Nucleotides of rat liver cells: electron microscope analysis

Nucleoids of rat hepatocytes have been studied with the aid of electron microscopy. Proceeding from a morphologic comparison of nucleoids obtained at different conditions, it has been inferred that rosette-like structures are the basic element of nuclear DNA loop organization detected by sedimentation and fluorescent methods. Divalent metal ions play a significant role in stabilizing rosette-like structures. A scheme for DNA organization in the somatic cell interphase nucleus is suggested.     

A limited loss of DNA compaction accompanying the release of cytoplasm from cells of Escherichia coli

The DNA of bacteria is compacted into nucleoids. We have lysed cells of Escherichia coli under conditions in which the cell envelope is retained. The extent of DNA compaction was determined by light microscopy, comparing DAPI fluorescence and phase contrast images. The release of cytoplasm upon lysis allowed the nucleoidal DNA to expand to fill the residual cell boundaries, supporting the role of cytoplasmic crowding in nucleoid compaction. The addition of polylysine allowed lysis with retention of DNA compaction. Furthermore, chloramphenicol treatment of cells resulted in nucleoids which were more resistant to decompaction upon lysis.     

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.     

Nucleoids, a subnuclear system capable of chain elongation

Nucleoids, prepared by salt extraction of non-DNase-digested nuclei, have properties similar, but not identical, to those of nuclear matrices which are prepared by salt extraction of DNase-digested nuclei. Nuclear matrices retained less pulse-labelled DNA, slightly less bound DNA polymerase alpha and DNA primase, but had greater in vitro DNA synthesis and in vitro priming. Nucleoids contained larger (110 S) DNA chains than nuclear matrices (30 S). Each type of residual nuclear structure could synthesize 4.5 S Okazaki fragments. When extracted with increasing concentrations of salt, DNase-digested nucleo lost the ability for further elongation of the 4.5 S DNA intermediate after 0.1-0.2 M NaCl, whereas undigested nuclei retained this ability up to 0.9 M NaCl. Chain elongation to 28 S DNA chains could be restored to nucleoids, but not to nuclear matrices, by the addition of nuclear extracts.     

Reduction of DNA primase activity in aging but still proliferating cells

The basis of the well-known decline in cell proliferation with increasing passage number of human diploid fibroblast-like cell cultures is not known. It has been found that DNA synthesis was deficient in the remaining but still proliferating cells, but when appropriate corrections reflecting the remaining dividing cells were made, the amount of DNA polymerase alpha bound to nuclear matrices was normal [Collins and Chu: Journal of Cellular Physiology 124:165-173, 1985]. In the present study, the declining percentages of S-phase and dividing cells were determined to provide better estimates of functional culture age than passage number. The amounts of DNA polymerase alpha and DNA primase activity were determined in cell lysates, permeabilized cells, and bound to nucleoids, which are residual nuclear structures similar to nuclear matrices except that no DNase-digestion step is employed. As expected, IMR 90 DNA synthesis declined with age, even after corrections for the declining numbers of proliferating cells. DNA polymerase alpha and DNA primase activity in cell lysates, permeabilized cells, and bound to nucleoids declined with increasing age. However, after appropriate corrections for the declining fraction of proliferating cells, the only activity that declined was that of DNA primase bound to nucleoids. Thus, a decrease in the binding of DNA primase to the nuclear site of DNA synthesis may account for the decreased DNA synthesis in aging but still proliferating cells.     

The effect of temperature on DNA structural transitions under the action of Cu2+ and Ca2+ ions in aqueous solutions

The work examines the structural transitions of DNA under the action of Cu2+ and Ca2+ ions in aqueous solution at temperatures of 29 and 45 degrees C by ir spectroscopy. Upon binding to the divalent ions studied, DNA transits into the compact state both at 29 and 45 degrees C. In the compact state DNA remains in B-form limits. The compaction process is of high positive cooperativity. As temperature increases the divalent metal ion concentration required to induce DNA compaction decreases in the case of Cu(2+)-induced compaction and increases in the case of Ca(2+)-induced compaction. It is suggested that the mechanism of the temperature effect on DNA compaction in the presence of Cu2+ ions possessing higher affinity for DNA bases differs from that of the temperature influence on Ca(2+)-induced DNA compaction. In the case of copper ions the determining factor is the increase of binding constants of the Cu2+ ions interacting with the denatured parts formed on DNA while in the case of calcium ions it is the decreased screening action of counterions upon the increase of their hydration with temperature. The efficiency of divalent metal ions studied in inducing DNA compaction depends on hydration of counterions. DNA compaction occurs in a narrow interval of Cu2+ concentrations. As the Cu2+ ion concentration increases, DNA compaction is replaced with Cu(2+)-induced DNA aggregation. At elevated temperatures Cu(2+)-induced DNA compaction could acquire a phase transition character.     

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.     

Electron Microscope and Autoradiographic Study of Ultrastructural Aspects of Competence and Deoxyribonucleic Acid Absorption in Bacillus subtilis: Localization of Uptake and of Transport of Transforming Deoxyribonucleic Acid in Competent Cells

With the aid of serial-section electron microscopy two types of mesosomes can be distinguished in cells of competent cultures of Bacillus subtilis: (i) mesosomes connected to the plasma membrane only (plasma membrane mesosomes) and (ii) mesosomes which extend from the plasma membrane into the nuclear bodies (nuclear mesosomes). Contrary to plasma membrane mesosomes, nuclear mesosomes are absent from the tip zones. Electron microscopic autoradiography of sections of Bacillus subtilis cells exposed to [(3)H]thymidine-labeled transforming deoxyribonucleic acid (DNA) for a short period of time shows that the DNA becomes associated with mesosomes. As a function of time the DNA migrates towards the nucleoids. Transport of DNA is completed within 15 to 60 min after termination of DNA uptake. During its migration the DNA continues to be associated with mesosomes, presumably with nuclear mesosomes. DNA initially associated with plasma membrane mesosomes of the tip zones is probably transported first towards the middle zones peripherally and from there towards the nucleoids.     

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.     

Isolation of the Escherichia coli nucleoid

Numerous protocols for the isolation of bacterial nucleoids have been described based on treatment of cells with sucrose-lysozyme-EDTA and subsequent lysis with detergents in the presence of counterions (e.g., NaCl, spermidine). Depending on the lysis conditions both envelope-free and envelope-bound nucleoids could be obtained, often in the same lysate. To investigate the mechanism(s) involved in compacting bacterial DNA in the living cell, we wished to isolate intact nucleoids in the absence of detergents and high concentrations of counterions. Here, we compare the general lysis method using detergents with a procedure involving osmotic shock of Escherichia coli spheroplasts that resulted in nucleoids free of envelope fragments. After staining the DNA with DAPI (4',6-diamidino-2-phenylindole) and cell lysis by either isolation procedure, free-floating nucleoids could be readily visualized in fluorescence microscope preparations. The detergent-salt and the osmotic-shock nucleoids appeared as relatively compact structures under the applied ionic conditions of 1 M and 10 mM, respectively. RNase treatment caused no dramatic changes in the size of either nucleoid.     

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.     

MFP1 is a thylakoid-associated,nucleoid-binding protein with a coiled-coil structure

Plastid DNA, like bacterial and mitochondrial DNA, is organized into protein–DNA complexes called nucleoids. Plastid nucleoids are believed to be associated with the inner envelope in developing plastids and the thylakoid membranes in mature chloroplasts, but the mechanism for this re-localization is unknown. Here, we present the further characterization of the coiled-coil DNA-binding protein MFP1 as a protein associated with nucleoids and with the thylakoid membranes in mature chloroplasts. MFP1 is located in plastids in both suspension culture cells and leaves and is attached to the thylakoid membranes with its C-terminal DNA-binding domain oriented towards the stroma. It has a major DNA-binding activity in mature Arabidopsis chloroplasts and binds to all tested chloroplast DNA fragments without detectable sequence specificity. Its expression is tightly correlated with the accumulation of thylakoid membranes. Importantly, it is associated in vivo with nucleoids, suggesting a function for MFP1 at the interface between chloroplast nucleoids and the developing thylakoid membrane system.     

Cooperative transitions of isolated Escherichia coli nucleoids: implications for the nucleoid as a cellular phase

The genomic DNA of Escherichia coli occurs in compact bodies known as nucleoids. Organization and structure of nucleoids are poorly understood. Compact, characteristically shaped, nucleoids isolated by the polylysine-spermidine procedure were visualized by DNA fluorescence microscopy. Treatment with urea or trypsin converted compact nucleoids to partially expanded forms. The transition in urea solutions was accompanied by release of most DNA-associated proteins; the transition point between compact and partially expanded forms was not changed by the loss of the proteins nor was it changed in nucleoids isolated from cells after exposure to chloramphenicol or from cells in which Dps, Fis, or H-NS and StpA had been deleted. Partially expanded forms became dispersed upon RNase exposure, indicating a role of RNA in maintaining the partial expansion. Partially expanded forms that had been stripped of most DNA-associated proteins were recompacted by polyethylene glycol 8,000, a macromolecular crowding agent, in a cooperative transition. DNA-associated proteins are suggested to have relatively little effect on the phase-like behavior of the cellular nucleoid. Changes in the urea transition indicate that a previously described procedure for compaction of polylysine-spermidine nucleoids may have an artifactual basis, and raise questions about reports of repetitive local structures involving the DNA of lysed cells.     

Cytoplasmic Nucleoids in the Generative Cell,Sperm Cell and Egg Cell of Calystegia heder acea

Cytoplasmic nucleoids in the generative cell of mature pollens, sperm cells of pollens cultured in vitro and egg cell of mature embryo sac in Calystegia bederacea Wall. were studied by means of the DNA fluorochrome DAPI in conjunction with epitluorescence microscopy for in situ detection of cytoplasmic DNA in cells. Results showed that many cytoplasmic DNA nucleoids were present in the generative cell and speim cells. Two types of nucleoids were observed, one with big and strong fluorescent dots, and the other with small and weak fluorescence. Many dot-shaped and a few circle-shaped nucleoids were randomly distributed in the thin layered cytoplasm of the egg cell. It was suggested that different types of nucleoids might represent plastid DNA and mitochondrion DNA respectively. Results provided cytological data that Calystegia hederaeea had the potential of plastid DNA biparental inheritance, and the mode of which merits further study via molecular biological methods.     

打碗花生殖细胞,精细胞及卵细胞中的细胞质类核

已有不少超微结构的资料阐明被子植物双亲和单亲母系质体遗传的细胞学基础。近年应用DAPI荧光染色的方法,可快速地从检测质体DNA存在的状况确定被子植物中具双亲遗传潜能的种。从质体的类核存在与否判断质体遗传方式为母系遗传或双亲遗传与已有的遗传分析结论基本一致,只有少数种类是矛盾的。DAPI荧光技术可以认为是研究细胞质遗传机理的一个重要手段。我们曾证明旋花科牵牛属植物生殖细胞、精细胞中存在细胞质类核,确定其具双亲或单亲父系质体遗传的潜能,并用RFLP技术进一步确定其为质体父系遗传型。本研究证明旋花科的打碗花属生殖细胞、精细胞和卵细胞中细胞质类核存在的状况与牵牛属的相似,提供了打碗花可能在质体遗传上与牵牛属 具相同的遗传方式的资料。     

Stabilization of Compact Spermidine Nucleoids fromEscherichia coliunder Crowded Conditions: Implications forin VivoNucleoid Structure

Nucleoids fromEscherichia coliwere isolated in the presence of spermidine at low salt concentrations. The nucleoids denature at relatively low temperatures or salt concentrations, yielding broad slowly sedimenting zones and/or macroscopic aggregates upon sucrose gradient centrifugation. Denaturation is accompanied by a loss of a characteristically compact shape as visualized by light and electron microscopy. Addition of polyethylene glycol or dextran prevents these changes, extending the range of stability of the isolated nucleoids to temperatures and ionic conditions like those which commonly occurin vivo.The effects of the polymers are consistent with stabilization by macromolecular crowding. Enzymatic digestion of the nucleoid DNA primarily releases three small proteins (H-NS, FIS, and HU) and RNA polymerase, as well as residual lysozyme from the cell lysis procedure. If isolated nucleoids are extracted with elevated salt concentrations under crowded, stabilized conditions, two of the proteins (HU and lysozyme) are efficiently removed and the compact form of the nucleoids is retained. These extracted nucleoids maintain their compact form upon reisolation into the initial uncrowded low-salt medium, indicating that HU, the most common “histone-like” protein ofE. coli,is not a necessary component for maintaining compaction in these preparations.