A physical map of the Salmonella typhimurium LT2 genome made by using XbaI analysis.

XbaI digestion and pulsed-field gel electrophoresis of the genome of Salmonella typhimurium LT2 yields 24 fragments: 23 fragments (total size, 4,807 kb) are from the chromosome, and one fragment (90 kb) is from the virulence plasmid pSLT. Some of the 23 fragments from the chromosome were located on the linkage map by the use of cloned genes as probes and by analysis of strains which gain an XbaI site from the insertion of Tn10. Twenty-one of the fragments were arranged as a circular physical map by the use of linking probes from a set of 41 lysogens in which Mud-P22 was stably inserted at different sites of the chromosome; fragment W (6.6 kb) and fragment X (6.4 kb) were not located on the physical map. XbaI digestion of strains with Tn10 insertions allowed the physical locations of specific genes along the chromosome to be determined on the basis of analysis of new-fragment sizes. There is good agreement between the order of genes on the linkage map, which is based primarily on P22 joint transduction and F-mediated conjugation, and the physical map, but there are frequently differences in the length of the interval from the two methods. These analyses allowed the measurement of the amount of DNA packaged in phage P22 heads by Mud-P22 lysogens following induction; this varies from ca. 100 kb (2 min) to 240 kb (5 min) in different parts of the chromosome.     

Packaging Specific Segments of the Salmonella Chromosome with Locked-in Mud-P22 Prophages

Hybrid genetic elements, Mud-P and Mud-Q (collectively, Mud-P22s), have been constructed that carry two-thirds of the temperate Salmonella phage P22 genome sandwiched between the ends of transposon Mu. Insertions of these elements in the Salmonella chromosome generate locked-in P22 prophages that cannot excise. Upon induction (as a consequence of the inactivation of P22 c2 repressor), a locked-in prophage replicates its DNA in situ, resulting in the amplification of neighboring regions of the chromosome and the processive packaging of three contiguous headsful of adjacent DNA in one direction from the P22 packaging site, pac. Phage particles in an induced lysate of a Mud-P22 lysogen contain DNA molecules corresponding to several minutes of chromosomal DNA adjacent to the site of prophage insertion and transduce nearby genetic markers with high efficiencies. Mud-P22 prophages have been introduced into an F' episome by transposition; resident Mud insertions on the Salmonella chromosome may be converted to Mud-P22 insertions by homologous recombination in P22-mediated transductional crosses.     

A Quantitative Model for Nonrandom Generalized Transduction, Applied to the Phage P22–SALMONELLA TYPHIMURIUM System

A mathematical model for nonrandom generalized transduction is proposed and analyzed. The model takes into account the finite number of transducing particle classes for any given marker. The equations for estimation of the distance between markers from contransduction frequency data are derived and standard errors of the estimates are given. The obtained relationships depend significantly on the number of classes of transducing fragments. The model was applied to estimate the number of transducing fragment classes for a given marker in transduction with phage P22 of Salmonella typhimurium. It was found that the literature data on frequencies of contransduction in crosses with mutual substitution of selective and nonselective markers can be rationalized most accurately by assuming that the mean number of classes is equal to 2. An improved method for analysis of cotransduction data is proposed on the basis of our model and the results of calculation. The method relies on solving a set of algebraic equations for cotransduction frequencies of markers located within one phage length. The method allows a relatively precise determination of distances between markers, positions of transducing particle ends and deletion or insertion lengths. The approach is applied to the trp-cysB-pyrF and aroC-hisT-purF-dhuA regions of the Salmonella typhimurium chromosome.     

High-resolution restriction map for a 240-kilobase region spanning 91 to 96 minutes on the Salmonella typhimurium LT2 chromosome.

A hierarchical approach allows the completion of contiguous sets of overlapping clones for small regions of a genome, one at a time rather than tackling the whole genome at once. On the basis of the BlnI restriction map for Salmonella typhimurium LT2, we dissected the chromosome into 21 different fragments by using a Tn5 transposon carrying a BlnI site. Dissected chromosomal fragments were purified by pulsed-field gel electrophoresis and used as probes for sorting a lambda DASHII genomic library of 2,304 primary clones. A total of 129 clones identified as spanning the region from 91 min to 98 min were partly ordered on the basis of the intensity of hybridization with mitomycin-induced Mud-P22 phage DNAs from insertions with pac sites in opposite orientations at 93 min used as probes. Decreased signal intensity with the Mud-P22 probes corresponded to the increased distance of the clone from the site of Mud-P22 insertion and allowed the clones to be placed in two groups from 91 min to 93 min and from 93 min to 98 min and into four intensity categories within the two groups. A member of each category was used to generate a riboprobe from the T3 promoter flanking the insert. This probe identified overlapping clones among the 129 clones. This subchromosomal library was then screened again with riboprobes from nonoverlapping clones. After four cycles of this strategy, a minimal contiguous sequence of 19 partly overlapping clones was selected for restriction mapping. A detailed map of 378 sites for eight restriction enzymes is presented for a region of about 240 kb. Working clockwise, the following genes were placed on this physical map on the basis of their restriction maps: malFEK, lamB, malM, lexA, qor, dnaB, alr, uvrA, proP, pmrB, pmrA, melA, melB, phoN, amiB, mutL, and miaA.     

Characterization of lambda cysB and of two derivatives carrying cysB amber mutations

The specialized transducing phage lambda cysB (Borck et al., 1976) was found to carry about 5 kilobases of Escherichia coli DNA. It was shown to have an intact cysB gene but none of the known neighbouring genetic loci. The phage (which is known to be deficient in its site-specific recombination functions) was shown to integrate into the chromosome of bacterial recipients at the cysB locus. Excision from this site occasionally generated recombinant phages that had exchanged their cysB allele for the one originally present in the host. In this way lambda cysB derivatives were prepared from lysogens of two strains carrying the amber mutations cysB242 and cysB257; these phases were proved by several tests to contain the expected cysB amber mutations.     

Genetic analysis in Salmonella typhimurium with a small collection of randomly spaced insertions of transposon Tn10 delta 16 delta 17

We report the isolation of a group of 279 Salmonella typhimurium strains carrying randomly spaced insertions of the minitransposon Tn10 delta 16 delta 17 and describe the use of these strains to facilitate genetic analysis. The insertions were isolated initially in individual recombinant lambda clones from a genomic library. Individual insertions were then moved into the S. typhimurium chromosome, where the distribution of insertion sites relative to standard genetic markers was analyzed in a series of transductional crosses. Since a different, randomly chosen clone was used to generate each insertion, the distribution of insertion positions should have been as random as the cloning events leading to the formation of the library. In agreement with this expectation, most S. typhimurium markers tested were cotransducible with one or more of these Tn10 delta 16 delta 17 insertions. We expect that most new mutations will be quickly classified and mapped by determination of the pattern of cotransduction with this set of insertions. This use is illustrated by the analysis of a group of lac operon fusions regulated by anaerobiosis. We also describe several other applications that should make this collection a useful new tool in S. typhimurium genetics.     

Genetic mapping by duplication segregation in Salmonella enterica

MudP and MudQ elements were used to induce duplications in Salmonella enterica by formation of a triple crossover between two transduced fragments and the host chromosome. The large size (36 kb) of MudP and MudQ is a favorable trait for duplication formation, probably because homology length is a limiting factor for the central crossover. Additional requirements are a multiplicity of infection of 2 or higher in the infecting phage suspensions (which reflects the need of two transduced fragments) and an exponentially growing recipient (which reflects the need of a chromosome replication fork). We describe a set of 11 strains of S. enterica, each carrying a chromosomal duplication with known endpoints. The collection covers all the Salmonella chromosome except the terminus. For mapping, a dominant marker (e.g., a transposon insertion in or near the locus to be mapped) is transduced into the 11-strain set. Several transductants from each cross are grown nonselectively, and haploid segregants are scored for the presence of the marker. If all the segregants contain the transduced marker, it maps outside the duplication interval. If the marker is found only in a fraction of the segregants, it maps within the duplicated region.     

Isolation and Characterization of φ80 Transducing Bacteriophage for a Ribonucleic Acid Polymerase Gene

A new method for isolating specialized transducing phages is described. It was used to isolate a group of phi80 transducing phages which carry various bacterial markers from the metB region of the Escherichia coli chromosome. Some of the phages selected for transduction of the supA36 marker were also shown to carry rif, a locus known to specify the beta subunit of ribonucleic acid polymerase. Expression of the prophage rif(r) gene in lysogens was demonstrated by its ability to confer rifampin resistance on part of the cellular ribonucleic acid polymerase pool.     

A BlnI restriction map of the Salmonella typhimurium LT2 genome.

BlnI or AvrII (5'-CCTAGG) sites are very rare in the Salmonella typhimurium LT2 genome. BlnI was used to construct a physical map which was correlated with the genetic map by using three methods. First, Tn10 carries BlnI sites, and the extra restriction sites produced by 34 genetically mapped Tn10 insertions were physically mapped by using pulsed-field gel electrophoresis. Second, six genetically mapped Mud-P22 prophage insertions were used to assign BlnI fragments. Integration of Mud-P22 introduces 30 kb of DNA that can easily be detected by a "shift up" in all but the largest BlnI fragments. Finally, induced Mud-P22 insertions package more than 100 kb of genomic DNA adjacent to one side of the insertion. Some of the smaller BlnI fragments were localized by hybridization to a dot blot array of 52 lysates from induced Mud-P22 insertions. Of the 10 BlnI sites mapped, 6 probably occur in or near the 16S rRNA genes at about 55, 71, 83, 86, 88.5, and 89.5 min. There is one BlnI site in the 90-kb pSLT plasmid. Two additional BlnI fragments of about 7 and 4 kb have not been localized. The size of the genome was estimated as 4.78 Mb (+/- 0.1 Mb) excluding pSLT but including prophages Fels-1 and Fels-2. One BlnI fragment that maps between 55 and 59 min showed a 40-kb reduction in size in a strain cured of the approximately 40-kb Fels-2 prophage.     

Fine Structure Genetic and Physical Map of the Phage P22 Tail Protein Gene

Bacteriophage P22 which are incapable of making functional tail protein can be propagated by the addition of purified mature tail protein trimers to either liquid or solidified medium. This unique in vitro complementation condition has allowed us to isolate 74 absolute lethal tail protein mutants of P22 after hydroxylamine mutagenesis. These phage mutants have an absolute requirement for purified P22 tail protein to be present in a soft agar overlay in order to form plaques and do not grow on any nonsense suppressing strains of Salmonella typhimurium. In order to genetically map and physically locate these mutations we have constructed two complementary sets of fine structure deletion mapping strains using a collection of Tn1 insertions in gene 9, the structural gene for the tail protein. Fourteen bacteriophage P22 strains carrying unique Tn1 transposon insertions (Ap phage) in gene 9 have been crossed with Ap phage carrying Tn1 insertions in gene 20. Phage carrying deletions that arose from homologous recombination between the Tn1 elements were isolated as P22 lysogens. The deletion prophage were shown to be missing all genetic information bracketed by the parental Tn1 elements and thus form a set of deletions into gene 9 from the 5' end of the gene. From the frequency of production of these deletion phage the orientation of the Tn1 insertions in gene 9 could be deduced. The genetic end points of the deletions in gene 9 and thus the order of Tn1 insertions were determined by marker rescue experiments using the original Ap phage. The genetic end points of the deletions in gene 20 were determined in similar experiments using nonsense mutations in gene 20. To locate the physical end points of these deletions in gene 9, DNA containing the Tn1 element has been cloned from each of the original Ap phage into plasmids. The precise point of insertion of Tn1 into gene 9 was determined by restriction enzyme mapping and DNA sequencing of the relevant portions of each of these plasmids. In vitro deletion of different 3' gene 9 sequences in the plasmid clones was accomplished through the use of unique restriction endonuclease sites in Tn1. The resulting plasmids form a set of deletions extending into the 3' end of the gene which are complementary compared to the deletion lysogens.(ABSTRACT TRUNCATED AT 400 WORDS)     

Gal transduction by phage lambda: on the origin and nature of LFT transducing genomes

Summary There are at least two classes of transducing particles made on the induction of normal lysogens: the first is capable of transducing by the insertion of the whole transducing genome into the host chromosome, so its genome must be capable of circularizing; the second transduces less well by insertion—perhaps not at all; if it does not transduce by insertion then its genome need not be linear.The formation of a transducing genome can be accomplished in three steps: (a) breaking the lysogenic bacterial chromosomes in two places, (b) joining the fragment ends together to form a circular structure, (c) opening the circle (by ter) to form a linear genome. If the resultant structure meets the requirements for packaging, it may be formed into a transducing phage, like a bougus .Any meaningful rearrangement of these steps in which step (b) is omitted or delayed leads to the formation of genomes, which are (1) unable to transduce by insertion (because both of its mature ends are unexposed) and (2) are on the average smaller than genomes which are capable of transducing by insertion (so the resultant transducing phage is less dense). Consequence (2) has been confirmed.We assume that the red function of catalyzes the joining of broken DNA molecules to each other. So red is responsible for rehealing the product of (a) back into a lysogenic chromosome and for catalyzing step (b), the healing of fragment ends into a circular structure. The much elevated level of stable transductants on induction of red ^– lysogens hereby is explained.Supported by grant E-2862 of the U.S.P.H.S. to Dr. Allan Campell.     

Incorporation of phi80 phage into unusual chromosome sites and isolation of a specialized transducing bacteriophage]

The mutant strain KS713 of Escherichia coli K-12 deleted for the normal insertion site and secondary preferable one was obtained. The insertion frequency of phage phi80 into the double deletion strain is reduced about 30-fold with respect to integration into the strain H47 with deletion of the primary phi80 attachment site and about 500-fold relative to integration into wild type Escherichia coli. Analysis of the rare abnormal lysogens of KS 713 strain indicates that there are secondary sites on the chromosome, which are utilized for prophage attachment if insertion at preferable secondary att80-II site is eliminated too. The insertion of phi80 phage into the bfe locus was obtained by the appropriate selection technique. Induced prophage excision from the bfe site was rather efficient and lysates contained phi80 phage particles that could specificically transduce the argH+ gene. Upon transduction into a recipient strain carrying recA, heterogenotes harbouring both the wild-type and the mutant argH genes were isolated. These heterogenotes were used for producing high-frequency transducing lysates.     

A Salmonella Phage-P22 Mutant Defective in Abortive Transduction

In the course of a lytic infection the Salmonella phage P22 occasionally encapsulates bacterial DNA instead of phage DNA. Thus, phage lysates include two classes of viral particles. Phage particles carrying bacterial DNA are referred to as transducing particles and deliver this DNA to a host as efficiently as particles carrying phage DNA. Once injected, the transduced DNA can either recombine with the recipient chromosome to form a ``complete'''' transductant, or it can establish itself as an expressible, nonreplicating genetic element and form an ``abortive'''' transductant. In this work, we describe a P22-phage mutant with reduced ability to form abortive transductants. The mutation responsible for this phenotype, called tdx-1, was found as one of two mutations contributing to the high-transducing phenotype of the P22-mutant HT12/4. In addition, the tdx-1 mutation is lethal when combined with an erf-am mutation. The tdx-1 mutation has been mapped to a region of the P22 genome that encodes several injected proteins and may involve more than one mutant locus. The phenotypes of the tdx-1 mutation suggest that the Tdx protein(s) normally assist in the circularization of the P22 genome and also contribute to the formation of DNA circles thought to be required for abortive transduction.     

Prophage map of converting corynebacteriophage beta.

A prophage map for corynebacteriophage beta consisting of seven markers has been constructed and compared with the vegetative map. The mapping system utilizes heteroimmune double lysogens and capitalizes on the fact that these double lysogens are very unstable and throw off monolysogenic segregants. The prophage map, produced by characterizing the recombinant phage in these monolysogenic segregants, appears to be a cyclic permutation of the vegetative map with the gene for toxin at one end of the prophage map and the gene for phage immunity at the other. This permutation is in accord with the Campbell model for insertion of lambda phage if a site between the toxin and immunity genes in the vegetative map is designated as the phage attachment site. The position of the gene for toxin in the prophage map suggests that converting phages may have originated as specialized transducing phages for this gene.     

A Novel P22 Prophage in Salmonella typhimurium

Under several sets of conditions, all of which seem to perturb purine metabolism, Salmonella typhimurium releases a variety of phages which were not known to be present in the strain. These cryptic phages are not induced by UV irradiation. Furthermore, the induction process does not require a functional recA gene product. While phages of several phenotypic classes have been recovered, including both turbid and clear plaque formers, all appear to be variants of P22 because all show DNA restriction patterns indistinguishable from that of P22. The variety of types suggests that the cryptic prophage is mutagenized as a consequence of the induction process. All the temperature phages tested are capable of transducing a variety of chromosomal markers with high efficiency. The phages induced in this novel way are capable of forming plaques on the strains that gave rise to them. Since the strains releasing phage are not immune to P22, the parental lysogens must not express immunity and the phage must be held in a cryptic state by a novel mechanism. The released phage possess an intact P22 immunity system because many can form standard immune lysogens after reinfection of Salmonella. These results raise the possibility that Salmonella typhimurium harbors cryptic phages that are subject to a novel system of global control related to purine metabolism. Preliminary evidence suggests that the regulation system may involve DNA modification.     

Characterization of SE1, a new general transducing phage of Salmonella typhimurium

A transducing phage, SE1, which is able to infect Salmonella typhimurium was isolated from a Salmonella enteritidis strain. SE1 is a temperate phage which is heteroimmune with respect to phages P22, L, KB1 and ES18. It is similar in morphology and size to phages P22, L and KB1 and is serologically related to phages P22 and L but not to KB1. Efficiencies of generalized transduction effected by phage SE1 are similar to those for P22HT (int7), a mutant which mediates a high frequency of chromosomal gene transduction. The lengths of chromosomal DNA transduced by SE1 and P22HT (int7) are similar. Furthermore, the SE1 prophage does not exclude the transducing particles from cells it has lysogenized; consequently it is possible to use both SE1 lysogens and non-lysogenic strains as recipients in SE1-mediated transduction experiments, and obtain similar transduction efficiencies. However, the SE1 prophage gives rise to a lysogenic conversion that decreases the rate of adsorption of SE1 and L phages by about 50%, but does not affect adsorption of P22. Altogether these results suggest that phage SE1 may be a useful tool in the genetic manipulation of S. typhimurium.     

Nonsense and insertion mutants in the relA gene of E. coli: cloning relA.

We have made use of lysogens of a specialized transducing bacteriophage, lambdapyrG+ relA+, to select nonsense (relAnon) and insertion (relAins) mutations in the relA gene. Three independent relAnon mutants were isolated on the phage. In all three, the relaxed phenotype was suppressed by supD, supE, supF or sup6. Three independent relAins mutants were isolated, all containing an insertion element (probably IS2) in an apparently identical location in the relA gene. Polyacrylamide gel electrophoretic analysis of peptides synthesized by the phages in ultraviolet lightkilled host cells revealed that no stringent factor was coded for by either the relAins or relAnon phages (the latter in a sup+ cell); stringent factor was detected when the relAnon phages were used in a similar experiment with supD or supE host cells. The relAnon and relAins mutations could be crossed in haploid form in the E. coli chromosome. These recombinants grew with a normal doubling time, had a ppGpp pool which was between 70 and 100% compared with the classical relA strain, and underwent a normal carbon source shift-down. A restriction endonuclease map of the pyrG relA region of the specialized transducing phage is presented in which the position of the insertion element (recognized by a novel Hind III-cut site) defines the position of the relA gene. This position was verified by an analysis of the structure of five plasmids formed by cloning portions of the region in the pBR322 cloning vehicle. Our results indicate that the relA gene is not an essential cellular function, that there might be a second mechanism for the synthesis of basal level ppGpp in the cell and that the sole function of the relA gene is apparently the high level ppGpp synthesis triggered in response to deacylated tRNA.     

Lethal Transposition of Mud Phages in Rec(-) Strains of Salmonella Typhimurium

Under several circumstances, the frequency with which Mud prophages form lysogens is apparently reduced in rec strains of Salmonella typhimurium. Lysogen formation by a MudI genome (37 kb) injected by a Mu virion is unaffected by a host rec mutation. However when the same MudI phage is injected by a phage P22 virion, lysogeny is reduced in a recA or recB mutant host. A host rec mutation reduces the lysogenization of mini-Mu phages injected by either Mu or P22 virions. When lysogen frequency is reduced by a host rec mutation, the surviving lysogens show an increased probability of carrying a deletion adjacent to the Mud insertion site. We propose that the rec effects seen are due to a failure of conservative Mu transposition. Replicative Mud transposition from a linear fragment causes a break in the host chromosome with a Mu prophage at both broken ends. These breaks are lethal unless repaired; repair can be achieved by Rec functions acting on the repeated Mu sequences or by secondary transposition events. In a normal Mu infection, the initial transposition from the injected fragment is conservative and does not break the chromosome. To account for the conditions under which rec effects are seen, we propose that conservative transposition of Mu depends on a protein that must be injected with the DNA. This protein can be injected by Mu but not by P22 virions. Injection or function of the protein may depend on its association with a particular Mu DNA sequence that is present and properly positioned in Mu capsids containing full-sized Mu or MudI genomes; this sequence may be lacking or abnormally positioned in the mini-Mud phages tested.     

Cloning and mapping of the manganese superoxide dismutase gene (sodA) of Escherichia coli K-12.

An Escherichia coli gene bank composed of large DNA fragments (about 40 kilobases) was constructed by using the small cosmid pHC79. From it, a clone was isolated for its ability to overproduce superoxide dismutase. The enzyme overproduced was manganese superoxide dismutase, as determined by electrophoresis and antibody precipitation. Maxicell analysis and two-dimensional O'Farrell polyacrylamide gel electrophoresis demonstrated that the structural gene, sodA, of manganese superoxide dismutase was cloned. Subcloning fragments from the original cosmid located the sodA gene within a 4.8-kilobase EcoRI-BamHI fragment. This fragment was inserted into a lambda phage which was deleted for the att region and consequently could only lysogenize by recombination between the cloned bacterial DNA insertion and the bacterial chromosome. Genetic mapping of the prophage in such lysogens indicated that the chromosomal sodA locus lies near 87 min on the E. coli map.