Polyadenylation can regulate ColE1 type plasmid copy number independently of any effect on RNAI decay by decreasing the interaction of antisense RNAI with its RNAII target

Replication of ColE1-type plasmids is regulated by RNAI, an antisense RNA that interacts with the replication pre-primer, RNAII. Exonucleolytic attack at the 3' end of RNAI is impeded in pcnB mutant bacteria, which lack poly(A) polymerase I-the principal RNA polyadenylase of E. coli; this leads to accumulation of an RNAI decay intermediate (RNAI(-5)) and dramatic reduction of the plasmid copy number. Here, we report that polyadenylation can also affect RNAI-mediated control of plasmid DNA replication by inhibiting interaction of RNAI(-5) with RNAII. We show that mutation of the host pcnB gene profoundly affects the plasmid copy number, even under experimental conditions that limit the effects of polyadenylation on RNAI(-5) decay. Moreover, poly(A) tails interfere with RNAI/RNAII interaction in vitro without producing any detectable alteration of RNAI secondary structure. Our results establish the existence of a previously undetected mechanism by which RNA polyadenylation can control plasmid copy number.     

Maintenance of pBR322-derived plasmids without functional RNAI

pBR322-derived plasmids that lack the bla gene and 40% of the gene for the replication inhibitor, RNAI, have been constructed. Since the RNAI gene totally overlaps with the gene for the replication primer, RNAII, this primer is similarly defective and also lacks its normal promoter. The primer is presumed to by synthesized either from the counter-tet promoter (plasmid pCL59) or from an inserted lacUV5 promoter (plasmid pCL59-65). Based mainly on the observation that the plasmid Rom protein, which normally assists in the RNAI/RNAII interaction, has no effect on the replication of the RNAI/RNAII-defective plasmids, we suggest that the defective RNAI is not functional while the defective RNAII primer, although less efficient, still allows plasmid replication. The defective plasmids are fully compatible with the intact parent plasmid, indicating that they do not share a common control of replication. In the absence of antibiotics, the bacteria lose the defective plasmid, beginning after 80 generations; under the same conditions, the parent plasmid is retained even after 140 generations. During exponential growth of their host, the number of defective plasmids in a culture increases exponentially with a doubling time either smaller or greater than that of the host cell growth, depending on the growth medium and, in the case of pCL59-65, on the presence or absence of lac inducer IPTG. As a result of these differences in host cell growth and plasmid replication, the plasmids are either gradually diluted out or their copy number continually increases. This shows that, without RNAI, plasmid replication is uncoupled from the host cell growth and not, as usual, adjusted to it. It also implies that the RNAI mechanism is the only means of replication control for ColE1-type plasmids that senses and adjusts the copy number; limiting host factors cannot provide a back-up control to stabilize copy numbers.     

The rate of processing and degradation of antisense RNAI regulates the replication of ColE1-type plasmids in vivo.

We show that the rate of degradation of RNAI, an anti-sense repressor of the replication primer RNAII, is a key element of control in the replication of ColE1-type plasmids in vivo. Cleavage of RNAI by RNAase E, a ribosomal RNA-processing enzyme encoded or controlled by the rne (also known as ams) locus, relieves repression by endonucleolytically converting RNAI to a very rapidly decaying product, pRNAI-5. A 5' triphosphate-terminated homolog of pRNAI-5 is degraded slowly and consequently inhibits replication. Nucleotide substitutions within the RNAase E cleavage sequence alter RNAI half-life and plasmid copy number, changing also the incompatibility phenotype. RNAI variants lacking the sequence cleaved by RNAase E are eliminated by growth rate-dependent degradation, resulting in growth-responsive control of plasmid replication and copy number.     

PcnB is required for the rapid degradation of RNAI, the antisense RNA that controls the copy number of CoIE1-related plasmids

The replication of CoIE1-related plasmids is controlled by an unstable antisense RNA, RNAI, which can interfere with the successful processing of the RNAII primer of replication. We show here that a host protein, PcnB, supports replication by promoting the decay of RNAI. In bacterial strains deleted for pcnB a stable, active form of RNAI, RNAI*, which appears to be identical to the product of 5′-end processing by RNAse E, accumulates. This leads to a reduction in plasmid copy number. We show, using a GST- PcnB fusion protein, that PcnB does not interfere with RNAI/RNAII binding in vitro. The fusion protein, like PcnB, has polyadenylating activity and is able to polyadenylate RNAI (and also another antisense RNA, CopA) in vitro.     

Sequence analysis and characterization of sulfonamide resistance plasmid pRF-1 from Salmonella enterica serovar Choleraesuis

The nucleotide sequence of a small plasmid, designated pRF-1, isolated from Salmonella enterica serovar Choleraesuis, was determined. We identified seven open reading frames (ORFs) encoded by 6066 nucleotides with a total G + C content of 53.6%. Analysis of the complete nucleotide sequence revealed a replicon of pRF-1 to have high similarity to the p15A origin of replication, with a possible cer-like region. ORF1, which is composed of 816 nucleotides, shows a high degree of similarity to dihydropteroate synthetase encoded by the sulII gene from plasmids in several enteropathogenic bacteria, which functions as the sulfonamide resistance determinant. In fact, Salmonella and Escherichia coli strains carrying pRF-1 were found to show strong resistance to sulfathiazole, suggesting that orf1 is a functional gene. Four of seven ORFs were found to encode putative proteins of unknown function.     

Salmonella enterica subsp. enterica serovar Enteritidis harbours ColE1, ColE2, and rolling-circle-like replicating plasmids

Using DNA hybridization, at least three distinct groups of low molecular mass plasmids were identified in Salmonella enterica subsp. enterica serovar Enteritidis. After sequencing representative plasmids from each group, we concluded that they belonged to ColE1, ColE2, and rolling-circle-like replicating plasmids. Plasmid pK (4245 bp) is a representative of widely distributed ColE1 plasmids. Plasmid pP (4301 bp) is homologous to ColE2 plasmids and was present predominantly in single-stranded DNA form. The smallest plasmids pJ (2096 bp) and pB (1983 bp) were classified as rolling-circle-like replicating plasmids. Both encoded only a single protein essential for their own replication, and they must have existed in an unusual molecular structure, as (i) they were capable of hybridization without denaturation, (ii) their DNA could be linearized with S1 nuclease, and (iii) even after such treatment, the ability to hybridize without denaturation did not disappear.     

Boundaries of the Origin of Replication: Creation of a pET-28a-Derived Vector with p15A Copy Control Allowing Compatible Coexistence with pET Vectors

During our studies involving protein-DNA interactions, we constructed plasmid pSAM to fulfill two requirements: 1) to facilitate transfer of cloned sequences from widely used expression vector pET-28a(+), and 2) to provide a vector compatible with pBR322-derived plasmids for use in cells harboring two different plasmids. Vector pSAM is a pET-28a(+)-derived plasmid with the p15A origin of replication (ori); pET-28a(+) contains the pBR322 replicon that is incompatible with other pBR322-derived plasmids. By replacing the original pET-28a(+) replicon–comprising the ori, RNAI, RNAII, and Rom–with the p15A replicon, we generated pSAM, which contains the pET-28a(+) multiple cloning site and is now compatible with pBR322-derived vectors. Plasmid copy number was assessed using quantitative PCR: pSAM copy number was maintained at 18±4 copies per cell, consistent with that of other p15A-type vectors. Compatibility with pBR322-derived vectors was tested with pGEX-6p-1 and pSAM, which maintained their copy numbers of 49±10 and 14±4, respectively, when both were present within the same cell. Swapping of the ori is a common practice; however, it is vital that all regions of the original replicon be removed. Additional vector pSAMRNAI illustrated that incompatibility remains when portions of the replicon, such as RNAI and/or Rom, are retained; pSAMRNAI, which contains the intact RNAI but not ROM, lowered the copy number of pGEX-6p-1 to 18±2 in doubly transformed cells due to retention of the pET-28a(+)-derived RNAI. Thus, pSAMRNAI is incompatible with vectors controlled by the pBR322 replicon and further demonstrates the need to remove all portions of the original replicon and to quantitatively assess copy number, both individually and in combination, to ensure vector compatibility. To our knowledge, this is the first instance where the nascent vector has been quantitatively assessed for both plasmid copy number and compatibility. New vector pSAM provides ease of transferring sequences from commonly used pET-28a(+) into a vector compatible with the pBR322 family of plasmids. This essential need is currently not filled.     

Control of ColE1 replication: low affinity specific binding of Rop (Rom) to RNAI and RNAII.

We have studied the interactions between the three molecules Rop, RNAI and RNAII that are involved in the regulatory mechanism controlling the replication of ColE1 plasmids. We show that it is possible to purify the two RNA molecules by passing an RNA mixture through an affinity column containing Rop immobilized to a solid support. The dissociation constants of the Rop-RNAI and Rop-RNAII complexes are of the order of 10(-4) M, several orders of magnitude higher than dissociation constants of stable protein-nucleic acid complexes (10(-10) M in the lambda repressor system). Although complete RNAI molecules have higher affinity, stem-and-loop I alone can also bind Rop, suggesting that this structure plays an important role in the interaction. Rop protects the stems of RNAI and RNAII from digestion by RNases while the sensitivity of the loops to digestion by RNase T1 is not affected by high concentrations of Rop. We propose a model for Rop-RNAI/RNAII interaction in which the dimeric protein acts as an adaptor between stem structures to position the two RNAs in the correct position for loop interaction.     

The complete nucleotide sequence of the colicinogenic plasmid ColA. High extent of homology with ColE1

Summary The complete nucleotide sequence of the colicinogenic plasmid ColA has been determined. The plasmid DNA consists of 6720 bp (molecular weight 4.48×10⁶). Fifteen putative biological functions have been identified using the functional map previously determined. These include 11 genes and 3 DNA sites. Nine genes encode proteins of which 3 have been fully characterized. The replication region of ColA coding for RNAI and RNAII is highly homologous to that of ColE1 andClo DF13. The same holds true for the site-specific recombination region containing palindromic symmetry and involved in stable maintenance of the plasmids. A high percentage of homology has been detected for putative mobility proteins encoded by ColA and ColE1. The exclusion proteins are also highly homologous.     

Multidrug-resistant Salmonella enterica serovar paratyphi A harbors IncHI1 plasmids similar to those found in serovar typhi

Salmonella enterica serovars Typhi and Paratyphi A cause systemic infections in humans which are referred to as enteric fever. Multidrug-resistant (MDR) serovar Typhi isolates emerged in the 1980s, and in recent years MDR serovar Paratyphi A infections have become established as a significant problem across Asia. MDR in serovar Typhi is almost invariably associated with IncHI1 plasmids, but the genetic basis of MDR in serovar Paratyphi A has remained predominantly undefined. The DNA sequence of an IncHI1 plasmid, pAKU_1, encoding MDR in a serovar Paratyphi A strain has been determined. Significantly, this plasmid shares a common IncHI1-associated DNA backbone with the serovar Typhi plasmid pHCM1 and an S. enterica serovar Typhimurium plasmid pR27. Plasmids pAKU_1 and pHCM1 share 14 antibiotic resistance genes encoded within similar mobile elements, which appear to form a 24-kb composite transposon that has transferred as a single unit into different positions into their IncHI1 backbones. Thus, these plasmids have acquired similar antibiotic resistance genes independently via the horizontal transfer of mobile DNA elements. Furthermore, two IncHI1 plasmids from a Vietnamese isolate of serovar Typhi were found to contain features of the backbone sequence of pAKU_1 rather than pHCM1, with the composite transposon inserted in the same location as in the pAKU_1 sequence. Our data show that these serovar Typhi and Paratyphi A IncHI1 plasmids share highly conserved core DNA and have acquired similar mobile elements encoding antibiotic resistance genes in past decades.     

Plasmid pC present in Salmonella enterica serovar Enteritidis PT14b strains encodes a restriction modification system

Salmonella enterica serovar Enteritidis (S. Enteritidis) possesses plasmids of different sizes and roles. Besides the serovar-specific virulence plasmid present in most field strains, S. Enteritidis can harbour plasmids of low molecular mass whose biological role is poorly understood. We therefore sequenced plasmid pC present in S. Enteritidis strains belonging to phage type PT14b. The size of plasmid was determined to be 5,269 bp and it was predicted to encode four open reading frames (ORFs). The first two ORFs were found (initial 3,230 bp) to be highly homologous to rom and mbeA genes of ColE1 plasmid of Escherichia coli. Proteins encoded by the other two ORFs were 99% homologous to a restriction methylase and restriction endonuclease encoded by plasmid pECO29 of a field strain of E. coli. Using insertional mutagenesis we confirmed experimentally that the plasmid pC-encoded restriction modification system was functional and could explain the high resistance of S. Enteritidis PT14b strains to phage infection.     

Aminoacyl-tRNA synthetases and DNA replication. Molecular mimicry between RNAII and tRNA(Lys).

Recent data pertaining to different research areas, aminoacyl-tRNA synthetases and replication of ColE1 plasmids, have provided mutually attractive prospects. The gene encoding Escherichia coli lysyl-tRNA synthetase was first isolated as a host suppressor mutation that restores replication of a mutant Co1E1 replicon. Comparison of RNAII and tRNA(Lys) suggests that lysyl-tRNA synthetase is involved in the formation of the displacement loop required for ColE1 plasmids replication and provides major identity elements of tRNA(Lys).     

pUB2380: characterization of a ColD-like resistance plasmid

A detailed analysis of the mobilizable, ColE1-like resistance plasmid, pUB2380, is reported. The 8.5-kb genome encodes six (possibly seven) major functions: (1) a ColD-like origin of replication, oriV, with associated replication functions, RNAI and RNAII; (2) a set of active mobilization functions highly homologous to that of ColE1, including the origin of transfer, oriT; (3) a ColE1-like multimer resolution site (cer); (4) a kanamycin-resistance determinant, aph, encoding an aminoglycoside-3'-phosphotransferase type 1; (5) an insertion sequence, IS1294; and (6) two genes, probably cotranscribed, of unknown function(s). The GC content of the various parts of the genome indicates that the plasmid is a hybrid structure assembled from DNA from at least three different sources, of which the replication region, the mobilization functions, and the resistance gene are likely to have originated in the enterobacteriaceae.     

Real time analysis of the RNAI-RNAII-Rop complex by surface plasmon resonance: from a decaying surface to a standard kinetic analysis

RNA loop-loop complexes are motifs that regulate biological functions in both prokaryotic and eukaryotic organisms. In E. coli, RNAI, an antisense RNA encoded by the ColE1 plasmid, regulates the plasmid replication by recognizing through loop-loop interactions RNAII, the RNA primer that binds to the plasmidic DNA to initiate the replication. Rop, a plasmid-encoded homodimeric protein interacts with this transient RNAI-RNAII kissing complex. A surface plasmon resonance (SPR)-based biosensor was used to investigate this protein-nucleic acid ternary complex, at 5 degrees C, in experimental conditions such as the protein binds either to the loop-loop complex while it dissociates or to a saturated stable RNAI-RNAII surface. The results show that RNAI hairpin dissociates from the RNAII surface 110 times slower in the presence of Rop than in its absence. Rop binds to RNAI-RNAII with an on-rate of 3.6 x 10(6) M(-1) s(-1) and an off-rate of 0.11 s(-1), resulting in a binding equilibrium constant equal to 31 nM. A Scatchard-plot analysis of the interaction monitored by SPR confirms a 1:1 complex of Rop and RNAI-RNAII as observed for non-natural Rop-loop-loop complexes.     

Molecular cloning and expression in Escherichia coli K-12 of the rfb gene cluster determining the O antigen of an E. coli O111 strain

The O antigen of Escherichia coli O111 is identical in structure to that of Salmonella enterica serovar adelaide. Another O-antigen structure, similar to that of E. coli O111 and S. enterica serovar adelaide is found in both E. coli O55 and S. enterica serovar greenside. Both O-antigen structures contain colitose, a 3,6 dideoxyhexose found only rarely in the Enterobacteriaceae. The O-antigen structure is determined by genes generally located in the rfb gene cluster. We cloned the rfb gene cluster from an E. coli O111 strain (M92), and the clone expressed O antigen in both E. coli K-12 and a K-12 strain deleted for rfb. Lipopolysaccharide analysis showed that the O antigen produced by strains containing the cloned DNA is polymerized. The chain length of O antigen was affected by a region outside of rfb but linked to it and present on some of the plasmids containing rfb. The rfb region of M92 was analysed and compared, by DNA hybridization, with that of strains with related O antigens. The possible evolution of the rfb genes in these O antigen groups is discussed.