Relationships of the Col plasmids E2, E3, E4, E5, E6, and E7: Restriction mapping and colicin gene fusions

Thirteen ColE plasmids representing the E2-E7 types have been compared by restriction mapping. Over 80% of their restriction sites were found to be similarly positioned, indicating that these plasmids share a common structure. Three variants are ColE2-CA42 and ColE7-K317, both of which contain 1.8-kb DNA segments in place of a 2.5-kb segment common to the other plasmids, and ColE6-CT14, which has an additional 5.0-kb DNA segment compared to the other plasmids. The colicin (col), immunity (imm), and colicin release (hic) genes of these plasmids have been localized to regions corresponding to those known for ColE3-CA38 and ColE2-P9, with the imm and hic genes adjacent to the 3' end of the col gene. Active colicin is produced from hybrid col genes containing 5' and 3' ends from different E-type plasmids. The 3'-termini of the fused col genes specify the colicin type.     

Cloning of the ColE3-CA38 colicin and immunity genes and identification of a plasmid region which enhances colicin production

The colicin and immunity genes of plasmid ColE3-CA38 have been localized by characterization of bacteria carrying its cloned restriction fragments. They are within a 3.14-kb EcoRI segment, such that the immunity gene contains the KpnI site, and the colicin gene is adjacent to it within a 2.1-kb KpnI-HincII segment. The immunity gene and one end of the colicin gene are in the region of ColE3-CA38 which is not homologous to the closely related plasmid ColE2-P9. A 0.64-kb PvuI-EcoRI segment of the plasmid adjacent to that containing the colicin and immunity genes was found to augment colicin production on solid media, and also affected the morphology of clearing zones produced by the cells when used as indicators in overlays of stabs of colicin E2 or E7 producers. The 0.64-kb segment was required in its native orientation relative to the 3.14-kb EcoRI segment to cause its effects.     

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.     

The nucleotide sequence surrounding the promoter region of colicin E1 gene

The nucleotide sequence of 570 bp, covering the N-terminal portion of the colicin E1 gene, was determined. The sequence of the N-terminal four amino acids of the colicin E1 protein, determined by manual Edman degradation, agreed with that predicted from the nucleotide sequence. From analysis of the 5'-terminal sequences of RNAs synthesized in vitro, the promoter and operator regions of the colicin E1 gene were assigned. These data indicate the existence of two promoters, one of which is located in the coding region for colicin E1. DNA sequence homology of 16 bp was found between the putative operator regions of the colicin E1 and recA genes.     

Structure of the murine mb-1 gene encoding a putative sIgM-associated molecule

Genomic DNA clones containing the B cell-specific murine mb-1 gene were isolated and a 5.6-kb BamH I fragment was characterized. It is 5629 bp long and contains five exons: an exon containing the 5' untranslated and the coding sequence of the signal peptide, an exon of 294 bp, which contains most of the extracellular sequence of the MB-1 protein, a 119-bp long exon coding mainly for the transmembrane portion, and two exons of 69 bp and 427 bp encoding the cytoplasmic domain and the 3'-untranslated region, respectively. The mb-1 gene does not contain a "TATA box" found in many eukaryotic promoters. The 5'-flanking region has sequence stretches homologous to IgVH 5'-promoter regions and a bcl 2 intron sequence. It contains the decanucleotide sequence (ATGGCAAATA) almost identical to the octamer motif of IgVH promoters. A B cell-specific DNase I-hypersensitive site was found in the 3'-flanking region indicating that this region might be involved in B cell-specific expression of mb-1. Southern blot analysis of genomic liver DNA with the cloned mb-1 cDNA suggests the existence of another mb-1-related gene segment.     

Assembly of colicin genes from a few DNA fragments. Nucleotide sequence of colicin D

The nucleotide sequence of a 2.4 kb Dral-EcoRV fragment of pColD-CA23 DNA was determined. The segment of DNA contained the colicin D structural gene (cda) and the colicin D immunity gene (cdi). From the nucleotide sequence it was deduced that colicin D had a molecular weight of 74683D and that the immunity protein had a molecular weight of 10057D. The amino-terminal portion of colicin D was found to be 96% homologous with the same region of colicin B. Both colicins share the same cell-surface receptor, FepA, and require the TonB protein for uptake. A putative TonB box pentapeptide sequence was identified in the amino terminus of the colicin D protein sequence. Since colicin D inhibits protein synthesis, it was unexpected that no homology was found between the carboxy-terminal part of this colicin and that of the protein synthesis inhibiting colicin E3 and cloacin DF13. This could indicate that colicin D does not function in the same manner as the latter two bacteriocins. The observed homology with colicin B supports the domain structure concept of colicin organization. The structural organization of the colicin operon is discussed. The extensive amino-terminal homology between colicins D and B, and the strong carboxy-terminal homology between colicins B, A, and N suggest an evolutionary assembly of colicin genes from a few DNA fragments which encode the functional domains responsible for colicin activity and uptake.     

Structural and functional organization of the colicin operon in the ColD-CA23 plasmid

The organization of the genes involved in colicin D synthesis was studied. These are colicin, immunity and lysis genes. The nucleotide sequence of the immunity gene, its structural and regulatory regions were determined. This gene was shown to be located next to the colicin gene on the same strand and followed by the lysis gene. When colicin synthesis is induced with mitomycin C the immunity gene is transcribed from the general SOS-dependent promotor as a part of the colicin operon. However it has its own SOS-independent promotor in normal growth conditions. A high homology in amino acid sequences of Co1D lysis protein and that of Co1E1, Co1E2, Co1E3, Co1DF13, Co1A was revealed. A detailed scheme of Co1D-CA23 colicin operon structural organization is suggested.     

Plasmid pColBM-Cl139 does not encode a colicin lysis protein but contains sequences highly homologous to the D protein (resolvase) and the oriV region of the miniF plasmid

Colicins are usually released from producing cells by so-called lysis proteins. No sequence homologous to the structurally very similar colicin lysis genes was found in the gene cluster cmi cma cbi cba, which determines the activity and immunity proteins of colicin B and M on pColBM-Cl139. Instead, the region upstream of cmi contained sequences that showed 91% homology to the structural gene of protein D (resolvase) and 75.5% homology to the rfsF sequence of the Escherichia coli miniF plasmid. It is concluded that colicins B and M are not released via the activity of lysis proteins and that the highly homologous regions encode a resolvase and its target respectively.     

Molecular characterisation of the colicin E2 operon and identification of its products

Summary The DNA sequence of the entire colicin E2 operon was determined. The operon comprises the colicin activity gene, ceaB, the colicin immunity gene, ceiB, and the lysis gene, celB, which is essential for colicin release from producing cells. A potential LexA binding site is located immediately upstream from ceaB, and a rho-independent terminator structure is located immediately downstream from celB. A comparison of the predicted amino acid sequences of colicin E2 and cloacin DF13 revealed extensive stretches of homology. These colicins have different modes of action and recognise different cell surface receptors; the two major regions of heterology at the carboxy terminus, and in the carboxy-terminal end of the central region probably correspond to the catalytic and receptor-recognition domains, respectively. Sequence homologies between colicins E2, A and E1 were less striking, and the colicin E2 immunity protein was not found to share extensive homology with the colicin E3 or cloacin DF13 immunity proteins. The lysis proteins of the ColE2, ColE1 and CloDF13 plasmids are almost identical except in the aminoterminal regions, which themselves have overall similarity with lipoprotein signal peptides. Processing of the ColE2 prolysis protein to the mature form was prevented by globomycin, a specific inhibitor of the lipoprotein signal peptidase. The mature ColE2 lysis protein was located in the cell envelope. The results are discussed in terms of the functional organisation of the colicin operons and the colicin proteins, and the way in which colicins are released from producing cells.     

Nucleotide sequence of promoter, operator and amino-terminal region of caa, the structural gene of colicin A

The nucleotide sequence of 378 bp covering the promoter-operator regions and the region coding for the N-terminal portion of the colicin A gene was determined. These assignments were made possible by the determination of the N-terminal 12 amino acids of the colicin A protein. DNA sequence homologies between operator regions of recA, lexA, uvrA, uvrB, cea and caa genes are discussed.     

Genetic analysis of ColN plasmid determinants for colicin production, release, and immunity.

Colicin N was identified as the 39,000-molecular-weight protein encoded by the 4,900-base-pair, multiple copy number, amplifiable plasmid ColN -284. Its production was controlled by the SOS regulatory circuit and by catabolite repression. Colicin accumulated intracellularly to ca. 10(6) molecules per cell after growth for 2 to 3 h in medium containing 0.5 microgram of mitomycin C per ml and was then released as the cells underwent partial lysis. Strains carrying pColN -284 and its derivatives exhibited low-level immunity to colicin N and were fully sensitive to all other colicins tested. Regions of the plasmid responsible for colicin N activity (cna), for mitomycin-induced lysis ( cnl ), and for colicin N immunity ( cni ) were localized and characterized by cloning, transposon Tn5 and hydroxylamine mutagenesis, and restriction endonuclease deletion and mapping analysis. The results are discussed in terms of both the organization of the cna, cnl , and cni genes and the respective role of cnl expression and colicin N production in mitomycin sensitivity, colicin export, and induced partial lysis of ColN + cells.     

Factors necessary for the export process of colicin E1 across cytoplasmic membrane of Escherichia coli

Factors necessary for the export process of colicin E1 across the cytoplasmic membrane of Escherichia coli were investigated. beta-Galactosidase activities from gene fusions between the colicin E1 and lacZ genes were recovered in the inner membrane fraction of E. coli when the region containing the internal signal-like sequence of colicin E1 [M. Yamada et al. (1982) Proc. Natl Acad. Sci. USA 79, 2827-2831] was present, but were found in the soluble fraction when the region was eliminated. The colicin E1 export was reduced upon insertion mutation in a gene that is located downstream from the colicin E1 gene in the same operon and responsible for mitomycin-C-induced killing of the host cell. A frame shift mutation of the colicin E1 plasmid was constructed to direct the protein which had lost the COOH-terminal 13 residues of original colicin E1 and was altered in 6 residues of the new COOH-terminal portion. The aberrant colicin E1 that was inducibly synthesized remained inside the cells. These results indicate that colicin E1 is exported with the aid of a product of the downstream gene and that the COOH-terminal portion is necessary for the export. The binding of colicin E1 to the cytoplasmic membrane through the internal signal-like sequence may be a step in the protein export process.     

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.     

Four plasmid genes are required for colicin V synthesis, export, and immunity.

The colicin V production and immunity genes were isolated from plasmid pColV-K30. A HindIII-to-SalI fragment of 9.4 kilobases was cloned into the compatible vectors pBR322 and pACYC184. Mutants defective in colicin production were generated by Tn5 insertions and by constructing deletions in vitro. Physical analysis of these mutations identified a 4.4-kilobase region of this DNA which contains all the plasmid genes (cva) needed for the production of colicin V. The colicin V immunity determinant (cvi) is in a 700-base-pair fragment located within one end of this region. Complementation tests identified three genes, called cvaA, cvaB, and cvaC, required for colicin production. Analysis of the proteins labeled in minicells harboring various Tn5 insertions allowed us to identify protein products for the cvaA and cvaC genes. Mutations in cvaA and cvaB eliminated colicin activity in culture supernatants, but not within the cells. Mutations in cvaC, however, eliminated all detectable activity. From these results we conclude that the cvaC gene codes for the structural gene for colicin V, while cvaA and cvaB are apparently needed for the normal export of the colicin.