Properties of membrane-associated folded chromosomes of E. coli related to initiation and termination of DNA replication

Analysis of folded chromosomes prepared from amino acid-starved E. coli cells or from a dnaC initiation mutant indicates that a unique structure is associated with completion or near completion of rounds of chromosome replication in E. coli. Chromosomes remain associated with portions of the bacterial cell envelope throughout the DNA replication cycle, but become more rapidly sedimenting as replication proceeds in the absence of reinitiation. Before reinitiation of chromosome replication occurs after restoring required amino acids to amino acid-starved cells or after lowering the temperature in a thermosensitive dnaC mutant, sedimentation velocities of the membrane-associated folded chromosomes decrease substantially. The decrease in sedimentation velocity does not depend on renewed DNA synthesis, but does require the activity of at least the dnaC gene product.     

Complementation of a dnaC initiation defect in vitro

Summary The dnaC28 mutant, CT28-3b, is an initiation defective dnaC strain. Extracts of the mutant failed to synthesize DNA in vitro when the strain was incubated at the restrictive temperature for two generation times prior to preparation of the extract. Addition of a complementing extract from a Col-E1::dnaC ⁺ hybrid plasmid containing strain or of partially purified dnaC protein resulted in substantial synthesis. Hybridization of the DNA made by these in vitro complementation extracts showed that a significant portion of this DNA was from the region near the chromosomal origin of replication.     

Re-examination of F plasmid replication in a dnaC mutant of Escherichia coli.

Summary The replication of an F plasmid in a dnaC mutant, thermolabile for initiation of chromosomal replication, has been re-examined using a novel DNA-DNA annealing assay. Plasmid replication ceases rapidly at non-permissive conditions, consistent with a direct role for the dnaC product in the replication of F.     

DNA synthesis in an Escherichia coli dna B dnaC mutant.

Summary An Escherichia coli K12 dnaB dnaC mutant was constructed by P1 transduction of the dnaC allele into a dnaB recipient strain dnaB dnaC transductants were discriminated from dnaB mutants by their inability to grow at 40° C after lysogenization with phage P1bac. The dnaB dnaC mutant character was verified by 1. P1 transduction, and 2. by in vitro complementation with dnaB and dnaC wild type protein fractions.DNA synthesis was studied in strains containing dnaB, dnaC, or dnaB dnaC alleles in an otherwise uniform genetic background with the dnaB character either unsuppressed or suppressed by P1bac prophage. Degradation at 42° C of [³H]-thymidine pulselabeled DNA in dnaB and dnaB dnaC mutants is suppressed by P1bac. However, unlike the dnaC mutant, the P1bac lysogen of the dnaB dnaC mutant exhibits an abrupt cessation of DNA synthesis and less residual cell divisions at 42° C indicating an inhibition of DNA chain elongation rather than a defect in DNA initiation. It is suggested that denaturation of the dnaB protein affects the dnaC function.     

RNA polymerase mutants of Escherichia coli. Streptolydigin resistance and its relation to rifampicin resistance

Summary Several streptolydigin-resistant mutants of Escherichia coli were shown to produce RNA polymerase with increased drug resistance due to a recessive mutation (stl) located between argH and thiA. With one mutant studied, enzyme reconstitution experiments directly demonstrated that the altered subunit is responsible for its drug resistance. It was also found that some mutations (rif or stv) conferring resistance to rifampicin (or streptovaricin) lead to a simultaneous change in resistance to streptolydigin, suggesting certain functional relationship between the polymerase structure affected by rif (or stv) and stl mutations. This inference was further supported by the results of cistron analysis and of extensive transductional mapping involving two stl and a number of rif mutations. Thus it was found that all the mutational sites affecting sensitivity of RNA polymerase to streptolydigin and to rifampicin are closely localized, with partial overlap to each other, within a short segment of the cistron which determines the structure of subunit. These results led us to propose that the subunit is directly responsible for catalyzing both initiation and chain elongation steps of RNA synthesis. The possible bearing of the present findings on the structure-function relationship of the polymerase is discussed.     

Replication of plasmids in mutants of Escherichia coli temperature-sensitive for initiation of deoxyribonucleic acid synthesis

Plasmid deoxyribonucleic acid (DNA) replication was studied in Escherichia coli hosts carrying temperature-sensitive (ts) initiation mutations. The replication of the R plasmid NR1 continues at the nonpermissive temperature in a ts dnaA mutant host but at a decreasing rate in proportion to the residual chromosome synthesis. The replication of NR1, as well as of the F plasmid F′lac, ceases immediately at the nonpermissive temperature in a ts dnaC mutant host. The ability to reinitiate R plasmid replication in the absence of protein or ribonucleic acid synthesis is accumulated at the nonpermissive temperature in a dnaC mutant host.     

Interaction of RNA polymerase mutations in haploid and merodiploid cells of Escherichia coli K-12

Summary Combination in the same chromosome of tsX mutation which affects the attachment of RNA polymerase to DNA template with either of two rifampicin resistant mutations (rif-r-1 or rif-r-5) is lethal. However tsX forms viable combination with other rifampicin resistant mutation—rif-r-76. Moreover a partial restoration of rifampicin binding capacity takes place: RNA polymerase from double tsX rif-r-76 mutant binds rifampicin better than the enzyme from tsX ⁺ rif-r-76 cells. No mutual influence of rifampicin resistant and streptolydigin resistant mutations was found.Heterozygous merodiploids (rif-r/rif-s and stl-r/stl-s) demonstrate phenotypic dominance of sensitivity to each of the drugs no matter whether resistant allele is localized in chromosome or in episome. However certain chromosomal mutations which themselves have no apparent effect on RNA polymerase may cause dominance of rif-r allele.About a half of total cellular RNA polymerase in crude extracts of rif-r/rif-s and stl-r/stl-s heterogenotes was found to be drug-resistant, though rif-s allele is dominant phenotypically.The development of T2 phage is completely inhibited by rifampicin in haploid rif-s cells and is only slightly affected in rif-r mutant. A partial resistance of phage development to rifampicin was observed in rif-r/rif-s heterogenotes which confirms that both rif-s and rif-r enzymes are simultaneously present in such cells.Sensitive and resistant RNA polymerase function independently when mixture of the two enzymes was incubated with the excess of DNA template. However a competition between the two enzymes for the DNA was observed if the limiting amount of the template is available. The result of this competition to major extent depends on which of the enzymes was added first. It is supposed that in certain conditions normal RNA polymerase may act as a repressor of the mutant enzyme: drug-sensitive RNA polymerase may bind to the template in the presence of the drug and thus prevent the function of drug-resistant enzyme. This hypothesis explains phenotypic dominance of sensitive alleles to resistant alleles which leads to inability of heterogenote cells to multiply in the presence of corresponding drugs.     

<Emphasis Type="Italic">fabC</Emphasis> of <Emphasis Type="Italic">Streptomyces lydicus</Emphasis> involvement in the biosynthesis of streptolydigin

Streptolydigin, a secondary metabolite produced by Streptomyces lydicus, is a potent inhibitor of bacterial RNA polymerases. It has been suggested that streptolydigin biosynthesis is associated with polyketide synthase (PKS) and nonribosomal peptide synthetase (NRPS). Thus, there is great interest in understanding the role of fatty acid biosynthesis in the biosynthesis of streptolydigin. In this paper, we cloned a type II fatty acid synthase (FAS II) gene cluster of fabDHCF from the genome of S. lydicus and constructed the SlyfabCF-disrupted mutant. Sequence analysis showed that SlyfabDHCF is 3.7 kb in length and encodes four separated proteins with conserved motifs and active residues, as shown in the FAS II of other bacteria. The SlyfabCF disruption inhibited streptolydigin biosynthesis and retarded mycelial growth, which were likely caused by the inhibition of fatty acid synthesis. Streptolydigin was not detected in the culture of the mutant strain by liquid chromatography–mass spectrometry. Meanwhile, the streptolol moiety of streptolydigin accumulated in cultures. As encoded by fabCF, acyl carrier protein (ACP) and β-ketoacyl-ACP synthase II are required for streptolydigin biosynthesis and likely involved in the step between PKS and NRPS. Our results provide the first genetic and metabolic evidence that SlyfabCF is shared by fatty acid synthesis and antibiotic streptolydigin synthesis.     

Growth and reactivation of single stranded DNA phage phiX174 in E. coli undergoing "thymineless death".

Summary Flac maintenance was aberrant at permissive temperature in a temperature-sensitive dnaC mutant of Salmonella typhimurium when the normally resident pLT2 plasmid was present. Flac was, however, efficiently transferred into the dnaC pLT2⁺ strain and the resulting Flac derivative was almost as efficient in transferring Flac as were dnaC ⁺ pLT2⁺ Flac strains indicating that aberrant Flac maintenance was not associated with appreciable inhibition of transfer replication. A range of F-like plasmids behaved like pLT2 in causing aberrant Flac maintenance when present in the dnaC pLT2^- strain. Flac was, however, stably maintained in the dnaC strain in the absence of other plasmids. Although the F-like plasmids destabilized Flac, each was stably maintained when introduced into strain 11G dnaC pLT2⁺ and pLT2 was also apparently stable under these conditions. The destabilizing effect of pLT2 and other fi ⁺ plasmids was not consequent upon their inhibiting the formation of a repressible F transfer component needed for Flac replication in the dnaC strain. Incompatibility between Flac and the other plasmids induced by the dnaC lesion also appeared unlikely to be a cause of the aberrant Flac maintenance. The possibility is discussed that the initiation of Flac replication differs from that of pLT2 and the F-like plasmids with F competing less effectively than the others for the DnaC gene product.     

NOVEL Escherichia coli dnaB mutant: direct involvement of the dnaB252 gene product in the synthesis of an origin-ribonucleic acid species during initiaion of a round of deoxyribonucleic acid replication.

The initiation process of deoxyribonucleic acid (DNA) replication in Escherichia coli has been studied using the thermoreversible dna initiation mutant E. coli HfrHl65/120/6 dna-252. This dna mutation was incorrectly classed as a dnaA mutation. Biochemical and genetic evidence suggests that the dna-252 mutant is a novel dnaB mutant, possessing phenotypic properties which distinguish it from other dnaB mutants. Sensitivity of reinitiation in the dna-252 mutant to specific inhibitors of protein, ribonucleic acid (RNA), and DNA synthesis was studied. Reinitiation is shown to be sensitive to rifampin and streptolydigin but not to cholramphenicol. Thus, the dna-252 gene product appears to be required during the initiation process for a step occurring either before or during synthesis of an RNA species (origin-RNA). Using reversible inhibition of RNA synthesis by streptolydigin of a streptolydigin-sensitive derivative of the dna-252 mutant, the dna-252 gene product is shown to be directly involved in the synthesis of an orgin-RNA species. These results are included in a schematic model presented in the accompanying paper of the temporal sequence of events occurring during the initiation process.     

Temporal sequence of events during the initiation process in Escherichia coli deoxyribonucleic acid replication: roles of the dnaA and dnaC gene products and ribonucleic acid polymerase.

Three thermosensitive deoxyribonucleic acid (DNA) initiation mutants of Escherichia coli exposed to the restrictive temperature for one to two generations were examined for the ability to reinitiate DNA replication after returning to the permissive temperature in the presence of rifampin, chloramphenicol, or nalidixic acid. Reinitiation in the dnaA mutant was inhibited by rifampin but not by chloramphenicol, whereas renitiation was not inhibited by rifampin but not by chloramphenicol, whereas reinitiation was not inhibited in two dnaC mutants by either rifampin or chloramphenicol. To observe the rifampin inhibition, the antibiotic must be added at least 10 min before return to the permissive temperature. The rifampin inhibition of reinitiation was not observed when a rifampin-resistant ribonucleic acid ((RNA) polymerase gene was introduced into the dnaA mutant, demonstrating that RNA polymerase synthesizes one or more RNA species required for the initation of DNA replication (origin-RNA). Reinitiation at 30 degrees C was not inhibited by streptolydigin in a stretolydigin-sensitive dnaA muntant. Incubation in the presence of nalidixic acid prevented subsequent reinitiation in the dnaC28 mutant but did not inhibit reinitiation in the dnaA5 muntant. These results demonstrate that the dnaA gene product acts before or during the synthesis of an origin-RNA, RNA polymerase synthesizes this origin RNA, and the dnaC gene product is involved in a step after this RNA synthesis event. Furthermore, these results suggest that the dnaC gene product is involved in the first deoxyribounucleotide polymerization event wheareas the dnaA gene product acts prior to this event. A model is presented describing the temporal sequence of events that occur during initiation of a round of DNA replication, based on results in this and the accompanying paper.     

Inhibition of RNA Polymerase by Streptolydigin

TWO antibiotics inhibit RNA synthesis by interacting directly with RNA polymerase. The rifamycin series^1–3 inhibit before RNA chain initiation and are without apparent effect during polymerization. Streptolydigin, however, inhibits initiation and chain elongation^4–9. Using the d(A-T)-directed reaction as a model system¹⁰, we will show that streptolydigin stabilizes the polymerase-template interaction.     

The dependence of temperate phage Mu-1 upon replication functions of E. coli K12

Summary Of the two bacterial functions involved in the initiation of DNA replication in E. coli K12, one, dnaC, is required for the growth of phage Mu-1, the other, dnaA, is not. The elongation function dnaB is also necessary for Mu development. The situation is less clear for dnaE (DNA polymerase III).Aspirant F.N.R.S.     

A missense mutation in the rpoC gene affects chromosomal replication control in Escherichia coli.

An RNA polymerase mutant with a single-base-pair change in the rpoC gene affects chromosome initiation control. The mutation, which is recessive, is a G to A transition leading to the substitution of aspartate for glycine at amino acid residue 1033 in the RNA polymerase beta' subunit. The chromosome copy number is increased twofold in the mutant at semipermissive growth temperatures (39 degrees C). In a delta oriC strain, in which chromosome initiation is governed by an F replicon, chromosome copy number is not affected. Plasmid pBR322 copy number is also increased in the mutant at 39 degrees C. The mutation causes a more than fivefold increased expression of the dnaA gene at 39 degrees C. It is conceivable that it is this high DnaA concentration which causes the high chromosome copy number and that the mutant RNA polymerase beta' subunit exerts its effect by altering the expression of the dnaA gene. However, other factors must be affected as well to explain why the RNA polymerase mutant can grow in a balanced fashion with a high chromosome concentration. This is in contrast to wild-type cells, which exhibit higher origin concentrations when DnaA protein is overproduced, but in which the overall DNA concentration is only moderately affected.     

RNA polymerase synthesis in vitro directed by T7 phage DNA

Summary T7 RNA polymerase is synthesized in vitro, dependent on T7 DNA. The in vitro synthesized T7 polymerase has the characteristic properties: resistance to rifampicin and streptolydigin and the typical template specificity.     

Mode of Action of Streptolydigin

Streptolydigin and rifamycin inhibit the catalytic function of ribonucleic acid (RNA) polymerase. Streptolydigin can inhibit polymerization after the reaction has started, whereas rifamycin is effective only if it is preincubated with RNA polymerase prior to the addition of substrates. The same relationships are observed with respect to these two antibiotics if the nucleoside triphosphate-pyrophosphate exchange reaction is used in the assay system. The inhibitory effect of streptolydigin is reversible by further addition of RNA polymerase but not by addition of deoxyribonucleic acid to the assay system.     

A nucleic acid sequence-based amplification (NASBA) system for Listeria monocytogenes and simple method for detection of amplimers

A NASBA system amplifying specific sequences of the Listeria monocytogenes hlyA gene and an immunoenzymatic assay for the detection of amplimers was developed. The immunoenzymatic assay utilized a simple microtiter plate format and an anti-RNA:DNA hybrid antibody for the detection of NASBA product (predominantly RNA) hybridized to an immobilized DNA probe. This highly sensitive isothermal amplification and detection system was reactive with genomic DNA from various L. monocytogenes isolates but not with other Listeria or non-Listeria species.