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.     

Small cytoplasmic RNA of Bacillus subtilis: functional relationship with human signal recognition particle 7S RNA and Escherichia coli 4.5S RNA.

Small cytoplasmic RNA (scRNA; 271 nucleotides) is an abundant and stable RNA of the gram-positive bacterium Bacillus subtilis. To investigate the function of scRNA in B. subtilis cells, we developed a strain that is dependent on isopropyl-beta-D-thiogalactopyranoside for scRNA synthesis by fusing the chromosomal scr locus with the spac-1 promoter by homologous recombination. Depletion of the inducer leads to a loss of scRNA synthesis, defects in protein synthesis and production of alpha-amylase and beta-lactamase, and eventual cell death. The loss of the scRNA gene in B. subtilis can be complemented by the introduction of human signal recognition particle 7S RNA, which is considered to be involved in protein transport, or Escherichia coli 4.5S RNA. These results provide further evidence for a functional relationship between B. subtilis scRNA, human signal recognition particle 7S RNA, and E. coli 4.5S RNA.     

Domain structure of the ribozyme from eubacterial ribonuclease P.

Large RNAs can be composed of discrete domains that fold independently. One such "folding domain" has been identified previously in the ribozyme from Bacillus subtilis ribonuclease P (denoted P RNA). This domain contains roughly one-third of all residues. Folding of an RNA construct consisting of the remaining two-thirds of B. subtilis P RNA was examined by Fe(II)-EDTA hydroxyl radical protection. This molecule folds into the proper higher-order structure under identical conditions as the full-length P RNA, suggesting the presence of a second folding domain in B. subtilis P RNA. Folding analysis of the Escherichia coli P RNA by hydroxyl radical protection shows that this P RNA is completely folded at 5-6 mM Mg2+. In order to analyze the structural organization of folding domains in E. coli P RNA, constructs were designed based on the domain structure of B. subtilis P RNA. Fe(II)-EDTA protection indicates that E. coli P RNA also contains two folding domains. Despite the significant differences at the secondary structure level, both P RNAs appear to converge structurally at the folding domain level. The pre-tRNA substrate, localized in previous studies, may bind across the folding domains with the acceptor stem/3'CCA contacting the domain including the active site and the T stem-loop contacting the other. Because all eubacterial P RNAs share considerable homology in secondary structure to either B. subtilis or E. coli P RNA, these results suggest that this domain structure may be applicable for most, if not all, eubacterial P RNAs. Identification of folding domains should be valuable in dissecting structure-function relationship of large RNAs.     

Regulation of 6S RNA by pRNA synthesis is required for efficient recovery from stationary phase in E. coli and B. subtilis

6S RNAs function through interaction with housekeeping forms of RNA polymerase holoenzyme (Eσ(70) in Escherichia coli, Eσ(A) in Bacillus subtilis). Escherichia coli 6S RNA accumulates to high levels during stationary phase, and has been shown to be released from Eσ(70) during exit from stationary phase by a process in which 6S RNA serves as a template for Eσ(70) to generate product RNAs (pRNAs). Here, we demonstrate that not only does pRNA synthesis occur, but it is an important mechanism for regulation of 6S RNA function that is required for cells to exit stationary phase efficiently in both E. coli and B. subtilis. Bacillus subtilis has two 6S RNAs, 6S-1 and 6S-2. Intriguingly, 6S-2 RNA does not direct pRNA synthesis under physiological conditions and its non-release from Eσ(A) prevents efficient outgrowth in cells lacking 6S-1 RNA. The behavioral differences in the two B. subtilis RNAs clearly demonstrate that they act independently, revealing a higher than anticipated diversity in 6S RNA function globally. Overexpression of a pRNA-synthesis-defective 6S RNA in E. coli leads to decreased cell viability, suggesting pRNA synthesis-mediated regulation of 6S RNA function is important at other times of growth as well.     

Escherichia coli 4.5S RNA gene function can be complemented by heterologous bacterial RNA genes.

The essential 4.5S RNA gene of Escherichia coli can be complemented by 4.5S RNA-like genes from three other eubacteria, including both gram-positive and gram-negative organisms. Two of the genes encode RNAs similar in size to the E. coli species; the third, from Bacillus subtilis, specifies an RNA more than twice as large. The heterologous genes are expressed efficiently in E. coli, and the product RNAs resemble those produced by cognate cells. We conclude that the heterologous RNAs can replace E. coli 4.5S RNA and that the essential function of 4.5S RNA is evolutionarily conserved. A consensus structure is presented for the functionally related 4.5S RNA homologs.     

Purification and properties of a new bacillus subtilis RNA processing enzyme. Cleavage of phage SP82 mRNA and Bacillus subtilis precursor rRNA

An RNA processing activity capable of cleaving Bacillus subtilis phage SP82 early mRNA has been purified to apparent homogeneity from crude extracts of uninfected B. subtilis. The enzyme, a functional monomer of Mr approximately 27,000, cleaves only at the 5' side of adenosine residues at processing sites and is competitively inhibited by double-stranded synthetic RNA polymers. Processed SP82 mRNAs were translated in an Escherichia coli cell-free system and no qualitative or quantitative effects of processing on the synthesis of polypeptides was observed. The processing enzyme does not cleave T7 mRNA, E. coli precursor rRNA, or double-stranded poly(AU). A recombinant plasmid containing portions of two B. subtilis rRNA gene sets was transcribed in vitro and the resulting RNA was cleaved in the spacer region between the 16 S and 23 S rRNA genes. The ability of the B. subtilis processing enzyme to cleave SP82 mRNA and B. subtilis precursor rRNA and the fact that the enzyme has high affinity for double-stranded RNA suggest that it is the functional analog of E. coli RNase III.     

Detection of high levels of polyadenylate-containing RNA in bacteria by the use of a single-step RNA isolation procedure

A new one-step procedure for the isolation of bacterial RNA, involving lysis by proteinase K in the presence of sodium dodecyl sulfate, is described. Pulse-labeled RNA isolated by this procedure for Bacillus brevis, Bacillus subtilis, and Escherichia coli B has been found to contain a substantial fraction (15-40%) of polyadenylated RNA as determined by adsorption to oligo(dT)-cellulose. This contrasts with RNA isolated by procedures involving phenol extraction, a process which appears to lead to the selective loss of polyadenylated RNA. The presence of polyadenylated RNA in E. coli was confirmed by an independent method which involved hybridization with [3H]polyuridylic acid. Using the proteinase K method for RNA isolation, it was possible to demonstrate the in vitro synthesis of polyadenylated RNA by toluene-treated cells of B. brevis, B. subtilis, and E. coli.