Nature of Lactose-fermenting Salmonella Strains Obtained from Clinical Sources

Six of seven lactose-fermenting (lac(+)) Salmonella strains obtained from clinical sources were found to be capable of transferring the lac(+) property by conjugation to Salmonella typhosa WR4204. All of the six S. typhosa strains which received the lac(+) property transferred it in turn to S. typhimurium WR5000 at the high frequencies typical of extrachromosomal F-merogenotes. These six lac elements were also transmissible from S. typhosa WR4204 to Proteus mirabilis and to some strains of Escherichia coli K-12; moreover, they were capable of promoting low frequency transfer of chromosomal genes from S. typhimurium WR5000 to S. typhosa WR4204. One of these lac elements was shown also to be capable of promoting low frequency chromosome transfer in E. coli K-12. E. coli K-12 strains harboring these lac elements exhibited sensitivity to the male specific phage R-17. Sensitivity to R-17 was not detected in Salmonella strains containing the elements. Examination of the lac elements in P. mirabilis by cesium chloride density gradient centrifugation showed that each element had a guanine plus cytosine content of 50%. The sizes of the elements varied from 0.8 to 3% of the total Proteus deoxyribonucleic acid. The amount of beta-galactosidase produced by induced and uninduced cultures of S. typhimurium WR5000 and S. typhosa WR4204 containing the lac elements was lower than that produced by these strains with the F-lac episome. The heat sensitivity of beta-galactosidase produced by the lac elements in their original Salmonella hosts indicated that the enzyme made by these strains differs from E. coli beta-galactosidase.     

Intergeneric conjugational hybridization of Escherichia coli and Salmonella typhimurium. 1. Obtaining a salmonella hybrid possessing greater recipient activity in crosses with Escherichia coli]

Intergeneric hybrids were selected from mating HfrH Escherichia coli with F- Salmonella typhimurium. The hybrid obtained from E. coli leu+ and pro+ genes possessed the increased recipient ability in the mating with E. coli HfrR1 (O--ilv--metE--ara). This hybrid lacked the ability to restrict the phage P1 DNA propagated on E. coli K-12. The replacement of mutated uvrA gene of Salmonella for uvrA+ gene of E. coli restore uvr+ phenotype of Salmonella mutant.     

Genetic Transfer of Salmonella typhimurium and Escherichia coli Lipopolysaccharide Antigens to Escherichia coli K-12

Escherichia coli K-12 varkappa971 was crossed with a smooth Salmonella typhimurium donor, HfrK6, which transfers early the ilv-linked rfa region determining lipopolysaccharide (LPS) core structure. Two ilv(+) hybrids differing in their response to the LPS-specific phages FO and C21 were then crossed with S. typhimurium HfrK9, which transfers early the rfb gene cluster determining O repeat unit structure. Most recombinants selected for his(+) (near rfb) were agglutinated by Salmonella factor 4 antiserum. Transfer of an F' factor (FS400) carrying the rfb-his region of S. typhimurium to the same two ilv(+) hybrids gave similar results. LPS extracted from two ilv(+),his(+), factor 4-positive hybrids contained abequose, the immunodominant sugar for factor 4 specificity. By contrast, his(+) hybrids obtained from varkappa971 itself by similar HfrK9 and F'FS400 crosses were not agglutinated by factor 4 antiserum, indicating that the parental E. coli varkappa971 does not have the capacity to attach Salmonella O repeat units to its LPS core. It is concluded that the Salmonella rfb genes are expressed only in E. coli varkappa971 hybrids which have also acquired ilv-linked genes (presumably rfa genes affecting core structure or O-translocase ability, or both) from a S. typhimurium donor. When E. coli varkappa971 was crossed with a smooth E. coli donor, Hfr59, of serotype O8, which transfers his early, most his(+) recombinants were agglutinated by E. coli O8 antiserum and lysed by the O8-specific phage, Omega8. This suggests that, although the parental E. coli K-12 strain varkappa971 cannot attach Salmonella-specific repeat units to its LPS core, it does have the capacity to attach E. coli O8-specific repeat units.     

Isolation of Circular Deoxyribonucleic Acid from Salmonella typhosa Hybrids Obtained from Matings with Escherichia coli Hfr Donors

Heterozygous, partial diploid Salmonella typhosa hybrids obtained from matings with Escherichia coli K-12 Hfr strains were observed to contain supercoiled, circular deoxyribonucleic acid (DNA) when examined by the dye-buoyant density method. Examination of one such S. typhosa hybrid after its loss, by segregation, of the inherited E. coli genetic markers revealed a concurrent loss of its supercoiled circular DNA. Subsequent remating of this segregant with various E. coli Hfr strains resulted in the reappearance of the circular DNA. Molecular weight determinations of circular DNA molecules isolated from a number of S. typhosa partial diploid hybrids were made by sucrose density gradient ultracentrifugation and electron microscopy. These studies revealed a range of molecular sizes among the various hybrids examined, but each hybrid exhibited only a single characteristic size for its contained circular DNA. The range of size is consistent with the presence in each hybrid of a different length of E. coli chromosome. It was concluded that the E. coli Hfr genetic segments transferred to these S. typhosa hybrids were conserved, in the diploid state, in the form of supercoiled, circular DNA molecules.     

Behavior of Coliphage Lambda in Shigella flexneri 2a

The insensitivity of wild-type Shigella flexneri 2a to coliphage lambda is a consequence of its native genetic defect in the malA gene cluster. The "smooth" S. flexneri 2a lipopolysaccharide layer affects the efficient adsorption of lambda. Derivatives, capable of serving as functional hosts for lambda, were obtained by repairing the malA lesion, enabling the expression of the malB-lambdarcp region of S. flexneri. Introduction of a mutation into S. flexneri causing a "rough" lipopolysaccharide character resulted in more efficient adsorption of lambda. Such S. flexneri hosts can be stably lysogenized and upon induction yield gal(+)-transducing lysates. Lambda propagated on a malA(+) rough S. flexneri host was restricted by Escherichia coli K-12 and E. coli B, but not by E. coli C. This S. flexneri host did not restrict lambda grown on these E. coli strains.     

Conservation and transfer of Escherichia coli genetic segments by partial diploid Hfr strains of Salmonella typhosa

Heterozygous, partial diploid hybrids were obtained in a Salmonella typhosa Hfr strain by using it as the recipient in a mating with the Escherichia coli Hfr donor WR2004 (O...proA...leu). Three of these S. typhosa Hfr hybrids were observed to mobilize and transfer the diploid E. coli genes, at high frequencies, to an E. coli recipient. The gradient of transfer frequencies of E. coli markers from these S. typhosa Hfr hybrids was similar to that observed with E. coli Hfr WR2004, from which they were derived. Interrupted matings with one of these S. typhosa Hfr hybrids, designated WR4272, showed the entry times for the proA, thr(-)leu, and argB E. coli diploid markers to be identical to the times obtained for these markers with E. coli Hfr WR2004. Also, the pattern of unselected inheritance of the diploid E. coli markers of S. typhosa Hfr hybrid WR4272 was similar to that observed with the chromosomal markers of E. coli Hfr WR2004. It was concluded that S. typhosa Hfr hybrid WR4272 contains, in addition to its Salmonella genome, a physically continuous E. coli chromosomal segment which is genetically complete from proA to at least the strA locus. The two other S. typhosa Hfr hybrids, on the basis of transmission frequency gradients, appeared to contain a continuous E. coli diploid segment complete from proA through the fuc locus. Other classes of S. typhosa Hfr hybrids, derived from mating with E. coli Hfr WR2010 (O...tna...xyl), were also observed to transfer E. coli genes at high frequency.     

Inefficiency of genetic recombination in hybrids between Escherichia coli and Salmonella typhosa

An Escherichia coli Hfr strain in which three negative chromosomal alleles (leu(-), arg(-), and mtl(-)) were closely linked to three positive alleles (ara(+), rha(+), and xyl(+), respectively) was employed in matings with a Salmonella typhosa recipient. The detected expression of the negative E. coli alleles in S. typhosa hybrids selected for receipt of an associated positive E. coli marker was used to determine the occurrence of haploid S. typhosa recombinants, as distinguished from stable partial diploid hybrids. At the same time, the inheritance patterns and segregation behavior of the positive alleles provided indicators of the occurrence of partial diploid hybrids. Examination of both positive and negative markers inherited by ara(+), rha(+), and xyl(-) selected S. typhosa hybrid classes indicated that relatively short E. coli chromosomal segments (generally about 4 min or less in length) were involved in recombination (haploidy), whereas rather extensive E. coli genetic segments were conserved in the diploid state. S. typhosa hybrids selected for receipt of the ara(+) marker showed a 52% incidence of leu(-) haploidy, which is probably close to being an accurate measure of recombination at the site of the ara(+) allele. S. typhosa hybrids selected for receipt of the rha(+) or xyl(+) markers showed only a 20% incidence of arg(-) or mtl(-) haploidy, respectively, but both of these hybrid classes exhibited a higher incidence of conservation of extensive E. coli diploid segments than did the ara(+) selected class. Remating of haploid S. typhosa hybrids with recombinant xyl(+)mtl(-) or rha(+)arg(-) regions resulted in higher frequencies of hybrid recovery than were observed in the initial matings. However, there was a higher incidence of partial diploidy and a lower incidence of haploidy among the hybrids obtained from these rematings.     

Chromosomal relocation of prophage-associated bacterial genes

Taylor, M. W. (Stanford University, Stanford, Calif.), and C. Yanofsky. Chromosomal relocation of prophage-associated bacterial genes. J. Bacteriol. 91:1469-1476. 1966.-Two distinguishable colony types, rough-edged and smooth-edged, were observed when tryptophan auxotrophs of Escherichia coli were transformed to tryptophan independence with DNA from the hybrid nondefective transducing phage i(lambda)h(phi80)T(1) (S)tryp A(+)B(+), and with the helper phage lambdai(434). P1kc transduction experiments with cells of the two types of colonies as genetic donors showed that the i(lambda)h(phi80)T(1) (S)tryp A(+)B(+) prophage was located at different regions of the E. coli chromosome. In cells of rough-edged colonies, the prophage was linked to the tryp-cys region, its normal location, whereas in cells of smooth-edged colonies the prophage was associated with the gal region. When transformation experiments were performed with a T(1) (R)tryp(-) deletion mutant as recipient, and phage lambdai(434) as helper, prophage localization was only detected at the gal region. Localization of (lambda)h(phi80)T(1) (S)tryp A(+)B(+) prophage near gal does not appear to be due to the formation of a recombinant phage carrying tryp A(+)B(+), but is due to some type of interaction between the genomes of i(lambda)h(phi80)T(1) (S)tryp A(+)B(+) and the helper phage. When conditions comparable to those used in transformation studies were employed in transduction experiments, including the use of helper phage, two classes of transductants with either cys or gal linkage were also observed. To examine whether the location of the prophage on the E. coli chromosome had any effect on the ability of the prophage-associated tryp A(+) and tryp B(+) genes to function or respond to different repression conditions, specific activities of the A and B subunits of tryptophan synthetase specified by the phage genome were measured. Similar values were obtained regardless of the location of the prophage-associated tryp genes. Furthermore, the prophage-associated tryp genes, free from their normal operator region, permitted enzyme formation which was unaffected by repression or derepression conditions.     

Cloning and characterization of recA genes froM Proteus vulgaris, Erwinia carotovora, Shigella flexneri, and Escherichia coli B/r

The recA genes of Proteus vulgaris, Erwinia carotovora, Shigella flexneri and Escherichia coli B/r have been isolated and introduced into Escherichia coli K-12. All the heterologous genes restore resistance to killing by UV irradiation and the mutagen 4-nitroquinoline-1-oxide in RecA- E. coli K-12 hosts. Recombination proficiency is also restored as measured by formation of Lac+ recombinants from duplicated mutant lacZ genes and the ability to propagate phage lambda derivatives requiring host recombination functions for growth (Fec-). The cloned heterologous genes increase the spontaneous induction of lambda prophage in lysogens of a recA strain. Addition of mitomycin C stimulates phage production in cells carrying the E. coli B/r and S. flexneri recA genes, but little or no stimulation is seen in cells carrying the E. carotovora and P. vulgaris recA genes. After treatment with nalidixic acid, the heterologous RecA proteins are synthesized at elevated levels, a result consistent with their regulation by the E. coli K-12 LexA repressor. Southern hybridization and preliminary restriction analysis indicate divergence among the coding sequences, but antibodies prepared against the E. coli K-12 RecA protein cross-react with the heterologous enzymes, indicating structural conservation among these proteins.     

Leakiness of Pleiotropic Maltose-negative, Bacteriophage λ-resistant Mutants of Escherichia coli K-12

Cultures of Escherichia coli K-12 malA(-)lambda(r)gal(-) can be transduced to gal(+) by bacteriophage lambdadg because of leakiness of the lambda(r) phenotype. The efficiency of such transduction is about 10(-5) that of transduction of mal(+)lambda(s) bacteria. Leaky cells (lambda(s)phenocopies) adsorb only very few phage particles, and many transductants, therefore, are defective heterogenotes or show integration of the gal(+) gene, which is unaccompanied by lysogenization.     

Occurrence of the bacteriophage lambda receptor in some enterobacteriaceae.

In Escherichia coli K-12, the receptor for phage lambda is an outer membrane protein which inactivates the phage in vitro. Lambda receptor activity was found in extracts from all wild strains of E. coli tested, although most of them fail to support growth of the phage. In some cases this failure is due to a masking of the receptor in vivo, the bacteria being unable to adsorb the phage or to react with antireceptor antibodies. In other cases, adsorption does occur, and the nature of the block in phage growth was not investigated. Most Mal+ strains of Shigella have lambda receptor, whereas most Mal- strains do not have it. Synthesis of the lambda receptor in Shigella is thus presumably controlled by the positive regulator gene of the maltose regulon as is the case in E. coli K-12. Phage lambda adsorbs on many Mal+ strains of Shigella and even yields plaques on some of them, although at a low frequency. No lambda receptor activity could be found in extracts of several strains of Salmonella and Levinea.     

EPISOMIC ELEMENT IN A STRAIN OF SALMONELLA TYPHOSA.

Falkow, Stanley (Walter Reed Army Institute of Research, Washington, D.C.) and L. S. Baron. Episomic element in a strain of Salmonella typhosa. J. Bacteriol. 84:581-589. 1962.-An episomic element, F(0)-lac(+), has been identified in a strain of Salmonella typhosa isolated from a natural habitat. The F(0)-lac(+) element is transferred at high frequency as a single unit of transmission and replication without linkage to any other genetic character. Cells receiving F(0)-lac(+) are heterogenotes as if F(0)-lac(+) is not integrated as part of the linear structure of the chromosome, but rather replicates autonomously or in some other association with the genome. Evidence from complementation tests and transduction experiments is presented that the lac genes carried by F(0) are identical or at least markedly similar to the lac genes of Escherichia coli K-12. The F(0) transmission factor cannot be precisely identified but it does not appear to be phage or colicin. F(0) does exhibit mutual repression with the sex factor, F, of E. coli, and immunological experiments indicate some relationship between F and F(0).     

Temperature Sensitivity of Maltose Utilization and Lambda Resistance in Escherichia coli B

Escherichia coli B strains that have acquired the malB region from E. coli K-12 are able to utilize maltose and to adsorb phage lambda when grown at 30 C, but when grown at 40 C they do not absorb phage lambda and are devoid of amylomaltase activity. These Mal(ts) Lam(ts) cells can be mutated or transduced to become able to grow on maltose at 40 C, but they still have no detectable amylomaltase activity nor functional lambda receptors at that temperature. This Mal(40) phenotype is governed by a gene located near or at malA. It is suggested that the temperature sensitivity of both characters results from a defect in malT. However, transduction of malA from E. coli B to E. coli K-12 results in a wild-type phenotype, whereas E. coli B cells that have acquired malA from E. coli K-12 donors are still temperature sensitive for both amylomaltase and lambda-receptor production.     

Lytic Replication of Coliphage Lambda in Salmonella typhosa Hybrids

Hybrids between Escherichia coli K-12 and Salmonella typhosa which conserved a continuous K-12 chromosomal diploid segment extending from pro through ara to the strA locus were sensitive to plaque formation by wild-type λ. These partially diploid S. typhosa hybrids could be lysogenized with λ and subsequently induced to produce infectious phage particles. When the K-12 genes were segregated from a lysogenic S. typhosa hybrid, phage-productive ability was no longer detectable due to loss of a genetic region necessary for vegetative replication of λ. However, λ prophage was shown to persist in a quiescent state in the S. typhosa hybrid segregant with phage-productive ability being reactivated after replacement of the essential K-12 λ replication region. Low-frequency transduction and high-frequency transduction lysates containing the gal⁺ genes of S. typhosa were prepared by induction of λ-lysogenic S. typhosa hybrids indicating that the attλ site is chromosomally located in S. typhosa in close proximity to the gal locus as in E. coli K-12. After propagation in S. typhosa hybrids, λ was subject to restriction by E. coli K-12 recipients, thus establishing that S. typhosa does not perform the K-12 modification of λ deoxyribonucleic acid. Hybrids of S. typhosa, however, did not restrict λ grown previously on E. coli K-12. The K-12 genetic region required for λ phage production in S. typhosa was located within min 66 to min 72 on the genetic map of the E. coli chromosome. Transfer of an F-merogenote encompassing the 66 to 72 min E. coli chromosomal region to λ-insensitive S. typhosa hybrids enabled them to replicate wild-type λ. The λ-insensitive S. typhosa hybrid, WR4255, which blocks λ replication, can be mutagenized to yield mutant strains sensitive to λvir and λimm434. These WR4255 mutants remained insensitive to plaque formation by wild-type λ.     

Effect of Lysogeny on Serum Sensitivity

When Escherichia coli K-12 was infected with lambda phage and mutants of lambda characterized by the production of temperature-sensitive repressors, the lysogenic bacteria were significantly more resistant to normal serum than the uninfected organisms. Infection of E. coli K-12 with a lambdoid phage, phi80, whose prophage attachment site is different from that of lambda, did not result in a detectable change in serum resistance. Similarly, infection with certain Pseudomonas and Shigella phages caused no detectable differences in serum resistance. Finally, the well-known conversion of the Salmonella anatum serotype to S. newington by E(15) phage indicated that, despite the relatively greater roughness of S. anatum, S. newington was more sensitive to normal serum than S. anatum. Thus, the effects of lysogeny on the sensitivity of bacteria to the bactericidal action of serum mediated by the complement system may be quite variable.     

Cloning of the ADPglucose pyrophosphorylase (glgC) and glycogen synthase (glgA) structural genes from Salmonella typhimurium LT2.

The structural genes of ADPglucose pyrophosphorylase (glgC) and glycogen synthase (glgA) from Salmonella typhimurium LT2 were cloned on a 5.8-kilobase-pair insert in the SalI site of pBR322. A single strand specific radioactive probe containing the N terminus of the Escherichia coli K-12 glgC gene in M13mp8 was used to hybridize against a S. typhimurium genomic library in lambda 1059. DNA from a plaque showing a positive hybridization signal was isolated, subcloned into pBR322, and transformed into E. coli K-12 RR1 and E. coli G6MD3 (a mutant with a deletion of the glg genes). Transformants were stained with iodine for the presence of glycogen. E. coli K-12 RR1 transformants stained dark brown, whereas G6MD3 transformants stained greenish yellow, and they both were shown to contain a 5.8-kilobase-pair insert in the SalI site of pBR322, designated pPL301. Enzyme assays of E. coli K-12 G6MD3 harboring pPL301 restored ADPglucose pyrophosphorylase and glycogen synthase activities. The specific activities of ADPglucose pyrophosphorylase and glycogen synthase in E. coli K-12 RR1(pPL301) were increased 6- to 7-fold and 13- to 15-fold, respectively. Immunological and kinetic studies showed that the expressed ADPglucose pyrophosphorylase activity in transformed E. coli K-12 G6MD3 cells was very similar to that of the wild-type enzyme.     

Diploidy for a structural gene specifying a major protein of the outer cell envelope membrane from Escherichia coli K-12.

Homogenotes, heterogenotes, and intergeneric hybrids have been studied that are diploid for the structural gene of a major outer cell envelope membrane protein (protein II) from Escherichia coli. This protein can act as a phage receptor. In wild-type homogenotes, diploidy for the gene did not cause a gene dosage effect. It could be shown with two heterogenotes that both the chromosomal mutant and the episomal wild-type genes are expressed, and in each case more of the mutant than the wild-type protein species was found in the cell envelope. In on case of 21 phage-resistant mutants missing protein II was a trans effect observed of the mutant gene on the expression of the episomal wild type gene. Transfer of E. coli episomes carrying the protein II structural gene into Salmonella typhimurium and Proteus mirabilis resulted in intergeneric hybrids that became sensitive to the relevant phage and harbored the E. coli protein II in their cell envelopes. The results may be taken as suggestive evidence for a simple feedback mechanism for the regulation of synthesis of protein II, and they show that there are no highly specific requirements on protein primary structure for incorporation into an outer cell envelope membrane.     

Interaction between the Sbcc Gene of Escherichia Coli and the Gam Gene of Phage λ

gam mutants of phage lambda carrying long palindromes fail to form plaques on wild-type Escherichia coli but do grow on strains that are mutant in the sbcC gene. gam + lambda carrying the same palindrome grow on both hosts and on a host deleted for the recB, C and D genes. These results suggest that the Gam protein of lambda, known to interact also with E. coli's recBCD protein, can interact with the product of the sbcC gene.     

Chromosomal Location of Ribosomal Protein Cistrons Determined by Intergeneric Bacterial Mating

Intergeneric mating between Escherichia coli and Salmonella typhosa was used to locate at least three 30S ribosomal proteins near the streptomycin locus in the region of 54 to 66 min of the E. coli map. This procedure utilizes differences in the electrophoretic patterns of 30S ribosomal protein of the parents. The results show that cistrons for 30S proteins of E. coli can replace those of S. typhosa in the Salmonella genome. Moreover, in a diploid hybrid with a Salmonella endogenote and an E. coli exogenote, both sets of cistrons are expressed.     

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.