Clo DF13 plasmid genes affecting Flac transfer and propagation of male specific RNA phages

Two atypical mobilization proteins are involved in plasmid CloDF13 relaxation

The mobilization region of plasmid CloDF13 was localized to a 3.6 kb DNA segment that was analysed by transposon mutagenesis and DNA sequencing. Analysis of the DNA sequence allowed us to identify two mobilization genes and the CloDF13 origin of conjugative transfer (oriT), which was localized to a 661 bp segment at one end of the mobilization (Mob) region. Thus, the overall organization was oriT-mobB-mobC. Plasmid CloDF13 DNA was isolated mainly as a relaxed form that contained a unique strand and site-specific cleavage site (nic). The position of nic was mapped to the sequence 5'-GGGTG/GTCGGG-3' by primer extension and sequencing reactions. Analysis of Mob- insertion mutants showed that mobC was essential for CloDF13 relaxation in vivo. The sequence of mobC predicts a protein (MobC) of 243 amino acids without significant similarity to previously reported relaxases. In addition to MobC, the product of mobB was also required for CloDF13 mobilization and for oriT relaxation in vivo. mobB codes for a protein (MobB) of 653 amino acids with three predicted transmembrane segments at the N-terminus and the NTP-binding motifs characteristic of the TraG family of conjugative coupling proteins. Membership of the TraG family was confirmed by the fact that CloDF13 mobilization by plasmid R388 was independent of TrwB and only required PILW. However, contrary to the activities found for other coupling proteins, MobB was required for efficient oriT cleavage in vivo, suggesting an additional role for this particular protein during oriT processing for mobilization. Additionally, the cleavage site produced by the joint activities of MobB and MobC was shown to contain unblocked ends, suggesting that no stable covalent intermediates between relaxase and DNA were formed during the nic cleavage reaction. This is the first report of a conjugative transfer system in which nic cleavage results in a free nicked-DNA intermediate.

Structure and nucleotide sequence of the region encoding the mobilization proteins of plasmid CloDF13

Mobilization of the non-conjugative plasmid CloDF13 requires both gene products of a conjugative plasmid and CloDF13-encoded information. About 30% of the CloDF13 genome is involved in plasmid transfer. The CloDF13 mobilization region comprises sequences acting in cis (bom, basis of mobilization) as well as protein-coding sequences (mob). Here we present the nucleotide sequence of the genes encoding the CloDF13 mobilization proteins. We confirmed the previous genetic data that the plasmid CloDF13 encodes two proteins involved in plasmid mobilization. The information for these proteins, designated B and C having Mrs of 57,890 and 15,870, respectively, is located within one operon directed by a promoter at 94% of the CloDF13 genome. The gene encoding the smaller protein is located distally within this operon. Transcription proceeds counter-clockwise and is terminated beyond gene C, although it can not be excluded that attenuation of the transcript occurs in the intergenic region. The role of the CloDF13 mobilization proteins in plasmid transfer will be discussed.

The complete nucleotide sequence of the bacteriocinogenic plasmid CloDF13

The complete nucleotide sequence of the bacteriocinogenic plasmid CloDF13 has been determined. The plasmid consists of 9957 base pairs (molecular weight 6.64 X 10(6] with a GC content of 54.4%. At this moment 16 identified biological functions can be assigned to the primary structure of the CloDF13 DNA. The functions include those of eight protein encoding genes, two untranslated RNA species, and six DNA sites. We discuss these functions in relation to the structure of CloDF13 DNA. For convenience we have divided the CloDF13 genome into five defined regions: region I (origin of vegetative replication, priming and control of replication, type I incompatibility), region II (cloacin DF13, cloacin immunity, cloacin release, cloacin operon control), region III (double-stranded DNA-phage interaction, type II incompatibility, multimer resolution), region IV (inhibition of male specific RNA phages and transfer of Flac), and region V (mobility proteins, basis of mobility).

Localization and nucleotide sequence of the bom region of Clo DF13

Mobilization of the non-conjugative plasmid Clo DF13 requires both gene products of a conjugative plasmid and Clo DF13 encoded proteins as well as a cis-acting Clo DF13 DNA region, termed bom (basis of mobility). The bom region was located within a 264 bp fragment around the unique HpaI site. Comparison with the corresponding ColE1 and pBR322 sequences showed similarities with respect to the secondary structure. With respect to a possible relationship between the origin of vegetative replication (oriV) and the origin of transfer (oriT), we found that neither distance nor orientation of the Clo DF13 bom region with respect to oriV had any significant influence on the mobilization frequency. Surprisingly, after cloning of the 264 bp HpaII fragment in a bom- vector, restoration of the bom+ phenotype was only observed in one orientation. From these observations and from the sequence analysis of the bom region we suggest that transcription into this cloned bom fragment is essential for effective mobilization of the plasmid.

Regulation of the F conjugation genes studied by hybridization and tra-lacZ fusion

Hybridization experiments and tra-lacZ fusions were used to obtain further insight into the complex series of control systems that affect F conjugation. We confirmed that the regular IncF FinOP control system represses transcription of traJ, and found that the traJ product is required for transcription of traM as well as of the traY-Z operon. The chromosomal sfrA gene product may be required to prevent premature termination of traJ transcription, while the sfrB gene product prevents premature termination at two sites within the traY-Z operon. The FinQ inhibition system determined by several IncI plasmids caused termination at three different sites in the operon, and that of JR66a at one further site. JR66a and R485 strongly inhibit F transfer, but have weak, or no (respectively) effects on transcription: they may inhibit function of one or more transfer gene products.

Protein H encoded by plasmid Clo DF13 involved in lysis of the bacterial host. I. Localisation of the gene and identification and subcellular localisation of the gene H product

The gene expression of the Clo DF13 "replication region", located between 1.8% and 12% on the plasmid genome, was studied using newly constructed Clo DF13 insertion and deletion mutants. We were able to detect a Clo DF13 specified protein of 6 kilodaltons (kd) by electrophoretic analysis of plasmid proteins, synthesized in Escherichia coli minicells, on 14-25% gradient polyacrylamide gels. The gene encoding this protein was mapped between 1.8% and 12% on the Clo DF13 genome. The nucleotide sequence of this region, as determined by Stuitje et al. (1980), revealed three open reading frames each potentially coding for a protein of 6 kd. Since these three proteins differ in amino acid composition we could distinguish which of these proteins was actually synthesized, by labeling Clo DF13 proteins with specific 14C-labeled amino acids. We found that gene H, located between 9.3% (bp 744) and 11% (bp 893), encodes the observed protein of 6 kd (denominated protein H). With respect to the subcellular localization we observed that protein H, which contains a large hydrophobic region at its C-terminal part, is predominantly present in the bacterial membrane. Although gene H is located close to the region known to be involved in Clo DF13 replication, its gene product, protein H, is not essential for the plasmid DNA replication process. The possibility of the existence of a comparable protein encoded by the related plasmid Col E1 will be discussed.

Interactions between the F conjugal transfer system and CloDF13::Tna plasmids

It was confirmed that all the F transfer genes required for the formation of stable mating pairs, including traN and traG, are essential for transfer of the two small multicopy plasmids ColE1 and cloDF13, whereas the traM, traI and traZ genes that are required for F conjugal DNA metabolism, are not. Differences between ColE1 and CloDF13 were that the F traD gene was needed for transfer of ColE1 but not of CloDF13, and that R100-1 efficiently transferred CloDF13 but not ColE1. A copy number mutant of CloDF13 inhibited F transfer and reduced plaque formation by the F-specific RNA phage f2, but not by Q beta or by the single-strand DNA phage f1. This phenotype suggests that the inhibition system (FinC) acts on traD, mutations in which give a similar phenotype. Hybridisation experiments with lambda tra phage DNA showed that transcription of traD was not reduced, and FinC probably inhibits function of the traD product rather than its synthesis. FinC-insensitive Flac mutants were isolated and characterised. One was shown to have an uppromoter mutation resulting in increased transcription of traJ and hence of the traY leads to Z operon including traD: the raised level of the traD product presumably then counteracted FinC inhibition.

Transcription of bacteriocinogenic plasmid CloDF13 in vivo and in vitro: structure of the cloacin immunity operon

Escherichia coli minicells harboring plasmid CloDF13 synthesized at least 25 messenger ribonucleic acid (RNA) species; three of these RNAs, a 2,400-, a 2,200-, and a 100-nucleotide RNA, were synthesized in relatively large amounts. Using insertion and deletion mutants of CloDF13 as well as an RNA blotting technique, we could demonstrate that these three RNAs are transcripts from the CloDF13 DNA region from 0 to 40%. This region contains the cloacin and immunity genes and the genetic information involved in plasmid DNA replication. A transcription map of this region is presented and discussed. The data indicate that the cloacin and immunity genes were coordinately transcribed into messenger RNAs of about 2,400 and 2,200 nucleotides, which differ in length at their 3' terminus. RNA polymerase binding studies and in vitro transcription assays indicated that transcription of these genes initiates at a promoter located around 32% on the CloDF13 map. Furthermore, it is shown that a 100-nucleotide RNA is encoded by the CloDF13 DNA region between 7.7 and 8.8% on the plasmid genome; the synthesis of this RNA proceeds in a direction opposite to the transcription of the cloacin and immunity genes.

Molecular structure of the immunity gene and immunity protein of the bacteriocinogenic plasmid Clo DF13

The nucleotide sequence of the Clo DF13 DNA region comprising the immunity gene has been determined. We also elucidated the aminoacid sequence of the 40 N-terminal and 7 C-terminal aminoacids of the purified immunity protein. From analysis of the data obtained we were able to locate the immunity gene between 11.7 and 14.5% on the Clo DF13 map, and to determine the complete aminoacid sequence of the immunity protein. It was observed that the Clo DF13 immunity gene encodes an 85 aminoacid protein and is transcribed in the same direction as the cloacin gene. These experimental data support our model, presented elsewhere, which implicates that the cloacin and immunity genes of Clo DF13 are coordinately transcribed from the cloacin promoter. We also present DNA sequence data indicating that an extra ribosome binding site precedes the immunity gene on the polycistronic mRNA. This ribosome binding site might explain the fact that in cloacinogenic cells more immunity protein than cloacin is synthesized. The comparison of the complete aminoacid sequence of the Clo DF13 immunity protein, with the aminoacid sequence data of the purified, comparable Col E3 immunity protein revealed that both proteins have extensive homologies in primary and secondary structure, although they are exchangeable only to a low extent in vivo and in vitro. It was also observed that a lysine residue was modified in immunity protein isolated from excreted bacteriocin complexes.

Genetic information of the bacteriocinogenic plasmid Clo DF13 involved in the inhibition of the multiplication of double stranded DNA phages

The presence of plasmid Clo DF13 in Escherichia coli cells alters the response of these cells to infection with the double stranded DNA phages P1vir, lambda vir or T1. The multiplication of these phages is reduced in Clo DF13 harbouring cells, resulting in an altered burstsize and plaque morphology. The degree of reduction is correlated to the amount of particular Clo DF13 gene product(s) in the cell. The genetic information of Clo DF13 involved in this plasmid-phage interaction could be located, using insertion and deletion mutants of Clo DF13, between 29 an 62% on the Clo DF13 physical map. The genetic analysis of this region shows that at least two different genes, K and L, coding for polypeptides with a molecular weight of respectively 21 KD and 10.5 KD, are located in this region. The results presented, indicate that gene L and not gene K is involved in the interaction of Clo DF13 with the propagation of double stranded DNA phages.

The nucleotide sequence surrounding the replication origin of the cop3 mutant of the bacteriocinogenic plasmid Clo DF13

The nucleotide sequence from about 100 base-pairs downstream to about 600 base pairs upstream the CloDF13 replication origin has been determined. A comparison of this sequence with the corresponding ColE1 origin sequence reveals that: The sequence at the origin of replication is conserved. There are large differences in the nucleotide sequence downstream the replication origin, whereas there is a large homology in the region of about 410 base-pairs upstream the replication origin. This conserved region might code for a largely homologous basic, arginine rich polypeptide of about 45 amino-acids, for both ColE1 and CloDF13. Although there are large differences in the primary structure of the region coding for the 100 nucleotide RNA, the secondary structure of this region seems to be conserved.