Bacillus subtilis ribonucleases J1 and J2 form a complex with altered enzyme behaviour

Ribonucleases J1 and J2 are recently discovered enzymes with dual 5′‐to‐3′ exoribonucleolytic/endoribonucleolytic activity that plays a key role in the maturation and degradation of Bacillus subtilis RNAs. RNase J1 is essential, while its paralogue RNase J2 is not. Up to now, it had generally been assumed that the two enzymes functioned independently. Here we present evidence that RNases J1 and J2 form a complex that is likely to be the predominant form of these enzymes in wild‐type cells. While both RNase J1 and the RNase J1/J2 complex have robust 5′‐to‐3′ exoribonuclease activity in vitro, RNase J2 has at least two orders of magnitude weaker exonuclease activity, providing a possible explanation for why RNase J1 is essential. The association of the two proteins also has an effect on the endoribonucleolytic properties of RNases J1 and J2. While the individual enzymes have similar endonucleolytic cleavage activities and specificities, as a complex they behave synergistically to alter cleavage site preference and to increase cleavage efficiency at specific sites. These observations dramatically change our perception of how these ribonucleases function and provide an interesting example of enzyme subfunctionalization after gene duplication.     

Ribonucleases J1 and J2: two novel endoribonucleases in B.subtilis with functional homology to E.coli RNase E

Many prokaryotic organisms lack an equivalent of RNase E, which plays a key role in mRNA degradation in Escherichia coli. In this paper, we report the purification and identification by mass spectrometry in Bacillus subtilis of two paralogous endoribonucleases, here named RNases J1 and J2, which share functional homologies with RNase E but no sequence similarity. Both enzymes are able to cleave the B.subtilis thrS leader at a site that can also be cleaved by E.coli RNase E. We have previously shown that cleavage at this site increases the stability of the downstream messenger. Moreover, RNases J1/J2 are sensitive to the 5′ phosphorylation state of the substrate in a site-specific manner. Orthologues of RNases J1/J2, which belong to the metallo-β-lactamase family, are evolutionarily conserved in many prokaryotic organisms, representing a new family of endoribonucleases. RNases J1/J2 appear to be implicated in regulatory processing/maturation of specific mRNAs, such as the T-box family members thrS and thrZ, but may also contribute to global mRNA degradation.     

The ribonucleases J1 and J2 are essential for growth and have independent roles in mRNA decay in Streptococcus pyogenes

The paralogous ribonucleases J1 and J2, recently identified in Bacillus subtilis, have both endoribonucleolytic and 5′‐to‐3′ exoribonucleolytic activities and participate in degradation and regulatory processing of mRNA. RNases J1 and J2 have partially overlapping target specificities, but only RNase J1 is essential for B. subtilis growth. Because mRNA decay is important in regulation of virulence factors of Streptococcus pyogenes (the group A streptococcus, GAS), we investigated the role of these newly described RNases in GAS. We found that conditional mutants for both RNases J1 and J2 require induction for growth, so we conclude that, unlike the case in B. subtilis, both of these RNases are essential for GAS growth, and therefore their functions are not redundant. We compared decay of representatives of the two classes of messages we had previously identified: Class I, which decay rapidly in exponential and stationary phase of growth (hasA and gyrA), and Class II, which are stable in stationary phase and exhibit a biphasic decay curve in exponential phase (sagA and sda). We report that RNases J1 and J2 affect the rate of decay of Class I messages and the length of the first phase in decay of Class II messages.     

Expression in Bacillus subtilis of the Bacillus thuringiensis cryIIIA toxin gene is not dependent on a sporulation-specific sigma factor and is increased in a spo0A mutant.

Expression of the Bacillus thuringiensis cryIIIA gene encoding a Coleoptera-specific toxin is weak during vegetative growth and is activated at the onset of the stationary phase. cryIIIA'-'lacZ fusions and primer extension analysis show that the regulation of cryIIIA expression is similar in Bacillus subtilis and in B. thuringiensis. Activation of cryIIIA expression was not altered in B. subtilis mutant strains deficient for the sigma H and sigma E sporulation-specific sigma factors or for minor sigma factors such as sigma B, sigma D, or sigma L. This result and the nucleotide sequence of the -35 and -10 regions of the cryIIIA promoter suggest that cryIIIA expression might be directed by the E sigma A form of RNA polymerase. Expression of the cryIIIA'-'lacZ fusion is shut off after t2 (2 h after time zero) of sporulation in the B. subtilis wild-type strain grown on nutrient broth sporulation medium. However, no decrease in cryIIIA-directed beta-galactosidase activity occurred in sigma H, kinA, or spo0A mutant strains. Moreover, beta-galactosidase activity was higher and remained elevated after t2 in the spo0A mutant strain. beta-Galactosidase activity was weak in abrB and spo0A abrB mutant strains, suggesting that AbrB is responsible for the higher level of cryIIIA expression observed in a spo0A mutant. However, both in spo0A and spo0A abrB mutant strains, beta-galactosidase activity remained elevated after t2, suggesting that even in the absence of AbrB, cryIIIA expression is controlled through modulation of the phosphorylated form of Spo0A. When the cryIIIA gene is expressed in a B. subtilis spo0A mutant strain or in the 168 wild-type strain, large amounts of toxins are produced and accumulate to form a flat rectangular crystal characteristic of the coleopteran-specific B. thuringiensis strains.     

Cleavage of a DNA-RNA-DNA/DNA chimeric substrate containing a single ribonucleotide at the DNA-RNA junction with prokaryotic RNases HII

We have analyzed the cleavage specificities of various prokaryotic Type 2 ribonucleases H (RNases H) on chimeric DNA-RNA-DNA/DNA substrates containing one to four ribonucleotides. RNases HII from Bacillus subtilis and Thermococcus kodakaraensis cleaved all of these substrates to produce a DNA segment with a 5'-monoribonucleotide. Consequently, these enzymes cleaved even the chimeric substrate containing a single ribonucleotide at the DNA-RNA junction (5'-side of the single ribonucleotide). In contrast, Escherichia coli RNase HI and B. subtilis RNase HIII did not cleave the chimeric substrate containing a single ribonucleotide. These results suggest that bacterial and archaeal RNases HII are involved in excision of a single ribonucleotide misincorporated into DNA.     

Erythromycin-induced ribosome stalling and RNase J1-mediated mRNA processing in Bacillus subtilis

Addition of erythromycin (Em) to a Bacillus subtilis strain carrying the ermC gene results in ribosome stalling in the ermC leader peptide coding sequence. Using Δ ermC , a deletion derivative of ermC that specifies the 254 nucleotide Δ ermC mRNA, we showed previously that ribosome stalling is concomitant with processing of Δ ermC mRNA, generating a 209 nucleotide RNA whose 5' end maps to codon 5 of the Δ ermC coding sequence. Here we probed for peptidyl-tRNA to show that ribosome stalling occurs after incorporation of the amino acid specified by codon 9. Thus, cleavage upstream of codon 5 is not an example of 'A-site cleavage' that has been reported for Escherichia coli . Analysis of Δ ermC mRNA processing in endoribonuclease mutant strains showed that this processing is RNase J1-dependent. Δ ermC mRNA processing was inhibited by the presence of stable secondary structure at the 5' end, demonstrating 5'-end dependence, and was shown to be a result of RNase J1 endonuclease activity, rather than 5'-to-3' exonuclease activity. Examination of processing in derivatives of Δ ermC that had codons inserted upstream of the ribosome stalling site revealed that Em-induced ribosome stalling can occur considerably further from the start codon than would be expected based on previous studies.     

A Bacillus subtilis gene-encoding protein homologous to eukaryotic SMC motor protein is necessary for chromosome partition

We have analysed the function of a gene of Bacillus subtilis , the product of which shows significant homology with eukaryotic SMC proteins essential for chromosome condensation and segregation. Two mutant strains were constructed; in one, the expression was under the control of the inducible spac promoter (conditional null) and, in the other, the gene was disrupted by insertion (disrupted null). Both could form colonies at 23°C but not at 37°C in the absence of the expression of the Smc protein, indicating that the B. subtilis smc gene was essential for cell growth at higher temperatures. Microscopic examination revealed the formation of anucleate and elongated cells and diffusion of nucleoids within the elongated cells in the disrupted null mutant grown at 23°C and in the conditional null mutant grown in low concentrations of IPTG at 37°C. In addition, immunofluorescence microscopy showed that subcellular localization of the Spo0J partition protein was irregular in the smc disrupted null mutant, compared with bipolar localization in wild-type cells. These results indicate that the B. subtilis smc gene is essential for chromosome partition. The role of B. subtilis Smc protein in chromosome partition is discussed.     

The Bacillus subtilis ydcDE operon encodes an endoribonuclease of the MazF/PemK family and its inhibitor

Operons encoding stable toxins and their labile antidote are widespread in prokaryotes and play important roles in plasmid partitioning and cellular responses to stress. One such family of toxins MazF/ChpAK/PemK encodes an endoribonuclease that inactivates cellular mRNAs by cleaving them at specific, but frequently occurring sites. Here we show that the Bacillus subtilis ydcE gene encodes a member of this family of RNases, which we have called EndoA. Overexpression of EndoA is toxic for bacterial cell growth and this toxicity is reversed by coexpression of the gene immediately upstream, ydcD. Furthermore, YdcD inhibits EndoA activity directly in vitro. EndoA has similar cleavage specificity to MazF and PemK and yields cleavage products with 3'-phosphate and 5'-hydroxyl groups, typical of EDTA-resistant degradative RNases. This is the first example of an antitoxin-toxin system in B. subtilis.     

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.     

Roles of endonuclease V, uracil-DNA glycosylase, and mismatch repair in Bacillus subtilis DNA base-deamination-induced mutagenesis

The disruption of ung, the unique uracil-DNA-glycosylase-encoding gene in Bacillus subtilis, slightly increased the spontaneous mutation frequency to rifampin resistance (Rif(r)), suggesting that additional repair pathways counteract the mutagenic effects of uracil in this microorganism. An alternative excision repair pathway is involved in this process, as the loss of YwqL, a putative endonuclease V homolog, significantly increased the mutation frequency of the ung null mutant, suggesting that Ung and YwqL both reduce the mutagenic effects of base deamination. Consistent with this notion, sodium bisulfite (SB) increased the Rif(r) mutation frequency of the single ung and double ung ywqL strains, and the absence of Ung and/or YwqL decreased the ability of B. subtilis to eliminate uracil from DNA. Interestingly, the Rif(r) mutation frequency of single ung and mutSL (mismatch repair [MMR] system) mutants was dramatically increased in a ung knockout strain that was also deficient in MutSL, suggesting that the MMR pathway also counteracts the mutagenic effects of uracil. Since the mutation frequency of the ung mutSL strain was significantly increased by SB, in addition to Ung, the mutagenic effects promoted by base deamination in growing B. subtilis cells are prevented not only by YwqL but also by MMR. Importantly, in nondividing cells of B. subtilis, the accumulations of mutations in three chromosomal alleles were significantly diminished following the disruption of ung and ywqL. Thus, under conditions of nutritional stress, the processing of deaminated bases in B. subtilis may normally occur in an error-prone manner to promote adaptive mutagenesis.     

Properties of a Bacillus subtilis polynucleotide phosphorylase deletion strain.

The pnpA gene of Bacillus subtilis, which codes for polynucleotide phosphorylase (PNPase), has been cloned and employed in the construction of pnpA deletion mutants. Growth defects of both B. subtilis and Escherichia coli PNPase-deficient strains were complemented with the cloned pnpA gene. RNA decay characteristics of the B. subtilis pnpA mutant were studied, including the in vivo decay of bulk mRNA and the in vitro decay of either poly(A) or total cellular RNA. The results showed that mRNA decay in the pnpA mutant is accomplished despite the absence of the major, Pi-dependent RNA decay activity of PNPase. In vitro experiments suggested that a previously identified, Mn2+ -dependent hydrolytic activity was important for decay in the pnpA mutant. In addition to a cold-sensitive-growth phenotype, the pnpA deletion mutant was found to be sensitive to growth in the presence of tetracycline, and this was due to an increased intracellular accumulation of the drug. The pnpA deletion strain also exhibited multiseptate, filamentous growth. It is hypothesized that defective processing of specific RNAs in the pnpA mutant results in these phenotypes.     

A general method for the consecutive integration of single copies of a heterologous gene at multiple locations in the Bacillus subtilis chromosome by replacement recombination.

We have devised a two-step procedure by which multiple copies of a heterologous gene can be consecutively integrated into the Bacillus subtilis 168 chromosome without the simultaneous integration of markers (antibiotic resistance). The procedure employs the high level of transformability of B. subtilis 168 strains and makes use of the observation that thymine-auxotrophic mutants of B. subtilis are resistant to the folic acid antagonist trimethoprim (Tmpr), whereas thymine prototrophs are sensitive. First, a thymine-auxotrophic B. subtilis mutant is transformed to prototrophy by integration of a thymidylate synthetase-encoding gene at the desired chromosomal locus. In a second step, the mutant strain is transformed with a DNA fragment carrying the heterologous gene and Tmpr colonies are selected. Approximately 5% of these appear to be thymine auxotrophic and contain a single copy of the heterologous gene at the chromosomal locus previously carrying the thymidylate synthetase-encoding gene. Repetition of the procedure at different locations on the bacterial chromosome allows the isolation of strains carrying multiple copies of the heterologous gene. The method was used to construct B. subtilis strains carrying one, two, and three copies of the Bacillus stearothermophilus branching enzyme gene (glgB) in their genomes.     

Bacillus subtilis F0F1 ATPase: DNA sequence of the atp operon and characterization of atp mutants.

We cloned and sequenced an operon of nine genes coding for the subunits of the Bacillus subtilis F0F1 ATP synthase. The arrangement of these genes in the operon is identical to that of the atp operon from Escherichia coli and from three other Bacillus species. The deduced amino acid sequences of the nine subunits are very similar to their counterparts from other organisms. We constructed two B. subtilis strains from which different parts of the atp operon were deleted. These B. subtilis atp mutants were unable to grow with succinate as the sole carbon and energy source. ATP was synthesized in these strains only by substrate-level phosphorylation. The two mutants had a decreased growth yield (43 and 56% of the wild-type level) and a decreased growth rate (61 and 66% of the wild-type level), correlating with a twofold decrease of the intracellular ATP/ADP ratio. In the absence of oxidative phosphorylation, B. subtilis increased ATP synthesis through substrate-level phosphorylation, as shown by the twofold increase of by-product formation (mainly acetate). The increased turnover of glycolysis in the mutant strain presumably led to increased synthesis of NADH, which would account for the observed stimulation of the respiration rate associated with an increase in the expression of genes coding for respiratory enzymes. It therefore appears that B. subtilis and E. coli respond in similar ways to the absence of oxidative phosphorylation.     

Regulation of horizontal gene transfer in Bacillus subtilis by activation of a conserved site-specific protease

The mobile genetic element ICEBs1 is an integrative and conjugative element (a conjugative transposon) found in Bacillus subtilis. The RecA-dependent SOS response and the RapI-PhrI cell sensory system activate ICEBs1 gene expression by stimulating cleavage of ImmR, the ICEBs1 immunity repressor, by the protease ImmA. We found that increasing the amount of wild-type ImmA in vivo caused partial derepression of ICEBs1 gene expression. However, during RapI-mediated derepression of ICEBs1 gene expression, ImmA levels did not detectably increase, indicating that RapI likely activates the protease ImmA by increasing its specific activity. We also isolated and characterized mutations in immA (immA(h)) that cause partial derepression of ICEBs1 gene expression in the absence of inducing signals. We obtained two types of immA(h) mutations: one type caused increased amounts of the mutant proteins in vivo but no detectable effect on specific activity in vitro; the other type had no detectable effect on the amount of the mutant protein in vivo but caused increased specific activity of the protein (as measured in vitro). Together, these findings indicate that derepression of ICEBs1 gene expression is likely caused by an increase in the specific activity of ImmA. Homologs of ImmA and ImmR are found in many mobile genetic elements, so the mechanisms that regulate ImmA-mediated cleavage of ImmR may be widely conserved.