Scanning electron microscopic detection of nuclear structures involved in DNA replication.
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In order to evaluate at the ultrastructural level the three dimensional chromatin arrangement during interphase and particularly during the S phase, the immunogold detection of Bromodeoxyuridine (BrdU), as a marker of DNA synthesis, was performed in human HeLa, HL60, and in murine Friend leukemia cells (FLC). Field emission in lens scanning electron microscopy analysis of ultrathin cryosections revealed the presence of a regular three-dimensional network of fibers in dispersed chromatin. This spatial architecture was apparently constituted mainly of 10 nm filaments organized in loops of about 80-100 nm. Nodal points and the overlapping of such coils appeared as thicker structures of about 30 nm in diameter. Thin filaments of about 5 nm did not show a regular distribution. This three-dimensional fiber organization seemed quite constant in the dispersed chromatin of all the cell lines analyzed. The DNase treatment of the samples selectively removed the 10 nm class fibers, whereas the BrdU labeling confirmed the presence of newly synthesized DNA organized into chromatin units with a regular arrangement. These data suggest that the 10 nm chromatin fiber likely represents the DNA condensation order at which DNA duplication starts and the main weft of a three dimensional network within the interphase nucleus. (+info)
Analysis of DNA of isolated chromatin subunits.
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Partial digestion of rat liver nuclei with staphylococcal nuclease results in the liberation of nucleo-protein complexes consisting of one or more upsilon bodies. By velocity centrifugation we have isolated the monomeric subunit in relatively pure form. We find that this subunit contains 185 base pairs of DNA and 240,000 daltons of protein, resulting in a protein to DNA ratio identical to that of unperturbed chromatin. The isolated monomeric particle is further susceptible to internal nuclease attack resulting in the solubilization of 46% of the monomeric DNA. Analysis of the resistant DNA reveals a complex but highly reproducible pattern of DNA fragments ranging from 160 to 60 base pairs in length. Analysis of the reassociation kinetics of the isolated subunit DNA reveals that most, if not all genomic sequences, are involved in this basic subunit structure. No special frequency class of DNA is absent from upsilon bodies. Furthermore, virtually all liver sequences transcribed into mRNA are present in upsilon body DNA. These results indicate that upsilon body formation may be random with respect to DNA sequence and suggest that the mere presence of upsilon bodies over a specific region of DNA is not sufficient to restrict its transcription. (+info)
Action of nicking-closing enzyme on supercoiled and nonsupercoiled closed circular DNA: formation of a Boltzmann distribution of topological isomers.
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Highly purified nicking-closing enzyme from mouse cells in 20-fold enzyme/substrate excess converts closed circular native PM2, ColE1, and Minicol DNA into limit product sets of DNAs. Each set has a mean degree of supercoiling of approximately zero. The individual species in the sets differ by deltatau = +/-1, +/-2, etc., and the relative masses fit a Boltzmann distribution. It was also demonstrated that "nonsupercoiled" closed circular duplex molecules serve as substrates for the nicking-closing enzyme, and that a distribution of topological isomers is generated. Polynucleotide ligase, acting on nicked circular DNA, forms under the same conditions, the same set of closed DNAs. The latter enzyme freezes the population into sets of molecules otherwise in configurational equilibrium in solution. (+info)
Properties of the adenovirus type 40 E1B promoter that contribute to its low transcriptional activity.
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The adenovirus type 5 (Ad5) E1B promoter contains two elements essential for maximal activity, a TATA box and a GC box. The enteric adenovirus type 40 (Ad40) E1B promoter has a TATA box sequence identical to that of Ad5 and a GC box that fits the Sp1 binding site consensus. Nevertheless, Ad40 E1B RNA synthesis is severely impaired in HeLa cells, attributable in part at least to the weak transactivating activity of Ad40 E1A. However, the responsiveness of Ad40 early promoters to E1A transactivation has not been directly demonstrated. Using a transient expression assay with a chloramphenicol acetyl transferase (CAT) reporter gene, the Ad40 E1B promoter was very poorly transactivated by E1A of both Ad40 and Ad5 and showed only a limited response to the promiscuous varicella zoster virus transactivator p140. Construction of Ad5 recombinant viruses expressing the CAT gene under the control of the Ad5 or Ad40 E1B promoter allowed detection and measurement of expression from the Ad40 E1B promoter in a well-defined background and showed that overall activity is some 100-fold lower than for the Ad5 E1B promoter. Deletion analysis revealed that sequences upstream of the Sp1 binding site down-modulated Ad40 E1B promoter responsiveness, and two protein binding sites, identified by DNase footprinting and gel retardation assay, may be implicated in this effect. Gel shift analysis also showed that the Ad40 Sp1 binding site had a reduced affinity for Sp1 protein, relative to the Ad5 site, and that the context as well as the core sequence had an influence on Sp1 recognition. (+info)
A phylogenomic study of DNA repair genes, proteins, and processes.
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The ability to recognize and repair abnormal DNA structures is common to all forms of life. Studies in a variety of species have identified an incredible diversity of DNA repair pathways. Documenting and characterizing the similarities and differences in repair between species has important value for understanding the origin and evolution of repair pathways as well as for improving our understanding of phenotypes affected by repair (e.g., mutation rates, lifespan, tumorigenesis, survival in extreme environments). Unfortunately, while repair processes have been studied in quite a few species, the ecological and evolutionary diversity of such studies has been limited. Complete genome sequences can provide potential sources of new information about repair in different species. In this paper, we present a global comparative analysis of DNA repair proteins and processes based upon the analysis of available complete genome sequences. We use a new form of analysis that combines genome sequence information and phylogenetic studies into a composite analysis we refer to as phylogenomics. We use this phylogenomic analysis to study the evolution of repair proteins and processes and to predict the repair phenotypes of those species for which we now know the complete genome sequence. (+info)
Solution structure of the CIDE-N domain of CIDE-B and a model for CIDE-N/CIDE-N interactions in the DNA fragmentation pathway of apoptosis.
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Apoptotic DNA fragmentation and chromatin condensation are mediated by the caspase-activated DFF40/ CAD nuclease, which is chaperoned and inhibited by DFF45/ICAD. CIDE proteins share a homologous regulatory CIDE-N domain with DFF40/CAD and DFF45/ ICAD. Here we report the solution structure of CIDE-N of human CIDE-B. We show that the CIDE-N of CIDE-B interacts with CIDE-N domains of both DFF40 and DFF45. The binding epitopes are similar and map to a highly charged bipolar surface region of CIDE-B. Furthermore, we demonstrate that the CIDE-N of CIDE-B regulates enzymatic activity of the DFF40/ DFF45 complex in vitro. Based on these results and mutagenesis data, we propose a model for the CIDE-N/ CIDE-N complex and discuss the role of this novel bipolar interaction in mediating downstream events of apoptosis. (+info)
GAGA factor-dependent transcription and establishment of DNase hypersensitivity are independent and unrelated events in vivo.
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Using a Drosophila transgenic system we investigated the ability of GAGA factor, a putative anti-repressor, to modulate transcription-related events in the absence or presence of a bona fide activator, the Adf-1 transcription factor. In contrast to previous in vitro and in vivo data linking the binding of GAGA factor to the acquisition of DNase hypersensitivity at heat shock promoters, we observed that inserting multiple GAGA binding motifs adjacent to a minimal alcohol dehydrogenase (Adh) promoter led to strongly elevated embryonic transcription without creation of a promoter-associated DNase-hypersensitive (DH) site. Establishment of DNase hypersensitivity required the presence of both GAGA and Adf-1 binding sites and was accompanied by a further, synergistic increase in transcription. Because Adf-1 is capable neither of establishing a DH site nor of promoting efficient transcription by itself in embryos, it is likely that DH site formation depends on a GAGA factor-mediated binding of Adf-1 to chromatin, perhaps facilitated by a locally remodeled downstream promoter region. More generally we suggest that GAGA factor-binding sequences may operate in a promoter-specific context, with transcriptional activation, polymerase pausing, and/or DH site formation critically dependent on the nature of the sequences (and their binding partners) linked in cis. (+info)
Identification of BFN1, a bifunctional nuclease induced during leaf and stem senescence in Arabidopsis.
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Nuclease I enzymes are responsible for the degradation of RNA and single-stranded DNA during several plant growth and developmental processes, including senescence. However, in the case of senescence the corresponding genes have not been reported. We describe the identification and characterization of BFN1 of Arabidopsis, and demonstrate that it is a senescence-associated nuclease I gene. BFN1 nuclease shows high similarity to the sequence of a barley nuclease induced during germination and a zinnia (Zinnia elegans) nuclease induced during xylogenesis. In transgenic plants overexpressing the BFN1 cDNA, a nuclease activity of about 38 kD was detected on both RNase and DNase activity gels. Levels of BFN1 mRNA were extremely low or undetectable in roots, leaves, and stems. In contrast, relatively high BFN1 mRNA levels were detected in flowers and during leaf and stem senescence. BFN1 nuclease activity was also induced during leaf and stem senescence. The strong response of the BFN1 gene to senescence indicated that it would be an excellent tool with which to study the mechanisms of senescence induction, as well as the role of the BFN1 enzyme in senescence using reverse genetic approaches in Arabidopsis. (+info)