Genetic mapping of the F plasmid gene that promotes degradation of stable ribonucleic acid in Escherichia coli.

F+ Escherichi coli cells that contain an srnA mutant allele degrade their stable ribonucleic acid (RNA) extensively after RNA synthesis is blocked at 42 degrees C. The relevant gene promoting degradation of stable RNA, srnB+, or its promoter was mapped between 1.7 and 2.8 kilobases on the F plasmid by using deleted F' plasmids and chimeric plasmids composed of pSC101 and fragments of F plasmid.     

The rifampicin-inducible genes srn6 from F and pnd from R483 are regulated by antisense RNAs and mediate plasmid maintenance by kiiling of plasmid-free segregants

The gene systems srnB of plasmid F and pnd of plasmid R483 were discovered because of their induction by rifampicin. Induction caused membrane damage, RNase I influx, degradation of stable RNA and, consequently, cell killing. We show here that the srnB and pnd systems mediate efficient stabilization of a mini-R1 test-plasmid. We also show that the killer genes srnB' and pndA are regulated by antisense RNAs, and that the srnC- and pndB-encoded antisense RNAs, denoted SrnC- and PndB-RNAs, are unstable molecules of approximately 60 nucleotides. The srnB and pndA mRNAs were found to be very stable. The differential decay rates of the inhibitory antisense RNAs and the killer-gene-encoding mRNAs explain the induction of these gene systems by rifampicin. Furthermore, the observed plasmid-stabilization phenotype associated with the srnB and pnd systems is a consequence of this differential RNA decay: the newborn plasmid-free cells inherit the stable mRNAs, which, after decay of the unstable antisense RNAs, are translated into killer proteins, thus leading to selective killing of the plasmid-free segregants. Thus our observations lead us to conclude that the F srnB and R483 pnd systems are phenotypically indistinguishable from the R1 hok/sok system, despite a 50% dissimilarity at the level of DNA sequence.     

Nucleotide sequence of the pnd gene in plasmid R483 and role of the pnd gene product in plasmolysis

The pnd gene of R plasmid R483, like the srnB gene of the F plasmid, increases the degradation of stable RNA in Escherichia coli. The nucleotide sequence of the pnd locus was determined and compared with that of the srnB locus. The genes have open reading frames that are 54% homologous, and both have an upstream inverted repeat sequence. The pnd gene expression seems to decrease the osmotic barrier of the cytoplasmic membrane, since no plasmolytic vacuoles were formed in the cells carrying the gene when the cells were exposed to hypertonic sucrose solution. This result suggests that RNase I in the periplasm passes through the altered membrane to degrade stable RNA in the cytoplasm.     

RNase T affects Escherichia coli growth and recovery from metabolic stress.

To determine the essentiality and role of RNase T in RNA metabolism, we constructed an Escherichia coli chromosomal rnt::kan mutation by using gene replacement with a disrupted, plasmid-borne copy of the rnt gene. Cell extracts of a strain with mutations in RNases BN, D, II, and I and an interuppted rnt gene were devoid of RNase T activity, although they retained a low level (less than 10%) of exonucleolytic activity on tRNA-C-C-[14C]A due to two other unidentified RNases. A mutant lacking tRNA nucleotidyltransferase in addition to the aforementioned RNases accumulated only about 5% as much defective tRNA as did RNase T-positive cells, indicating that this RNase is responsible for essentially all tRNA end turnover in E. coli. tRNA from rnt::kan strains displayed a slightly reduced capacity to be aminoacylated, raising the possibility that RNase T may also participate in tRNA processing. Strains devoid of RNase T displayed slower growth rates than did the wild type, and this phenotype was accentuated by the absence of the other exoribonucleases. A strain lacking RNase T and other RNases displayed a normal response to UV irradiation and to the growth of bacteriophages but was severely affected in its ability to recover from a starvation regimen. The data demonstrate that the absence of RNase T affects the normal functioning of E. coli, but it can be compensated for to some degree by the presence of other RNases. Possible roles of RNase T in RNA metabolism are discussed.     

The roles of RNA polymerase and RNAase I in stable RNA degradation in Escherichia coli carrying the srnB+ gene

In Escherichia coli cells carrying the srnB+ gene of the F plasmid, rifampin, added at 42 degrees C, induces the extensive rapid degradation of the usually stable cellular RNA (Ohnishi, Y., (1975) Science 187, 257-258; Ohnishi, Y., Iguma, H., Ono, T., Nagaishi, H. and Clark, A.J. (1977) J. Bacteriol. 132, 784-789). We have studied further the necessity for rifampin and for high temperature in this degradation. Streptolydigin, another inhibitor of RNA polymerase, did not induce the RNA degradation. Moreover, the stable RNA of some strains in which RNA polymerase is temperature-sensitive did not degrade at the restrictive temperature in the absence of rifampin. These data suggest that rifampin has an essential role in the RNA degradation, possibly by the modification of RNA polymerase function. A protein (Mr 12 000) newly synthesized at 42 degrees C in the presence of rifampin appeared to be the product of the srnB+ gene that promoted the RNA degradation. In a mutant deficient in RNAase I, the extent of the RNA degradation induced by rifampin was greatly reduced. RNAase activity of cell-free crude extract from the RNA-degraded cells was temperature-dependent. The RNAase was purified as RNAase I in DEAE-cellulose column chromatography and Sephadex G-100 gel filtration. Both in vivo and with purified RNAase I, a shift of the incubation mixture from 42 to 30 degrees C, or the addition of Mg2+ ions, stopped the RNA degradation. Thus, an effect on RNA polymerase seems to initiate the expression of the srnB+ gene and the activation of RNAase I, which is then responsible for the RNA degradation of E. coli cells carrying the srnB+ gene.     

Ribonuclease D is not essential for the normal growth of Escherichia coli or bacteriophage T4 or for the biosynthesis of a T4 suppressor tRNA

Transposon Tn10-mediated rearrangement was used to isolate a strain of Escherichia coli carrying a deletion in the rnd region which is known to encode the structural gene for the putative 3' tRNA processing nuclease, RNase D. Genetic analysis indicated that about 0.4-0.5 min of the chromosome in the 39.5-40.0 min region was deleted. The mutant strain was devoid of RNase D activity, but other RNase activities were unaffected. The viability of the mutant strain and its normal growth characteristics indicate that RNase D is not essential for E. coli survival. The normal plating efficiency in this mutant host of wild type T4 and a T4 psu1+-amber double mutant indicates that RNase D is also not required for T4 growth or psu1+-tRNA processing. The implications of these findings for the role of RNase D in bacterial and bacteriophage tRNA metabolism, and the possible involvement of alternative enzymes, are discussed.     

Plasmid genes increase membrane permeability in Escherichia coli

The membrane permeability to o-nitrophenyl beta-D-galactoside is increased in the presence of rifampicin in Escherichia coli cells carrying srnB+ or pnd+ plasmids, but not in the cells carrying srnB- or pnd- mutant plasmids. The same permeability alteration was also observed at 42 degrees C when a rpoC4- mutant strain was used as a host strain in the absence of rifampicin. These results and the blockage of the effects by action of chloramphenicol suggest that the increase of permeability to o-nitrophenyl galactoside was caused by the expression of srnB+ or pnd+ gene, respectively. srnB+ gene expression leads to massive RNA degradation, probably through the activation of the rna+ gene product. In an rna- strain carrying the srnB+ plasmid, the extent of RNA degradation was reduced, whereas the permeability to o-nitrophenyl galactoside was increased to the same level as in the rna+ strain. Also, the increase in permeability to o-nitrophenyl galactoside was observed at 30 degrees C, although high-temperature incubation (42 degrees C) was necessary for the induction of RNA degradation. These results suggest that the alteration in permeability is a more direct effect of the expression of srnB+ or pnd+ gene and that the RNA degradation is a secondary phenomenon caused by the alteration in the membrane.     

Ultraviolet Sensitivity Gene of Escherichia coli B

The ultraviolet sensitivity gene of Escherichia coli B was introduced into a K-12 recipient by transduction with phage P1. The uvs gene of E. coli B is cotransducible with the proC locus of K-12, is closely linked to tsx, is not linked to lacZ, and only rarely to purE. The transductants are mucoid, filamentous on irradiation, and show plating-medium response. The order of markers is lacZ proC tsx uvs purE.     

Modular construction of a tertiary RNA structure: the specificity domain of the Bacillus subtilis RNase P RNA

The structure of the specificity domain (S-domain) of the Bacillus subtilis RNase P RNA has been proposed to be composed of a core and a buttress module, analogous to the bipartite structure of the P4-P6 domain of the Tetrahymena group I ribozyme. The core module is the functional unit of the S-domain and contains the binding site for the T stem-loop of a tRNA. The buttress module provides structural stability to the core module and consists of a GA3 tetraloop and its receptor. To explicitly test the hypothesis that modular construction can describe the structure of the S-domain and is a useful RNA design strategy, we analyzed the equilibrium folding and substrate binding of three classes of S-domain mutants. Addition or deletion of a base pair in the helical linker region between the modules only modestly destabilizes the tertiary structure. tRNA binding selectivity is affected in one but not in two other mutants of this class. Elimination of the GA3 tetraloop-receptor interactions significantly destabilizes the core module and results in the loss of tRNA binding selectivity. Replacing the buttress module with that of a homologous RNase P RNA maintains the tRNA binding selectivity. Overall, we have observed that the linker regions between the two modules can tolerate moderate structural changes and that the buttress modules can be shuffled between homologous S-domains. These results suggest that it is feasible to design an RNA using a buttress module to stabilize a functional module.     

Dramatic size variation of yeast mitochondrial RNAs suggests that RNase P RNAs can be quite small

The gene coding for the AU-rich RNA required for mitochondrial RNase P activity in Saccharomyces cerevisiae codes for a 490-base RNA while that in Candida glabrata codes for a 227-base RNA. We have detected a 140-nucleotide RNA coded by the mitochondrial DNA from Saccharomycopsis fibuligera by hybridization with an oligonucleotide complementary to a conserved sequence found in mitochondrial and prokaryotic RNase P RNAs. DNA sequence analysis of the mitochondrial DNA from the region coding for this RNA revealed a second conserved sequence block characteristic of RNase P RNA genes and the presence of a downstream tRNA(Pro) gene. Like previously characterized mitochondrial RNase P RNAs, this small RNA is extremely AU-rich. The discovery of this 140-base RNA suggests that naturally occurring RNase P RNAs may be quite small.     

Interaction of the Bacillus subtilis RNase P with the 30S ribosomal subunit

Ribonuclease P (RNase P) is a ribozyme required for the 5' maturation of all tRNA. RNase P and the ribosome are the only known ribozymes conserved in all organisms. We set out to determine whether this ribonucleoprotein enzyme interacts with other cellular components, which may imply other functions for this conserved ribozyme. Incubation of the Bacillus subtilis RNase P holoenzyme with fractionated B. subtilis cellular extracts and purified ribosomal subunits results in the formation of a gel-shifted complex with the 30S ribosomal subunit at a binding affinity of approximately 40 nM in 0.1 M NH(4)Cl and 10 mM MgCl(2). The complex does not form with the RNase P RNA alone and is disrupted by a mRNA mimic polyuridine, but is stable in the presence of high concentrations of mature tRNA. Endogenous RNase P can also be detected in the 30S ribosomal fraction. Cleavage of a pre-tRNA substrate by the RNase P holoenzyme remains the same in the presence of the 30S ribosome, but the cleavage of an artificial non-tRNA substrate is inhibited eightfold. Hydroxyl radical protection and chemical modification identify several protected residues located in a highly conserved region in the RNase P RNA. A single mutation within this region significantly reduces binding, providing strong support on the specificity of the RNase P-30S ribosome complex. Our results also suggest that the dimeric form of the RNase P is primarily involved in 30S ribosome binding. We discuss several models on a potential function of the RNase P-30S ribosome complex.     

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.