Mechanism of binding of the antisense and target RNAs involved in the regulation of IncB plasmid replication.

The replication frequency of the IncB miniplasmid pMU720 is dependent upon the expression of the repA gene. Binding of a small, highly structured, antisense RNA (RNA I) to its complementary target in the RepA mRNA (RNA II) inhibits repA expression and thus regulates replication. Analyses of binding of RNA I to RNA II indicated that the reaction consists of three major steps. The first step, initial kissing complex formation, involves base pairing between complementary sequences in the hairpin loops of RNA I and RNA II. The second step is facilitated by interior loop structures in the upper stems of RNA I and RNA II and involves intrastand melting and interstrand pairing of the upper stem regions to form an extended kissing complex. This complex was shown to be sufficient for inhibition of repA expression. The third step involves stabilization of the extended kissing complex by pairing between complementary single-stranded tail regions of RNA I and RNA II. Thus, the final product of RNA I-RNA II binding is not a full duplex between the two molecules.     

Interaction between the antisense and target RNAs involved in the regulation of IncB plasmid replication.

Physical analysis of RNA I, the small antisense RNA which regulates the replication of IncB miniplasmid pMU720, showed that it is a highly structured molecule containing an imperfectly paired stem closed by a 6-base hairpin loop. Mutational studies revealed that a 3-base sequence in the hairpin loop is critical to the interaction between RNA I and its complementary target in the RepA mRNA (RNA II). Furthermore, a 2-base interior loop in the upper stem was found to play an important role in facilitating effective binding between RNA I and RNA II. From these analyses, a model describing the molecular mechanism of binding between RNA I and RNA II is proposed.     

Identification and characterization of novel ColE1-type, high-copy number plasmid mutants in Legionella pneumophila

ColE1-type plasmids are commonly used in bacterial genetics research, and replication of these plasmids is regulated by interaction of RNA I and RNA II. Although these plasmids are narrow-host-range, they can be maintained in Legionella pneumophila under antibiotic selection, with low-copy number and instability. Here, we have described the isolation of two novel spontaneous mutants of pBC(gfp)Pmip, pBG307 and pBG309, which are able to mark the L. pneumophila with strong green fluorescence when exposed to visible light. One of the mutants, pBG307, has a single CG-->TA mutation in RNA II promoter located 2-bases upstream the - 10 region. Another one, pBG309, has the same mutation, as well as an additional CG-->AT mutation in the 76th nucleotide of RNA I, or in the 6th nucleotide of RNA II. A plasmid with the single mutation in RNA I, pBG308, was also constructed. Characterization of these plasmids carrying the enhanced green fluorescent protein (gfpmut2) gene revealed that the green fluorescence intensities of these plasmids were 2- to 30-fold higher than that of the wild type and both of the mutations contribute to increase the plasmid copy number and/or plasmid stability. The mutation located in RNA II promoter played a more dominant role in elevating the copy number, compared to the mutation in RNA I. We also tested the mutant plasmids for replication in Escherichia coli, and found that their copy number and stability were dramatically decreased, except pBG307. Our data suggest that these plasmids might be useful and convenient in genetic studies in L. pneumophila.     

Origin-specific reduction of ColE1 plasmid copy number due to mutations in a distinct region of the Escherichia coli RNA polymerase

Mutations affecting a region of the Escherichia coli RNA polymerase have been isolated that specifically reduce the copy number of ColE1-type plasmids. The mutations, which result in a single amino acid alteration (G1161R) or a 41-amino acid deletion (Delta1149-1190) are located near the 3'-terminal region in the rpoC gene, which encodes the largest subunit (beta ') of the RNA polymerase. The rpoC deletion and the point mutation cause over 20- and 10-fold reductions, respectively, in the copy number of ColE1. ColE1 plasmid numbers are regulated by two plasmid-encoded RNAs: RNA II, which acts as a preprimer for the DNA polymerase I to start initiation of replication, and RNA I, its antisense inhibitor. Altered expression from the RNA I and RNA II promoters in vivo was observed in the RNA polymerase mutants. The RNA I/RNA II ratio is higher in the mutants than in the wild-type strain and this is most probably the main reason for the reduction in the ColE1 copy number in the two rpoC mutants.     

The nuclear gene MRS2 is essential for the excision of group II introns from yeast mitochondrial transcripts in vivo.

RNA splicing defects in mitochondrial intron mutants can be suppressed by a high dosage of several proteins encoded by nuclear genes. In this study we report on the isolation, nucleotide sequence, and possible functions of the nuclear MRS2 gene. When present on high copy number plasmids, the MRS2 gene acts as a suppressor of various mitochondrial intron mutations, suggesting that the MRS2 protein functions as a splicing factor. This notion is supported by the observations that disruption of the single chromosomal copy of the MRS2 gene causes (i) a pet- phenotype and (ii) a block in mitochondrial RNA splicing of all four mitochondrial group II introns, some of which are efficiently self-splicing in vitro. In contrast, the five group I introns monitored here are excised from pre-mRNA in a MRS2-disrupted background although at reduced rates. So far the MRS2 gene product is unique in that it is essential for splicing of all four group II introns, but relatively unimportant for splicing of group I introns. In strains devoid of any mitochondrial introns the MRS2 gene disruption still causes a pet- phenotype and cytochrome deficiency, although the standard pattern of mitochondrial translation products is produced. Therefore, apart from RNA splicing, the absence of the MRS2 protein may disturb the assembly of mitochondrial membrane complexes.     

Suppression of ColE1 high-copy-number mutants by mutations in the polA gene of Escherichia coli.

We isolated three Escherichia coli suppressor strains that reduce the copy number of a mutant ColE1 high-copy-number plasmid. These mutations lower the copy number of the mutant plasmid in vivo up to 15-fold; the wild-type plasmid copy number is reduced by two- to threefold. The suppressor strains do not affect the copy numbers of non-ColE1-type plasmids tested, suggesting that their effects are specific for ColE1-type plasmids. Two of the suppressor strains show ColE1 allele-specific suppression; i.e., certain plasmid copy number mutations are suppressed more efficiently than others, suggesting specificity in the interaction between the suppressor gene product and plasmid replication component(s). All of the mutations were genetically mapped to the chromosomal polA gene, which encodes DNA polymerase I. The suppressor mutational changes were identified by DNA sequencing and found to alter single nucleotides in the region encoding the Klenow fragment of DNA polymerase I. Two mutations map in the DNA-binding cleft of the polymerase region and are suggested to affect specific interactions of the enzyme with the replication primer RNA encoded by the plasmid. The third suppressor alters a residue in the 3'-5' exonuclease domain of the enzyme. Implications for the interaction of DNA polymerase I with the ColE1 primer RNA are discussed.     

Replication control of plasmid pLS1: efficient regulation of plasmid copy number is exerted by the combined action of two plasmid components, CopG and RNA II

Two elements, the products of genes copG and rnall , are involved in the copy-number control of plasmid pLS1. RNA II is synthesized in a dosage-dependent manner. Mutations in both components have been characterized. To determine the regulatory role of the two genes, we have cloned copG , rnall or both elements at various gene dosages into pLS1-compatible plasmids. Assays of incompatibility towards wild-type or mutant pLS1 plasmids showed that: (i) the rnall gene product, rather than the DNA sequence encoding it, is responsible for the incompatibility, and (ii) CopG and RNA II act in trans and are able to correct up fluctuations in pLS1 copy number. A correlation between the gene dosage at which the regulatory elements were supplied and the incompatibility effect on the resident plasmid was observed. The entire copG-rnall circuit has a synergistic effect when compared with any of its components in the correction of pLS1 copy-number fluctuations, indicating that, in the homoplasmid steady-state situation, the control of pLS1 replication is exerted by the co-ordinate action of CopG and RNA II.     

Comparative analysis of the replicon regions of eleven ColE2-related plasmids.

The incA gene product of ColE2-P9 and ColE3-CA38 plasmids is an antisense RNA that regulates the production of the plasmid-coded Rep protein essential for replication. The Rep protein specifically binds to the origin and synthesizes a unique primer RNA at the origin. The IncB incompatibility is due to competition for the Rep protein among the origins of the same binding specificity. We localized the regions sufficient for autonomous replication of 15 ColE plasmids related to ColE2-P9 and ColE3-CA38 (ColE2-related plasmids), analyzed their incompatibility properties, and determined the nucleotide sequences of the replicon regions of 9 representative plasmids. The results suggest that all of these plasmids share common mechanisms for initiation of DNA replication and its control. Five IncA specificity types, 4 IncB specificity types, and 9 of the 20 possible combinations of the IncA and IncB types were found. The specificity of interaction of the Rep proteins and the origins might be determined by insertion or deletion of single nucleotides and substitution of several nucleotides at specific sites in the origins and by apparently corresponding insertion or deletion and substitution of amino acid sequences at specific regions in the C-terminal portions of the Rep proteins. For plasmids of four IncA specificity types, the nine-nucleotide sequences at the loop regions of the stem-loop structures of antisense RNAs are identical, suggesting an evolutionary significance of the sequence. The mosaic structures of the replicon regions with homologous and nonhomologous segments suggest that some of them were generated by exchanging functional parts through homologous recombination.     

High copy number of the pUC plasmid results from a Rom/Rop-suppressible point mutation in RNA II

The plasmids pUC18 and pUC19 are pBR322 derivatives that replicate at a copy number several fold higher than the parent during growth of Escherichia coli at 37 degrees C. We show here that the high copy number of pUC plasmids results from a single point mutation in the replication primer, RNA II, and that the phenotypic effects of this mutation can be suppressed by the Rom (RNA one modulator)/Rop protein or by lowering the growth temperature to 30 degrees C. The mutation's effects are enhanced by cell growth at 42 degrees C, at which copy number is further increased. During normal cell growth, the pUC mutation does not affect the length or function of RNA I, the antisense repressor of plasmid DNA replication, but may, as computer analysis suggests, alter the secondary structure of pUC RNA II. We suggest that the pUC mutation impedes interactions between the repressor and the primer by producing a temperature-dependent alteration of the RNA II conformation. The Rom/Rop protein may either promote normal folding of the mutated RNA II or, alternatively, may enable the interaction of sub-optimally folded RNA II with the repressor.     

Effect of gene amplification on mercuric ion reduction activity of Escherichia coli.

The mercury resistance (mer) operon of plasmid R100 was cloned onto various plasmid vectors to study the effect of mer gene amplification on the rate of Hg2+ reduction by Escherichia coli cells. The plasmids were maintained at copy numbers ranging from 3 to 140 copies per cell. The overall Hg2+ reduction rate of intact cells increased only 2.4-fold for the 47-fold gene amplification. In contrast, the rate of the cytoplasmic reduction reaction, measured in permeabilized cells, increased linearly with increasing gene copy number, resulting in a 6.8-fold overall amplification. RNA hybridizations indicated that mRNA of the cytoplasmic mercuric reductase (merA gene product) increased 11-fold with the 47-fold gene amplification, while mRNA of the transport protein (merT gene product) increased only 5.4-fold. Radiolabeled proteins produced in maxicells were used to correlate the expression levels of the mer polypeptides with the measured reduction rates. The results indicated that, with increasing gene copy number, there was an approximately 5-fold increase in the merA gene product compared with a 2.5-fold increase in the merT gene product. These data demonstrate a parallel increase of Hg2+ reduction activity and transport protein expression in intact cells with plasmids with different copy numbers. In contrast, the expression level of the mercuric reductase gene underwent higher amplification than that of the transport genes at both the RNA and protein levels as plasmid copy number increased.     

Effect of gene amplification on mercuric ion reduction activity of Escherichia coli.

The mercury resistance (mer) operon of plasmid R100 was cloned onto various plasmid vectors to study the effect of mer gene amplification on the rate of Hg2+ reduction by Escherichia coli cells. The plasmids were maintained at copy numbers ranging from 3 to 140 copies per cell. The overall Hg2+ reduction rate of intact cells increased only 2.4-fold for the 47-fold gene amplification. In contrast, the rate of the cytoplasmic reduction reaction, measured in permeabilized cells, increased linearly with increasing gene copy number, resulting in a 6.8-fold overall amplification. RNA hybridizations indicated that mRNA of the cytoplasmic mercuric reductase (merA gene product) increased 11-fold with the 47-fold gene amplification, while mRNA of the transport protein (merT gene product) increased only 5.4-fold. Radiolabeled proteins produced in maxicells were used to correlate the expression levels of the mer polypeptides with the measured reduction rates. The results indicated that, with increasing gene copy number, there was an approximately 5-fold increase in the merA gene product compared with a 2.5-fold increase in the merT gene product. These data demonstrate a parallel increase of Hg2+ reduction activity and transport protein expression in intact cells with plasmids with different copy numbers. In contrast, the expression level of the mercuric reductase gene underwent higher amplification than that of the transport genes at both the RNA and protein levels as plasmid copy number increased.     

I-like R plasmids promote degradation of stable ribonucleic acid in Escherichia coli.

Some I-like R plasmids, R483, R144, R64drd-11 and R621a, belonging to compatibility groups IncI alpha and I gamma promoted degradation of stable RNA in the srnA1 cells of Escherichia coli after addition of rifampin at 42 degrees C. R16 and R834 plasmids of compatibility group IncB also promoted the degradation of RNA. However, other many kinds of plasmids did not. The promotion of RNA degradation was delayed by the addition of chloramphenicol with rifampin.     

Copy number control of IncIalpha plasmid ColIb-P9 by competition between pseudoknot formation and antisense RNA binding at a specific RNA site.

Replication of a low-copy-number IncIalpha plasmid ColIb-P9 depends on expression of the repZ gene encoding the replication initiator protein. repZ expression is negatively controlled by the small antisense Inc RNA, and requires formation of a pseudoknot in the RepZ mRNA consisting of stem-loop I, the Inc RNA target, and a downstream sequence complementary to the loop I. The loop I sequence comprises 5'-rUUGGCG-3', conserved in many prokaryotic antisense systems, and was proposed to be the important site of copy number control. Here we show that the level of repZ expression is rate-limiting for replication and thus copy number, by comparing the levels of repZ expression and copy number from different mutant ColIb-P9 derivatives defective in Inc RNA and pseudoknot formation. Kinetic analyses using in vitro transcribed RNAs indicate that Inc RNA binding and the pseudoknot formation are competitive at the level of initial base paring to loop I. This initial interaction is stimulated by the presence of the loop U residue in the 5'-rUUGGCG-3' motif. These results indicate that the competition between the two RNA-RNA interactions at the specific site is a novel regulatory mechanism for establishing the constant level of repZ expression and thus copy number.