Isolation of specialized lambda transducing bacteriophages for flagellar genes (fla) of Escherichia coli K-12.

Specialized transducing lambda phages carrying the region III flagellar genes (fla) of Escherichia coli K-12 were isolated by a new method. A strain carrying both a cryptic lambda prophage near the his genes and a deletion of the attlambda gene was used as a starting strain. The lysogen of lambdacI857pga18-bio69 was isolated in which the prophage was integrated within the lambda cryptic genes by means of recombination with the residual lambda DNA. The strains with deletions starting within the prophage and ending in these fla genes were selected from among the heat-resistant survivors of the lysogen. They were then infected with heat-inducible and lysis-defective lambda phages and, thus, specialized transducing phage lines for hag and fla were obtained. High-frequency transfer lines of rare phages carrying the fla genes were isolated by inducing a strain carrying a heat-inducible lambda prophage near the his genes and selecting by transduction of a fla deletion strain. Preliminary characterization of these transducing phages is also reported.     

Genetic and physical studies of lambda transducing bacteriophage carrying the beta subunit gene of the Escherichia coli ribonucleic acid polymerase.

The prophage lambdac1857 was inserted into the bfe gene located near rif (the structural gene for the beta subunit of deoxyribonucleic acid [DNA]-dependent ribonucleic acid polymerase) on the Escherichia coli chromosome. Induced lysates (low-frequency transducing lysates) of such a lysogen contained defective lambda phage particles (lambdadrif+) that can specifically transduce the wild-type rif+ gene. Upon transduction into a recipient strain carrying recA, heterogenotes harboring both the wild-type and the mutant rif genes were isolated. Rec+ derivatives of these heterogenotes produce high-frequency transducing lysates that contain lambdadrif+ and normal active phages at a ratio of 1 to 2. The results of marker rescue experiments and of density determination with several transducing phages indicate that most of the late genes are deleted and replaced by a segment of the chromosomal DNA carrying the bfe-rif region. The length of the chromosomal segment seems to vary between approximately 0.5 and 0.6% of the total bacterial DNA among the three independently isolated lambdadrif+ phages. Electron microscopy of heteroduplex DNA consisting of one strand from lambdadrif+-6 and the other from lambdaimm-21 phages directly confirmed that most of the phage DNA of the "left arm" was replaced by the bacterial DNA. The heteroduplex study also demonstrated that the integration of prophage lambda into the bfe region occurred at the normal cross-over point within the phage attachment site.     

Isolation of specialized transducing bacteriophages carrying the structural genes of the hexuronate system in Escherichia coli K-12: exu region.

In Escherichia coli HfrH 58, isolated by Shimada et al., a heat-inducible phage has been integrated in a secondary attachment site. We have characterized tha nature of the lambda integration. The exuR regulatory gene is inactivated by prophage integration. Genetic and biochemical analysis indicated a gene order: uxaA-uxaC-exuT-(exuR')-lambdaNRAJ (exuR'). By induction of HfrH 58, one class of deletions extending into the exu region was obtained. Analysis of these deletions confirms the exu region topography and the regulatory mechanism of the hexuronate system previously described. It has been possible to regenerate a functional exuR gene by prophage exision. Various lambda transducing particles plaque-forming and defective transducing phages carrying the left part or the right part of the exu region, have been derived from the secondary site lysogen HfrH 58. A phage carrying the entire exuR region was constructed by a cross between these two types of phage. The construction and characterization of these exu transducing phages are presented.     

Formation of lambda transducing phage in vitro: involvement of DNA gyrase

We found that transducing phages carrying the gal or bio regions of the Escherichia coli genome were formed during in vitro packaging of endogenous lambda DNA. Structural analysis of the transducing phage genomes indicated that they were formed by abnormal excision of lambda prophage. Formation of transducing phages was stimulated by oxolinic acid, an inhibitor of DNA gyrase, implying that DNA gyrase participates in the abnormal excision of lambda prophage. When pBR322 DNA was added to the reaction mixture, transducing phages into which pBR322 had been inserted were produced at a high frequency. This reaction was also stimulated by oxolinic acid. Sequence analyses revealed that pBR322 is inserted into the sites of abnormal excision of the prophage. These results show that transducing phages can be formed by DNA gyrase-dependent illegitimate recombination in an in vitro system and that secondary recombination takes place frequently at the site where the first recombination occurs.     

Molecular cloning of four tricarboxylic acid cyclic genes of Escherichia coli.

A fragment of DNA (3.1 kilobases [kb]) from a ColE1 Escherichia coli DNA hybrid plasmid containing the bacterial citrate synthase gene (gltA) was subcloned in both orientations into phage lambda vectors by in vitro recombination. The resulting phages were able to transduce gltA and, as prophages, complemented the lesion of a gltA mutant, showing that a functional gltA gene is contained in the 3.1-kb fragment. The segment of E. coli DNA cloned in these lambda gltA phages was extended in vivo by prophage integration and aberrant excision in the gltA region. Plaque-forming derivatives, carrying up to three additional tricarboxylic acid cycle genes, succinate dehydrogenase (sdh), 2-oxoglutarate dehydrogenase (sucA), and dihydrolipoamide succinyltransferase (sucB), were isolated and characterized by their transducing and complementing activities with corresponding mutants, and the order of the genes was confirmed as gltA-sdh-sucA-sucB. Physical maps of a variety of the transducing phages showed that the four tricarboxylic acid cycle genes are contained in a 12.8-kb segment of bacterial DNA. The four gene products, plus a possible succinate dehydrogenase small subunit, were identified in postinfection labeling studies, and the polarities of gene expression were defined as counterclockwise for gltA and clockwise for sdh, sucA, and sucB, relative to the E. coli linkage map.     

Direct and general selection for lysogens of Escherichia coli by phage lambda recombinant clones.

We report a simple in vivo technique for introducing an antibiotic resistance marker into phage lambda. This technique could be used for direct selection of lysogens harboring recombinant phages from the Kohara lambda bank (a collection of ordered lambda clones carrying Escherichia coli DNA segments). The two-step method uses homologous recombination and lambda DNA packaging to replace the nonessential lambda DNA lying between the lysis genes and the right cohesive (cos) end with the neomycin phosphotransferase (npt) gene from Tn903. This occurs during lytic growth of the phage on a plasmid-containing host strain. Neomycin-resistant (npt+) recombinant phages are then selected from the lysates containing the progeny phage by transduction of a polA1 lambda lysogenic host strain to neomycin resistance. We have tested this method with two different Kohara lambda phage clones; in both cases, neomycin resistance cotransduced with the auxotrophic marker carried by the lambda clone, indicating complete genetic linkage. Linkage was verified by restriction mapping of purified DNA from a recombinant phage clone. We also demonstrate that insertion of the npt+ recombinant phages into the lambda prophage can be readily distinguished from insertion into bacterial chromosomal sequences.     

Selection of lambda Spi- transducing phages using the P2 old gene cloned onto a plasmid

The old gene product of the P2 prophage interferes with plaque formation by lambda wild type phage but allows lambda phages whose red and gam genes have been deleted to form small, visible plaques (the lambda Spi- phenotype). The old gene product also kills Escherichia coli recB or recC mutants. We have cloned the old gene into the high-copy-number plasmid pBR322, where it prevents plaque formation by both lambda Spi+ and lambda Spi- phages. We transferred a DNA fragment that carries the old gene to the low-copy-number plasmid pSC101 and found that lambda Spi- phages can be selected on strains that carry this plasmid. The plasmid-borne old gene kills E. coli recB mutants, providing a selection for old- mutants.     

New transducing phage with RNA polymerase beta- and beta'-subunit genes derived from a hybrid phage lambda att80: isolation, genetic analysis and physical mapping]

A hybrid lambda att 80 phage with the genetic structure lambda (A-J) phi 80 (att-int-xis) imm lambda..cI857s7 is shown to be a convenient vector for creating transducing phages. On the one hand, the restriction analysis indicates that it has 3 restriction sites for EcoRI in comparison with 5 and 9 sites for parental phages lambda and phi 80 respectively. On the other hand, its buoyant density is less than that of phage lambda and under centrifugation it is easier separated from the phage transducing particles. When lambda att 80 prophage was excluded from the bfe locus of Escherichia coli, transducing phages with genes of two RNA polymerase beta-subunits (rpoB and rpoC) were isolated. To identify the latter, a convenient genetic test was worked out. A physical map of lambda att 80 drifd 35 transducing phage, carrying rpoB and rpoC genes has been constructed using endonucleases EcoRI and HindIII. A comparison of this map and the corresponding maps of transducing phages lambda drifd 18 and lambda drifd 47, studied earlier, led to the discovery of two integration sites of phage lambda within the locus bfe spaced apart by about 1800 nucleotide pairs. At all the sites both phages (lambda and lambda att 80) have integrated in the locus bfe in the counter clockwise order.     

Isolation and characterization of nondefective transducing lambda bacteriophages carrying fla genes of Escherichia coli K-12.

In Escherichia coli K-12, 11 fla genes and a hag gene are located between his and uvrC, making two clusters at map positions 42.5 and 43.0 min. Nondefective transducing lambda phages for these genes were isolated. Low-frequency-transducing donors were constructed starting from lysogens of lambda cI857 in which the prophage is integrated at a secondary attachment site at 44 min on the E. coli map. Two strategies were used to delete the region between the prophage and the fla genes. Deletion mutants of the supD locus between fla and the prophage were isolated by selecting for loss of Su1+, an allele of supD. A strain with a deletion starting within the prophage and ending at a position close to the fla genes was isolated from heat-resistant derivatives of the lysogen. A lysogen of lambda b2 was then constructed in which the prophage had integrated at the site of the defective prophage by means of recombination with residual lambda deoxyribonucleic acid. From low-frequency-transducing lysate of the donor strains thus constructed, either directly or in combination with a procedure that extends the loci transduced, various lambda pfla's were isolated. lambda pflaL1 carries all nine fla genes at 43 min, and lambda pflaH14 carries hag and two fla genes at 42.5 min.     

Isolation of generalized transducing bacteriophages for uropathogenic strains of Escherichia coli

The traditional genetic procedure for random or site-specific mutagenesis in Escherichia coli K-12 involves mutagenesis, isolation of mutants, and transduction of the mutation into a clean genetic background. The transduction step reduces the likelihood of complications due to secondary mutations. Though well established, this protocol is not tenable for many pathogenic E. coli strains, such as uropathogenic strain CFT073, because it is resistant to known K-12 transducing bacteriophages, such as P1. CFT073 mutants generated via a technique such as lambda Red mutagenesis may contain unknown secondary mutations. Here we describe the isolation and characterization of transducing bacteriophages for CFT073. Seventy-seven phage isolates were acquired from effluent water samples collected from a wastewater treatment plant in Madison, WI. The phages were differentiated by a host sensitivity-typing scheme with a panel of E. coli strains from the ECOR collection and clinical uropathogenic isolates. We found 49 unique phage isolates. These were then examined for their ability to transduce antibiotic resistance gene insertions at multiple loci between different mutant strains of CFT073. We identified 4 different phages capable of CFT073 generalized transduction. These phages also plaque on the model uropathogenic E. coli strains 536, UTI89, and NU14. The highest-efficiency transducing phage, ΦEB49, was further characterized by DNA sequence analysis, revealing a double-stranded genome 47,180 bp in length and showing similarity to other sequenced phages. When combined with a technique like lambda Red mutagenesis, the newly characterized transducing phages provide a significant development in the genetic tools available for the study of uropathogenic E. coli.     

Isolation of specialized transducing bacteriophages carrying deletions of the regulatory region of the Escherichia coli K-12 tryptophan operon.

A lysogen of a wild-type strain of Escherichia coli K-12 carrying a heat-inducible lambda-phi80 hybrid prophage was induced to yield transducing phages carrying all of the structural genes of the tryptophan operon. The presence or absence of elements of the trp regulatory region was determined by examining the effects of lambda genes N and cI on trp gene expression. The phages were further characterized by transduction studies and by examining anthranilate synthetase (EC 4.1.3.27) (TRYPE+D) synthesis in the presence of the lambda cI product. A number of phages deleted for the trp promoter were found. Recombination studies between trpOc bacteria and the transducing phages have yielded information that can be used to order the trp end points of some phages and to provide an estimate of the size of the trp promoter region.     

Deletion of late genes of the prophage lambda

The deletions in tandem prophage lambda appear with high frequency (to 10%) in rec A- strain of Escherichia coli. The deletions were shown by marker rescue and hybridization of fragments of DNA on nitrocellulose filters with nick-translated phage lambda DNA localized only in prophage area. Right and left att sites are not involved. The majority of defective lysogens had all regulatory regions and deletions of late structural genes. These strains may be used for construction of the host-vector systems with the strongest promoter p'R of phage lambda.     

Isolation and characterization of lambda specialized transducing bacteriophages carrying Klebsiella pneumoniae nif genes

Seve lambda dnif specialized transducing bacteriophages were isolated from Escherichia coli strains containing plasmids carrying the his-nif region of Klebsiella pneumoniae. These phages collectively carry deoxyribonucleic acid for all of the genes in the nif regulon and adjacent deoxyribonucleic acid of K. pneumoniae. The phages were isolated by using Mu insertions in the nif region to direct the integration of lambda pMu phages in nif via formation of lambda pMu-Mu dilysogens which, upon induction, yielded lambda dnif phages. This procedure should be generally applicable for isolating lambda specialized transducing phages carrying genes from E. coli or other bacteria.     

Isolation and characterization of lambda transducing bacteriophages for the su1+ (supD minus) amber suppressor of Escherichia coli.

Specialized lambda transducing phages for the sul+ (supD-) amber suppressor in Escherichia coli K-12 have been isolated, using a secondary site lambda-cI857 lysogen in which we have shown the prophage to be closely linked to sul+.sul+ transducing particles were detected frequently, at 10-5 per plaque-forming unit, in lysates prepared from the secondary-site lysogens. High-frequency transducing lysates were obtained from several independently isolated sul+ transductants and were analyzed by CsCl equilibrium density gradient centrifugation. The transducing phages are defective; marker rescue analysis indicates that the lambda-N gene is not present. In lambda-cI857DELTANdSul+, a bio-type transducing phage, the genes specifying recombination and excision functions have been replaced by bacterial deoxyribonucleic acid.     

Molecular characterization of ilvC specialized transducing phages of Escherichia coli K-12

A series of lambda defective ilvC specialized transducing phage has been isolated which carry regions of isoleucine and valine structural and regulatory genes derived from the ilv cluster at minute 83 on the linkage map of the chromosome of Escherichia coli K-12. The ilv genes carried by these phages and their order have been determined by transduction of auxotrophs. The ilvC+ lysogen of an ilvC- strain gave rise, after heat induction of the lysogen, to transducing particles which carried the wild-type allele of the cya-marker. Further experiments have shown that the lambda defective ilvC phages were able to cotransduce a rho-15ts mutation as well as a rep-5 mutation. Hence, the order of the clockwise excision of the ilv cluster was found to be ilvC-rho-rep-cya. Enzyme levels in strains carrying the lambda defective ilvC phages indicated the the ilvC gene was not altered by the insertion of lambda into the ilv cluster. The isolation and digestion of lambda defective ilvC DNA by EcoRI and HindIII restriction endonucleases demonstrated that the specialized transducing phages carried part of the genome from the E. coli K-12 chromosome.     

Evidence that the outer membrane protein gene nmpC of Escherichia coli K-12 lies within the defective qsr'' prophage.

Recombinants between phage lambda and the defective qsr' prophage of Escherichia coli K-12 were made in an nmpC (p+) mutant strain and in the nmpC+ parent. The outer membrane of strains lysogenic for recombinant qsr' phage derived from the nmpC (p+) strain contained a new protein identical in electrophoretic mobility to the NmpC porin and to the Lc porin encoded by phage PA-2. Lysogens of qsr' recombinants from the nmpC+ strain and lysogens of lambda p4, which carries the qsr' region, did not produce this protein. When observed by electron microscopy, the DNA acquired from the qsr' prophage showed homology with the region of the DNA molecule of phage PA-2 which contains the lc gene. Relative to that of the recombinant from the nmpC (p+) mutant, the DNA molecule of the recombinant from the nmpC+ parent contained an insertion near the lc gene. These results were supported by blot hybridization analysis of the E. coli chromosome with probes derived from the lc gene of phage PA-2. A sequence homologous to the lc gene was found at the nmpC locus, and the parental strains contained an insertion, tentatively identified as IS5B, located near the 3' end of the porin coding sequence. We conclude that the structural gene for the NmpC porin protein is located within the defective qsr' prophage at 12.5 min on the E. coli K-12 map and that this gene can be activated by loss of an insertion element.     

Isolation and Characterization of dnaX and dnaY Temperature-Sensitive Mutants of ESCHERICHIA COLI

Escherichia coli mutants with temperature-sensitive (ts) mutations in dnaX and dnaY genes have been isolated. Based on transduction by phage P1, dnaX and Y have been mapped at minutes 10.4--10.5 and 12.1, respectively, in the sequence dnaX purE dnaY. Both dna Xts36 and Yts10 are recessive to wild-type alleles present on episomes. F13 carries both dnaX+ and Y+; the shorter F210 carries dnaY+, but not X+. Lambda tranducing phages that carry dnaX+ or Y+ have been isolated, and hybrid plasmids of Col E1 and E. coli DNA from the Clarke and Carbon (1976) collection also carry portions of the dnaX purE dnaY region. Results obtained with the lambda transducing phages and the hybrid plasmids suggest that dnaX is a different gene from the previously characterized dnaZ gene, which is also near minute 10.5--The dnaXts36 mutant, after a shift to 42 degrees, stopped DNA synthesis gradually, and the total amount of DNA increased two-fold. When this mutant was shifted to 44 degrees, the rate of DNA synthesis dropped immediately and the final increment of DNA was only 10% of the initial amount. Replicative DNA synthesis in toluene-treated cells was completely inhibited at 42 degrees and was partially inhibited even at 30 degrees.--When the dnaYts10 mutant was shifted to 42 degrees, DNA synthesis gradually stopped, and the amount of DNA increased 3.6-fold. At 44 degrees, residual DNA synthesis amounted to a two-fold increase. Replicative DNA synthesis in vitro in toluene-treated cells was inactivated after 20 minutes at 42 degrees or by "preincubation" of cells at 42 degrees before toluene treatment.--The dnaX and dnaY products probably function in polymerization of DNA, although participation also in initiation cannot be excluded.     

Cosmid DNA packaging in vivo

The packaging of cosmid DNA into phage particles during phage lambda growth is described. Evidence is presented supporting the work of others that cosmid transducing phages contain linear multimers of cosmid DNA in which the number of cosmid copies is that required to make a packagable DNA length (greater than 0.77 of the lambda DNA length). The yield of cosmid transducing phages declines sharply as the number of cosmid copies required to make a packagable DNA length increases. The cosmid DNA replication that produces the packaging substrate shares with lambda rolling-circle replication a dependence on the lambda gam gene product.     

Mapping of insertion mutations in gnd of Escherichia coli with deletions defining the ends of the gene.

A genetic map was prepared for gnd, the gene of Escherichia coli which encodes the metabolically regulated 6-phosphogluconate dehydrogenase. Direct selection methods were used for the isolation of mutants with deletions that define the respective ends of gnd. These selections depended on the availability of a defective lysogen in which gnd was present on a lambda h80 dgnd his prophage located at the att phi 80 region of the chromosome. Mutants with deletions entering gnd from the his-distal end were selected as Gnd- TonB- mutants. Mutants with his-proximal gnd deletions were selected as Gnd-, temperature-resistant mutants of a specially prepared stable lysogen. Gnd- mutants were also isolated after mutagenesis with bacteriophage Mu cts61, and genetic tests were used to determine which mutants carry a Mu cts61 prophage in gnd. The deletion mutations were mapped against each other and against the insertion mutations through the use of F' merodiploid strains. The insertion mutations mapped at seven distinct sites in gnd; three mapped under the deletions defining the his-proximal portion of the gene and three mapped with the his-distal deletions.