DNA replication and nuclear architecture

The model of in situ DNA replication provided by immunofluorescence and confocal imaging is compared with observations obtained by electron microscopic studies. Discrepancies between both types of observations call into question the replication focus as a persistent nuclear structure and as a replication entity where DNA replication takes place. Most electron microscopic analyses reveal that replication sites are confined to dispersed chromatin areas at the periphery of condensed chromatin, and the distribution of replication factors exhibits the same localization pattern. Moreover, rapid migration of newly synthesized DNA from the replication sites towards the interior of condensed chromatin regions obviously takes place during S-phase. It implies modifications of replication domains, hardly detectable by fluorescence microscopy. The confrontation of different observations carried out at light microscopic or electron microscopic levels of resolution lead to a conclusion that a combination of in vivo fluorescence analysis with a subsequent ultrastructural investigation performed on the same cells will represent an optimal approach in future studies of nuclear functions in situ.     

Eucaryotic DNA Replication Complex: Study of Structure and Function Using the Affinity Modification Technique

Eucaryotic DNA replication complex is now one of the most intensively studied subjects of molecular biology and biochemistry. In addition to detailed studies on the structures and functions of individual DNA polymerases involved in this process, other enzymes and protein factors are also given much attention. The structures and functions of proteins in the replication complexes are studied by various approaches, including X-ray diffraction analysis. At present, this approach provides sufficient information about the structures and functions of individual biopolymers and their complexes with ligands. However, this approach is unsuitable for studies on proteins, which cannot be cloned and isolated in amounts sufficient for X-ray diffraction analysis. Moreover, this approach is inapplicable for studies on multicomponent systems, such as DNA replication and repair complexes. Furthermore, data of X-ray diffraction analysis virtually never characterize the variety of dynamic interactions in enzymatic systems. Affinity modification is an alternative and rather successful approach for studies on structure-functional organization of supramolecular structures. This approach can be used for studies on individual enzymes and their complexes with substrates and also on systems consisting of numerous interacting proteins and nucleic acids. The purpose of this review is to analyze the available data obtained by affinity modification studies on the eucaryotic replication complex.     

Site-specific initiation of DNA replication within the non-transcribed spacer of Physarum rDNA.

Physarum polycephalum rRNA genes are found on extrachromosomal 60 kb linear palindromic DNA molecules. Previous work using electron microscope visualization suggested that these molecules are duplicated from one of four potential replication origins located in the 24 kb central non-transcribed spacer [Vogt and Braun (1977) Eur. J. Biochem., 80, 557-566]. Considering the controversy on the nature of the replication origins in eukaryotic cells, where both site-specific or delocalized initiations have been described, we study here Physarum rDNA replication by two dimensional agarose gel electrophoresis and compare the results to those obtained by electron microscopy. Without the need of cell treatment or enrichment in replication intermediates, we detect hybridization signals corresponding to replicating rDNA fragments throughout the cell cycle, confirming that the synthesis of rDNA molecules is not under the control of S-phase. The patterns of replication intermediates along rDNA minichromosomes are consistent with the existence of four site-specific replication origins, whose localization in the central non-transcribed spacer is in agreement with the electron microscope mapping. It is also shown that, on a few molecules, at least two origins are active simultaneously.     

Fine structure of interphase nuclei

The initiation and replication sites of DNA synthesis in the plasmodial nuclei of Physarum polycephalum were studied with electron microscopic autoradiography. By using both thin sectioning and whole mount techniques, it was shown that the dense chromatin masses in the nucleus consisted of predominantly elementary chromatin-like fibrils, approximately 300 Å in diameter while the electron transparent region in the nucleus consisted of predominantly finer fibrils, less than 100 Å in diameter. With electron microscopic autoradiography it was found that (1) the initiation sites of DNA synthesis were definitely in the boundary regions between the dense chromatin masses and the electron transparent region, (2) the initiation and replication sites of DNA synthesis were definitely not on the nuclear membrane, (3) within a few minutes, replication sites migrated from the initiation sites to the electron transparent region and (4) in this electron transparent region, almost all of the nuclear DNA was synthesized.     

Application of Electron Diffraction to Biological Electron Microscopy

Three methods by which electron diffraction may be applied to problems in electron microscopy are discussed from a fundamental point of view, and experimental applications with biological specimens are demonstrated for each case. It is shown that wide-angle electron diffraction provides valuable information for evaluating specimen damage that can occur either during specimen preparation or while in the electron beam. Dark-field electron microscopy can be used both to enhance the image contrast and to provide highly restricted and therefore highly specific information about the object. Low-angle electron diffraction provides quantitative information about the object structure in the range from 20 A to ~ 1000 A. Lowangle electron diffraction also demonstrates the important role of Fourier contrast with biological specimens, which are usually characterized by structural features with dimensions of 20 A or larger.     

Evidence for multiple vegetative DNA replication origins and alternative replication mechanisms of bovine papillomavirus type 1

By following up the chance detection in the electron microscope of a DNA replication intermediate within a preparation of bovine papillomavirus (BPV-1) DNA isolated from purified virus particles, information was obtained about the mechanism of BPV-1 genome replication during the final stages of virus multiplication in naturally infected bovine wart tissue. The structure of viral replication intermediates was investigated by electron microscopic analysis of viral DNA linearized by digestion with restriction endonucleases which cleave the circular BPV-1 chromosome at defined sites. Both Cairns and rolling circle-type molecules were identified. Furthermore, replication eyes were widely distributed within the viral genome, indicating that vegetative BPV-1 DNA replication origins are largely uncoupled from previously described plasmid maintenance sequence elements.     

Plasmid deoxyribonucleic acid replication in Streptomyces griseus

A series of electron micrographs showing the presence of different molecular forms representing various replication stages of plasmid deoxyribonucleic acid from Streptomyces griseus was obtained. Based upon an analysis of these electron micrographs, a tentative model for plasmid deoxyribonucleic acid replication in S. griseus is proposed.     

Electron microscopy of thin protein crystal sections.

In continuation of an earlier publication (Hoppe et al., 1968), further experiments are described here on the preparation of thin film sections of embedded protein crystals for investigation by electron microscopy and electron diffraction. Several embedding media were compared, the best being Aquon. Periodicities were observed in electron micrographs as well as in electron diffraction patterns. In diffraction experiments the best resolution observed was approximately 10 to 11 Å.     

Origin and mode of replication of plasmids pE194 and pUB110

Replication of the multicopy antibiotic resistance plasmids pE194 and pUB110 has been studied in Bacillus subtilis. Based on electron microscopic analysis of replication intermediates and on evidence from deletants, we have determined that both plasmids replicate unidirectionally from fixed origins by a Θ mechanism. The location of these origins and the directions of replication have been determined relative to the physical maps. A cointegrate of pE194 and pUB110 has also been studied and evidence is presented from electron microscopy, temperature resistance, and copy number analysis that the cointegrate uses both parental replication origins.     

Direct determination of crystallographic phases for diffraction data from phospholipid multilamellar arrays.

Direct determination of crystallographic phases based on probabilistic of sigma 1 and sigma 2 "triplet" structure invariants has been found to be an effective technique for structure analysis with lamellar x-ray or electron diffraction intensity data from phospholipids. In many cases, nearly all phase values are determined, permitting a structure density (electron density for x-ray diffraction; electrostatic potential for electron diffraction) map to be calculated, which is directly interpretable in terms of known bilayer lipid structure. The major source of error is found to be due to the distortion of observed electron diffraction intensity data by incoherent multiple scattering, which can significantly affect the appearance of the electrostatic potential map, but not the success of the phase determination, as long as the observed Patterson function can be interpreted.     

Fine structures of interphase nuclei : III. Replication site analysis of DNA during the S period of Crepis capillaris

The replication sites and morphological steps of chromosomal condensation during S period in the nuclei of Crepis capillaris root tip cells have been studied with light and electron microscopic autoradiography. From light microscopic autoradiographic observations, the S period can be divided with three portions, early S, mid S, and late S period. Labelled nuclei for each portion of the S period have also been found by using electron microscopic autoradiography. With electron microscopic autoradiography it has been found that in early, mid, and late S period, the replication sites are distributed in the electron transparent regions, interspersed with dense chromatin masses of variable size which are distributed throughout the nucleus. The time-dependent behavior of the label indicates that when compared with either mid or early replicated DNA, a majority of this chromatin, which contains predominantly late replicated DNA, is the earliest chromatin to be organized into the condensed chromatin. They are organized into the condensed chromatin within 15 min after the termination of replication.     

Electron diffraction studies of molecular ordering and orientation in phospholipid monolayer domains.

The molecular order and orientation of phase separated domains in monolayers of DP(Me)PE and DP(Me)2PE were determined by electron diffraction. Dark and bright fluorescent domains at the air-water interface were observed by fluorescence microscopy. The monolayers were transferred to Formvar coated electron microscope grids for electron diffraction studies. The positions of domains on the marker grids were recorded in fluorescence micrographs, which were used as guide maps to locate these domains in the electron microscope. Selected area electron diffraction patterns were obtained from predetermined areas within and outside the dark domains. Sharp hexagonal diffraction patterns were recorded from dark domains, and diffuse diffraction rings from bright areas in between dark domains. The diffraction results indicated that the dark domains and bright areas were comprised of lipid molecules in solid and fluid states, respectively. The orientation of diffraction patterns from adjacent locations within a dark domains changed gradually, indicating a continuous bending of the molecular packing lattice vector within these domains. Orientation directors in U-shaped DP(Me)2PE domains followed the turn of the arm; no vortex nor branching was indicated by electron diffraction. Directors branching from the "stem" of highly invaginated DP(Me)PE domains usually occurred at twinning angles of n pi/3 from the stem director, which would minimize packing defects in the development of thinner branches. Electron diffraction from local areas of individual domains proved that dark fluorescent domains were solid ones, and that pseudo-long range order existed in these solid domains.     

Demonstration of chromosome replication by BrdU antibody technique and electron microscopy

Summary We describe the use of different reporter groups in visualizing replication patterns on metaphase chromosomes after BrdU incorporation by the BrdU antibody technique for the electron microscope. There is an inverse correlation between the density of the label and the size of the reporter particles. This observation alludes to stereo problems interfering with the access of the labeled antibodies into the chromatin. The use of silver enhancement enables easy detection of 1-nm and 5-nm gold particles, which make replication patterns visible in the electron microscope as does the diaminobenzidine/ H₂O₂ reaction. Possible consequences for the demonstration of replication patterns and for nonradioactive DNA in situ hybridization are discussed.     

The glucan–chitin complex in Saccharomyces cerevisiae. IV. The electron diffraction of crustacean and yeast cell wall chitin

Crustacean and yeast cell wall chitin were analyzed by means of transmission electron microscopy and selected-area diffraction. Single fibrils 8–25 nm wide have been observed in the micrographs of crustacean chitin. Analysis of a series of diffraction patterns obtained from thin crustacean chitin platelets yielded results which were in a better agreement with the theoretical structural model than those measured earlier. In this respect electron diffraction is shown to be superior to the more commonly used x-ray diffraction. Yeast cell wall chitin had a less perfect structure than the crustacean chitin. Single fibrils were not observed on the micrographs and electron diffraction patterns did not show any preferred fiber orientation. The evaluation of electron-diffraction patterns of both the primary septum and the adjacent circular zone of scar ring led to the conclusion that α-chitin is present in both these parts of the mother bud scar.     

Electron microscopic analysis of chromatin replication in the cellular blastoderm drosophila melanogaster embryo

Transmission electron microscopic techniques were used to study the spatial distribution of replicons and the ultrastructure of chromatin in the S phase genome of cellular blastoderm Drosophila melanogaster embryos. We observed chromatin exhibiting distinct bifurcations along each fiber during the initial 20 min of the first cell cycle of blastulation. We interpreted the “bubble-like” configurations produced by adjacent bifurcations as intermediate structures in chromatin replication (that is, replicons). We observed homologous ribonucleoprotein (RNP) fiber arrays on both chromatid arms within some replicons, implying DNA sequence homology and reinforcing the identification of such arms as daughter chromatid fibers. We did not observe replicon configurations on chromatin obtained from embryos staged at more than 20 min into cellular blastulation. Daughter chromatid fibers, however, were identified by the presence of identical RNP fiber arrays on chromatid strands arranged in parallel on the electron microscope grid.We examined the distribution of replicon structures on the cellular blastoderm genome and compared it with electron microscopic data on DNA replication in cleavage embryos (Blumenthal, Kriegstein and Hogness, 1973). S phase is completed in slightly < 4 min during cleavage, or approximately one fifth the time required for DNA synthesis in cellular blastoderm embryos. The mean distance separating adjacent replication origins at cellularization was estimated to be 10.6 kilobases (kb), a value 35% greater than the 7.9 kb inter-origin average determined for cleavage embryos. In contrast to the near-simultaneous activation of replication origins during cleavage replication, we observed that replication origins are not activated synchronously at cellular blastulation. We concluded that the marked increase in the duration of S phase is effected by a reduction in the frequency of replication activation events which occur asynchronously during genome replication at cellularization.We found that the ultrastructure of newly replicated chromatin exhibited a morphology indistinguishable from nucleosomal chromatin. Unreplicated chromatin fibers separating adjacent replicons also exhibit spherical subunits. We inferred that the spherical structures on replicating chromatin are nucleosomes and concluded that histones are not disassociated from the DNA significantly prior to DNA replication, and that a very rapid reassociation of nucleosomes occurs on both daughter DNA molecules following replication.     

Location of the origin of replication for the 7.5-kb Chlamydia trachomatis plasmid.

The hypothetical origin of replication for the 7.5-kb plasmid common to Chlamydia trachomatis is believed to be in a region of the plasmid that contains four 22-bp tandem repeats preceded by an A-T-rich region. To test this hypothesis, replication of plasmid DNA in metabolically active reticulate bodies of the Lymphogranuloma venereum biovar of C. trachomatis was examined by electron microscopy. The results presented show that the origin of replication appears to be near the tandem repeats of pCHL2. In addition, replication of the 7.5-kb plasmid is unidirectional, and the copy number during replication is 7-10. The evidence presented suggests that C. trachomatis has a homologue to the Escherichia coli dnaA gene and that this homologue might be involved in replication of the C. trachomatis 7.5-kb plasmid.     

Electron diffraction from single crystals of DNA.

Crystals of DNA have been grown in a form suitable for study by electron diffraction and electron microscopy. Preliminary electron diffraction patterns of any type that have been obtained from single crystals of highly polymerized DNA. The patterns, obtained from frozen, hydrated crystals with the beam approximately parallel to the DNA strand axis, show a hexagonal geometrical arrangement with a (1,0) Bragg spacing of 23.1 A.     

Single-molecule analysis of DNA replication in Xenopus egg extracts

The recent advent in single-molecule imaging and manipulation methods has made a significant impact on the understanding of molecular mechanisms underlying many essential cellular processes. Single-molecule techniques such as electron microscopy and DNA fiber assays have been employed to study the duplication of genome in eukaryotes. Here, we describe a single-molecule assay that allows replication of DNA attached to the functionalized surface of a microfluidic flow cell in a soluble Xenopus leavis egg extract replication system and subsequent visualization of replication products via fluorescence microscopy. We also explain a method for detection of replication proteins, through fluorescently labeled antibodies, on partially replicated DNA immobilized at both ends to the surface.     

An electron microscopic and optical diffraction analysis of the structure of Limulus telson muscle thick filaments

Long, thick filaments (greater than 4.0 micrometer) rapidly and gently isolated from fresh, unstimulated Limulus muscle by an improved procedure have been examined by electron microscopy and optical diffraction. Images of negatively stained filaments appear highly periodic with a well-preserved myosin cross-bridge array. Optical diffraction patterns of the electron micrographs show a wealth of detail and are consistent with a myosin helical repeat of 43.8 nm, similar to that observed by x-ray diffraction. Analysis of the optical diffraction patterns, in conjunction with the appearance in electron micrographs of the filaments, supports a model for the filament in which the myosin cross-bridges are arranged on a four-stranded helix, with 12 cross-bridges per turn or each helix, thus giving an axial repeat every third level of cross-bridges (43.8 nm).     

The crystalline glycoprotein cell wall of the green alga Chlorogonium elongatum: a structural analysis.

Members of the Chlamydomonaceae, mostly single-celled green algae, have been shown to contain a crystalline glycoprotein cell wall component. Most of the species examined fall into a class of algae whose walls have an identical crystalline unit cell. Chlorogonium elongatum has been chosen as a representative of this class in order to investigate in more detail its cell wall structure. The alga has a spindleshaped cell wall which retains its asymmetric shape on isolation. Sections from walls fized in the presence of tannic acid clearly reveal a regular subunit monolayer, about 20 nm thick, within the wall. Sodium dodecylsulphate (SDS) polyacrylamide gel electrophoresis shows the presence of at least 2 major glycoprotein species in the wall. Negatively stained purified cell walls demonstrate the crystalline nature of the cell wall. Optical diffraction of bright-field images and direct electron diffraction both give clear diffraction patterns whose spacings extend out to 3 nm and fall on a reciprocal lattice whose vectors describe a 2-dimensional unit cell within the wall 21.5 nm X 7.0 nm and an included angle of 80 degrees. Lattice defects within the cell wall are revealed by both negative staining and surface replication. Through-focal series were used to choose images with the optimal degree of underfocus for image processing. Linear integration and optical filtering of such images gave essentially the same result. A similar image was also obtained by computing the autocorrelation function of the amplitudes in the electron-diffraction pattern and the optical-diffraction pattern of the in-focus image. On the basis of these data a 2-dimensional model of the crystalline cell wall layer is presented.