System for Detecting Inducers of Lysogenic Escherichia coli W1709(λ) and Its Applicability as a Screen for Antineoplastic Antibodies

Studies were conducted to determine conditions of maximal sensitivity for a test system designed to detect chemical inducers of phage production in the streptomycin-dependent, lysogenic Escherichia coli strain W1709(λ). This strain was found to be induced by all antibiotics previously reported to be inducers of E. coli K-12(λ). However, the system employing W1709(λ) proved superior for screening fermentation filtrates because its growth, in contrast to that of K-12(λ), was not stimulated during the induction period by filtrate nutrients. Thus, misleading high phage counts, which accompany cell growth stimulation, were not produced by filtrates devoid of inducing activity. The inducing capability of 95 fermentation filtrates, each containing an unidentified antibiotic(s) inhibitory for one or more transplanted rodent tumors, was determined in the W1709(λ) system. A low incidence of inducers was found among inhibitors of sarcoma 180, adenocarcinoma 755, solid myeloid leukemia C1498, and adenocarcinoma of the duodenum in the hamster. However, seven of eight filtrates active against leukemia 1210 had induction capability. From a screen of actinomycete culture filtrates, 28 of the first 1,000 were identified as producers of induction activity. Thus far, of the nine cultures from this group that were subjected to examination, eight demonstrated at least presumptive evidence of antineoplastic activity.     

Deoxyribonucleic Acid Replication in λ Bacteriophage Mutants

After ultraviolet light induction of Escherichia coli K-12 strain W3350(λ), several structural intermediate forms of phage deoxyribonucleic acid (DNA) are synthesized. The early defective lysogens of λ, sus O₈, sus P₃, and T₁₁, were found to synthesize none of the DNA structural intermediates. A lysogen believed to be defective in all known phage activities, λsus N₇, was found to be able to synthesize an early phage DNA intermediate. The lysogen λsus Q₂₁, defective in late phage functions, is able to synthesize the early phage DNA intermediate and a concatenated molecule of greater molecular weight than the mature λ DNA.     

Molecular Mechanism of Heat Shock-Provoked Disassembly of the Coliphage λ Replication Complex

We have found previously that, in contrast to the free O initiator protein of λ phage or plasmid rapidly degraded by the Escherichia coli ClpP/ClpX protease, the λO present in the replication complex (RC) is protected from proteolysis. However, in cells growing in a complete medium, a temperature shift from 30 to 43°C resulted in the decay of the λO fraction, which indicated disassembly of RC. This process occurred due to heat shock induction of the groE operon, coding for molecular chaperones of the Hsp60 system. Here we demonstrate that an increase in the cellular concentration of GroEL and GroES proteins is not in itself sufficient to cause RC disassembly. Another requirement is a DNA gyrase-mediated negative resupercoiling of λ plasmid DNA, which counteracts DNA relaxation and starts to dominate 10 min after the temperature upshift. We presume that RC dissociates from λ DNA during the negative resupercoiling, becoming susceptible to the subsequent action of GroEL/S and ClpP/ClpX proteins. In contrast to λcro⁺, in λcro⁻ plasmid-harboring cells, the RC reveals heat shock resistance. After temperature upshift of the λcrots plasmid-harboring cells, a Cro repressor-independent control of λ DNA replication and heat shock resistance of RC are established before the period of DNA gyrase-mediated negative supercoiling. We suggest that the tight binding of RC to λ DNA is due to interaction of RC with other DNA-bound proteins, and is related to the molecular basis of the λcro⁻ plasmid replication control.     

Properties of Mitomycin C-sensitive Mutants of Escherichia coli K-12

Strains hypersensitive to mitomycin C (MC) were isolated from Escherichia coli K-12 after treatment with nitrosoguanidine. Of 43 MC-sensitive strains tested for their ultraviolet light (UV) sensitivity and for their ability to reactivate UV-inactivated λ phage, 38 were found to be insensitive to UV irradiation and to be able to reactivate UV-irradiated bacteriophage λ. Some properties of the MC-sensitive, uvr⁺ mutants were analyzed. Synthesis of deoxyribonucleic acid (DNA) in MC-sensitive, uvr⁺ mutants was inhibited at a lower concentration of MC than in the wild-type strain. Mutant cells, labeled with ³H-thymidine and then exposed to MC, released radioactivity as low molecular weight compounds. The amount of radioactivity released was the same as that from the wild-type strain. MC-sensitive, uvr⁺ mutants, as well as the corresponding wild-type strain, were equally susceptible to induction of prophage 80 by UV irradiation. However, MC induction of prophage was achieved in MC-sensitive, uvr⁺ mutants at a lower concentration of the antibiotic than in the wild-type strain. Genetic experiments indicated that a gene controlling MC sensitivity is located close to that determining lactose fermentation of E. coli. It is situated on episome F′13, and the wild type is dominant to the MC-sensitive allele.     

Host Specificity of Salmonella typhimurium Deoxyribonucleic Acid Restriction and Modification

The restriction and modification genes of Salmonella typhimurium which lie near the thr locus were transferred to a restrictionless mutant of Escherichia coli. These genes were found to be allelic to the E. coli K, B, and A restriction and modification genes. E. coli recombinants with the restriction and modification host specificity of S. typhimurium restricted phage λ that had been modified by each of the seven known host specificities of E. coli at efficiency of plating levels of about 10⁻². Phage λ modified with the S. typhimurium host specificity was restricted by six of the seven E. coli host specificities but not by the RII (fi⁻ R-factor controlled) host specificity. It is proposed that the restriction and modification enzymes of this S. typhimurium host specificity have two substrates, one of which is a substrate for the RII host specificity enzymes.     

Bacteriophage Lysozyme Synthesis in Escherichia coli K-12(λ) Infected with rII Mutant of Bacteriophage T4

When Escherichia coli K-12(λ) was infected with a T4rII bacteriophage, synthesis of lysozyme appeared at the normal time but stopped 15 min after infection. The lysozyme produced was 1% of the normal level.     

Prophage Induction in Escherichia coli (Lambda) by N-Nitrosamines

Carcinogenic N-nitrosamines were tested for their ability to induce λ in a lysogenic strain of Escherichia coli K-12 (58-161 F⁺). Dimethylnitrosamine, di-n-propylnitrosamine, methyl-n-propylnitrosamine, and N-nitrosopiperidine were shown to be inducers of prophage.     

Interaction of Colicins with Bacterial Cells III. Colicin-tolerant Mutations in Escherichia coli

Mutants that adsorb certain colicins without being killed, i.e., tolerant mutants (tol), were isolated from Escherichia coli K-12 strains. Selection was done either with colicin K or E2. Several groups of mutants showing different phenotypes were found, and some of them showed tolerance to both K and E colicins, which have different receptors. Many of these mutants mapped near gal. Typical mutants from group II, III, and IV were studied in more detail. The mutant loci were contransducible with gal by phage P1. The linkage order was deduced to be tol-gal-λ. In partially diploid strains, these mutant loci are recessive to wild-type alleles. Temperature-dependent conditionally tolerant mutants were also isolated. Two groups were found: the first was tolerant to E2 and E3 at 40 C, but sensitive at 30 C; the second was tolerant to E2 at 30 C, but sensitive at 40 C. Experiments done with these mutants suggest that these mutations affect the heat lability of some protein that is necessary for the response of cells to colicins. Conditionally lethal tolerant mutants were isolated which at 40 C were tolerant to E2 and E3 and could not grow, but which at 30 C were fully sensitive and grew normally. The mutation mapped near malA. The tolerance at 40 C is not due to a consequence of an inactivation of general cellular metabolism, but presumably is a cause of the subsequent inhibition of cellular growth. The results suggest that some protein components involved in the response to colicin are also vital to normal cellular growth.     

Temperature-Sensitive Modification and Restriction Phenotypes of an Escherichia coli dnaD Mutant

A mutant of Escherichia coli temperature-sensitive for deoxyribonucleic acid synthesis, dnaD, was found to have temperature-sensitive modification and restriction phenotypes. In contrast to the original observation by Carl (1970), the mutant could support the growth of λ phage at 41 C. However, the λ phages thus produced were able to form plaques with normal plating efficiency only on E. coli C, a restriction-less strain, but not on E. coli K. Since the λ phages produced in the mutant at 30 C could form plaques equally well on both E. coli strains, it was concluded that the dnaD mutant has a temperature-sensitive modification phenotype. Furthermore, since the dnaD mutant allowed some growth of unmodified λ·C phages at 41 C but less at 30 C, the mutant is also temperature sensitive in restriction. The relationship, if any, between temperature-sensitive deoxyribonucleic acid synthesis and temperature-sensitive modification-restriction in the dnaD mutant is not known. Similar experiments were done with three dnaC mutants and one dnaA mutant. Two dnaC mutants were found to have altered restriction phenotypes at 41 C, but none of the mutants were defective in modification.     

Tracking EcoKI and DNA fifty years on: a golden story full of surprises

1953 was a historical year for biology, as it marked the birth of the DNA helix, but also a report by Bertani and Weigle on ‘a barrier to infection’ of bacteriophage λ in its natural host, Escherichia coli K-12, that could be lifted by ‘host-controlled variation’ of the virus. This paper lay dormant till Nobel laureate Arber and PhD student Dussoix showed that the λ DNA was rejected and degraded upon infection of different bacterial hosts, unless it carried host-specific modification of that DNA, thus laying the foundations for the phenomenon of restriction and modification (R-M). The restriction enzyme of E.coli K-12, EcoKI, was purified in 1968 and required S-adenosylmethionine (AdoMet) and ATP as cofactors. By the end of the decade there was substantial evidence for a chromosomal locus hsdK with three genes encoding restriction (R), modification (M) and specificity (S) subunits that assembled into a large complex of >400 kDa. The 1970s brought the message that EcoKI cut away from its DNA recognition target, to which site the enzyme remained bound while translocating the DNA past itself, with concomitant ATP hydrolysis and subsequent double-strand nicks. This translocation event created clearly visible DNA loops in the electron microscope. EcoKI became the archetypal Type I R-M enzyme with curious DNA translocating properties reminiscent of helicases, recognizing the bipartite asymmetric site AAC(N6)GTGC. Cloning of the hsdK locus in 1976 facilitated molecular understanding of this sophisticated R-M complex and in an elegant ‘pas de deux’ Murray and Dryden constructed the present model based on a large body of experimental data plus bioinformatics. This review celebrates the golden anniversary of EcoKI and ends with the exciting progress on the vital issue of restriction alleviation after DNA damage, also first reported in 1953, which involves intricate control of R subunit activity by the bacterial proteasome ClpXP, important results that will keep scientists on the EcoKI track for another 50 years to come.     

Cnr interferes with dimerization of the replication protein alpha in phage-plasmid P4

DNA replication of phage-plasmid P4 in its host Escherichia coli depends on its replication protein α. In the plasmid state, P4 copy number is controlled by the regulator protein Cnr (copy number regulation). Mutations in α (α^cr) that prevent regulation by Cnr cause P4 over-replication and cell death. Using the two-hybrid system in Saccharomyces cerevisiae and a system based on λ immunity in E.coli for in vivo detection of protein–protein interactions, we found that: (i) α protein interacts with Cnr, whereas α^cr proteins do not; (ii) both α–α and α^cr–α^cr interactions occur and the interaction domain is located within the C-terminal of α; (iii) Cnr–Cnr interaction also occurs. Using an in vivo competition assay, we found that Cnr interferes with both α–α and α^cr–α^cr dimerization. Our data suggest that Cnr and α interact in at least two ways, which may have different functional roles in P4 replication control.     

Polynucleotide Sequence Divergence Among Strains of Escherichia coli and Closely Related Organisms

Polynucleotide sequence similarity tests were carried out to determine the extent of divergence present in a number of Escherichia coli strains, obtained from diverse human, animal, and laboratory sources, and closely related strains of Shigella, Salmonella, and the Alkalescens-Dispar group. At 60 C, relative reassociation of deoxyribonucleic acid (DNA) from the various strains with E. coli K-12 DNA ranged from 100 to 36%, with the highest level of reassociation found for three strains derived from K-12, and the lowest levels for two “atypical” E. coli strains and S. typhimurium. The change in thermal elution midpoint, which indicates the stability of DNA duplexes, ranged from 0.1 to 14.5 C, with thermal stability closely following the reassociation data. Reassociation experiments performed at 75 C, at which temperature only the more closely related DNA species form stable duplexes, gave similar indications of relatedness. At both temperatures, Alkalescens-Dispar strains showed close relatedness to E. coli, supporting the idea that they should be included in the genus Escherichia. Reciprocal binding experiments with E. coli BB, 02A, and K-12 yielded different reassociation values, suggesting that the genomes of these strains are of different size. The BB genome was calculated to be 9% larger than that of K-12, and that of 02A 9% larger than that of BB. Calculation of genome size for a series of E. coli strains yielded values ranging from 2.29 × 10⁹ to 2.97 × 10⁹ daltons. E. coli strains and closely related organisms were compared by Adansonian analysis for their relatedness to a hypothetical median strain. E. coli 0128a was the most closely related to this median organism. In general, these data compared well with the data from reassociation experiments among E. coli strains. However, anomalous results were obtained in the cases of Shigella flexneri, S. typhimurium, and “atypical” E. coli strains.     

Conserved Structural Regions Involved in the Catalytic Mechanism of Escherichia coli K-12 WaaO (RfaI)

Escherichia coli K-12 WaaO (formerly known as RfaI) is a nonprocessive α-1,3 glucosyltransferase, involved in the synthesis of the R core of lipopolysaccharide. By comparing the amino acid sequence of WaaO with those of 11 homologous α-glycosyltransferases, four strictly conserved regions, I, II, III, and IV, were identified. Since functionally related transferases are predicted to have a similar architecture in the catalytic sites, it is assumed that these four regions are directly involved in the formation of α-glycosidic linkage from α-linked nucleotide diphospho-sugar donor. Hydrophobic cluster analysis revealed a conserved domain at the N termini of these α-glycosyltransferases. This domain was similar to that previously reported for β-glycosyltransferases. Thus, this domain is likely to be involved in the formation of β-glycosidic linkage between the donor sugar and the enzyme at the first step of the reaction. Site-directed mutagenesis analysis of E. coli K-12 WaaO revealed four critical amino acid residues.     

Only One ATP-binding DnaX Subunit Is Required for Initiation Complex Formation by the Escherichia coli DNA Polymerase III Holoenzyme

The DnaX complex (DnaX₃δδ′χψ) within the Escherichia coli DNA polymerase III holoenzyme serves to load the dimeric sliding clamp processivity factor, β₂, onto DNA. The complex contains three DnaX subunits, which occur in two forms: τ and the shorter γ, produced by translational frameshifting. Ten forms of E. coli DnaX complex containing all possible combinations of wild-type or a Walker A motif K51E variant τ or γ have been reconstituted and rigorously purified. DnaX complexes containing three DnaX K51E subunits do not bind ATP. Comparison of their ability to support formation of initiation complexes, as measured by processive replication by the DNA polymerase III holoenzyme, indicates a minimal requirement for one ATP-binding DnaX subunit. DnaX complexes containing two mutant DnaX subunits support DNA synthesis at about two-thirds the level of their wild-type counterparts. β₂ binding (determined functionally) is diminished 12–30-fold for DnaX complexes containing two K51E subunits, suggesting that multiple ATPs must be bound to place the DnaX complex into a conformation with maximal affinity for β₂. DNA synthesis activity can be restored by increased concentrations of β₂. In contrast, severe defects in ATP hydrolysis are observed upon introduction of a single K51E DnaX subunit. Thus, ATP binding, hydrolysis, and the ability to form initiation complexes are not tightly coupled. These results suggest that although ATP hydrolysis likely enhances β₂ loading, it is not absolutely required in a mechanistic sense for formation of functional initiation complexes.     

The UDP-glucose Dehydrogenase of Escherichia coli K-12 Displays Substrate Inhibition by NAD That Is Relieved by Nucleotide Triphosphates

UDP-glucose dehydrogenase (Ugd) generates UDP-glucuronic acid, an important precursor for the production of many hexuronic acid-containing bacterial surface glycostructures. In Escherichia coli K-12, Ugd is important for biosynthesis of the environmentally regulated exopolysaccharide known as colanic acid, whereas in other E. coli isolates, the same enzyme is required for production of the constitutive group 1 capsular polysaccharides, which act as virulence determinants. Recent studies have implicated tyrosine phosphorylation in the activation of Ugd from E. coli K-12, although it is not known if this is a feature shared by bacterial Ugd proteins. The activities of Ugd from E. coli K-12 and from the group 1 capsule prototype (serotype K30) were compared. Surprisingly, for both enzymes, site-directed Tyr → Phe mutants affecting the previously proposed phosphorylation site retained similar kinetic properties to the wild-type protein. Purified Ugd from E. coli K-12 had significant levels of NAD substrate inhibition, which could be alleviated by the addition of ATP and several other nucleotide triphosphates. Mutations in a previously identified UDP-glucuronic acid allosteric binding site decreased the binding affinity of the nucleotide triphosphate. Ugd from E. coli serotype K30 was not inhibited by NAD, but its activity still increased in the presence of ATP.     

Directionality of lambda plasmid DNA replication carried out by the heritable replication complex

There are two ‘pathways’ of replication of λ plasmids in Escherichia coli. One pathway requires the assembly of a new replication complex before replication and the second pathway is based on the activity of the replication complex inherited by one of two daughter plasmid copies after a preceding replication round. Such a phenomenon was postulated to occur also in other replicons, including Saccharomyces cerevisiae autonomously replicating sequences. Here we investigated directionality of λ plasmid replication carried out by the heritable and newly assembled replication complexes. Using two-dimensional agarose gel electrophoresis and electron microscopy we demonstrated that in both normal growth conditions and during the relaxed response to amino acid starvation (when only replication carried out by the heritable complex is possible), bidirectionally and undirectionally replicating plasmid molecules occurred in host cells in roughly equal proportions. The results are compatible with the hypothesis that both complexes (heritable and newly assembled) are equivalent.     

The Multifaceted Benefits of Protein Co-expression in Escherichia coli

We report here that the expression of protein complexes in vivo in Escherichia coli can be more convenient than traditional reconstitution experiments in vitro. In particular, we show that the poor solubility of Escherichia coli DNA polymerase III ε subunit (featuring 3’-5’ exonuclease activity) is highly improved when the same protein is co-expressed with the α and θ subunits (featuring DNA polymerase activity and stabilizing ε, respectively). We also show that protein co-expression in E. coli can be used to efficiently test the competence of subunits from different bacterial species to associate in a functional protein complex. We indeed show that the α subunit of Deinococcus radiodurans DNA polymerase III can be co-expressed in vivo with the ε subunit of E. coli. In addition, we report on the use of protein co-expression to modulate mutation frequency in E. coli. By expressing the wild-type ε subunit under the control of the araBAD promoter (arabinose-inducible), and co-expressing the mutagenic D12A variant of the same protein, under the control of the lac promoter (inducible by isopropyl-thio-β-D-galactopyranoside, IPTG), we were able to alter the E. coli mutation frequency using appropriate concentrations of the inducers arabinose and IPTG. Finally, we discuss recent advances and future challenges of protein co-expression in E. coli.