Novel aspects of the structure of the Escherichia coli nucleoid investigated by a rapid sedimentation assay

The Escherichia coli nucleoid is maintained in its folded highly condensed state by constraints which involve RNA and protein. We have developed a rapid sedimentation assay to determine the state of folding of the membrane-free nucleoid. An approximate measure of the stability of the nucleoids under various conditions can then be estimated by measuring the temperature at which the nucleoids unfold. Using ethidium and gamma irradiation (which removes the negative supercoiling of the native nucleoid) as probes, it can be shown that there are two types of constraint involved in the condensation of the nucleoid. One of these constraints is destabilized by ethidium but stabilized by negative supercoiling; the second constraint is unaffected by both ethidium and negative supercoiling. Several models can be proposed: (i) a DNA . RNA duplex, (ii) a double-strand DNA (dsDNA) . RNA triplex, (iii) DNA-protein interactions, (iv) a topological knot with RNA, and (v) a DNA tetraplex. The topological knot model is not consistent with the data and many combinations of the others can be excluded. If RNA is involved in both constraints then RNA . DNA duplexes and dsDNA . RNA triplexes are involved in stabilizing the nucleoid.     

Folding of prokaryotic DNA. Isolation and characterization of nucleoids from Bacillus licheniformis

Intact and fast-sedimenting nucleoids of Bacillus licheniformis were isolated under low-salt conditions and without addition of detergents, polyamines or Mg2+. These nucleoids were partially unfolded by treatment with RNase and completely unfolded by treatments that disrupt protein-DNA interactions, like incubation with proteinase K, 0.1% sodium dodecyl sulphate and high ionic strength. Ethidium bromide intercalation studies on RNase-treated, proteinase-K-treated and non-treated nucleoids in combination with sedimentation analysis of DNase-I-treated nucleoids revealed that DNA is organized in independent, negatively supertwisted domains. In contrast to the DNA organization in bacterial nucleoids, isolated under high-salt conditions and in the presence of detergents (Stonington & Pettijohn, 1971; Worcel & Burgi, 1972), the domains of supertwisted DNA in the low-salt-isolated nucleoids studied here are restrained by protein-DNA interactions. A major role for nascent RNA in restraining supertwisted DNA was not observed. The superhelix density of B. licheniformis nucleoids calculated from the change of the sedimentation coefficient upon ethidium bromide intercalation, was of the same order of magnitude as that of other bacterial nucleoids and eukaryotic chromosomes, isolated under high-salt conditions: namely, -0.150 (corrected to standard conditions: 0.2 M-NaCl, 37 degrees C; Bauer, 1978). Electron microscopy of spread nucleoids showed relaxed DNA and regions of condensed DNA. Spreading in the presence of 100 micrograms ethidium bromide per ml revealed only condensed structures, indicating that nucleoids are intact. From spreadings of proteinase-K-treated nucleoids we infer that supertwisted DNA and the protein-DNA interactions, responsible for restraining the superhelical DNA conformation, are localized in the regions of condensed DNA.     

Characterization of Escherichia coli nucleoids released by osmotic shock

Nucleoids were isolated by osmotic shock from Escherichia coli spheroplasts at relatively low salt concentrations and in the absence of detergents. Sucrose-protected cells, made osmotically sensitive by growth in the presence of ampicillin or by digestion with low lysozyme concentrations (50-5 μg/ml), were shocked by 100-fold dilution of the sucrose buffer. Liberated nucleoids stained with 4',6-diamidino-2-phenylindole dihydrochloride hydrate (DAPI), the dimeric cyanine dye TOTO-1, or fluorescent DNA-binding protein appeared as cloud-like structures, in the absence of phase contrast. Because UV-irradiation disrupted the DAPI-stained nucleoids within 5-10 s, they were imaged by time-lapse microscopy with exposure times less than 2 s. The volume of nucleoids isolated from ampicillin- or low-lysozyme spheroplasts and minimally exposed to UV (<2 s) was on average ～42 μm(3). Lysozyme at concentrations above 1 μg/ml in the lysate compacted the nucleoids. Treatment with protease E or K (20-200 μg/ml) and sodium dodecyl sulfate (SDS; 0.001-0.01%) caused a twofold volume increase and showed a granular nucleoid at the earliest UV-exposure; the expansion could be reversed with 50 μM ethidium bromide, but not with chloroquine. While DNase (1 μg/ml) caused a rapid disruption of the nucleoids, RNase (0.1-400 μg/ml) had no effect. DAPI-stained nucleoids treated with protease, SDS or DNase consisted of granular substructures at the earliest exposure similar to UV-disrupted nucleoids obtained after prolonged (>4 s) UV irradiation. We interpret the measured volume in terms of a physical model of the nucleoid viewed as a branched DNA supercoil crosslinked by adhering proteins into a homogeneous network.     

Novobiocin treatment reverses radiation-induced alterations in higher-order DNA structure in L5178Y nucleoids

We have studied the effect of novobiocin treatment on radiation-induced damage and its repair in higher-order DNA structure in two mouse leukemia cell lines differing in their radiosensitivity, L5178Y-R (LY-R) and L5178Y-S (LY-S). We used the fluorescent halo technique to measure alterations in the superhelical density and the topological constraints of DNA in LY-R and LY-S nucleoids. The results for untreated cells show that both cell lines reached maximal DNA unwinding at the same concentration of propidium iodide (PI), whereas LY-S nucleoids were less efficient in their ability to rewind their DNA. The loop size did not differ significantly between the cell lines. Incubation of LY-R and LY-S cells with novobiocin at a concentration which does not influence survival (0.1 mM for 45 min), but inhibits DNA synthesis in LY-R cells (by 28%) to a greater extent than in LY-S cells (by 10%), also causes more DNA unwinding in LY-R nucleoids than in LY-S nucleoids. However, a decreased superhelical density was observed in nucleoids from both cell lines. Novobiocin applied before, and present during, irradiation prevents radiation-induced alterations in DNA supercoiling more efficiently in LY-R than in LY-S cells. The presence of novobiocin during the repair period increased DNA rewinding to levels not significantly different from control values in nucleoids from both cell lines.     

Conformational constraints in nuclear DNA.

We have investigated DNA superstructure in a wide range of nuclei of higher cells by gently lysing cells to release structures that resemble nuclei but are depleted of nuclear proteins. The sedimentation properties of these structures, which we call nucleoids, have been examined in sucrose gradients containing the intercalating agent, ethidium. The sedimentation rate of nucleoids derived from the growing cells of mammals, birds, amphibians and insects varies in the manner characteristic of circular and superhelical molecules of DNA. These characteristic changes in sedimentation rate are abolished by irradiating the nucleoids with low doses of gamma-rays, a procedure known to introduce single-strand scissions into DNA. We have also investigated by similar means DNA superstructure in nucleoids derived from a variety of different chick cells. Nucleoids derived from adult hen erythrocytes differ from the other nucleoids studied in that their sedimentation rate does not vary in the manner characteristic of supercoiled DNA.     

Nucleoid halo expansion indirectly measures DNA damage in single cells

A simple test has been developed that measures how much DNA damage has occurred in a single mammalian cell. The procedure is based on the microscopic examination of "halos" of nucleoids that adhere to coverslips. Nucleoids are produced by flowing salt solutions containing detergents over the attached cells. The nucleoid halos are thought to be a tangle of loops of free DNA that emanate from the remnants of the nucleus. When visualized by staining with ethidium bromide the nucleoid halos first expand, and then contract as the concentration of ethidium increases. Exposure of nucleoids to very low levels of DNA chain-breaking treatments results in the incremental expansion of the halos to a maximum of 15 microns or more. Our assay is based upon quantitating the degree of halo expansion. If intact cells are exposed to DNA-damaging treatments, then allowed increasing periods of post-treatment growth before forming nucleoids, the DNA repair processes result first in expanded and then in contracted halos. By admixing a supercoiled plasma DNA of known length (38 kb) to nucleoids with contracted halos, the fractional halo expansion and the fraction of surviving plasmid supercoils can be measured from the same solution. Use of photodynamic DNA damage showed that the halo expansion was 11.6 times more sensitive than plasmid relaxation. Use of gamma-irradiation showed that the halo expansion was 3.6 times more sensitive than plasmid relaxation. The latter value demonstrates that one break per 137,000 bp results in the expansion of the halos to 63% of their maximal value. We estimate that this method will detect about 5000 breaks per nucleus containing 5 x 10(9) bp.     

Changes in DNA topology during spermatogenesis

DNA topology in histone- and protamine-depleted nuclei (nucleoids) from somatic cells, sperm, and spermatogenic cells was studied to determine if the superhelical configuration of DNA looped domains is altered during spermatogenesis. The expansion and contraction of nucleoid DNA was measured with a fluorescence microscope following exposure of nucleoids to different concentrations of ethidium bromide (EB). Nucleoids from Xenopus laevis erythrocytes, primary spermatocytes, and round spermatids, and from Rana catesbeiana sperm all exhibited a biphasic change (condensed-relaxed-condensed) in size as a function of exposure to increasing concentrations (0.5–100 g/ml) of EB, indicating that they contain negatively supercoiled DNA. In contrast, DNA in sperm nucleoids from Xenopus laevis and Bufo fowleri was relaxed and expanded at low (0.5–6 g/ml) EB concentrations, but became gradually condensed as the EB concentration was increased (6–100 g/ml). Nucleoids prepared from all cell types retained the general shape of the nucleus regardless of the superhelical configuration of the nucleoid DNA. Sperm nucleoid DNA condensed by 100 g/ml EB was relaxed by exposure to UV light, DNase I, proteinase K, or 4 M urea, but not by RNase A or 10 mM dithiothreitol. These results demonstrate that the DNA in sperm nucleoids is constrained in domains of supercoiling by nonbasic nuclear proteins. Negatively supercoiled DNA is present in nucleoids from cells with a full complement of histones, including Rana sperm, but not in nucleoids from Xenopus and Bufo sperm in which histones are replaced by intermediate-type protamines. Histone replacement in these species, therefore, is accompanied by unfolding of nucleosomal DNA and active removal of the negative supercoils. Results presented also suggest an important role for the nonbasic nuclear proteins of sperm in the morphogenesis of the nucleus and the arrangement of DNA.     

Dying of Gamma-Irradiated Escherichia coli Studied by the Use of Prophage

Loss of the biological activity of deoxyribonucleic acid in gamma-irradiated Escherichia coli cells was studied. The study is based on two sets of experimental data: (i) post-irradiation heat inducibility of the cells whose chromosomes were "labeled" with the thermoinducible lambdacI857ind prophage, and (ii) post-irradiation capacity of nonlysogenic cells to promote growth of the unirradiated lambdacI857ind phage. The results show that, at the beginning of incubation after irradiation, the number of plaques formed upon heat induction of lysogenic cells was much higher than the viable cell count of the nonheated culture. This high resistance of the heat inducibility gradually decreased during post-irradiation incubation. Finally, after a period of 4 h, there was no difference in sensitivity between the heat inducibility and the colony-forming ability of gamma-irradiated cells. The capacity of gamma-irradiated bacteria to support growth of unirradiated lambdacI857ind is radioresistant; this resistance, in contrast to that of heat inducibility, is much less affected during post-irradiation incubation. A continuous decrease in radioresistance of heat inducibility without a corresponding decrease in radioresistance of the capacity suggests that functional failure of initially undamaged and/or repaired parts of the chromosome gradually develops after irradiation. From the fact that after 4 h all colony formers are capable of being induced by heat, whereas no chromosomal activity can be detected in nonviable cells, two conclusions may be drawn: (i) gamma-irradiated E. coli cells destined to die reach their biological end point within 4 h of post-irradiation incubation; (ii) in most cells, functional failure of the whole chromosome is the immediate cause of death.     

Competence growth factors can cause modification in higher-order chromatin structure in mouse embryo 3T3 fibroblasts

The authors compared sedimentation rates of nucleoids from mouse embryo 3T3 fibroblasts cultured in the presence or absence of different cell growth factors. The results clearly showed that rapidly sedimenting nucleoids are obtained only when cells are supplied with any of the following competence growth factors: platelet-derived growth factor (PDGF), fibroblast growth factor (FGF), or the product of the oncogene v-sis (a peptide homologous to PDGF). The tumor promoter phorbol 12-myristate 13-acetate, an activator of protein kinase C and a partial mitogen, shares this property with the competence growth factors. Removal of these factors from the medium causes cells to enter Go and nucleoids to sediment at a slower rate. Protein synthesis is required for growth factor induction of change in nucleoid sedimentation, but inhibition of either DNA synthesis or DNA repair does not antagonize the effect of growth factors. Titration of nucleoids with ethidium bromide indicates that one possible mechanism for the nucleoid change is the unwinding of DNA in supercoiled loops. The results indicated that the nucleoid change constitutes a cell response to competence factors that might have an important role in cell proliferation.     

Measurement of DNA damage in mammalian cells using flow cytometry

A technique for the detection of DNA damage induced by radiation insult has been developed. Cells were lysed with a buffer containing 2 M sodium chloride to release the DNA in a supercoiled form, the nucleoid. These were stained with the DNA intercalating dye, ethidium bromide, and exposed to laser light within a flow cytometer. Scattered and fluorescent light was analyzed from the laser/nucleoid interaction following irradiation of viable cells with gamma rays. The addition of ethidium bromide to prepared nucleoids caused a reduction in scattered light due to condensation of the nucleoid. Irradiation of cells prior to nucleoid production and ethidium bromide treatment restricted this condensation and produced a dose-dependent increase in laser scatter. Nucleoids derived from human lymphocytes showed enhanced light scatter from 5 Gy, compared to Chinese hamster ovary (CHO) fibroblasts where doses above 10 Gy were required. Up to 30 Gy CHO nucleoids showed a dose-dependent reduction in the ethidium bromide fluorescence. This technique allows detection of altered light scattering and fluorescent behavior of nucleoids after cellular irradiation; these may be related to structural changes within the nucleus induced by the radiation. The use of flow cytometry compared to other methods allows a rapid analysis of nuclear damage within individual cells.     

Analysis of metal-induced DNA lesions and DNA-repair replication in mammalian cells

The potency of several metal compounds in causing lesions in DNA either directly or by exposure of intact cultured cells has been examined using the neutral conditions of nucleoid gradient sedimentation. HgCl2 was clearly the most potent inducer of single-strand breakage when added to isolated nucleoids or when nucleoids were prepared from cells treated with this compound. CaCrO4 , however, caused DNA-strand breaks in nucleoids isolated from cells treated with this agent but did not induce DNA strand breaks when added directly to nucleoids. Although less potent than HgCl2, NiCl2 also caused significant single strand breakage in isolated nucleoids or in nucleoids prepared from cells treated with this metal. Since strand breakage of DNA in intact cells may occur secondary to activation of DNA-dependent nucleases during repair replication, CsCl gradient density sedimentation was utilized to examine whether repair processes were induced by exposure of cells to NiCl2, HgCl2 and CaCrO4 . CaCrO4 and NiCl2 induced substantial DNA-repair activity at concentrations and exposure times where DNA lesions could not be detected whereas HgCl2 induced a 10-fold lower level of DNA-repair activity compared to CaCrO4 at optimal concentrations which again were below the concentrations of this metal that produced measurable DNA lesions. Both the induction of DNA-repair activity and DNA-strand breakage by these metals was concentration- and time-dependent. These results demonstrate some unique aspects of the interaction of HgCl2, NiCl2 and CaCrO4 with the DNA of intact cells and point to the possible important correlation of induction of DNA repair to carcinogenesis since nickel and chromate have clearly been implicated as carcinogens and induce considerable repair whereas HgCl2 is not considered a carcinogen and induces the least DNA repair despite its potency in producing DNA lesions.     

Purification and characterization of an endonuclease from calf thymus acting on irradiated DNA.

An endonuclease acting on DNA exposed to ultraviolet light or gamma-rays has been extensively purified from calf thymus. The enzyme has a pH optimum at pH 7.0-7.5, acts with equal efficiency in the presence of EDTA or divalent cations (Mg-2+ or Ca-2+), is inhibited by NaCl and tRNA and is inactivated by incubation at 50 degrees C. Its molecular weight, determined by Sephadex chromatography or sodium dodecylsulfate gel electrophoresis, is approx. 30 000. The enzyme catalyzes the formation of breaks with 5'-phosphate termini in double-stranded DNA irradiated with ultraviolet or gamma-rays. It does not act on unirradiated DNA or denatured DNA. Since in all these properties the enzymatic activity on ultraviolet- and gamma-irradiated DNA behaved similarly and since the two activities cochromatographed in all systems used during purification, we conclude that they are associated with the same protein. The site of action of the enzyme in ultraviolet-irradiated DNA is a photoproduct other than pyrimidine dimers. Such a photoproduct can also be induced by irradiation of the DNA in vivo, i.e. within the cells.     

Alkali lability and rapid initiation of excision repair following photoaffinity damage by ethidium azide

DNA damage and repair provoked by ethidium azide (EA) photoaffinity labeling in mouse leukemia cells was studied by measuring sedimentation properties of nucleoids in neutral sucrose gradients, and it was found that the strand opening step was faster than that which followed damage of cells by ultraviolet (UV) light. The two insults were compared at levels of damage which gave the same overall rates of repair synthesis in intact cells and which required the same length of time to complete repair, as judged by the restoration of supercoiling of the isolated nucleoids. In the case of UV, single-strand breaks in DNA were detectable at 30 min, maximum at 2 h, and the superhelical properties restored at 21 h. With photoaffinity labeling, single-strand breaks were prominent immediately, even when photolabeling of cells was done on ice, but restoration of DNA supercoiling still required 21 h. Photolabeling of isolated nucleoids or isolated viral DNA with EA failed to introduce DNA strand breaks. However, it was discovered that photoaffinity labeling of DNA with EA resulted in alkali labile sites shown by single strand breaks produced on alkaline sucrose sedimentation or by alkali exposure followed by sedimentation on neutral formamide gradients. These results suggest that the drug attachment sites should be identifiable by the location of such single strand breaks.     

Properties of condensed bacteriophage T4 DNA isolated from Escherichia coli infected with bacteriophage T4.

Methods developed for isolating bacterial nucleoids were applied to bacteria infected with phage T4. The replicating pool of T4 DNA was isolated as a particle composed of condensed T4 DNA and certain RNA and protein components of the cell. The particles have a narrow sedimentation profile (weight-average s=2,500S) and have, on average, a T4 DNA content similar to that of the infected cell. Their dimensions observed via electron and fluorescence microscopy are similar to the dimensions of the intracellular DNA pool. The DNA packaging density is less than that of the isolated bacterial nucleoid but appears to be roughly similar to its state in vivo. Host-cell proteins and T4-specific proteins bound to the DNA were characterized by electrophoresis on polyacrylamide gels. The major host proteins are the RNA polymerase subunits and two envelope proteins (molecular weights, 36,000 and 31,000). Other major proteins of the host cell were absent or barely detectable. Single-strand breaks can be introduced into the DNA with gamma radiation or DNase without affecting its sedimentation rate. This and other studies of the effects of intercalated ethidium molecules have suggested that the average superhelical density of the condensed DNA is small. However, these studies also indicated that there may be a few domains in the DNA that become positively supercoiled in the presence of high concentrations of ethidium bromide. In contrast to the Escherichia coli nucleoid, the T4 DNA structure remains condensed after the RNA and protein components have been removed (although there may be slight relaxation in the state of condensation under these conditions).     

Fluorescence-detected circular dichroism of ethidium in vivo and bound to deoxyribonucleic acid in vitro

Fluorescence-detected circular dichroism (FDCD) spectra are reported for ethidium in Escherichia coli cells and bound to E. coli DNA in vitro. FDCD bands are observed at 325 and 385 nm. These bands change amplitude as the ethidium to DNA ratio changes. Spectra are similar for in vivo and in vitro measurements. However, the bands at 325 and 385 nm disappear when ethidium binds to macromolecules without intercalating between base pairs. The results demonstrate that FDCD spectra can be measured in cell suspensions and indicate that ethidium binds to nucleic acids in E. coli cells by intercalation.     

Enzymatic digestion of DNA gamma-irradiated in aqueous solution separation of the digests by ion-exchange chromatography.

Aqueous solutions of DNA were gamma-irradiated in the presence and absence of oxygen and enzymatically hydrolysed by the combined action of pancreatic deoxyribonuclease (DNase I), snake-venom phosphodiesterase (PDE I), spleen phosphodiesterase (PDE II) and alkaline phosphatase. In contrast to unirradiated DNA, which is fully hydrolysed to nucleosides by these enzymes, gamma-irradiated DNA yields a series of oligonucleotides. Their isolation might enalbe the future identification of the chemical nature of DNA lesions.     

Melanin both causes and prevents oxidative base damage in DNA: quantification by anti-thymine glycol antibody.

The present study employs immunological methods to measure modified bases in DNA. A polyclonal antibody specific for thymine glycol was used to quantify the level of thymine glycol in calf thymus DNA gamma-irradiated in solutions containing varying concentrations of DOPA-eumelanin. Melanin decreased the number of thymine glycols produced by 200 Gy at low melanin concentrations. At high melanin concentrations, the number of thymine glycols increased. Thymine glycol was also produced in unirradiated DNA-eumelanin mixtures. DOPA-eumelanin was found to produce single-strand breaks in supercoiled phi X174 RF DNA. The breaks were measured by conversion of form I to form II as detected by agarose gel electrophoresis. The level of damage produced by melanin could be modulated by agents known either to stabilize or to scavenge active oxygen species. These studies demonstrate that melanin can both scavenge and generate active free radicals.     

Multiple restraints to the unfolding of spermidine nucleoids from Escherichia coli

Bacterial DNA is largely localized in compact bodies known as nucleoids. The structure of the bacterial nucleoid and the forces that maintain its DNA in a highly compact yet accessible form are largely unknown. In the present study, we used urea to cause controlled unfolding of spermidine nucleoids isolated from Escherichia coli to determine factors that are involved in nucleoid compaction. Isolated nucleoids unfolded at approximately 3.2 M urea. Addition of pancreatic RNase reduced the urea concentration for unfolding to approximately 1.8 M urea, indicating a role of RNA in nucleoid compaction. The transitions at approximately 3.2 and approximately 1.8 M urea reflected a RNase-sensitive and a RNase-resistant restraint to unfolding, respectively. Removal of the RNase-sensitive restraint allowed us to test for roles of proteins and supercoiling in nucleoid compaction and structure. The remaining (RNase-resistant) restraints were removed by low NaCl concentrations as well as by urea. To determine if stability would be altered by treatments that caused morphological changes in the nucleoids, transitions were also measured on nucleoids from cells exposed to chloramphenicol; the RNase-sensitive restraint in such nucleoids was stabilized to much higher urea concentrations than that in nucleoids from untreated cells, whereas the RNase-resistant transition appeared unchanged.