared in F.R. Blattner's laboratory), and lambda Ch25rne+ was selected by its ability upon lysogenization to enable a temperature-sensitive (ts) rne-3071 mutant to grow and to exhibit normal RNA processing at the nonpermissive temperature of 45 degrees C. The level of RNase E was doubled in an rne+ strain lysogenized with lambda Ch25rne+. lambda Ch25rne+ directs the synthesis of a polypeptide of 71 000 m.wt., which is the size of RNase E. Restriction analysis and electron micrography of heteroduplexes suggested that the size of the host DNA insert is about 1.9 kb.     

Structural requirements for processing of synthetic tRNAHis precursors by the catalytic RNA component of RNase P

Experiments were conducted to investigate structural features of the aminoacyl stem region of precursor histidine tRNA critical for the proper cleavage by the catalytic RNA component of RNase P that is responsible for 5' maturation. Histidine tRNA was chosen for study because tRNAHis has an 8 base pair instead of the typical 7-base pair aminoacyl stem. The importance of the 3' proximal CCA sequence in the 5'-processing reaction was also investigated. Our results show that the tRNAHis precursor patterned after the natural Bacillus subtilis gene is cleaved by catalytic RNAs from B. subtilis or Escherichia coli, leaving an extra G residue at the 5'-end of the aminoacyl stem. Replacing the 3' proximal CCA sequence in the substrate still allowed the catalytic RNA to cleave at the proper position, but it increased the Km of the reaction. Changing the sequence of the 3' leader region to increase the length of the aminoacyl stem did not alter the cleavage site but reduced the reaction rate. However, replacing the G residue at the expected 5' mature end by an A changed the processing site, resulting in the creation of a 7-base pair aminoacyl stem. The Km of this reaction was not substantially altered. These experiments indicate that the extra 5' G residue in B. subtilis tRNAHis is left on by RNase P processing because of the precursor's structure at the aminoacyl stem and that the cleavage site can be altered by a single base change. We have also shown that the catalytic RNA alone from either B. subtilis or E. coli is capable of cleaving a precursor tRNA in which the 3' proximal CCA sequence is replaced by other nucleotides.     

Nucleotide sequence and stability of the RNA component of RNase P from a temperature-sensitive mutant of E. coli.

The gene coding for the RNA component of RNase P was cloned from a temperature-sensitive mutant of Escherichia coli defective in RNase P activity (ts709) and its parental wild-type strain (4273), and the complete nucleotide sequences of the gene and its flanking regions were determined. The 5'- and 3'-terminal sequences of the RNA component were determined and mapped on the DNA sequence. The mutant gene has GC-to-AT substitutions at positions corresponding to 89 and 365 nucleotides downstream from the 5' terminus of the RNA sequence. Comparing to the wild-type RNA, the mutant RNA is less stable and rapidly degraded in vivo and in vitro.     

The sequence of the 6S RNA gene of Pseudomonas aeruginosa.

From the gram-negative eubacterium Pseudomonas aeruginosa we have isolated a stable 6S RNA, approximately 180 nucleotides in length. The RNA was partially sequenced and identified by comparison with the known Escherichia coli 6S RNA sequence. Southern hybridizations revealed a single copy gene coding for the 6S RNA. DNA from other prokaryotes, i.e. E. coli, Thermus thermophilus, Bacillus subtilis, Bacillus stearothermophilus and Halobacterium maris mortui, did not give detectable hybridization signals. The 6S RNA gene was cloned in E. coli and its complete primary structure was determined. Although the 6S RNA sequences from P. aeruginosa and E. coli share only a 60.4% homology, we are able to propose a common secondary structural model.     

Bacillus subtilis RNase III gene: cloning, function of the gene in Escherichia coli, and construction of Bacillus subtilis strains with altered rnc loci.

The rnc gene of Bacillus subtilis, which has 36% amino acid identity with the gene that encodes Escherichia coli RNase III endonuclease, was cloned in E. coli and shown by functional assays to encode B. subtilis RNase III (Bs-RNase III). The cloned B. subtilis rnc gene could complement an E. coli rnc strain that is deficient in rRNA processing, suggesting that Bs-RNase III is involved in rRNA processing in B. subtilis. Attempts to construct a B. subtilis rnc null mutant were unsuccessful, but a strain was constructed in which only a carboxy-terminal truncated version of Bs-RNase III was expressed. The truncated Bs-RNase III showed virtually no activity in vitro but was active in vivo. Analysis of expression of a copy of the rnc gene integrated at the amy locus and transcribed from a p(spac) promoter suggested that expression of the B. subtilis rnc is under regulatory control.     

Metal ion and substrate structure dependence of the processing of tRNA precursors by RNase P and M1 RNA

A synthetic tRNA precursor analog containing the structural elements of Escherichia coli tRNA(Phe) was characterized as a substrate for E. coli ribonuclease P and for M1 RNA, the catalytic RNA subunit. Processing of the synthetic precursor exhibited a Mg2+ dependence quite similar to that of natural tRNA precursors such as E. coli tRNA(Tyr) precursor. It was found that Sr2+, Ca2+, and Ba2+ ions promoted processing of the dimeric precursor at Mg2+ concentrations otherwise insufficient to support processing; very similar behavior was noted for E. coli tRNA(Tyr). As noted previously for natural tRNA precursors, the absence of the 3'-terminal CA sequence in the synthetic precursor diminished the facility of processing of this substrate by RNase P and M1 RNA. A study of the Mg2+ dependence of processing of the synthetic tRNA dimeric substrate radiolabeled between C75 and A76 provided unequivocal evidence for an alteration in the actual site of processing by E. coli RNase P as a function of Mg2+ concentration. This property was subsequently demonstrated to obtain (Carter, B. J., Vold, B.S., and Hecht, S. M. (1990) J. Biol. Chem. 265, 7100-7103) for a mutant Bacillus subtilis tRNAHis precursor containing a potential A-C base pair at the end of the acceptor stem.     

Identification of the rph (RNase PH) gene of Bacillus subtilis: evidence for suppression of cold-sensitive mutations in Escherichia coli.

A shotgun cloning of Bacillus subtilis DNA into pBR322 yielded a 2-kb fragment that suppresses the cold-sensitive defect of the nusA10(Cs) Escherichia coli mutant. The responsible gene encodes an open reading frame that is greater than 50% identical at the amino acid level to the E. coli rph gene, which was formerly called orfE. This B. subtilis gene is located at 251 degrees adjacent to the gerM gene on the B. subtilis genetic map. It has been named rph because, like its E. coli analog, it encodes a phosphate-dependent exoribonuclease activity, RNase PH, that removes the 3' nucleotides from precursor tRNAs. The cloned B. subtilis rph gene also suppresses the cold-sensitive phenotype of other unrelated cold-sensitive mutants of E. coli, but not the temperature-sensitive phenotype of three temperature-sensitive mutants, including the nusA11(Ts) mutant, that were tested.     

Phylogenetic comparative chemical footprint analysis of the interaction between ribonuclease P RNA and tRNA.

Ribonuclease P RNA is the catalytic moiety of the ribonucleoprotein enzyme that endonucleolytically cleaves precursor sequences from the 5' ends of pre-tRNAs. The bacterial RNase P RNA-tRNA complex was examined with a footprinting approach, utilizing chemical modification to determine RNase P RNA nucleotides that potentially contact tRNA. RNase P RNA was modified with dimethylsulfate or kethoxal in the presence or absence of tRNA, and sites of modification were detected by primer extension. Comparison of the results reveals RNase P bases that are protected from modification upon binding tRNA. Analyses were carried out with RNase P RNAs from three different bacteria: Escherichia coli, Chromatium vinosum and Bacillus subtilis. Discrete bases of these RNAs that lie within conserved, homologous portions of the secondary structures are similarly protected. One protection among all three RNAs was attributed to the precursor segment of pre-tRNA. Experiments using pre-tRNAs containing precursor segments of variable length demonstrate that a precursor segment of only 2-4 nucleotides is sufficient to confer this protection. Deletion of the 3'-terminal CCA sequence of tRNA correlates with loss of protection of a particular loop in the RNase P RNA secondary structure. Analysis of mutant tRNAs containing sequential 3'-terminal deletions suggests a relative orientation of the bound tRNA CCA to that loop.     

Cloning of the Bacillus subtilis glutamine phosphoribosylpyrophosphate amidotransferase gene in Escherichia coli. Nucleotide sequence determination and properties of the plasmid-encoded enzyme

The Bacillus subtilis gene encoding glutamine phosphoribosylpyrophosphate amidotransferase (amidophosphoribosyltransferase) was cloned in pBR322. This gene is designated purF by analogy with the corresponding gene in Escherichia coli. B. subtilis purF was expressed in E. coli from a plasmid promoter. The plasmid-encoded enzyme was functional in vivo and complemented an E. coli purF mutant strain. The nucleotide sequence of a 1651-base pair B. subtilis DNA fragment was determined, thus localizing the 1428-base pair structural gene. A primary translation product of 476 amino acid residues was deduced from the DNA sequence. Comparison with the previously determined NH2-terminal amino acid sequence indicates that 11 residues are proteolytically removed from the NH2 terminus, leaving a protein chain of 465 residues having an NH2-terminal active site cysteine residue. Plasmid-encoded B. subtilis amidophosphoribosyltransferase was purified from E. coli cells and compared to the enzymes from B. subtilis and E. coli. The plasmid-encoded enzyme was similar in properties to amidophosphoribosyltransferase obtained from B. subtilis. Enzyme specific activity, immunological reactivity, in vitro lability to O2, Fe-S content, and NH2-terminal processing were virtually identical with amidophosphoribosyltransferase purified from B. subtilis. Thus E. coli correctly processed the NH2 terminus and assembled [4Fe-4S] centers in B. subtilis amidophosphoribosyltransferase although it does not perform these maturation steps on its own enzyme. Amino acid sequence comparison indicates that the B. subtilis and E. coli enzymes are homologous. Catalytic and regulatory domains were tentatively identified based on comparison with E. coli amidophosphoribosyltransferase and other phosphoribosyltransferase (Argos, P., Hanei, M., Wilson, J., and Kelley, W. (1983) J. Biol. Chem. 258, 6450-6457).     

Contribution of structural elements to Thermus thermophilus ribonuclease P RNA function.

We have performed a deletion and mutational analysis of the catalytic ribonuclease (RNase) P RNA subunit from the extreme thermophilic eubacterium Thermus thermophilus HB8. Catalytic activity was reduced 600-fold when the terminal helix, connecting the 5' and 3' ends of the molecule, was destroyed by deleting 15 nucleotides from the 3' end. In comparison, the removal of a large portion (94 nucleotides, about one quarter of the RNA) of the upper loop region impaired function only to a relatively moderate extent (400-fold reduction in activity). The terminal helix appears to be crucial for the proper folding of RNase P RNA, possibly by orientating the adjacent universally conserved pseudoknot structure. The region containing the lower half of the pseudoknot structure was shown to be a key element for enzyme function, as was the region of nucleotides 328-335. Deleting a conserved hairpin (nucleotides 304-327) adjacent to this region and replacing the hairpin by a tetranucleotide sequence or a single cytidine reduced catalytic activity only 6-fold, whereas a simultaneous mutation of the five highly conserved nucleotides in the region of nucleotides 328-335 reduced catalytic activity by > 10(5)-fold. The two strictly conserved adenines 244 and 245 (nucleotides 248/249 in Escherichia coli RNase P RNA) were not as essential for enzyme function as suggested by previous data. However, additional disruption of two helical segments (nucleotides 235-242) adjacent to nucleotides 244 and 245 reduced activity by > 10(4)-fold, supporting the notion that nucleotides in this region are also part of the active core structure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cloning, sequencing and genetic mapping of a Bacillus subtilis cell wall hydrolase gene

We have cloned DNA fragments from Bacillus subtilis 168S into Escherichia coli, which produced a lytic zone on an agar medium containing B. subtilis cell wall. Sequencing of the fragments showed the presence of an open reading frame (ORF) which encodes a polypeptide of 272 amino acids with a molecular mass of 29919 Da. The deduced amino acid sequence showed considerable homology with that of the cell wall hydrolase gene of Bacillus sp. (Potvin, C., Leclerc, D., Tremblay, G., Asselin, A. & Bellemare, G. (1988). Molecular and General Genetics 214, 241-248). Accordingly, the gene was designated cwlA, for cell wall lysis. The N-terminal amino acid sequence of cwlA gene product prepared from a E. coli clone was AIKVVKNLVSKSKYGLKCPN, which is consistent with that of the deduced sequence starting from Ala at second position from the initiation codon of the cwlA gene. A presumed sigma A promoter and a rho-independent terminator were found upstream and downstream of the ORF, respectively. A chloramphenicol-resistance determinant integrated into the ORF was mapped by PBS1 transduction, which indicated the gene sequence dnaE-aroD-cwlA.     

Mycoplasma fermentans simplifies our view of the catalytic core of ribonuclease P RNA.

The catalytic RNA moiety of (eu)bacterial RNase P is responsible for cleavage of the 5' leader sequence from precursor tRNAs. We report the sequence, the catalytic properties, and a phylogenetic-comparative structural analysis of the RNase P RNA from Mycoplasma fermentans, at 276 nt the smallest known RNase P RNA. This RNA is noteworthy in that it lacks a stem-loop structure (helix P12) that was thought previously to be universally present in bacterial RNase P RNAs. This finding suggests that helix P12 is not required for catalytic activity in vivo. In order to test this possibility in vitro, the kinetic properties of M. fermentans RNase P RNA and a mutant Escherichia coli RNase P RNA that was engineered to lack helix P12 were determined. These RNase P RNAs are catalytically active with efficiencies (Kcat/Km) comparable to that of native E. coli RNase P RNA. These results show that helix P12 is dispensable in vivo in some organisms, and therefore is unlikely to be essential for the mechanism of RNase P action. The notion that all phylogenetically volatile structures in RNase P RNA are dispensable for the catalytic mechanism was tested. A synthetic RNA representing the phylogenetic minimum RNase P RNA was constructed by deleting all evolutionarily variable structures from the M. fermentans RNA. This simplified RNA (Micro P RNA) was catalytically active in vitro with approximately 600-fold decrease in catalytic efficiency relative to the native RNA.     

A novel endoribonuclease, RNase LS, in Escherichia coli

The dmd gene of bacteriophage T4 is required for the stability of late-gene mRNAs. When this gene is mutated, late genes are globally silenced because of rapid degradation of their mRNAs. Our previous work suggested that a novel Escherichia coli endonuclease, RNase LS, is responsible for the rapid degradation of mRNAs. In this study, we demonstrated that rnlA (formerly yfjN) is essential for RNase LS activity both in vivo and in vitro. In addition, we investigated a role of RNase LS in the RNA metabolism of E. coli cells under vegetative growth conditions. A mutation in rnlA reduced the decay rate of many E. coli mRNAs, although there are differences in the mutational effects on the stabilization of different mRNAs. In addition, we found that a 307-nucleotide fragment with an internal sequence of 23S rRNA accumulated to a high level in rnlA mutant cells. These results strongly suggest that RNase LS plays a role in the RNA metabolism of E. coli as well as phage T4.     

Ribonuclease P RNA: models of the 15/16 bulge from Escherichia coli and the P15 stem loop of Bacillus subtilis.

The Escherichia coli ribonuclease P RNA 15/16 internal bulge loop and the Bacillus subtilis P15 stem loop are important substrate binding sites for the CCA-3' terminus of pre-tRNA. Models of E. coli 15/16 bulge loop and the B. subtilis P15 stem loop have been constructed using MC-SYM, a constraint satisfaction program. The models use covariation analysis data for suggesting initial base pairings, chemical probing, and protection/modification results to determine particular pairing orientations, and mutational experimental analysis data for tRNA-RNase P RNA contacts. The structures from E. coli and B. subtilis, although different in secondary structure, have similar sequence and function. Using MC-SYM, we are able to illustrate how the 3' end of the pre-tRNA is able to interact with this segment of the catalytic RNase P RNA. In addition, we propose additional hydrogen bonding between A76 in the 3' terminus of the tRNA and the 15/16 region of E. coli and to the loop of B. subtilis.