Cloning of the pif region of the F sex factor and identification of a pif protein product

F exclusion of bacteriophage T7 occurs at the cell membrane

The F plasmid PifA protein, known to be the cause of F exclusion of bacteriophage T7, is shown to be a membrane-associated protein. No transmembrane domains of PifA were located. In contrast, T7 gp1.2 and gp10, the two phage proteins that trigger phage exclusion, are both soluble cytoplasmic proteins. The Escherichia coli FxsA protein, which, at higher concentrations than found in wild-type cells, protects T7 from exclusion, is shown to interact with PifA. FxsA is a polytopic membrane protein with four transmembrane segments and a long cytoplasmic C-terminal tail. This tail is not important in alleviating F exclusion and can be deleted; in contrast, the fourth transmembrane segment of FxsA is critical in allowing wild-type T7 to grow in the presence of F PifA. These data suggest that the primary event that triggers the exclusion process occurs at the cytoplasmic membrane and that FxsA sequesters PifA so that membrane damage is minimized.

The essential role of fumarate reductase in haem-dependent growth stimulation of Bacteroides fragilis

Haem is required for optimal growth of the bacterial anaerobe Bacteroides fragilis. Previous studies have shown that growth in the presence of haem is coincident with increased yields of ATP from glucose, expression of b-type cytochromes and expression of fumarate reductase activity. This paper describes the identification of the genes that encode the cytochrome, iron-sulfur cluster protein and flavoprotein of the B. fragilis fumarate reductase. These genes, frdC, frdA and frdB, respectively, are organized in an operon. Nonpolar, in-frame deletions of frdC and frdB were constructed in the B. fragilis chromosome. These mutant strains had no detectable fumarate reductase or succinate dehydrogenase activity. In addition, the frd mutant strains showed a threefold increase in generation time, relative to the wild-type strain. Growth of these mutant strains was fully restored to the wild-type rate by the introduction of a B. fragilis replicon containing the entire frd operon. Growth of the frd mutant strains was partially restored by supplementing the growth medium with succinate, indicating that the frd gene products function as a fumarate reductase. During growth on glucose, the frd mutant strains showed a threefold decrease in cell mass yield, relative to the wild-type strain. These data indicate that fumarate reductase is important for both energy metabolism and succinate biosynthesis in B. fragilis.

Molecular characterization of a new abortive infection system (AbiU) from Lactococcus lactis LL51-1

This study reports on the identification and characterization of a novel abortive infection system, AbiU, from Lactococcus lactis. AbiU confers resistance to phages from the three main industrially relevant lactococcal phage species: c2, 936, and P335. The presence of AbiU reduced the efficiency of plaquing against specific phage from each species as follows: 3.7 x 10(-1), 1.0 x 10(-2), and 1.0 x 10(-1), respectively. abiU involves two open reading frames, abiU1 (1,772 bp) and abiU2 (1,019 bp). Evidence indicates that AbiU1 is responsible for phage resistance and that AbiU2 may downregulate phage resistance against 936 and P335 type phages but not c2 type phage. AbiU appeared to delay transcription of both phage 712 and c2, with the effect being more marked on phage c2.

Increased synthesis of an Escherichia coli membrane protein suppresses F exclusion of bacteriophage T7

Increased synthesis of the protein FxsA alleviates the exclusion of T7 in cells harboring the F plasmid. In contrast to wild-type or cells defective in fxsA, overexpression of fxsA+ allows T7 to form plaques at normal efficiency even though the burst size is reduced to about half that obtained on the isogenic F- strain. No defect in DNA synthesis was observed but late protein synthesis remains partially inhibited and a reduced level of cell leakiness, a prominent feature of F+ cells abortively infected by T7, persists. The FxsA protein is shown to be a cytoplasmic membrane protein. How T7 avoids exclusion by F in cells that exhibit increased levels of FxsA is discussed in terms of its membrane localization.

Stabilization of the relaxosome and stimulation of conjugal transfer are genetically distinct functions of the R1162 protein MobB

MobB is a small protein encoded by the broad-host-range plasmid R1162 and required for efficient mobilization of its DNA during conjugation. The protein was shown previously to stabilize the relaxosome, the complex of plasmid DNA and mobilization proteins at the origin of transfer (oriT). We have generated in-frame mobB deletions that specifically inactivate the stabilizing effect of MobB while still allowing a high rate of transfer. Thus, MobB has two genetically distinct functions in transfer. The effect of another deletion, extending into mobA, indicates that both functions require a specific region of MobA protein that is distinct from the nicking-ligating domain. The mobB mutations that specifically affected stability also resulted in poor growth of cells, due to increased transcription from the promoters adjacent to oriT. The effects of the mutations could be suppressed not only by full-length MobB provided in trans, as expected, but also by additional copies of oriT, cloned in pBR322. In addition, in the presence of MobA both the full-length and truncated forms of MobB stimulated recombination between oriT-containing plasmids. We propose a model in which MobB regulates expression of plasmid genes by altering the stability of the relaxosome, in a manner that involves the coupling of plasmid molecules.

Both the fipA gene of pKM101 and the pifC gene of F inhibit conjugal transfer of RP1 by an effect on traG

The mechanisms by which gene products inhibit the conjugal transfer of IncP plasmids (e.g., RP1) have been little studied. We have isolated and characterized one such gene, fipA (624 nucleotides), from the SmaI (14.8 kb)-AatII (15.6 kb) region of pKM101(IncN). This gene, which is also conserved in other IncN plasmids, is transcribed in an anticlockwise direction, probably as part of a transfer operon that includes traHI. The FipA protein (24 kDa) appears to be cytoplasmic and, when expressed from a multicopy plasmid, retards the growth of Escherichia coli WP2. The mode of action of fipA was compared with that of the apparently unrelated pifC gene from F(IncFI). Both genes inhibit the transfer of IncPalpha and IncPbeta plasmids but to different degrees. They also inhibit the mobilization of RSF1010 (which requires the RP1 pilus genes and traG) but not of CloDF13 (which encodes a traG homolog). Evidence that traG was the specific target of inhibition was obtained in an artificial system in which cloned traG was used to enhance RSF1010 mobilization via the N pilus system. Such enhancement did not occur in the presence of fipA or pifC. The availability of an in vivo assay of PifC enabled us to show that F pif operon expression increased in cells carrying F'lac and traG, but only if the traG coding sequence was intact. This finding suggested that conjugal inhibition of RP1 was most likely due to a PifC-TraG protein interaction. On phenotypic grounds inhibition of traG by fipA is also likely to occur posttranscriptionally. Whether or not the selection of traG as the inhibition target is an evolutionary tactic to limit the spread of P plasmids, we anticipate that fipA and pifC will prove useful in further investigation of the conjugal roles of traG and its homologs.

Phenotypic and genetic characterization of the bacteriophage abortive infection mechanism AbiK from Lactococcus lactis

The natural plasmid pSRQ800 isolated from Lactococcus lactis subsp. lactis W1 conferred strong phage resistance against small isometric phages of the 936 and P335 species when introduced into phage-sensitive L. lactis strains. It had very limited effect on prolate phages of the c2 species. The phage resistance mechanism encoded on pSRQ800 is a temperature-sensitive abortive infection system (Abi). Plasmid pSRQ800 was mapped, and the Abi genetic determinant was localized on a 4.5-kb EcoRI fragment. Cloning and sequencing of the 4.5-kb fragment allowed the identification of two large open reading frames. Deletion mutants showed that only orf1 was needed to produce the Abi phenotype. orf1 (renamed abiK) coded for a predicted protein of 599 amino acids (AbiK) with an estimated molecular size of 71.4 kDa and a pI of 7.98. DNA and protein sequence alignment programs found no significant homology with databases. However, a database query based on amino acid composition suggested that AbiK might be in the same protein family as AbiA. No phage DNA replication nor phage structural protein production was detected in infected AbiK+ L. lactis cells. This system is believed to act at or prior to phage DNA replication. WHen cloned into a high-copy vector, AbiK efficiency increased 100-fold. AbiK provides another powerful tool that can be useful in controlling phages during lactococcal fermentations.

Incomplete entry of bacteriophage T7 DNA into F plasmid-containing Escherichia coli

The penetration of bacteriophage T7 DNA into F plasmid-containing Escherichia coli cells was determined by measuring Dam methylation of the entering genome. T7 strains that cannot productively infect F-containing cells fail to completely translocate their DNA into the cell before the infection aborts. The entry of the first 44% of the genome occurs normally in an F-containing cell, but the entry of the remainder is aberrant. Bypassing the normal mode of entry of the T7 genome by transfecting naked DNA into competent cells fails to suppress F exclusion of phage development. However, overexpression of various nontoxic T7 1.2 alleles from a high-copy-number plasmid or expression of T3 1.2 from a T7 genome allows phage growth in the presence of F.

Genes 1.2 and 10 of bacteriophages T3 and T7 determine the permeability lesions observed in infected cells of Escherichia coli expressing the F plasmid gene pifA

Infections of F plasmid-containing strains of Escherichia coli by bacteriophage T7 result in membrane damage that allows nucleotides to exude from the infected cell into the culture medium. Only pifA of the F pif operon is necessary for "leakiness" of the T7-infected cell. Expression of either T7 gene 1.2 or gene 10 is sufficient to cause leakiness, since infections by phage containing null mutations in both of these genes do not result in permeability changes of the F-containing cell. Even in the absence of phage infection, expression from plasmids of either gene 1.2 or 10 can cause permeability changes, particularly of F plasmid-containing cells. In contrast, gene 1.2 of the related bacteriophage T3 prevents leakiness of the infected cell. In the absence of T3 gene 1.2 function, expression of gene 10 causes membrane damage that allows nucleotides to leak from the cell. Genes 1.2 and 10 of both T3 and T7 are the two genes involved in determining resistance or sensitivity to F exclusion; F exclusion and leakiness of the phage-infected cell are therefore closely related phenomena. However, since leakiness of the infected cell does not necessarily result in phage exclusion, it cannot be used as a predictor of an abortive infection.

Expression of gene 1.2 and gene 10 of bacteriophage T7 is lethal to F plasmid-containing Escherichia coli

Plasmids expressing bacteriophage T7 gene 1.2 or gene 10 DNA transform F plasmid-containing strains of Escherichia coli only at low efficiency, though they transform plasmid-free strains normally. The gene products T7 gp1.2 and T7 gp10 appear to be the toxic agents, and their effects are directed towards the product of the F pifA gene, PifA. T7 gp1.2 and gp10 are also the two targets of the pif exclusion system of F, and their synthesis normally triggers the abortive infection of T7 in pifA+ hosts. The properties of plasmids containing T7 gene 1.2 or 10 suggest that they can be used to study the molecular mechanisms of phage exclusion in model systems that avoid the pleiotropic dysfunctions associated with an abortive infection.

Localization of Separate Genetic Loci for Reduced Sensitivity towards Small Isometric-Headed Bacteriophage sk1 and Prolate-Headed Bacteriophage c2 on pGBK17 from Lactococcus lactis subsp. lactis KR2

The mechanism of reduced sensitivity to the small isometric-headed bacteriophage sk1 encoded on a 19-kilobase (kb) Hpa II fragment subcloned from pKR223 of Lactococcus lactis subsp. lactis KR2 was examined. The reduced sensitivity to phage sk1 was due to a modest restriction/modification (R/M) system that was not active against prolate-headed phage c2. The genetic loci for the R/M system against sk1 and the abortive phage infection (Abi) mechanism effective against phage c2 were then localized by restriction mapping, subcloning, and deletion analysis. The restriction gene was localized to a region of a 2.7-kb Eco RV fragment and included an Eco RI site within that fragment. The modification gene was found to be physically separable from the restriction gene and was present on a 1.75-kb Bst EII- Xba I fragment. The genetic locus for the Abi phenotype against phage c2 was localized to a region containing a 1.3-kb Eco RI fragment. Attempts to clone the c2 Abi mechanism independent of the sk1 R/M system were unsuccessful, suggesting that expression of the abi genes required sequences upstream of the modification gene. Some pGBK17 (vector pGB301 plus a 19-kb Hpa II insert fragment) transformants exhibited the R/M system against phage sk1 but lost the Abi mechanism against phage c2. These transformants contained a 1.2- to 1.3-kb insertion in the Abi region. The data identified genetic loci on a cloned 19-kb Hpa II fragment responsible for restriction activity and for modification activity against a small isometric-headed phage and for Abi activity against prolate-headed phage c2. A putative insertion element was also found to inactivate the abi gene(s).

Mapping and regulation of the pifC promoter of the F plasmid

The pif region of the F plasmid, which causes abortive infection of Escherichia coli by T7 bacteriophage, is autogenously controlled by the product of the pifC gene. Here we describe the identification of the pif operon promoter by S1-nuclease mapping, and show that it is autoregulated at the transcriptional level and that its activity is modulated by integration host factor.

A simple method of distinguishing the bacterial viruses T3 and T7, and a critical reevaluation of their heterologous and homologous exclusion

A method is presented allowing a clear distinction between bacterial viruses T3 and T7 by plating on selectively permissive host cells. The indicator strains are Escherichia coli cells containing either cloned pif genes (exclusively permissive for T3) or the EcoRV DNA restriction system (permissive only for T7): The efficiencies of plating of the two phages on these hosts differ by more than 8 orders of magnitude. This method was applied to reinvestigate the controversial question of mutual exclusion between T3 and T7. Under single-burst conditions, about 50% of coinfected cells (permissive for both viruses) produced T3 and T7 progeny while about 25% reproduced only T3 and about 25% only T7. The burst size of co-infected cells was slightly reduced, compared to controls infected with only one virus type. Homologous exclusion among T3 phages was also not seen; rather, there was a gene dosage effect: T3-encoded RNA polymerase activity as well as T3-specific RNA synthesis increased proportionally to the multiplicity of infection (2.5-20 plaque-forming units/cell).

Abortive infection of Escherichia coli F+ cells by bacteriophage T7 requires ribosomal misreading

The use of different precisely mapped T3/T7 recombinants strengthens the conclusion that abortive infection by T7 of F plasmid-carrying cells is due to the nucleotide sequence at the end of the T7 gene 1. Furthermore, we demonstrate that the exclusion requires suppression of ochre stop codons, a phenomenon that occurs with low frequency in wild-type cells due to ribosomal misreading. The introduction of rspL mutations in which ribosomal misreading is reduced alleviates the exclusion and the presence of ochre tRNA suppressors increases its severity.

The miniF plasmid C protein: sequence, purification and DNA binding

The C (pifC) protein of miniF represses transcription of its own gene by binding to the pif operator (pifO); it is also needed for replication initiated from the miniF primary origin (ori-1). We have determined the nucleotide sequence of the C gene. The gene has been inserted into an expression vector under Ptrp control where it is expressed at high levels. The C protein has been purified from cells carrying the Ptrp-C plasmid, and a preliminary study of C protein-DNA binding properties has been carried out. C protein binds strongly to pifO, and weakly to sequences in the ori-1 region.

Site-specific and illegitimate recombination in the oriV1 region of the F factor. DNA sequences involved in recombination and resolution

We have defined some of the sequences involved in high frequency recA-independent recombination at the oriV1 region of the F factor. Using a mobilization assay, we determined that plasmid pMB080, a pBR322 derivative bearing the PvuII-BamHI (F factor co-ordinates 45.43 to 46.0) fragment from the oriV1 region of F, contained all sequences necessary to undergo efficient site-specific recombination with the F derivative pOX38, which retains the oriV1 region. We constructed a series of pMB080 deletions in vitro using exonucleases S1 and Bal31. Deletions removing a ten base-pair sequence, which forms part of an inverted repeat segment located 62 base-pairs to the left of the NcoI site (45.87) within the cloned fragment, totally eliminated the recA-independent recombination reaction. Other deletions differentially affected both the frequency and stability of cointegrate molecules formed by the site-specific recombination system. The F factor oriV1 region is involved also in low-frequency recombination with several sites on pBR322 and related plasmids. We have determined the precise location of these recombination sites within oriV1 by DNA sequencing. These studies revealed that recombination always took place within an eight base-pair spacer region between the ten base-pair inverted repeats found to be important for oriV1-oriV1 interactions. We propose that the low-efficiency recombination between pBR322 and pOX38 results from the ability of the F site-specific recombination apparatus to weakly recognize and interact with sequences that bear some resemblance to the normal oriV1 recognition elements. Furthermore, we suggest, by analogy with the lambda paradigm, that the nucleotide sequences at the junctions of secondary site recombinants define at least one crossover site used during the normal site-specific recombination process.

Mutational and in vivo methylation analysis of F-factor PifC protein binding to the pif operator and the region containing the primary origin of mini-F replication

We have used in vivo methods to identify multiple DNA-binding sites for the negatively autoregulated mini-F replication factor PifC. Sequence analysis of pif operator constitutive mutants, isolated as insensitive to repression by PifC, establishes the structure of pifO. This site contains a 17-base-pair (bp) region of dyad symmetry with 7-bp perfect inverted repeats separated by 3 bp. In vivo DNA methylation studies with dimethyl sulfate show that the reactivity of five of six guanine residues in the pifO region is altered in the presence of PifC protein. In addition, there are several sites of PifC-dependent methylation enhancement and protection upstream of pifO within repeated sequences bearing homology to pifO. The significance of the repeated PifC binding sequences and their relationship to the primary origin of mini-F replication (oriV1) are discussed.

Distribution of basic replicons having homology with RepFIA, RepFIB, and RepFIC among IncF group plasmids

Plasmids encoding F-like pili have been divided into groups on the basis of their incompatibility behavior. Three basic replicons have been recognized previously in the IncFI plasmid group and we have now examined their distribution in representative plasmids from 22 of the currently recognized incompatibility groups. The occurrence of these basic replicons was found to be rare outside of the IncF group, and significant hybridization was shown only for RepFIA to IncH1 and I group plasmids. Homology to the RepFIC basic replicon was found in all but one of the IncF group plasmids examined but RepFIA and RepFIB have a more restricted distribution. It appears likely that some plasmids carry vestiges of replicons which still express incompatibility but are incapable of replication. We suggest that evolutionary divergence among the plasmids of the IncF group has resulted from various genetic rearrangements among these basic replicons.

F factor inhibition of conjugal transfer of broad-host-range plasmid RP4: requirement for the protein product of pif operon regulatory gene pifC

By the use of deletions, point mutations, and gene fusions, we show that the protein product of the F factor pifC gene is responsible for F factor inhibition of plasmid RP4 conjugal transfer. Deletion analysis of pif sequences carried by pSC101-F chimeric plasmids demonstrated that removal of all or part of the pifC coding sequence greatly decreased or abolished the ability of these plasmids to inhibit RP4 transfer. Amber mutations in the pifC gene eliminated inhibition in an Su- host strain but not in and Su+ (supF) host. Plasmids carrying nonpolar pifC mutations did not decrease the efficiency of RP4 transfer when present in trans. Whereas pifC+ plasmids inhibited RP4 transfer, the presence of RP4 in the same cell as F' lac increased F'lac Pif activity approximately 1,000-fold. This effect most likely resulted from the binding of the pifC product to RP4 DNA and concomitant derepression of the F factor pif operon. PifC inhibited trans mobilization of pMS204, a nonconjugative plasmid carrying the RP4 oriT locus, by the RP1 derivative pUB307. pMS204 had no trans effect on pif operon expression, whereas pUB307 increased F'lac Pif expression, as did RP4. Our results suggest that the pifC product inhibits expression of one or more RP4 genes, the products of which are required for conjugal transfer of RP4 and are required in trans for mobilization of nonconjugal RP4 oriT containing plasmids.

Regulation of expression from the glnA promoter of Bacillus subtilis requires the glnA gene product

Expression of the cloned glnA gene [coding for glutamine synthetase (EC 6.3.1.2)] of Bacillus subtilis was 10-fold higher in an Escherichia coli strain grown under nitrogen-limiting conditions than in the same strain under nitrogen-excess conditions. Mutations in the E. coli glnA, glnB, glnD, glnE, glnF, glnG, and glnL genes had no effect on the observed regulation. To test whether sequences within the B. subtilis DNA (3.2 kilobase pairs) were responsible for the observed regulation, a plasmid carrying a transcriptional fusion of the B. subtilis glnA promoter with E. coli lacZ was constructed. beta-Galactosidase levels coded for by this plasmid were found to be negatively regulated in trans by a plasmid carrying the entire B. subtilis glnA gene. Analysis of various deletion plasmids showed that the 1.4-kilobase-pair region encoding glutamine synthetase was necessary for the observed regulation of beta-galactosidase. Plasmids coding for 67% or more of the glutamine synthetase polypeptide gave at least partial repression, but a plasmid carrying 30% of the structural gene, as well as a plasmid carrying a deletion internal to glnA, gave no repression. DNA downstream from glnA (to within 130 base pairs of the end of the gene) was not required for the observed regulation. These results suggest that the glnA gene of B. subtilis is autoregulated, supporting the model for glnA control proposed by Dean et al. [Dean, D. R., Hoch, J. A. & Aronson, A. I. (1977) J. Bacteriol. 131, 981-987].

The mini-F primary origin. Sequence analysis and multiple activities

The sequence of an 897 base-pair fragment (42.1 to 43.0 kilobase co-ordinates on the F genetic map) containing the primary origin (ori-1) of mini-F replication has been determined. It contains one significant open reading frame, which probably codes for part of the C protein thought to be necessary for ori-1 replication activity. Tests of the ability of the sequenced ori-1 region to direct replication of DNA polymerase I-dependent replicons revealed that ori-1 replication requires adjacent mini-F sequences, 43.0 to 43.9 kilobase co-ordinates on the F genetic map in cis as well as a trans-acting gene product, probably the E protein, from the essential replication region of mini-F. In addition, a sequence required for control of pif gene expression has been mapped to a 160 base-pair region immediately upstream from the C (pifC) gene, and the crossover site of a specific recA-independent recombination mechanism has been mapped to a 220 base-pair region on the side of the pif control sequence distal to the C gene.

F plasmid pif region: Tn1725 mutagenesis and polypeptide analysis

Analysis of Tn1725 insertions in the Pif+ plasmid pRS2496 showed the maximum limits of the F pif region to be between 43.7 and 47.15 on the 100-kb map of the F plasmid. The effect of these insertions on the expression of pif polypeptides indicated that two of the pif genes, pifA and pifC, lie within a polycistronic operon.

Cloning and analysis of pif, replication and leading regions of the F plasmid

We describe the molecular cloning of BglII fragments of the hybrid plasmid pRS5 (pSC101 and EcoRI fragments of F; f7, f5, f3 and f6). The clones isolated were examined for the expression of F-specified replication, incompatibility, mobilization and inhibition of T7 bacteriophage multiplication. Proteins directed by the BglII clones were labelled in Escherichia coli K12 maxicells and analyzed by SDS-polyacrylamide gel electrophoresis. The sizes of previously reported proteins, encoded by the replication, incompatibility and leading regions encompassed by these plasmids have been confirmed in this study. In addition, the results demonstrate that a pif gene, which encodes an 80,000 dalton polypeptide essential for the inhibition T7 phage multiplication, is located on the BglII fragment that spans the junction of EcoRI fragments f7 and f5.

Molecular analysis of F plasmid pif region specifying abortive infection of T7 phage

We report the molecular cloning of the pif region of the F plasmid and its physical dissection by subcloning and deletion analysis. Examination of the polypeptide products synthesized in maxicells by plasmids carrying defined pif sequences has shown that the region specifies at least two proteins of molecular weights 80,000 and 40,000, the genes for which appear to lie in the same transcriptional unit. In addition, analysis of pif-lacZ fusion plasmids has detected a pif promoter and determined the direction of transcription across the pif region.

Regulation of the F-factor pif operon: pifO, a site required in cis for autoregulation, titrates the pifC product in trans

F factor pifC, pifA, and pifB gene expression is subject to negative regulation by the product of the pifC locus (J.F. Miller and M. H. Malamy, J. Bacteriol. 156:338-347, 1983). In this paper, we describe the properties of a new regulatory site in the pif region, pifO, which is required in cis for autoregulation of pif gene expression. Spontaneous pifO mutations were isolated that allow expression of a pifC-lacZ protein fusion in the presence of pifC product in trans. Recombination of these pifO mutations onto F'lac results in increased pifA and pifB activity. Thus, a single regulatory element, pifO, regulates pifC, pifA, and pifB expression in cis. The presence of multiple copies of a fragment from the pif region carrying wild-type pifO sequences (F coordinates 42.9 to 42.43 kilobases) in trans to F'lac results in an increase in pifA and pifB activity as measured by inhibition of T7 plating. When the pifO mutations are recombined onto a plasmid carrying pifO, the resulting recombinants are greatly decreased in the ability to increase F'lac pif expression. These results suggest that increased F'lac pifA and pifB expression caused by pifO sequences in trans is a consequence of titration of pifC product and derepression of the pif operon.

Virus-plasmid interactions: mutants of bacteriophage T3 that abortively infect plasmid F-containing (F+) strains of Escherichia coli

Bacteriophage T7 and many closely related phages abortively infect plasmid F-containing (F+) strains of Escherichia coli. However phage T3, which is also closely related to T7, grows normally in F+ hosts. Mutants of phage T3 that, like T7, are subject to F-mediated restriction have been isolated. These T3 mutants lack or are defective in one or both of two genes that are nonessential for phage growth in F-, wild-type strains. Our results show that the products of phage T3 gene 1.1 or 1.2, or both, are essential for growth and suggest that the comparable phage T7 genes are naturally defective in their ability to counteract the inhibitory effects of F-encoded proteins.

A new insertion sequence, IS121, is found on the Mu dI1 (Ap lac) bacteriophage and the Escherichia coli K-12 chromosome

We have discovered a new insertion sequence, now designated IS121, as a component of the Mu dI1 (Ap lac) phage. This sequence is 1.2 kilobases long and contains single recognition sites for the HincII, Bg1II, and HindIII restriction endonucleases. IS121 is present in at least three copies in the chromosome of several Escherichia coli K-12 strains. When present in the nonconjugative plasmid pBR322, IS121 can mediate cointegrate formation with an F' lac plasmid and transfer of pBR322 sequences to suitable recipients. IS121 is also capable of precise or nearly precise excision. As part of the study of IS121, we have determined the physical structure of the Mu dI1 (Ap lac) phage and established an extensive restriction endonuclease map of this phage. A revised schema for the formation of the Mu dI1 (Ap lac) phage is presented.

Identification of the pifC gene and its role in negative control of F factor pif gene expression

The pif region of the F factor includes two genes, pifA and pifB, that lead to abortive T7 infection. We have identified a new gene in this region, pifC, by constructing an in vitro fusion of pif DNA at 41.6 kilobases on the F factor physical map to the lacZ gene. A PifC-LacZ fusion protein of 149,000 daltons has been identified by immunoprecipitation and polyacrylamide gel electrophoresis. This allows us to assign the N terminus of pifC to 42.5 kilobases on the F map. Using fusions of pifC, pifA, and pifB to lacZ, we have studied the regulation of pif gene expression and have shown that the product of pifC negatively controls its own expression and that of pifA and pifB.