The folded genome of Escherichia coli isolated in a protein-DNA-RNA complex

Paranemic structures of DNA and their role in DNA unwinding

A DNA structure is defined as paranemic if the participating strands can be separated without mutual rotation of the opposite strands. The experimental methods employed to detect paranemic, unwound, DNA regions is described, including probing by single-strand specific nucleases (SNN), conformation-specific chemical probes, topoisomer analysis, NMR, and other physical methods. The available evidence for the following paranemic structures is surveyed: single-stranded DNA, slippage structures, cruciforms, alternating B-Z regions, triplexes (H-DNA), paranemic duplexes and RNA, protein-stabilized paranemic DNA. The problem of DNA unwinding during gene copying processes is analyzed; the possibility that extended paranemic DNA regions are transiently formed during replication, transcription, and recombination is considered, and the evidence supporting the participation of paranemic DNA forms in genes committed to or undergoing copying processes is summarized.

Gyrase inhibitors can increase gyrA expression and DNA supercoiling

Treatment of bacterial cells with inhibitors of gyrase at high concentration leads to relaxation of DNA supercoils, presumably through interference with the supercoiling activity of gyrase. Under certain conditions, however, the inhibitors can also increase supercoiling. In the case of coumermycin A1, this increase occurs at low drug concentrations. Oxolinic acid increases supercoiling in a partially resistant mutant. We found that increases in chromosomal DNA supercoiling, which were blocked by treatment with chloramphenicol, were accompanied by an increased expression rate of gyrA. This result is consistent with gyrase being responsible for the increase in supercoiling. In wild-type cells, increases in gyrA expression were transient, suggesting that when supercoiling reaches sufficiently high levels, gyrase expression declines. Oxolinic acid studies carried out with a delta topA strain showed that drug treatment also increased plasmid supercoiling. The levels of supercoiling and topoisomer heterogeneity were much higher when the plasmid contained one of several promoters fused to galK. Since oxolinic acid causes an increase in gyrA expression, it appears that gyrase levels may be important in transcription-mediated changes in supercoiling even when topoisomerase I is absent.

Differential effects of DNA gyrase inhibitors on the genetic transformation of Neisseria gonorrhoeae

Inhibitors of DNA gyrase in Escherichia coli exerted differential effects on the genetic transformation of Neisseria gonorrhoeae. When competent cells of the gonococcus were exposed to novobiocin before the uptake of transforming antibiotic resistance DNA, there was a 50 to 60% reduction in the number of transformants compared with the number of control untreated cells. Norfloxacin, a more potent inhibitor of DNA gyrase and an analog of nalidixic acid, nearly abolished the production of transformants by recipient cells. On the contrary, exposure of competent cells to nalidixic acid had no effect on transformant yield. The target of these inhibitors appears to be at the level of recombination. Possible mechanisms are discussed.

Cloning and sequencing of the HU-2 gene of Escherichia coli

The Escherichia coli HU-2 gene was cloned using a DNA fragment from the HU-1 gene as a probe. The amino acid sequence of the HU-2 protein deduced from the nucleotide sequence is in good agreement with the published sequence. The nucleotide sequence has a possible promoter and a typical ribosomal binding site upstream of the translation initiation codon (AUG) and a possible rho-independent terminater site downstream of the termination codon (UAA) of the gene.

Effects of DNA gyrase inhibitors in Escherichia coli topoisomerase I mutants

Relaxation of titratable supercoils in bacterial nucleoids was measured following treatment of topA mutants with coumermycin or oxolinic acid, inhibitors of DNA gyrase. Relaxation occurred after treatment of the mutants with either inhibitor. We detected no significant difference in relaxation between topA- and topA+ strains treated with coumermycin. This finding, together with previous observations, supports the idea that relaxation caused by coumermycin probably arises from the relaxing activity of gyrase itself. The source of DNA relaxation caused by oxolinic acid was not identified. Nucleoid supercoiling can be increased by adding oxolinic acid to a strain that carries three topoisomerase mutations: delta topA, gyrB225, and gyrA (Nalr) (S. H. Manes, G. J. Pruss, and K. Drlica, J. Bacteriol. 155:420-423, 1983). We found that this increase in supercoiling requires partial sensitivity to the drug and at the delta topA and gyrA mutations. Full resistance to oxolinic acid in the presence of the delta topA, gyrB225, and gyrA mutations was conferred by an additional mutation that maps at or near gyrB.

Biochemical topology: applications to DNA recombination and replication

Processes of DNA rearrangement such as recombination or replication frequently have as products different subsets of the limitless number of distinguishable catenanes or knots. The use of gel electrophoresis and electron microscopy for analysis of these topological isomers has made it possible to deduce physical and geometric features of DNA structure and reaction mechanisms that are otherwise experimentally inaccessible. Quantitative as well as qualitative characterization is possible for any pathway in which the fate of a circular DNA can be followed. The history, theory, and techniques are reviewed and illustrative examples from recent studies are presented.

Proteins tightly bound to DNA and DNA-synthesizing activity of nucleoids from Escherichia coli

Membrane-attached nucleoids were isolated from E. coli and separated from proteins by 2 M NaCl. Disintegration of such nucleoids by ultrasound and subsequent centrifugation resulted in the formation of two fractions: a sediment (fraction I) and a supernatant (fraction II). The protein:DNA ratio of fraction I was equal to 27 and was different from that to fraction II (2.6). More than 70% of the proteins not dissociating at 2 M NaCl and bound to DNA of both fractions were polypeptides with molecular weights (Mw) of 31,000-23,000 daltons (31-23 Kdal). After pulse labelling of the cells with [3H]-thymidine, the specific radioactivity of newly synthesized DNA associated with fraction I was shown to be considerably higher than that of fraction II. The analysis of DNA-synthesizing activities in fractions I and II showed that both nucleoid fractions contained DNA polymerase I. After dissolving the two fractions in 8 M urea - 0.15% sodium dodecylsulphate (SDS) they were chromatographed on hydroxyapatite. DNA-protein complexes were obtained that did not dissociate at 4 M guanidine X HCl - 5 M urea and 1% SDS. The main protein of the complexes was a 31 Kdal polypeptide tightly bound to DNA.

The FI gene product of bacterial virus Lambda is related to the E. coli chromosomal protein NS2 and is involved in intracellular DNA organization

A likely function of the Lambda FI gene product (gpFI) is condensation of developmental forms of the bacteriophage DNA in the host cell. Several characteristics of gpFI support this hypothesis: it is similar in its structure and properties to E. coli NS proteins whose involvement in the bacterial DNA condensation has been established and it comigrates with DNA during fractionation of host cell lysate through a sucrose gradient.

Molecular cloning and nucleotide sequence of the HU-1 gene of Escherichia coli

The Escherichia coli HU-1 was cloned by use of mixed synthetic oligonucleotides (17-mer) predicted from a portion of its amino acid sequence. The amino acid sequence of the HU-1 protein deduced from the nucleotide sequence is in good agreement with the published sequence. The nucleotide sequence has a possible promoter and a typical ribosomal binding site upstream from the translational initiation codon (GUG) of the HU-1 gene.

Inhibition of excision repair of DNA in u.v.-irradiated Escherichia coli by phenethyl alcohol

Membrane-specific drugs such as procaine and chlorpromazine have been shown to inhibit excision repair of DNA in u.v.-irradiated E. coli. One possible mechanism is that, if association of DNA with the cell membrane is essential for excision repair, this process may be susceptible to drugs affecting the structure of cell membranes. We examined the effect of phenethyl alcohol, which is a membrane-specific drug and known to dissociate the DNA-membrane complex, on excision repair of DNA in u.v.-irradiated E. coli cells. The cells were irradiated with u.v. light and then held at 30 degrees C in buffer (liquid-holding) in the presence or absence of phenethyl alcohol. It was found that phenethyl alcohol inhibits the liquid-holding recovery in both wild-type and recA strains, corresponding to its dissociating action on the DNA-membrane complex. Thus, the association of DNA with cell membrane is an important factor for excision repair in E. coli. Procaine did not show the dissociating effect, suggesting that at least two different mechanisms are responsible for the involvement of cell membrane in excision repair of DNA in E. coli.

The association of transcribed genes with the nuclear matrix of Drosophila cells during heat shock

Using the transcriptional modulation afforded by heat shock, we found that the association of active genes with the nuclear matrix was not dependent on their level of transcription. Heat shock genes were matrix associated both before heat shock (when transcription was relatively low), and during heat shock (when transcription was greatly increased). Conversely, the cytoplasmic actin gene was matrix associated during normal growth conditions (when transcription was high) and during heat shock (when transcription was greatly decreased). Removal of greater than 99.7% of nascent RNA during preparation of the matrices did not affect these findings. Detailed examination of the cytoplasmic actin gene revealed that its matrix association was apparently mediated by multiple interactions near the 5' end of the gene.

Bacterial anatomy in retrospect and prospect

Progress in bacterial anatomy over a period of about 15 years is reviewed. In particular, attention is paid to developments in which the Department of Electron Microscopy and Molecular Cytology was involved. Past and present problems in bacterial anatomy as well as approaches to their solution are discussed.

The effect of bleomycin on DNA in Escherichia coli K12 cells

In Escherichia coli cells treated to reduce colony-forming ability to about 10%, bleomycin causes fewer than six randomly located DNA single-strand breaks or three double-strand breaks per genome. This is many fewer than produced by strand-breaking agents such as ionizing radiations in cells with similar loss of colony-forming ability. Bleomycin treatment to this level of colony-forming ability does affect the intracellular DNA, as shown by a change in the sedimentation rate of the chromosomal structure found in lysates made with sodium dodecyl sulfate. Bleomycin may act on only a limited part of the chromosome of such cells, perhaps the part associated with the outer cell membrane, or it may make strand breaks that are less repairable than those formed by ionizing radiations. Extensive DNA degradation in heavily treated cells (colony-forming ability 1% or less) could be from the action on DNA of bleomycin entering freely through membranes which are no longer intact, or from enzymatic degradation in heavily damaged cells.

Isolation and characterization of nucleoid proteins from Escherichia coli

Of the molecular species of proteins associated with the nucleoids of Escherichia coli cells, those with relatively high affinity to bind to DNA were isolated and characterized. Seven classes of nucleoid proteins with molecular weights of 9,000, 17,000 (two molecular species), 22,000, 24,000, 27,000 and 28,000 were isolated at more than 90% purity or were partially purified. On the basis of its amino acid composition and other chemical properties, the 9,000 dalton protein was identified as HLP II (or HU protein or BH2) (Pettijohn 1982; Rouvière-Yaniv and Gros 1975; Varshavsky et al. 1978). The 17 K protein consisted of two molecular species and one of these, 17 K (a) protein, seemed to be identical with HLPI (or protein 1 or BH1) reported previously (Pettijohn 1982; Varshavsky et al. 1977; Varshavsky et al. 1978). The 26 K protein was identical to the 22 K protein (Kishi et al. 1982). The 27 K protein showed immunological cross-reactivity with the antibody for histone H2A and was thus identified as the H protein reported previously (Hübscher et al. 1980). Two basic proteins, 9 K and 17 K(a), showed relatively high binding affinities to DNA, while the 28 K protein showed moderate binding affinity. The biological significance of these nucleoid proteins, which constitute a family of proteins participating in formation of the nucleoid structure, is discussed.

Characteristics of chromosomal DNA isolated from Escherichia coli spheroplasts

The chromosomal DNA of Escherichia coli spheroplasts induced by penicillin G was studied biochemically and electron microscopically. Although the spheroplasts were unable to divide, they continued to synthesize chromosomal DNA for several hours even in the presence of penicillin G. Some differences were observed between the chromosomal DNA of the parent cells and that of the spheroplasts in sucrose gradient centrifugation and electron microscopy; two types of chromosomal DNA, a slower sedimenting form and a faster sedimenting form, were released from the gently lysed parent cells. The former was membrane-free folded chromosome and the latter was membrane-associated chromosome. In contrast, the chromosome from the spheroplast showed a single intermediate value of sedimentation coefficient between those of the chromosomal DNA from the parent cell. Cytochrome spreading for electron microscopy showed that the spheroplast chromosomal DNA formed an aggregated mass consisting of several chromosome-molecules of the parent cell.

DNA supercoiling in gyrase mutants

Nucleoids isolated from Escherichia coli strains carrying temperature-sensitive gyrA or gyrB mutations were examined by sedimentation in ethidium bromide-containing sucrose density gradients. A shift to restrictive temperature resulted in nucleoid DNA relaxation in all of the mutant strains. Three of these mutants exhibited reversible nucleoid relaxation: when cultures incubated at restrictive temperature were cooled to 0 degree C over a 4- to 5-min period, supercoiling returned to levels observed with cells grown at permissive temperature. Incubation of these three mutants at restrictive temperature also caused nucleoid sedimentation rates to increase by about 50%.

Effect of mutation, electric membrane potential, and metabolic inhibitors on the accessibility of nucleic acids to ethidium bromide in Escherichia coli cells

The uptake of ethidium bromide by Escherichia coli K 12 cells has been studied by using 14C-labeled ethidium and spectrofluorometry on three E. coli strains: the first one (AB1157) has an ethidium-resistant phenotype; the second one derives from the first one after a single mutation (at 10 min on the E. coli genetic map) and has an ethidium-sensitive (Ebs) phenotype; the third one is the acrA strain which appeared to have the same phenotype as the Ebs strain. When the cells are in exponential growth, no ethidium enters wild-type cells, and a very limited amount of ethidium enters Ebs and acrA cells. Massive quantities of ethidium enter AB1157, Ebs, and acrA cells treated by uncouplers and respiring Ebs cells treated by the membrane ATPase-inhibitor dicyclohexylcarbodiimide. A small amount of ethidium enters cells treated in M9 succinate medium by metabolic inhibitors such as KCN or cells starved with oxygen in the same M9 medium. The amount of ethidium and ethidium dimer retained at equilibrium by either type of cell, and by cells infected by T5 phage, as well as the kinetics of influx and efflux, has been measured under a variety of situations (membrane energized or not, and/or membrane ATPase inhibited or not). Furthermore, it was shown that ethidium binds to both RNA and DNA when it enters CCCP-treated wild-type E. coli cells, whereas it binds mainly to DNA when it enters Ebs and acrA cells in exponential growth. As it will be discussed, it is difficult to account for the EthBr uptake by invoking only membrane functions and active transport. Therefore, it is proposed that the variations of the nucleic acid accessibility in E. coli cells might play a role in the control of this uptake. Accordingly, in ethidium-sensitive cells, the mutation would have caused a significant part of the chromosomal DNA (10-20%) to become accessible to ethidium. Hansen [Hansen M. T. (1982) Mutat. Res. 106, 209-216], after a study of the photobinding of psoralen to nucleic acids in the acrA mutant, also suggested that DNA environment was modified in acrA cells.

Effect of bacteriophage phi X174 infection on the conformation of Escherichia coli DNA

The cistron A proteins of bacteriophage phi X174 inhibit the synthesis of beta-galactosidase of host Escherichia coli. A drastic reduction in the rate of transcription of the lac gene is observed in infected cells. This loss in the efficiency of transcription is due to conformational changes in the host DNA. Probably the host DNA is nicked at a few sites along its length and some of its negative superhelical twists are released.

Possible involvement of DNA-linked RNA in the initiation of Bacillus subtilis chromosome replication

After thermal denaturation, an in vivo-labeled RNA was found in a temperature-sensitive initiation mutant of Bacillus subtilis (dna-37) associated with high-molecular-weight DNA. This RNA could be clearly distinguished from other RNA species by different techniques of separation, such as Sepharose 2B filtration, chromatography on nitrocellulose, and equilibrium centrifugation in density gradient. It was obtained even when HCHO was present during denaturation and chilling of nucleic acids and was still detected after a second denaturation as well as after incubation with proteinase K. Properties of the complex were not altered by prior treatment with RNase H. A control experiment using two samples of the complex treated either with pancreatic DNase or with pancreatic RNase, denatured together and centrifuged in the same density gradient, showed that no artifactual associations occur between the DNA and the RNA components of the complex. These results demonstrate that the DNA and RNA in the complex are associated by neither hydrogen bonds nor proteins, but are indicative of a DNA-RNA covalent linkage. In addition, during synchronous replication after a previous period at a nonpermissive temperature, DNA-linked RNA synthesis took place at specific times which coincided with the appearance of rifampin resistance of the first and the second replication cycles. A possible involvement of this RNA in the initiation of chromosome replication is discussed.

Isolation of membrane-associated folded chromosomes from Anacystis nidulans

Particles containing folded DNA were isolated from the blue-green alga Anacystis nidulans. The structure of these particles is vesicle-like and similar to that of membrane-associated nuclear bodies which had been isolated from Escherichia coli under comparable conditions. The sedimentation constant is between 8000 and 9000 Svedbergs. The DNA is inside the particles and is attached to the thylakoid membranes.

Chromosomes in living Escherichia coli cells are segregated into domains of supercoiling

Torsional tension in the DNA double helix can be detected in living cells of Escherichia coli from measurements of the rate of trimethylpsoralen photobinding to the intracellular DNA. Here we show that this tension is relaxed in vivo when single-strand DNA breaks are introduced by gamma-irradiation and that approximately 160 nicks per genome equivalent of DNA are required to relax greater than 95% of the tension. Chromosomes containing less than 160 nicks per genome equivalent lose only a part of the tension, depending on the number of nicks. The remaining tension is maintained during incubations of cells at 0 degrees C. Chromosomes with tension relaxed by incubation of cells with inhibitors of DNA gyrase interact with the trimethylpsoralen probe independently of the number of nicks introduced by gamma-irradiation. The results fit a model in which the chromosome in growing E. coli cells (mean generation time, 30 min) is segregated into 43 +/- 10 domains of supercoiling per genome equivalent of DNA or 120 +/- 30 domains per nucleoid. The number of domains is unchanged in cells depleted of nascent RNA by growth with rifampicin, but varies somewhat in cells growing at different rates in different media.

Novel histone H2A-like protein of escherichia coli

A histone-like protein (H) from Escherichia coli has been purified to more than 98% homogeneity by using its capacity to inhibit DNA functions. H protein behaves as a dimer of 28,000-dalton subunits. The histone H2A-like properties of H protein are: (i) binding to DNA at a stoichiometry of 1 H protein dimer per 75 bases; (ii) abundance of about 30,000 molecules per cell, sufficient to bind about 20% of the chromosome; (iii) limiting digestion of double-stranded DNA by micrococcal nuclease; (iv) reannealing of complementary single-stranded DNA; (v) amino acid composition resembling that of eukaryotic histone H2A; (vi) neutralization of H protein by antibody specific for H2A; (vii) heat stability; and (viii) acid solubility. The capacity of H protein to bind DNA prevents its template or substrate functions n several reactions in vitro: DNA synthesis by several polymerases; transcription by RNA polymerase; DNA topoisomerase activity; and DNA-dependent ATP hydrolysis by rep protein, dnaB protein, or protein n'. Together with other histone-like proteins of E. coli, H protein may organize the E. coli chromosome into nucleosomes, such as in eukaryotic chromatin.

Shutoff of lambda gene expression by bacteriophage T4: role of the T4 alc gene

Bacteriophage T4 normally contains 5-hydroxymethylcytosine instead of cytosine in its DNA. Multiple mutants of T4 which synthesize DNA with cytosine do not transcribe their late genes due to the action of the T4 alc gene (Snyder et al., Proc. Natl. Acad. Sci. U.S.A. 73:3098--3102, 1976), which is also responsible for unfolding the host nucleoid after T4 infection (Sirotkin et al., Nature [London] 265:28--32, 1977; Tigges et al., J. Virol. 24:775--785, 1977). It seems reasonable that T4 alc function plays a role in shutting off host transcription, and the observation that some of the RNA made after infection with a T4 alc mutant hybridizes to Escherichia coli DNA (Sirotkin et al., Nature [London] 265:28--32, 1977; Tigges et al., J. Virol. 24:775--785, 1977) supports this hypothesis. Although it is likely that the roles of the alc function in the blocking of some types of transcription and in the unfolding of the host nucleoid are related, it is not known how these effects are achieved or, in fact, whether all types of transcription are affected equally by the alc function. In an attempt to answer these questions, we studied the effect of T4 alc function on bacteriophage lambda transcription and on the structure of intracellular lambda DNA. We found that the alc function is responsible for the shutoff of lambda late transcription but probably not for the shutoff of lambda early transcription. We also found that alc does not block lambda transcription by directly removing the supercoils from circular lambda DNA via either a nicking or topoisomerase activity. Furthermore, we conclude that T4 infection also prevents the translation of non-T4 mRNA because late lambda mRNA's were made after superinfection by a T4 alcs mutant and were of normal length but were not translated into lambda late proteins.

Association of the 2-micron DNA plasmid with yeast folded chromosomes

The 2-micron DNA plasmid cosedimented in sucrose gradients with the folded chromosome on centrifugation of lysates from logarithmically growing yeast cells. It banded with both the slow-sedimenting g1 form derived from prereplicative cells and the fast-sedimenting g2 form from postreplicative cells. When cells were induced to withdraw from the cell cycle by nitrogen starvation, the folded chromosome was converted to the g0 form, which sedimented more slowly than the g1 form, and only 1/10th the amount of 2-micron DNA cosedimented with this g0 form as compared to the logarithmic-phase forms, g1 and g2. Expression of the temperature-sensitive cell division cycle (cdc) 28 mutation, which defines the "start" of the cell cycle, resulted in a rapid alteration in the folded chromosome sedimentation pattern, and less than 20% of the 2-micron DNA cosedimented with the folded chromosome. These results raise the possibility that association of the 2-micron DNA plasmid with structures in the cell corresponding to the folded chromosome is subject to cell division cycle control.

Photoaddition of trimethylpsoralen as a probe for the intracellular organization of Escherchia coli DNA

It has been previously demonstrated that photoreaction with 4,5',8-tri-methylpsoralen (trioxsalen) can be used as a probe for the in vivo structure of eucaryotic chromatin. We have used this probe to analyze the organization of intracellular Escherichia coli DNA. In contrast to eucaryotic DNA, bacterial DNA within the intact cell is not protected from saturating doses of trioxsalen photoaddition. The final level of covalently bound trioxsalen upon saturation is identical to that found with purified DNA. In addition, the distribution of interstrand DNA cross-links formed by low doses of trioxsalen photoadducts does not exhibit the repeating pattern that has been observed with eucaryotic nucleosomes.

Chromatin structure in the unicellular algae Olisthodiscus luteus, Crypthecodinium cohnii and Peridiniun balticum

Isolated nuclei of the unicellular alga Olisthodiscus luteus, the uninucleate dinoflagellate Crypthecodinium cohnii and the binucleate dinoflagellate Peridinium balticum were lysed and deposited on grids by the microcentrifugation technique. The ultrastructure of the released chromatin fibers was compared to that of mouse liver nuclei. Chromatin from nuclei of Olisthodiscus luteus and the "eukaryotic" nuclei of Peridinium balticum, appeared as linear arrays of regularly repeating subunits which were identical in size and morphology to mouse nucleosomes. In contrast, the chromatin fibers from Crypthecodinium cohnii nuclei appeared as smoothe threads with a diameter of about 6.5 nm. Nuclear preparations containing mixtures of "dinokaryotic" and "eukaryotic" nuclei of Peridinium balticum also contained smooth fibers which most likely originated from the dinokaryotic nuclei. These and other results demonstrating the presence of nucleosomes in lower eukaryotes suggest that the subunit structure of chromatin arose very early in the evolution of the eukaryotic cell.

Requirement of DNA gyrase for the initiation of chromosome replication in Escherichia coli K-12

It has been found that strains carrying mutations in the dnaA gene are unusually sensitive to COU, NAL or NOV, which are known to inhibit DNA gyrase activities. The delay in the initiation of chromosome replication after COU treatment has been observed in cells with chromosomes synchronized by amino acid starvation or by temperature shift-up (dnaA46). The unusual sensitivity of growth to COU of the initiation mutant runs parallel to a higher sensitivity to the drug of the initiation of chromosome replication. The double mutant, dnaA46, cou-110 has been isolated and mutation cou-110 conferring resistance of growth, initiation and elongation of chromosome replication to COU was mapped in the gene coding for the subunit of DNA gyrase. The reduced frequency of appearance of the mutants resistant to COU, NAL, or NOV in the initiation mutant suggests that some mutations in genes coding for DNA gyrase subunits cannot coexist with the dnaA46 mutation. The possible mechanisms of the requirement of DNA gyrase for dnaA-dependent initiation of E. coli chromosome are discussed.

Gel electrophoretic separation of transcription complexes: an assay for RNA polymerase selectivity and a method for promoter mapping

We describe a method for analyzing ternary transcription complexes, of RNA polymerase, DNA and nascent RNA32 chains, by agarose gel electrophoresis. When the RNA of such complexes is 32P-labelled, a simple comparison of the DNA fluorogram with an autoradiogram identifies transcriptionally active DNA molecules and restriction fragments in any mixture. Two limitations on the method are described: 1) retardation during electrophoresis of polymerase-DNA complexes relative to their conjugate bare NA fragments; 2) failure of very large ternary complexes to enter gels. The following potential applications of the method are surveyed: transcription unit (elongation) mapping, separation of RNA molecules in a mixture of transcripts, dinucleotide primer mapping and identification of preferred template conformations.

Review: ethidium fluorescence assays. Part 1. Physicochemical studies

DNA and RNA can be assayed rapidly and very sensitively by exploiting the enhanced fluorescence of ethidium intercalated into duplex regions. By assaying at different pHs and introducing a heating/cooling cycle, a great many physicochemical aspects of DNA and RNA can be studied avoiding the use of radiolabels, and often giving information not otherwise readily obtainable. Studies are described on duplex DNA which involve measurement of extinction coefficients, cross-linking by chemicals, Cot curve analysis as well as estimation of drug-DNA binding constants. The assays can be adapted to investigate multi-stranded nucleic acid structures. The use of covalently closed circular DNA also allows rapid and extremely sensitive measurements of nicking caused by irradiation or drugs.

Superhelical DNA in Streptococcus sanguis: role in recombination in vivo

Competent Streptococcus sanguis treated with non-lethal doses of coumermycin A1 immediately before or after uptake of radioactive transforming DNA were reduced in their capacity to yield transformants. This treatment did not alter bacterial ability to bind DNA in DNase I-resistant form, nor did it prevent the single-stranded donor DNA-recipient protein complexes formed upon uptake at the surface of the bacteria from translocating to chromosomal sites. Inhibition of transformation by heterospecific DNA was greater than that by homospecific DNA. The reduction in transformant yield was not accompanied by any loss of donor counts incorporated into the recipient chromosome, but rather by a loss of genetic activity of incorporated donor material indicating a failure of genetic integration and degradation of donor DNA as a consequence of coumermycin treatment. The inhibitory effect of coumermycin on transformation was associated with in vivo loss of chromosomal DNA superhelicity, The chromosomal DNA remained intact, however, indicative of inhibition of a gyrase-like enzyme responsible for the maintenance of negative supercoiling of the S. sanguis chromosome. Upon treatment with the drug, a coumermycin-resistant mutant strain showed neither loss of chromosomal superhelicity nor any inhibitory effect on genetic integration of donor DNA. The evidence supports the idea that chromosomal superhelicity promotes genetic recombination in vivo.

Deoxyribonucleic acid and outer membrane: binding to outer membrane involves a specific protein

The binding of deoxyribonucleic acid (DNA) to the outer membrane of Escherichia coli was examined. The amount of DNA found to be bound to outer membrane was low and was estimated to be about 0.4% of the total DNA. Treatment of cells with chloramphenicol or rifampin caused a disassociation of the apparent DNA-outer membrane complex. The results presented here suggest that the binding between membrane and DNA is specific and involves a membrane protein having a molecular weight of 13,000.

Shutoff of host macromolecular synthesis after T-even bacteriophage infection

Images

Characterization of Azotobacter vinelandii deoxyribonucleic acid and folded chromosomes

The properties of Azotobacter vinelandii deoxyribonucleic acid (DNA) and folded chromosomes were studied and compared to those of Escherichia coli as a standard. Based on melting temperature and buoyant density measurements, the guanosine + cytosine content of purified A. vinelandii DNA was 65%, whereas that of E. coli DNA was 50%. The results of renaturation studies showed that the unique DNA sequence lengths of the two organisms were similar with Cot1/2 values of 7.3 +/- 0.4 mol.s/liter and 7.5 +/- 0.3 mol.s/liter, respectively, for A. vinelandii and E. coli. Folded chromosomes of A. vinelandii sedimented in a centrifugal field at a rate identical to those derived from E. coli, 1,600 to 1,700S. Based on the DNA content per cell and the mass of a single genome, A. vinelandii contains at least 40 chromosomes per cell.

Ionizing radiation damage to the folded chromosome of Escherichia coli K-12: sedimentation properties of irradiated nucleoids and chromosomal deoxyribonucleic acid

The structures of the membrane-free nucleoid of Escherichia coli K-12 and of unfolded chromosomal deoxyribonucleic acid (DNA) were investigated by low-speed sedimentation on neutral sucrose gradients after irradiation with 60Co gamma rays. Irradiation both in vivo and in vitro was used as a molecular probe of the constraints on DNA packaging in the bacterial chromosome. The number of domains of supercoiling was estimated to be approximately 180 per genome equivalent of DNA, based on measurements of relaxation caused by single-strand break formation in folded chromosomes gamma irradiated in vivo and in vitro. Similar estimates based on the target size of ribonucleic acid molecules responsible for maintaining the compact packaging of the nucleoid predicted negligible unfolding due to the formation of ribonucleic acid single-strand breaks at doses of up to 10 krad; this was born out by experimental measurements. Unfolding of the nucleoid in vitro by limit digestion with ribonuclease or by heating at 70 degrees C resulted in DNA complexes with sedimentation coefficients of 1,030 +/- 59S and 625 +/- 15S, respectively. The difference in these rates was apparently due to more complete deproteinization and thus less mass in the heated material. These structures are believed to represent intact, replicating genomes in the form of complex-theta structures containing two to three genome equivalents of DNA. The rate of formation of double-strand breaks was determined from molecular weight measurements of thermally unfolded chromosomal DNA gamma irradiated in vitro. Break formation was linear with doses up to 10 krad and occurred at a rate of 0.27 double-strand break per krad per genome equivalent of DNA (1,080 eV/double-strand break). The influence of possible nonlinear DNA conformations on these values is discussed.

Biochemical characterization of nonintegrated plasmid-folded chromosome complexes: sex factor F and the Escherichia coli nucleoid

The existence of nonintegrated plasmid-chromosome complexes has been deduced in previous work from the cosedimentation of covalently closed, circular plasmids with host folded chromosomes. In the present work, it is shown that about 70 to 90% of the covalently closed, circular F deoxyribonucleic acid could be released in vitro from chromosome complexes by ribonuclease treatment but not by protease, Sarkosyl, or ethidium bromide. Consistent with the in vitro studies, Escherichia coli cells treated for 5 min with rifampin, an inhibitor of ribonucleic acid initiation, released upon lysis 90% of their plasmid deoxyribonucleic acid as freely sedimenting molecules.

Membrane-bound deoxyribonucleic acid from Escherichia coli: effects of replication, protein synthesis, and ribonucleic acid synthesis

The experiments presented in this paper suggest that the shift observed in sedimentation of deoxyribonucleic acid from cells of Escherichia coli subjected to amino acid starvation is related to inhibition of ribonucleic acid synthesis rather than to its release from the membrane at the termination of replication.

Compact Escherichia coli nucleoids in a highly supercoiled conformation

Escherichia coli nucleoids were visualized in a compact, highly supercoiled conformation at 1 M NaCl. After the salt concentration was lowered to 0.15 M NaCl, the nucleoids uncoiled in beaded fibers in which RNA-mediated structural domains could be distinguished.

Isolation of large bacterial plasmids and characterization of the P2 incompatibility group plasmids pMG1 and pMG5

Large plasmids from Agrobacterium tumefaciens, Salmonella typhimurium, Escherichia coli, Pseudomonas putida, and Pseudomonas aeruginosa were routinely and consistently isolated using a procedure which does not require ultracentrifugation but includes steps designed to separate large-plasmid DNA from the bacterial folded chromosome. It also selectively removes fragments of broken chromosome. A variety of large plasmids was readily visualized with agarose gel electorphoresis, including five between 70 and 85 megadaltons (Mdal) in size, six between 90 and 143 Mdal, one that was larger than 200 Mdal, and one that was larger than 300 Mdal. This isolation procedure allowed initial estimation of the molecular sizes of the two IncP2 plasmids, pMG1 and pMG5, which were 312 and 280 Mdal, respectively. A standard curve for size determination by gel electrophoresis including plasmids between 23 and 143 Mdal in size did not extrapolate linearly for plasmids of the 300-Mdal size range. Unique response of different plasmids to the isolation procedure included sensitivity of IncP1 plasmids to high pH and the co-isolation of a 20-Mdal "cryptic" plasmid in conjunction.

Association of the folded chromosome with the cell envelope of Escherichia coli: nature of the membrane-associated DNA

Membrane-associated folded chromosomes isolated from Escherichia coli in the presence of spermidine sedimented at about 5,800S. The folded chromosome and the membrane fragment were each stable in the absence of the other; a 1,700S folded chromosome was obtained after removal of the membrane by a Sarkosyl treatment, and a 4,000S membrane fragment remained after digestion of the chromosomal DNA with deoxyribonuclease I. The interaction between the folded chromosome and the membrane fragment was stable, and, even when the DNA was unfolded, both components remained associated and cosedimented. The large frictional effect of the unfolded DNA reduced the sedimentation rate of the complex to about 2,000S. Partial removal of this unfolded DNA with restriction endonucleases caused the membrane fragments and the remaining associated DNA to sediment faster, at about 3,500S. The DNA remaining associated with the membrane fragments after restriction endonuclease treatment, about 4.5% of the total DNA when EcoRI was used, was indistinguishable from the DNA released from the membranes by three criteria: (i) DNA size distribution in agarose gels after electrophoresis, (ii) reassociation kinetics, and (iii) thermal elution from hydroxylapatite. This finding, that random DNA sequences rather than specific ones were responsible for the majority of the DNA-membrane interactions, argues against the folded chromosome's being a static structure with specific DNA sequences interacting with the cell envelope.