Cloning of the dnaB gene of Escherichia coli: the dnaB gene of groPB534 and groPB612 and the replication of phage lambda

Summary Fragments of the E. coli chromosome that carry the dnaB groPB534 or groPB612 alleles have been cloned into a cosmid vector. The resulting recombinant plasmids contained the genes uvrA, groP (B534 or B612), and lexA. Further subcloning into high copy number plasmids, during which the uvrA and lexA genes were removed successively, yielded a groPB534 and groPB612 DNA fragment of about 2.4 kb each. Both fragments contained an overlapping 1.8 kb segment of DNA in which the sites of all restriction enzymes tested were identical. The size of these dnaB gene fragments were further delimited by deletion analysis.In E. coli groPB534 in which wild-type and A mutants do not replicate (Georgopoulos and Herskowitz 1971) phage replication is rescued if the strain contains the groPB534 gene on high copy number plasmids. On the contrary, in E. coli groPB612, which is temperature-sensitive for its groP character, replication of and A is abolished at 30° C if the strain contains the groPB612 recombinant plasmid. On the other hand, replication of B remains unaffected whether or not the groP strains harbor the isogenic dnaB gene-containing plasmid. The results suggest that within the cell not only the quality but also the relative amounts of dnaB and P protein are crucial for phage replication.     

Tn903 induces inverted duplications in the chromosome of bacteriophage lambda

Specialized transducing strains of bacteriophage lambda have been isolated that carry the transposable kanamycin resistance element, Tn903. Tn903 carries an inverted duplication of 1130 base-pairs flanking the kanamycin resistance gene. Often, when λ::Tn903 particles are infected into bacterial cells, the lambda chromosome is rearranged into a defective lambda plasmid which replicates with the bacterial cell. The formation of the defective plasmids (called Tn903λdv) is most likely induced by the Tn903 insertion itself. This follows from the fact that the novel DNA sequence found in these plasmids, with respect to the ancestral λTn903 chromosome, is always adjacent to the Tn903 element. Physical chromosomal mapping of these plasmids shows that they contain large inverted duplications of lambda sequences situated about the Tn903 insertion. The formation of the Tn903λdv plasmids from the ancestral λTn903 is not dependent on the recombination functions provided through the phage red gene or the host recA gene.     

Suppression and enhancement of temperature sensitivity of dnaB mutations of Escherichia coli K12 by conjugative plasmids.

A majority of wild-type, conjugative antibiotic-resistance plasmids from a standard collection had the ability to suppress or to enhance the temperature sensitivity of dnaB mutants of Escherichia coli K12. This ability appears to be widely dispersed among all plasmid groups. The mode of suppression does not involve the insertion of the plasmid into the chromosome. Plasmid-induced suppression or enhancement is not as a rule mutation specific and can extend to several mutations within the dnaB region. The patterns of suppression and enhancement suggest a direct or indirect interaction between a plasmid-specified product and the dnaB protein.     

Replication of small plasmids in extracts of Escherichia coli: involvement of the dnaB and dnaC protein in the replication of early replicative intermediates.

Summary The role of E. coli dnaB and dnaC protein in the replication of plasmid ColE1 and RSF1030 DNA was investigated in a soluble in vitro system (Staudenbauer, 1976a). Extracts from dnaB and dnaC mutants which are phenotypically DNA initiationor DNA elongation-defective were examined for their replicative capacity. It was found that all mutants tested are deficient in the synthesis of supercoiled plasmid DNA. Deficient extracts of dnaB mutants could be partially complemented by purified dnaB wild type protein but required for full complementation dnaC wild type protein as well. The dnaB wild type protein could be replaced by a P1dnaB analog (ban) protein complexed with a dnaB ts protein. Deficient extracts of dnaC mutants were complemented by purified dnaC wild type protein alone.The in vitro plasmid replication cycle had been separated into an early and late stage (Staudenbauer, 1977). Analysis by CsCl velocity centrifugation of the plasmid DNA synthesized in mutant extracts indicates that the early stage, namely the synthesis of early replicative intermediates, proceeds in all dnaB and dnaC mutants tested. However, replication of the early intermediates during the late stage depends on both the dnaB and dnaC protein. These conclusions were confirmed using inhibitors of DNA synthesis.     

A dnaB analog specified by bacteriophage P1

Bacteriophage P1 is shown to determine a product that can substitute in DNA replication for the protein specified by cistron dnaB of Escherichia coli. The viral dnaB analog (ban) is repressed in the wild-type P1 prophage and expressed constitutively in plaque-forming mutants, P1bac, described here. A particular P1bac prophage allows lysogens of dnaBts bacteria to survive as colony-formers at temperatures that arrest DNA synthesis in the non-lysogens. The P1bac prophage furthermore permits construction of an otherwise inviable strain bearing the unsuppressed amber mutation dnaB266.P1bac prophages also suppress the groP character which is associated with certain dnaB mutations. The subclass of dnaB mutations called groP are those which prevent the growth of bacteriophage λ⁺ at temperatures permissive for bacterial DNA synthesis, but allow the growth of certain λ mutants (λπ); π mutations have been mapped in gene P. Thus, λ⁺ is enabled to grow in groP hosts by the presence of P1bac-1 prophage. When dnaB protein is absent, however, as in the case of the unsuppressed amber mutant, the ban protein furnished by the P1bac prophage does not support λ growth. Therefore, in the groP(P1bac-1) lysogens both the dnaB and ban products are needed for λ growth, suggesting interactions between these E. coli and P1 proteins or their subunits.Mutations (termed ban) that prevent the expression of the dnaB analog determined by P1 have been obtained. P1bac-1ban-1, unlike P1bac-1, fails to replicate in dnaBts hosts at temperatures non-permissive for bacterial DNA synthesis. Thus, the dnaB protein and its P1-determined analog can interchangeably fulfill an essential role in the replication of both the E. coli and P1 replicons. At permissive temperatures the lysogenization of certain dnaBts strains by P1bac-1ban-1 is very inefficient, probably as a result of negative complementation.Mutations bac-1 and ban-1 are closely linked on the P1 chromosome and their order relative to several amber mutations has been determined. Dominance studies of the alleles in transient diploids show that the ban-1 mutation is recessive to ban⁺. The bac-1 mutation, on the other hand, behaves in dominance tests as a DNA site mutation that permits constitutive expression in cis of the operon to which the ban gene belongs.     

A dnaB analog function specified by bacteriophage P7 and its comparison to the similar function specified by bacteriophage P1

Summary Evidence is presented that bacteriophage P7 specifies an analog of the E. coli DNA replication protein, dnaB. As in the related bacteriophage P1 (D'Ari et al., 1975; Ogawa, 1975), in lysogens of P7, the production of the analog protein is repressed and constitutive mutants could be isolated. Such constitutive of several dnaB(ts) mutations and also rescue a strain carrying a dnaB amber mutation. While neither P7 nor the mutant P1bacban (defective in the structural gene ban) could suppress dnaB(ts) mutations efficiently, recombinants between these two phages could do so, indicating the presence of a functional dnaB analog gene (called sdb) on P7. In a dnaB amber strain suppressed by the presence of the constitutive mutant P7csb, bacteriophage failed to replicate which is a further similarity between P7 and P1. P7csb mutants or P7-P1bacban recombinants were found to be less thermoresistant than P1bac1 suggesting that the P7-specified dnaB analog protein or its production is relatively less tolerant of temperatures above 37°C.     

DNA replication in dnaB mutants of Escherichia coli: Gene product interaction and synthesis of 4 S pieces

The DNA produced by several dnaB mutants has been examined both in vivo and in vitro. The alleles chosen for study had previously been shown to differ over a wide range in the apparent severity of their effects on DNA replication.Comparison of DNA replication between dnaB heteroallelic diploids and the constituent haploid strains indicates interaction between the dnaB products in the heteroallelic diploids. The data are consistent with a functional multimeric aggregate of dnaB gene products that is at least a tetramer.Alkaline sucrose gradient profiles of pulse-labeled DNA, synthesized by some of the mutants in vivo and by mutant lysates in vitro, exhibit a peak at about 4 S. The 4 S DNA is most apparent in those mutants in which replication is most severely restricted by temperature.This 4 S material can be chased in vitro into DNA larger than Okazaki pieces, and density transfer experiments indicate that these pieces are formed at the replication fork. Conversion of the 4 S material to large DNA is not altered by inhibition of polynucleotide ligase either by the presence of the lig-4 polA1 mutations in vivo or by the addition of nicotinamide mononucleotide in vitro. The in vitro observations suggest that 4 S pieces are formed on only one side of the replication fork.     

Specificity determinants for bacteriophage lambda DNA replication: I. A chain of interactions that controls the initiation of replication

The genetic elements which control autonomous DNA replication differ in functional specificity among coliphage λ, the coliphages φ80 and 82, and the Salmonella phage P22. Hybrid phages derived by genetic recombination between λ and each of these related phages have been used to define and to localize specificity determinants for DNA replication.In λ-P22 hybrid phages (Hilliker & Botstein, 1976) the replication control elements segregate as an intact unit. By contrast, some viable λ-φ80 and λ.82 hybrid phages arise by recombination within the replication control region, in a small interval inside structural gene O. From the properties of such hybrid phages, we infer that the O gene product of λ and the functionally equivalent proteins of φ80 and 82 each interact with a specific nucleotide sequence in the cognate ori site, the DNA target for control of the origin of replication. With respect to this interaction, both the O products and the receptor sequences within ori show stringent type specificity. The donor and receptor specificity determinants for the ori-O interaction lie within an interval of less than 400 base-pairs.The O gene product also interacts with the product of replication gene P (Tomizawa, 1971). The O-P interaction displays limited type specificity; the P-like protein of φ80 can function together with the O protein of λ, but the P protein of λ cannot function with the O-like protein of φ80. The specificity determinants for the O-P interaction can be separated from those for the ori-O interaction.We propose that a chain of interactions between ori, O product, P product, and replication functions of the bacterial host, Escherichia coli, controls specific template selection and the assembly of the essential replication apparatus in the initiation of λ DNA replication.     

A dnaB analog ban, specified by bacteriophage P1: genetic and physiological evidence for functional analogy and interactions between the two products.

Summary Bacteriophage P1 has been shown previously to determine a product ban than can substitute in DNA replication for the protein specified by cistron dnaB of Escherichia coli. However, ban product furnished by P1 bac prophage (ban constitutive) substitutes only poorly for DNA replication in the absence of dnaB product in a strain bearing an unsuppressed amber mutation, dnaB266, as shown by the cryosensitivity of the dnaB266 (P1 bac) lysogen and its unability to support growth. An additional mutation (termed crr) in the P1 bac prophage has been obtained which confers cryoresistance to the sup ⁺ dnaB266 (P1 bac crr) lysogen and restores its ability to support growth. ban product produced in P1 bac crr lysogen fulfills all dnaB roles in vivo, especially in the various instances in which ban product expressed in P1 bac lysogens does not. The ban product is expressed constitutively in P1 crr prophage. The crr-1 mutation is tightly linked to the bac-1 and ban-1 mutations and is dominant over crr ⁺. The nature of the crr mutation is discussed: two hypotheses are considered, that of a mutation in the ban gene rendering the ban product more active or that of a site mutation in the ban operon increasing the level of ban expression. Expression of ban product (wild type or altered) leads to interactions with the variously altered dnaB product. Both positive and negative interactions are described. Genetic results presented here suggest that ban and dnaB subunits interact to form hybrid dnaB-like molecules; the average composition of which depends on the relative quantities of ban and dnaB subunits in the cell.     

Transposon 10 promoted deletions and inversions in the transfer genes of R100-1

Summary The replication of the ColE1 plasmid was studied in extracts from E. coli dnaG mutants. It was found that the synthesis of the complementary strands of ColE1 DNA can be carried out in these extracts in two consecutive steps: (1) synthesis of the leading L strand independent of the dnaG function, and (2) synthesis of the lagging H strand depending upon addition of wild-type dnaG protein. In contrast to L strand synthesis, the latter reaction is insensitive to rifampicin and novobiocin. Both synthetic pathways are however blocked by antiserum directed against dnaB protein. This indicates an additional role of the dnaB protein in duplex DNA replication besides assisting the dnaG protein in the priming of lagging strand synthesis. The T7 gene-4 protein acting in conjunction with T7 DNA polymerase can substitute for both the function of the dnaB and dnaG protein. It is concluded that plasmid replication proceeds by a semi-discontinuous mechanism.     

Analysis of the dnaB function of Escherichia coli K12 and the dnaB-like function of P1 prophage

The dnaB function of Escherichia coli K12 was studied with a series of isogenic strains differing from each other only by a mutation in the dnaB gene. The strains showed different phenotypes depending on the particular dnaB mutation they carry. A clear example is provided by a strain carrying dnaB266 mutation which turned out to be an amber mutation. When the mutation was suppressed by different suppressors, the strains showed different phenotypes. Thus, dnaB proteins which differ from each other by only one amino acid at the mutation site give different phenotypes. Mutation dnaB266 is lethal to the host when not suppressed. Hence the dnaB protein is essential for bacterial growth.Three P1 mutants, P1mcb-4, P1mcb-5 and P1mcb-8, were isolated which converted the temperature-sensitive bacterial growth of dnaB266-supE to resistant growth. Lysogenization with P1mcb allowed growth of dnaB266su⁻ strain which was absolutely defective in the bacterial dnaB function, indicating that the dnaB-like function of P1 prophage can substitute for the bacterial dnaB function. However, lysogenization by P1mcb did not support the growth of λ and λπ phages on dnaB 266su⁻. While P1mcb-4 and P1mcb-5 prophages altered the phenotypes of other dnaB strains to permit the growth of bacterial and λ phage at 32 °C and 42 °C, P1mcb-8 prophage supports the growth of λ phages and bacteria at 42 °C but not λ phage growth on groP-bacteria at 32 °C. The alteration of phenotypes of the P1mcb lysogens varied depending on the dnaB mutations they carried. Mutual interaction between the bacterial dnaB protein and the phage dnaB-like protein which results in different phenotypes of lysogens is suggested.     

Bacteriophage P1 Ban protein is a hexameric DNA helicase that interacts with and substitutes for Escherichia coli DnaB

Since the ban gene of bacteriophage P1 suppresses a number of conditionally lethal dnaB mutations in Escherichia coli, it was assumed that Ban protein is a DNA helicase (DnaB analogue) that can substitute for DnaB in the host replication machinery. We isolated and sequenced the ban gene, purified the product, and analysed the function of Ban protein in vitro and in vivo. Ban hydrolyses ATP, unwinds DNA and forms hexamers in the presence of ATP and magnesium ions. Since all existing conditionally lethal dnaB strains bear DnaB proteins that may interfere with the protein under study, we constructed a dnaB null strain by using a genetic set-up designed to provoke the conditional loss of the entire dnaB gene from E.coli cells. This novel tool was used to show that Ban restores the viability of cells that completely lack DnaB at 30°C, but not at 42°C. Surprisingly, growth was restored by the dnaB252 mutation at a temperature that is restrictive for ban and dnaB252 taken separately. This indicates that Ban and DnaB are able to interact in vivo. Complementary to these results, we demonstrate the formation of DnaB–Ban hetero-oligomers in vitro by ion exchange chromatography. We discuss the interaction of bacterial proteins and their phage-encoded analogues to fulfil functions that are essential to phage and host growth.     

The isolation and characterization of escherichia coli dnaB::Tn10 insertion mutations

Summary Exploitation of the ability of the ban protein encoded by phage P1 to compensate for dnaB-defective host mutations, allowed the isolation of dnaB::Tn10 insertion mutations. The presence of P1bac prophage was required for survival of dnaB::Tn10 mutants, and such lysogens were cryosensitive. The insertions were shown to map in dnaB by transduction and this was confirmed by complementation analysis. The dnaB::Tn10 (P1bac) strains were non-permissive for growth but did support the growth of -dnaB ⁺specialized transducing phage. No antigenically active dnaB product could be detected by immunologic assays using either of two methods. In addition, it was shown that the observed cryosensitivity of P1bac suppression was a direct result of reversible inactivation of the ban protein at low temperature.     

Number and size distribution of the DNA chains in Escherichia coli.

The essential replication protein encoded by gene O of bacteriophage λ (O-λ) is one of the major polypeptides produced in vitro in a DNA-dependent protein synthesizing system with λ DNA as template (Yates et al., 1977). We have used this system to identify the proteins encoded by lambdoid phages φ80 and 82 and equivalent in function to O-λ. The O protein of each phage type differs slightly in polypeptide molecular weight. Hybrid λ-φ80 and λ-82 phages derived by recombination within gene O direct synthesis of hybrid O proteins with the aminoterminal segment characteristic of one parent, and the carboxyl-terminal segment characteristic of the other. Differences in structure among O-λ, O-80 and O-λ82 segregate together with specificity determinants for interactions between the O protein and the control site ori, and between the O protein and the product of replication gene P. The coding region for the O protein includes ori.