Genetic and physical characterization of the ColIb plasmid using ColIb-R222 hybrids

Plasmid Co1IB contains an ssi signal close to the replication origin

Taking advantage of the plaque morphology method, we identified a single-strand initiation (ssi) signal in plasmid pSM32, a mini-Co1Ib plasmid. This ssi signal was situated in the 350-nt HaeIII segment of the 1.8-kb S7 fragment, and located nearly 400 nt downstream of the origin of DNA replication. Introduction of the ssi signal into a mutant of filamentous phage M13 lacking oric resulted in restoration of phage growth and RFI DNA synthesis. Interestingly, DNA homology studies showed that the nucleotide sequence of the ssi signal was extremely homologous with that of the "G4-type" ssi signal in plasmid R100.

Transfer region of IncI1 plasmid R64 and role of shufflon in R64 transfer

To locate the transfer region of the 122-kiloase plasmid R64drd-11 belonging to incompatibility group I1, a series of deletion derivatives was constructed by in vitro recombinant DNA techniques followed by double homologous recombination in vivo. A plasmid designated pKK609 and bearing a 56.7-kilobase R64 sequence was the smallest transferable plasmid. A plasmid designated pKK610 and no longer possessing the 44-base-pair sequence of the R64 transfer system is located at one end. The other end of the R64 transfer region comprises a DNA segment of about 19 kilobases responsible for pilus formation. Shufflon, DNA with a novel rearrangement in R64, was found to be involved in pilus formation.

Organization of the replication control region of plasmid ColIb-P9

We identified a 1,845-base-pair sequence that contains essential information for the autonomous replication and regulation of the 93-kilobase-pair IncI alpha group ColIb-P9 plasmid. Biochemical and genetic analyses revealed that this sequence specifies at least two structural genes, designated repZ and inc. The repZ gene encodes a protein with a molecular weight of 39,000, which probably functions as an initiator for the ColIb-P9 replicon. The inc gene that phenotypically governs the incompatibility encodes an RNA with a size of about 70 bases. This small RNA acts in trans to repress the expression of repZ, thereby functioning to maintain a constant copy number of the ColIb-P9 replicon in host cells.

Nucleotide sequence of a DNA fragment that contains the abi gene of the ColIb plasmid

A 1989-bp PstI DNA fragment from the ColIb plasmid, which contains the abi gene that is necessary for the abortive response to infections by bacteriophage BF23 or T5, was sequenced. A candidate open reading frame for the abi gene has been suggested on the basis of a Shine-Dalgarno sequence appropriately placed ahead of its ATG initiation codon, a promoter upstream from the Shine-Dalgarno sequence, and a location compatible with deletion mapping. The polypeptide that would be coded by this open reading frame is 89 amino acids long and strongly hydrophobic. A promoter that could serve this open reading frame was detected by exonuclease III "footprinting" using RNA polymerase from uninfected Escherichia coli as the DNA-binding protein.

ColIb plasmid genes that inhibit the replication of T5 and T7 bacteriophage

The colicin Ib (ColIb) plasmid genes that inhibit the replication of the T5-like and T7 bacteriophage have been cloned on an approximately 7200-bp ClaI fragment and their sites relative to each other and to the colicin immunity (imm) gene have been mapped. The inhibition of wild-type T7 by the clone is shown to be caused by the same gene or genes (pic) that cause the inhibition of T7 kinase-negative mutants and is a different gene than the one that causes inhibition of T5 (ibf or abi). The pic gene does not hybridize to the pif genes of the F plasmid that also cause the replication of T7 to be inhibited. The abi gene and the pic gene map very closely together but are under the control of different promoters. The abi gene has a maximum size of 900 bp and lies approximately 3000 bp away from the immunity gene, distal to the colicin gene. A site which maps in or near the gene binds very tightly to Escherichia coli RNA polymerase. The pic gene or genes lie between the abi gene and the imm gene and are contiguous with abi. Promoters for pic have been mapped and hypotheses to explain the inhibition of T7 by a cloned gene but not the whole ColIb plasmid are presented.

Distribution of shufflon among IncI plasmids

A shufflon or clustered inversion is a novel type of DNA rearrangement originally discovered in the IncI1 plasmid R64 (T. Komano, A. Kubo, and T. Nisioka, Nucleic Acids Res. 15:1165-1172, 1987). In a 1.95-kilobase region of R64 DNA, four DNA segments inverted independently or in groups, resulting in a complex DNA rearrangement. We found similar types of shufflon in other IncI1 plasmids, including delta, pIP111, pIP565, pIP112, pIP186, R144, R163, R483, and R621a. A variant type of shufflon occurs in the IncI1 plasmid ColIb.

Organization and regulation of the conjugation genes of IncI1 plasmid colIb-P9

The IncI1 plasmid ColIb-P9 is among a group of related plasmids that encode the I1 type of conjugation system. The I1 system is known to include two morphologically distinct types of pilus, a DNA primase gene (sog) and an exclusion determinant (exc). Transposon mutagenesis and analysis of cloned fragments of ColIb were used to identify the location of these determinants with respect to an EcoRI restriction map. Also identified were the location of the origin of transfer (oriT) and a gene determining an EDTA-resistant nuclease, which is coordinately regulated with the transfer genes. The results indicate that the ColIb tra genes are separated into at least three Tra regions. The pleiotropic nature of transposon insertion mutations in two of these regions suggests that two positive regulators are required for expression of the transfer genes and evidence is also found for a trans-acting repressor. It is suggested that the I1 conjugation system may have evolved following fusion of two distinct types of conjugative plasmid.

Role and specificity of plasmid RP4-encoded DNA primase in bacterial conjugation

The role of the DNA primase of IncP plasmids was examined with a derivative of RP4 containing Tn7 in the primase gene (pri). The mutant was defective in mediating bacterial conjugation, with the deficiency varying according to the bacterial strains used as donors and recipients. Complementation tests involving recombinant plasmids carrying cloned fragments of RP4 indicated that the primase acts to promote some event in the recipient cell after DNA transfer and that this requirement can be satisfied by plasmid primase made in the donor cell. It is proposed that the enzyme or its products or both are transmitted to the recipient cell during conjugation, and the role of the enzyme in the conjugative processing of RP4 is discussed. Specificity of plasmid primases was assessed with derivatives of RP4 and the IncI1 plasmid ColIb-P9, which is known to encode a DNA primase active in conjugation. When supplied in the donor cell, neither of the primases encoded by these plasmids substituted effectively in the nonhomologous conjugation system. Since ColIb primase provided in the recipient cell acted weakly on transferred RP4 DNA, it is suggested that the specificity of these enzymes reflects their inability to be transmitted via the conjugation apparatus of the nonhomologous plasmid.

Physical and genetic characterization of the IncI plasmid R144-drd3

A physical and genetic map of the IncI plasmid R144-drd3 was obtained by determining restriction endonuclease sites and by physical and genetic analysis of cloned fragments, of Tn1 insertion mutants and of deletion mutants.

Conjugative transfer of IncI1 plasmid DNA primase

DNA primase of ColIb-P9drd-1 generates RNA primers that are thought to initiate DNA synthesis on the conjugatively transferred strand of the plasmid. To examine whether plasmid-specified primase is transferred during conjugation, we exploited the property of the enzyme to promote bacterial DNA replication in dnaG (primase-defective) mutants of Escherichia coli. It was found that dnaG3 recipient cells, treated with rifampicin to inhibit transcription, recovered ability to synthesise bacterial DNA by a process requiring an active plasmid primase gene in donor cells and a functional conjugation system. A non-transferable primase gene in the donor strain complemented a primase-negative derivative of ColIb-P9drd-1, confirming that the enzyme responsible for recovery was supplied by donor cells. The implication is that certain proteins are transmitted from donor cells to promote conjugative metabolism of plasmid DNA in the recipients.

Physical and genetic analyses of the Inc-I alpha plasmid R64

A 126-kilobase (kb) physical and genetic map of the Inc-I alpha plasmid R64 was constructed by using the restriction enzymes, BamHI, SalI, XhoI, HindIII, and EcoRI. The replication (Rep) and incompatability (Inc) functions of this plasmid were located in a 1.75-kb segment of an EcoRI fragment, E10 (3.3 kb). In addition, the genes determining growth inhibition of phage BF23 (Ibf), suppression of dnaG ( Sog ), resistance to tetracycline (Tetr), and resistance to streptomycin ( Strr ) were located on the 5.5-kb HindIII-XhoI fragment, the 8.1-kb EcoRI fragment (E5), the 4.6-kb HindIII fragment (H8), and the 4.1-kb HindIII fragment (H10), respectively. The map of R64 was compared with that of ColIb, which belongs to the Inc-I alpha group.

Effect of the plasmid ColIb-P9 on cellular processes related to DNA repair

The plasmid ColIb-P9 introduced into Escherichia coli K12 umuC mutant cells suppresses the deficiencies in mutagenesis and repair of mutants after UV-irradiation. These data suggest that ColIb-P9 encodes a product with a function similar to that of the chromosomal gene umuC. Tn5 insertion mutants of ColIb-P9 were isolated with an altered ability to restore UV-mutagenesis in the umuC mutant. The same plasmid mutations were shown to eliminate the effects of ColIb-P9 on UV-mutagenesis, survival after UV and mitomycin C treatment, reactivation of UV-irradiated lambda in unirradiated cells, Weigle-reactivation, induction of colicin E1 synthesis. The ColIb-P9 genes responsible for the enhancement of UV-mutagenesis were cloned within a 14 Md SalI fragment. Their location was established by restriction analysis of the mutant plasmid ColIb 6-13::Tn5. While the action of the plasmids ColIb-P9 and pKM101 is similar, these plasmids were shown to have opposite effects on cell survival and colicin E1 synthesis after mitomycin C treatment. A study of the mutant plasmids ColIb::Tn5 and pGW12 (muc- mutant of pKM101) has shown the difference in the effects of ColIb-P9 and pKM101 to be associated with the plasmid genes responsible for the protective and mutagenesis-enhancing effects of these plasmids in UV-irradiated cells.

Structure and inherent properties of the bacteriophage lambda head shell. IV. Small-head mutants

Missense mutants of bacteriophage lambda that produce small proheads were found among prophage mutants defective in the major head protein gpE. Measurements of the sedimentation coefficient and molecular weight of the small proheads showed that they have the T = 4 structure composed of 240 molecules of gpE instead of the wild-type T = 7 structure composed of 420 molecules of gpE. When the phage mutants were grown in groE mutants of Escherichia coli, they produced small unprocessed proheads, which contained a smaller number (about 60) of the core protein (gpNu3) molecules than normal unprocessed proheads, which contain about 180 molecules of gpNu3. This shows that the major head protein determines the size of not only the shell but also the core of unprocessed proheads. These mutants by themselves produce very few mature small-headed phage particles, partly because the lambda DNA molecule, whose cos sites are separated at a distance of 48,500 bases, is too long to be packaged into the small proheads. However, the small proheads can package shorter DNA in vivo and in vitro at somewhat reduced efficiency, if the length or a multiple of the length between the cos sites of the DNA is 13,000 to 19,000 bases.

Location of the abi, col and imm genes on pHU011, a colicin Ib plasmid derivative

A cleavage site map of pHU011, a derivative of the colicin Ib plasmid containing the complete SalI-B fragment ligated to pBR322, has been determined. Sites of cleavage by PstI were determined using the Smith and Birnstiel [Nucl. Acids Res. 3 (1976) 2387-2398] method of mapping, whereas those for XbaI, XhoI, and HindIII were determined by double digestions or digestion of isolated fragments. In addition, the sites of the abi gene, which causes the abortive infection by T5 bacteriophage, and of the colicin (col) gene have been determined. The results indicate that these genes are not contiguous.

Inhibition of T7 bacteriophage replication by a colicin Ib plasmid gene

Clones containing fragments of the colicin Ib (ColIb) plasmid inserted into pBR322 have been found that inhibit the replication of T7 bacteriophage. Cells containing the whole ColIb plasmid grow T7 normally but cannot grow T7 protein kinase-negative mutants of T7. The cloned fragments inhibit not only the T7 protein kinaseless mutants but wild-type T7 as well. However, the whole plasmid can suppress the wild-type T7 inhibition caused by the cloned inhibiting genes. These results are consistent with a model in which a ColIb gene (pic) exists which can inhibit replication of T7 phage. A second gene (rpi) can repress the function of pic provided the rpi product is phosphorylated.

Construction and analysis of miniplasmids of the colicin Ib plasmid

Miniplasmids of the colicin Ib (ColIb) plasmid have been isolated from two Tn5-induced mutants of ColIb and their structure determined. These have then been used to order the sequence of restriction endonuclease fragments of the whole plasmid. In addition, the sites of the colicin, colicin immunity, and abortive infection gene have been determined in relation to the restriction sites. By comparison of the miniplasmids with other "I" incompatibility group plasmids, the probable location of the incompatibility gene and the origin of replication have been confirmed.