Nucleotide sequence of the immunity and lysis region of the ColE9-J plasmid

We have determined the nucleotide sequence of a 1500 bp fragment of the ColE9-J plasmid which encodes colicin E9 immunity and colicin E5 immunity and contains two lys genes. Open reading frames corresponding to the four genes have been located and their position confirmed by transposon mutagenesis of sub-clones of the ColE9-J plasmid. The E9imm gene shows 69% homology at both the nucleotide and the amino acid level to the previously sequenced E2imm gene. The E5imm gene shows little homology to any other E colicin immunity gene which has been sequenced. The lys gene distal to the 3' end of the E5imm gene shows considerable sequence homology to all other previously sequenced E colicin lys genes. The lys gene distal to the 3' end of the E9imm gene is identical to the pColE2 and pColE3 lys genes for the first 59 nucleotides but encodes a much smaller gene product than any other lys gene which has been sequenced. The two lys genes sequenced here are exceptions to Shepherd's rule concerning the number of RNY codons in the three possible reading frames.     

Nucleotide sequences from the colicin E5, E6 and E9 operons: Presence of a degenerate transposon-like structure in the ColE9-J plasmid

Summary The nucleotide sequences of 1288 bp of plasmid ColE5-099, 1609 bp of ColE6-CT14 and 2099 bp of ColE9-J were determined. These sequences encompass the structural genes for the C-terminal receptor-binding and nuclease domains of colicins E5, E6 and E9, theircis- ortrans-acting immunity proteins and four lysis proteins including an atypical one of non-lipoprotein nature (Lys^*) present in the ColE9-J plasmid. The ColE6 gene organisation, in the ordercol-imm-E8imm-lys, is identical to that found in the previously described double-immunity gene system of ColE3-CA38 (an RNase producer). The corresponding genes in the two plasmids are 87%–94% homologous. In ColE9-J, the genes are organised ascol-imm-lys ^*-E5imm-lys. The E9col-imm gene pair is homologous to the colicin E2-P9 type (a DNase producer). Downstream from E9imm is an E5imm (designated E5imm[E9]) which istrans-acting. Neither the predicted structures of E5Imm[E9] nor thecis-acting Imm resident in the ColE5-099 plasmid which differs by a single amino acid shows any resemblance to other immunity structures which have been sequenced. Furthermore, the E5col sequences differ from those predicted previously for other colicins except for the conservedbtuB-specified receptor-binding domain. A novel 205 nucleotide long insertion sequence is found in the ColE9-J plasmid. This insertion sequence, which we named ISE9, has features reminiscent of the degenerate transposon IS101 previously found in plasmid pSC101. One effect of ISE9 is the presence of the atypical lysis gene,lys ^*. The presence of a transposon-like element in the ColE9 plasmid exemplifies a new phenomenon relevant to the evolution of colicin E plasmids. Issued as NRCC publication no. 30065     

Nucleotide sequence of small ColE1 derivatives: Structure of the regions essential for autonomous replication and colicin E1 immunity

Summary A small ColE1 derivative, pAO2, which replicates like the original ColE1 and confers immunity to colicin E1 on its host cell has been constructed from a quarter region of ColE1 DNA (Oka, 1978). The entire nucleotide sequence of pAO2 (1,613 base pairs) was determined based on its fine cleavage map. The sequence of a similar plasmid, pAO3, carrying additional 70 base pairs was also deduced.The sequence in the region covering the replication initiation site on these plasmids was consistent with those reported for ColE1 by Tomizawa et al. (1977) and by Bastia (1977). DNA sequences indispensable for autonomous replication were examined by constructing plasmids from various restriction fragments of pAO2 DNA. As a result, a region of 436 base pairs was found to contain sufficient information to permit replication. The occurrence of initiation and termination codons and of the ribosome-binding sequence on pAO2 DNA suggests that a polypeptide chain consisting of 113 amino acid residues may be encoded by the region in which the colicin E1 immunity gene has been mapped.Abbreviations ColE1 colicin E1 plasmid - Tris tris-(hydroxymethyl)aminomethane - EDTA ethylenediaminetetraacetate - dNTP deoxyribonucleoside triphosphates - ATP adenosine 5-triphosphate     

Nucleotide sequences from the colicin E8 operon: homology with plasmid ColE2-P9

The primary structures of the immunity (Imm) and lysis (Lys) proteins, and the C-terminal 205 amino acid residues of colicin E8 were deduced from nucleotide sequencing of the 1,265 bp ClaI-PvuI DNA fragment of plasmid ColE8-J. The gene order is col-imm-lys confirming previous genetic data. A comparison of the colicin E8 peptide sequence with the available colicin E2-P9 sequence shows an identical receptor-binding domain but 20 amino acid replacements and a clustering of synonymous codon usage in the nuclease-active region. Sequence homology of the two colicins indicates that they are descended from a common ancestral gene and that colicin E8, like colicin E2, may also function as a DNA endonuclease. The native ColE8 imm (resident copy) is 258 bp long and is predicted to encode an acidic protein of 9,604 mol. wt. The six amino acid replacements between the resident imm and the previously reported non-resident copy of the ColE8 imm ([E8 imm]) found in the ribonuclease-producing ColE3-CA38 plasmid offer an explanation for the incomplete protection conferred by [E8 Imm] to exogenously added colicin E8. Except for one nucleotide and amino acid change in the putative signal peptide sequence, the ColE8 lys structure is identical to that present in ColE2-P9 and ColE3-CA38.     

Cloning and characterization of the ColE7 plasmid

The 6.2 kb ColE7-K317 plasmid was mapped and the DNA fragments of the colicin E7 operon subcloned into pUC18 and pUC19. The size of the functional colicin E7 operon deduced by subcloning was 2.3 kb. The colicin E7 gene product was purified by carboxymethylcellulose chromatography. Both colicin E7 and E9 were demonstrated to exhibit a non-specific DNAase-type activity by in vitro biological assay. The molecular mass of colicin E7 was 61 kDa, as determined by SDS-PAGE. From DNA sequence data, the estimated sizes of the E7 immunity protein and the E7 lysis protein were 9926 Da and 4847 Da, respectively. Comparison of restriction maps and DNA sequence data suggests that ColE7 and ColE2 are more closely related than other E colicin plasmids.     

Incompatibility between E colicin plasmids

We have tested the ability of pairs of colicin E plasmids to replicate stably in the same cell line. Although many of the pairs of E colicin plasmids were compatible, plasmids ColE3-CA38, ColE7-K317 and ColE8-J were mutually incompatible, as were ColE5-099, ColE6-CT14 and ColE9-J. Incompatibility between ColE6-CT14 and ColE5-099 or ColE9-J was asymmetrical, whereas incompatibility between the other plasmid pairs was symmetrical.     

Structural and functional organization of ColE2 and ColE3 replicons

Summary The complete nucleotide sequences of the 1.5 kb regions of ColE2 and ColE3 plasmids containing the segments sufficient for autonomous replication have been determined. They are quite homologous (greater than 90%), indicating that these two plasmids share common mechanisms of initiation of replication and its regulation. An open reading frame with a coding capacity for a protein of about 300 amino acids is present in both ColE2 and ColE3 and it actually specifies the Rep (for replication) protein, which is the plasmid specific trans-acting factor required for autonomous replication. The amino acid sequences of the Rep proteins of ColE2 and ColE3 are quite homologous (greater than 90%). The cis-acting sites (origins) where replication initiates in the presence of the trans-acting factors consist of 32 bp for ColE2 and 33 bp for ColE3. They are the smallest of all the prokaryotic replication origins so far reported. They are nonhomologous only at two positions, one of which, a deletion of a single nucleotide in ColE2 (or an insertion in ColE3), determines the plasmid specificity in interaction of the origins with the Rep proteins. Both plasmids carry a region with an identical nucleotide sequence and the one in ColE2, the IncA region, has been shown to express incompatibility against both ColE2 and ColE3. These results indicate that these plasmids share a common IncA determinant. A possibility that a small antisense RNA is involved in copy number control and incompatibility (IncA function) was suggested.     

cea-kil operon of the ColE1 plasmid.

We isolated a series of Tn5 transposon insertion mutants and chemically induced mutants with mutations in the region of the ColE1 plasmid that includes the cea (colicin) and imm (immunity) genes. Bacterial cells harboring each of the mutant plasmids were tested for their response to the colicin-inducing agent mitomycin C. All insertion mutations within the cea gene failed to bring about cell killing after mitomycin C treatment. A cea- amber mutation exerted a polar effect on killing by mitomycin C. Two insertions beyond the cea gene but within or near the imm gene also prevented the lethal response to mitomycin C. These findings suggest the presence in the ColE1 plasmid of an operon containing the cea and kil genes whose product is needed for mitomycin C-induced lethality. Bacteria carrying ColE1 plasmids with Tn5 inserted within the cea gene produced serologically cross-reacting fragments of the colicin E1 molecule, the lengths of which were proportional to the distance between the insertion and the promoter end of the cea gene.     

Characterisation of the ColE8 plasmid, a new member of the group E colicin plasmids

We have determined the restriction map of the ColE8-J plasmid after cloning it into the pBR322 vector. By subcloning and transposon mutagenesis we have localized the colicin immunity gene, the colicin structural gene, and lys, the region that determines MC sensitivity. In contrast to the ColE3-CA38 plasmid, the genes coding for colicin E8 production and immunity cannot be cloned on a single EcoRI fragment. Insertion of Tn5 transposons into the colicin structural gene region of the recombinant plasmid inactivated colicin production and MC sensitivity. Insertion of transposons into the lys region reduced colicin E8 production and MC induced lysis, the extent of which was dependent upon the precise site of insertion. We propose that the colicin E8 structural gene and lys must be transcribed from a common promoter situated proximal to the structural gene, whilst the colicin E8 immunity gene is transcribed from a second promoter. The lys region is responsible both for cell lysis after MC induction and positive regulation of colicin E8 synthesis.     

Nucleotide sequence and gene organization of ColE1 DNA

The primary structure of the plasmid ColE1 DNA has been determined. The plasmid DNA consists of 6646 base pairs (molecular mass of 4.43 MDa) and is 48.46% in GC content. The phi 80 trp insert of the composite plasmid of ColE1, pVH51, has also been determined. The determination of the nucleotide sequence of ColE1 DNA provides the basis for examining the relationships between the DNA sequence and the gene organization of the plasmid. The focus of this paper is to use this sequence data coupled with a review of the literature and our own work to examine the nine known functional regions of ColE1: imm (colicin E1 immunity), rep (replication function), inc (plasmid incompatibility and copy number control), bom (basis of mobility), rom (modulator of inhibition of primer formation by RNA I), mob (plasmid mobilization), cer (determinant for conversion of plasmid multimers to monomers), exc (plasmid entry exclusion), cea (structural gene for colicin E1), and kil (structural gene for the Kil protein).     

Characterization of the ColE9-J plasmid and analysis of its genetic organization

We have determined the restriction and functional map of the ColE9-J plasmid. By sub-cloning and transposon mutagenesis we have shown that the ColE9imm gene and the ColE5imm gene present on the ColE9-J plasmid are located on separate EcoRI fragments. Using an expression vector we have demonstrated the presence of two lys genes on the ColE9-J plasmid, both of which are dependent upon the colicin E9 structural gene promoter. Promoter mapping studies imply that the colicin E9 structural gene and the ColE5imm gene are transcribed in the same direction, but that the ColE9imm gene is transcribed in the opposite orientation.     

Structuro-functional organization of segments of Co1A plasmid DNA, determining its stable inheritance

Two par regions were localized within the structure of a small colicinogenic plasmid ColA. One of them functions at the expense of plasmid multimere resolution. Analysis of the nucleotide sequence of the region revealed the existence of essential homology with the par locus of plasmid ColE1. As compared to E. coli C600, the function of multimere forms' resolution of plasmid DNA in E. coli C is reduced or absent due to par regions of the ColE1 type. Par regions of various degrees of homology with the par locus of ColE1 were localized by Southern hybridization within the structure of colicinogenic plasmids ColN and ColD. The stabilization of the colicinogenic plasmids is believed to be also determined by the functioning of genes connected with the synthesis and action of colicin.     

Analysis of the promoters for the two immunity genes present in the ColE3-CA38 plasmid using two new promoter probe vectors.

We have constructed two new promoter probe vectors which carry a polylinker derived from plasmid pUC19 proximal to the 5' end of a promoter-less galactokinase gene. Using these two vectors we have demonstrated that the ColE3imm gene and the ColE8imm gene present on the ColE3-CA38 plasmid have their own promoters, independent of the SOS promoter of the colicin E3 structural gene. The activity of two terminators, one located proximal to the 5' end of the ColE8imm gene, the other located proximal to the 5' end of the lys gene, were shown by a comparison of the galactokinase activity conferred by several of the recombinant plasmids.     

The transposon Tn1 as a probe for studying ColE1 structure and function.

Summary Insertion of the transposable genetic element Tn1 into different sites of plasmid ColE1 results in a number of mutant phenotypes. Whereas all plasmids examined were present in normal amount, all showed reduced immunity to killing by colicin E1. Of six insertions isolated after conjugation, five fail to produce colicin, are conjugally proficient (transmissible), and map within a 500 nucleotide region of the genome. The other is conjugally deficient, produces colicin normally and maps close to two others with a similar phenotype isolated after transformation. Of four others isolated after transformation, two have similar properties to the original five transmissible plasmids. The other two are nontransmissible and produce colicin. Non-transmissibility is correlated with reduced relaxation complex. Patterns of protein synthesis in minicels by ColE1 and ColE1:: Tn1 plasmids have been examined: all ColE1 plasmids containing Tn1 show an altered pattern of ColE1 protein synthesis in addition to three presumptive Tn1-specified proteins, one of which is shown to be -lactamase. ColE1:: Tn1 plasmids can be inserted into the conjugative plasmid R64drd11 to form a cointegrate in which ColE1 and Tn1 function can be expressed.     

Characterization of the cea gene of the ColE7 plasmid.

Summary The complete nucleotide sequence (1731 nucleotides) of the gene encoding colicin E7 (cea) of plasmid CoIE7-K317 was determined. This sequence encoded a deduced polypeptide of 576 amino acids of molecular weight 61349 Da. Comparison of the nucleotide and amino acid sequences ofcea E7 with those of other E-group colicins revealed that colicin E7 was closely related to colicin E2, both in gene sequence and in predicted secondary structure of the deduced protein. Judging from the results of cross-immunity tests, we postulated that CoIE7 is probably a proximate ancestor of Co1E2 and Co1E8. Based on results from colicin production tests on cells harboring a 5 end deleted form of thecea E7 gene, we propose, that a previously unknown, non-inducible promoter may be involved in regulation of the constitutive expression of thecea E7 gene.     

Plasmid ColE3 specifies a lysis protein.

Tn5 insertion mutations in plasmid ColE3 were isolated and characterized. Several of the mutants synthesized normal amounts of active colicin E3 but, unlike wild-type colicinogenic cells, did not release measurable amounts of colicin into the culture medium. Cells bearing the mutant plasmids were immune to exogenous colicin E3 at about the same level as wild-type colicinogenic cells. All of these lysis mutants mapped near, but outside of, the structural genes for colicin E3 and immunity protein. Cells carrying the insertion mutations which did not release colicin E3 into the medium were not killed by UV exposure at levels that killed cells bearing wild-type plasmids. The protein specified by the lysis gene was identified in minicells and in mitomycin C-induced cells. A small protein, with a molecular weight between 6,000 and 7,000, was found in cells which released colicin into the medium, but not in mutant cells that did not release colicin. Two mutants with insertions within the structural gene for colicin E3 were also characterized. They produced no colicin activity, but both synthesized a peptide consistent with their map position near the middle of the colicin gene. These two insertion mutants were also phenotypically lysis mutants--they were not killed by UV doses lethal to wild-type colicinogenic cells and they did not synthesize the small putative lysis protein. Therefore, the lysis gene is probably in the same operon as the structural gene for colicin E3.     

Recombination at ColE1 cer requires the Escherichia coli xerC gene product, a member of the lambda integrase family of site-specific recombinases.

Site-specific recombination at the plasmid ColE1 cer site requires the Escherichia coli chromosomal gene xerC. The xerC gene has been localized to the 85-min region of the E. coli chromosome, between cya and uvrD. The nucleotide sequences of the xerC gene and flanking regions have been determined. The xerC gene encodes a protein with a calculated molecular mass of 33.8 kDa. This protein has substantial sequence similarity to the lambda integrase family of site-specific recombinases and is probably the cer recombinase. The xerC gene is expressed as part of a multicistronic unit that includes the dapF gene and two other open reading frames.