Chloramphenicol causes fusion of separated nucleoids in Escherichia coli K-12 cells and filaments.

Chloramphenicol is frequently used for better visualization of the Escherichia coli nucleoid. Here, we show that chloramphenicol causes not only rounding off of the nucleoid but also fusion of as many as four separated nucleoids. Nucleoid fusion occurred in fast-growing cells and in filaments obtained by dicF antisense RNA induction or in ftsZ84(Ts) and pbpB(Ts) mutants. Thus, treatment with chloramphenicol erroneously suggests that DNA segregation is inhibited.     

Proteins firmly bound to DNA in the E. coli nucleoid

The nucleoid isolated from E. coli cells was subjected to further deletion by treatment with 2 M NaCl. After disintegration of this nucleoid by ultrasonication, two fractions were obtained, i. e., a rapidly (RS) and slowly sedimenting (SS) ones. The protein, RNA and DNA patterns in the RS fraction are similar to that of the eukaryotic cell nuclear matrix. Electrophoretic analysis of total non-dissociating by 2 M NaCl proteins revealed that the RS and SS fractions predominantly contain proteins with Mr 31,27 and 23 kD. The protein with Mr = 31 kD is firmly bound to DNA, does not dissociate in the guanidine hydrochloride (4 M)-urea (5 M) mixture as well as in solution of 1% sodium-dodecyl sulphate and may be responsible for the chromosome binding to the E. coli membrane.     

Analysis by isopycnic centrifugation of isolated nucleoids of Escherichia coli.

The isolated, formaldehyde-fixed nucleoid of E. coli has been analyzed by isopycnic centrifugation in CsCl density gradients. The membrane-free nucleoid bands at a density of 1.69 +/- 0.02 g/cm3. The membrane-associated nucleoid bands at a density of 1.46 +/- 0.02 g/cm3. Both species sediment to equilibrium as nearly monodisperse bands in CsCl, suggesting that the nucleoid components of DNA, RNA and protein are present in relatively constant ratios. These ratios are constant regardless of the position of the nucleoids in the heterogeneous sedimentation profile of a preparative sucrose gradient. The fixed nucleoids remain condensed during isopycnic centrifugation and there is no detectable loss of RNA from the nucleoid.     

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.     

Effect of chemical fixatives on accurate preservation of Escherichia coli and Bacillus subtilis structure in cells prepared by freeze-substitution.

Five chemical fixatives were evaluated for their ability to accurately preserve bacterial ultrastructure during freeze-substitution of select Escherichia coli and Bacillus subtilis strains. Radioisotopes were specifically incorporated into the peptidoglycan, lipopolysaccharide, and nucleic acids of E. coli SFK11 and W7 and into the peptidoglycan and RNA of B. subtilis 168 and W23. The ease of extraction of radiolabels, as assessed by liquid scintillation counting during all stages of processing for freeze-substitution, was used as an indicator of cell structural integrity and retention of cellular chemical composition. Subsequent visual examination by electron microscopy was used to confirm ultrastructural conformation. The fixatives used were: 2% (wt/vol) osmium tetroxide and 2% (wt/vol) uranyl acetate; 2% (vol/vol) glutaraldehyde and 2% (wt/vol) uranyl acetate; 2% (vol/vol) acrolein and 2% (wt/vol) uranyl acetate; 2% (wt/vol) gallic acid; and 2% (wt/vol) uranyl acetate. All fixatives were prepared in a substitution solvent of anhydrous acetone. Extraction of cellular constituents depended on the chemical fixative used. A combination of 2% osmium tetroxide-2% uranyl acetate or 2% gallic acid alone resulted in optimum fixation as ascertained by least extraction of radiolabels. In both gram-positive and gram-negative organisms, high levels of radiolabel were detected in the processing fluids in which 2% acrolein-2% uranyl acetate, 2% glutaraldehyde-2% uranyl acetate, or 2% uranyl acetate alone were used as fixatives. Ultrastructural variations were observed in cells freeze-substituted in the presence of different chemical fixatives. We recommend the use of osmium tetroxide and uranyl acetate in acetone for routine freeze-substitution of eubacteria, while gallic acid is recommended for use when microanalytical processing necessitates the omission of osmium.     

A rapid method for preparation of bacterial plasmids

A method for isolating plasmids from Escherichia coli which requires less than 8 h from cell pellet to purified plasmid essentially free of protein, RNA, and chromosomal DNA is presented. By this procedure, amplified plasmid pBR322 was isolated from E. coli strain RR1. The final product had no detectable protein or RNA, and plasmid comprised approximately 99% of the total DNA. The procedure includes lysozyme treatment in hypertonic solution followed by lysis with a mild detergent in the presence of high salt and an RNase inhibitor--conditions which prevent unfolding of the bacterial nucleoid. After centrifuging out the nucleoid and cell debris, the nucleic acids are selectively precipitated with a neutral solution of sodium trichloroacetate and ethanol. RNA is degraded with RNase and the degradation products and RNase are eliminated through a second trichloroacetate/ethanol precipitation. Finally, the plasmid is resuspended and passed through a nitrocellulose filter to remove aggregates and any residual protein and single-stranded DNA--giving a plasmid preparation suitable for electrophoretic fractionation or cleavage with restriction nucleases.     

Introduction of proteins into living bacterial cells: distribution of labeled HU protein in Escherichia coli.

Growing bacterial cells forming division septa have sites near the septa that are sensitive to EDTA shock. Cells treated with EDTA incorporate proteins and other molecules from the surrounding medium, probably via vesiclelike lesions at the septa that are induced by EDTA. The amount of protein taken up is proportional to the protein concentration in the permeabilization medium. Incorporated molecules equilibrate throughout the cytoplasm, and those with affinity for DNA bind to the nucleoid. Conditions that promote the viability of permeabilized cells and help to avoid otherwise irreversible effects of EDTA are defined. Procedures for selecting cells that have incorporated protein and for studying the distribution of the protein and its effects in growing-dividing cells are described. The procedure may have several applications to molecular and cellular biology; however, we describe here the localization in living cells of the histonelike protein HU. Fluorescence microscopy of cells containing different amounts of fluorescein-labeled HU (varied from approximately 10(3) to 10(5) molecules per cell) showed that the HU concentrates in the nucleoid and is uniformly distributed throughout this structure. Control experiments demonstrated that unlabeled interior parts of the nucleoid can be resolved when labeled proteins that do not bind DNA or enter the nucleoid are introduced into living cells. It was concluded that in vivo added HU binds primarily DNA and that there are no intrinsic restrictions on major regions of the nucleoid to which the added HU protein may bind.     

High resolution autoradiography of Escherichia coli cells infected with bacteriophage R17

Granboulan, Nicole (Institute de Recherches sur le Cancer, Villejuif, Seine, France), and Richard M. Franklin. High-resolution autoradiography of Escherichia coli cells infected with bacteriophage R17. J. Bacteriol. 91:849-857. 1966.-The ultrastructural alterations in Escherichia coli infected with the RNA bacteriophage R17 were further investigated by means of the technique of high-resolution autoradiography. Tritiated precursors to ribonucleic acid (RNA), deoxyribonucleic acid (DNA), and protein were employed in separate experiments. A striking inhibition of cellular RNA, DNA, and protein synthesis was noted. Whereas normal RNA synthesis occurs in the nucleoid, in infected cells RNA synthesis is predominantly cytoplasmic, but later in the latent period, and during the stage of active viral growth, the label is localized in a polar region. In the late stages of viral growth, RNA synthesis occurs only around the crystals. Protein synthesis also becomes localized in a polar region, but DNA synthesis remains confined to the nucleoid. Under conditions of chloramphenicol inhibition of viral-coat protein synthesis, RNA label is localized in the paranuclear lesion, providing further indication that RNA forms this fibrillar structure.     

HU-GFP and DAPI co-localize on the Escherichia coli nucleoid

The heterodimeric HU protein, one of the most abundant DNA binding proteins, plays a pleiotropic role in bacteria. Among others, HU was shown to contribute to the maintenance of DNA superhelical density in Escherichia coli. By its properties HU shares some traits with histones and HMG proteins. More recently, its specific binding to DNA recombination and repair intermediates suggests that HU should be considered as a DNA damage sensor. For all these reasons, it will be of interest to follow the localization of HU within the living bacterial cells. To this end, we constructed HU-GFP fusion proteins and compared by microscopy the GFP green fluorescence with images of the nucleoid after DAPI staining. We show that DAPI and HU-GFP colocalize on the E. coli nucleoid. HU, therefore, can be considered as a natural tracer of DNA in the living bacterial cell.     

Dynamic state of DNA topology is essential for genome condensation in bacteria

In bacteria, Dps is one of the critical proteins to build up a condensed nucleoid in response to the environmental stresses. In this study, we found that the expression of Dps and the nucleoid condensation was not simply correlated in Escherichia coli, and that Fis, which is an E. coli (gamma-Proteobacteria)-specific nucleoid protein, interfered with the Dps-dependent nucleoid condensation. Atomic force microscopy and Northern blot analyses indicated that the inhibitory effect of Fis was due to the repression of the expression of Topoismerase I (Topo I) and DNA gyrase. In the Deltafis strain, both topA and gyrA/B genes were found to be upregulated. Overexpression of Topo I and DNA gyrase enhanced the nucleoid condensation in the presence of Dps. DNA-topology assays using the cell extract showed that the extracts from the Deltafis and Topo I-/DNA gyrase-overexpressing strains, but not the wild-type extract, shifted the population toward relaxed forms. These results indicate that the topology of DNA is dynamically transmutable and that the topology control is important for Dps-induced nucleoid condensation.     

Membrane-bound mitochondrial DNA: isolation, transcription and protein composition.

Mitochondrial membrane-bound DNA complex from bovine heart mitochondria lysed in the presence of Triton X-100 was isolated by differential centrifugation. The yield of "nucleoid" is about 30 microgram protein/mg mitochondrial protein. It contains about 3-5 microgram DNA/mg protein and varying amounts of RNA. The heart mitochondrial nucleoid actively synthesizes RNA. The nucleoid fraction contains about sixteen different proteins as evidenced by urea-SDS gel electrophoresis and about twenty-one proteins as evidenced by acid-urea gel electrophoresis. It appears that the nucleoid is attached to the inner membrane since it does contain cytochromes.     

Mutual relationship between antibiotics and resting spores of Bacillus subtilis: morphological changes and macromolecular synthesis after germination of spores treated with cyclic polypeptide and aminoglycoside antibiotics

Morphological changes and synthesis of DNA, RNA, protein, and cell wall were investigated during germination of resting spores of Bacillus subtilis exposed transiently to the cyclic polypeptide antibiotics, polymyxin B and gramicidin S, and the aminoglycoside antibiotics, streptomycin, kanamycin, and gentamicin. Normal germinated spores showed breaks of the spore coat, a diminution in size and a fibrillar appearance of the cortex, a swelling core, a cell wall as thick as that of vegetable cells, some mesosomes and DNA fibrils. On the other hand, no breaks of the spore coat, a spore core with a slight swelling and irregular form, a thin cell wall, no demonstration of the nuclear material and no granularity in the cytoplasm were characteristic of the germinated spores derived from polymyxin B- and gramicidin S-treated resting spores. With gramicidin S-treated germinated spores a few vacuoles were formed in the cytoplasm. Both polymyxin B- and gramicidin S-treated germinated spores showed little or no synthesis of DNA, RNA, and protein. The vegetative cells derived from streptomycin-treated resting spores demonstrated several finely granular regions in the cytoplasm and a disorder of the fibrillar nucleoid, and their autolysis occurred early. Their DNA and RNA synthesis was normal, whereas protein synthesis was low. In spite of no occurrence of cell division and very low protein synthesis, the most striking characteristics of the outgrowing cells derived from kanamycin-treated resting spores were a markedly thickened cell wall and a continuous incorporation of labeled D-alanine suggesting cell wall synthesis; RNA synthesis was slightly lower and DNA synthesis was almost normal. The outgrowing cells from gentamicin-treated resting spores also revealed relatively thick cell walls and a very slight incorporation of labeled D-alanine. Their DNA and RNA synthesis was fairly low and protein synthesis was almost completely inhibited. These results coincide with the growth curves of individual antibiotic-treated resting spores.     

A comparative proteomic approach to better define Deinococcus nucleoid specificities

Compared to radiation-sensitive bacteria, the nucleoids of radiation-resistant Deinococcus species show a higher degree of compaction. Such a condensed nucleoid may contribute to the extreme radiation resistance of Deinococcus by limiting dispersion of radiation-induced DNA fragments. Architectural proteins may play a role in this high degree of nucleoid compaction, but comparative genomics revealed only a limited number of Deinococcus homologs of known nucleoid-associated proteins (NAPs) from other species such as Escherichia coli. A comparative proteomic approach was used to identify potentially novel proteins from isolated nucleoids of Deinococcus radiodurans and Deinococcus deserti. Proteins in nucleoid enriched fractions were identified and semi-quantified by shotgun proteomics. Based on normalized spectral counts, the histone-like DNA-binding protein HU appeared to be the most abundant among candidate NAPs from both micro-organisms. By immunofluorescence microscopy, D. radiodurans HU and both DNA gyrase subunits were shown to be distributed throughout the nucleoid structure and absent from the cytoplasm. Taken together, our results suggest that D. radiodurans and D. deserti bacteria contain a very low diversity of NAPs, with HU and DNA gyrase being the main proteins involved in the organization of the Deinococcus nucleoids.     

Use of on-section immunolabeling and cryosubstitution for studies of bacterial DNA distribution.

Escherichia coli cells were very rapidly frozen and substituted at a low temperature with 3% glutaraldehyde in acetone. Infiltration and embedding with Lowicryl K4M were carried out at -35 degrees C. This procedure resulted in good structural preservation of both the nucleoid morphology and its DNA plasm, such that immunolabeling with the protein-A gold technique could be carried out. With antibodies specific for either double-stranded DNA (dsDNA) or single-stranded DNA (ssDNA), it was shown that dsDNA was present throughout the nucleoid but that ssDNA was located on the nucleoid periphery. Chloramphenicol-treated cells, in which protein synthesis but not DNA replication is stopped, produced a characteristic ringlike nucleoid shape and had both dsDNA and ssDNA present throughout the annular section of the DNA plasm. The relationship between metabolically active DNA and overall bacterial genome organization is discussed.