Inhibitory effect of simiao qingwen baidu decoction on epstein-barr virus EA, VCA expression and DNA replication in vitro.

This article aims to investigate the role of Simiao Qingwen Baidu Decoction (traditional Chinese medicine) in Epstein-Barr virus (EBV)-induced infectious mononucleosis. Sprague Dawley rats were given Simiao Qingwen Baidu Decoction by gavage, and the medicated serum was collected. EBV-latent infected human Burkitt lymphomas Raji and EBV-transformed marmosets B lymphoblast cell B95-8 were treated with medicated serum. CCK8 assay and flow cytometry were performed to detect cell proliferation and apoptosis. Indirect immunofluorescence assay was performed to analyze EA or VCA positive expression. The copy-number of EBV-DNA and the gene expression were detected by quantitative PCR or quantitative real-time PCR. We found that the medicated serum inhibited proliferation of Raji and B95-8 cells, especially 10 %-medicated serum. The 10 %-medicated serum significantly suppressed EA expression in Raji cells and VCA expression in B95-8 cells. The expression of BZLF1, BRLF1, BMLF1 and EBNA-1 in Raji cells was significantly inhibited by 10 %-medicated serum. 10 %-medicated serum caused a decrease in the copy-number of EBV-DNA in Raji cells. In conclusion, our data imply that Simiao Qingwen Baidu Decoction represses the expression of EA and VCA, and EBV-DNA replication. Thus, our work suggests that Simiao Qingwen Baidu Decoction may play a vital role in anti-EBV.

Gluconeogenesis, lipogenesis, and HBV replication are commonly regulated by PGC-1α-dependent pathway.

PGC-1α, a major metabolic regulator of gluconeogenesis and lipogenesis, is strongly induced to coactivate Hepatitis B virus (HBV) gene expression in the liver of fasting mice. We found that 8-Br-cAMP and glucocorticoids synergistically induce PGC-1α and its downstream targets, including PEPCK and G6Pase. Also, HBV core promoter activity was synergistically enhanced by 8-Br-cAMP and glucocorticoids. Graptopetalum paraguayense (GP), a herbal medicine, is commonly used in Taiwan to treat liver disorders. Partially purified fraction of GP (named HH-F3) suppressed 8-Br-cAMP/glucocorticoid-induced G6Pase, PEPCK and PGC-1α expression and suppressed HBV core promoter activity. HH-F3 blocked HBV core promoter activity via inhibition of PGC-1α expression. Ectopically expressed PGC-1α rescued HH-F3-inhibited HBV surface antigen expression, HBV mRNA production, core protein levels, and HBV replication. HH-F3 also inhibited fatty acid synthase (FASN) expression and decreased lipid accumulation by down-regulating PGC-1α. Thus, HH-F3 can inhibit HBV replication, gluconeogenesis and lipogenesis by down-regulating PGC-1α. Our study indicates that targeting PGC-1α may be a therapeutic strategy for treatment of HBV infections. HH-F3 may have potential use for the treatment of chronic hepatitis B patients with associated metabolic syndrome.

DNA topoisomerase II-dependent control of the cell cycle progression in root meristems of Allium cepa.

The catalytic ability of DNA topoisomerases (Topo) to generate short-term DNA breaks allow these enzymes to play crucial functions in managing DNA topology during S-phase replication, transcription, and chromatin-remodelling processes required to achieve commitment for the onset and transition through mitosis. Our experiments on root meristem cells of onion (Allium cepa) were designed to gain insight into the contribution of Topo II to plant-specific progression throughout interphase and mitosis. Irrespective of the position of the cell in interphase, the immunofluorescence of Topo II revealed similar nuclear labelling pattern with well defined signals dispersed in the nucleoplasm and the cortical zone of the nucleolus. Only weak labelling was detected in metaphase and anaphase chromosomes. Experiments with two potent anti-Topo II agents, doxorubicin (DOX, an anthracycline) and a bisdioxopiperazine derivative, ICRF-193, suggest that the inhibition-mediated increase in Topo II immunofluorescence may represent a compensatory mechanism, by which an up-regulated expression of the enzyme tends to counteract the drug-induced loss of indispensable catalytic and relaxation functions. γ-H2AX immunolabelling seems to indicate that both DOX- and ICRF-193-induced alterations in cell cycle progression reflect primarily the activity of the G2/M DNA damage checkpoint. Our findings provide evidence for the plant-specific cell cycle control mechanism induced by Topo II inhibitors under DNA stress conditions.

REV7 is required for anaphase-promoting complex-dependent ubiquitination and degradation of translesion DNA polymerase REV1.

REV1 is a Y-family polymerase specialized for replicating across DNA lesions at the stalled replication folk. Due to the high error rate of REV1-dependent translesion DNA synthesis (TLS), tight regulation of REV1 activity is essential. Here, we show that human REV1 undergoes proteosomal degradation mediated by the E3 ubiquitin ligase known as anaphase-promoting complex (APC). REV1 associates with APC. Overexpression of APC coactivator CDH1 or CDC20 promotes polyubiquitination and proteosomal degradation of REV1. Surprisingly, polyubiquitination of REV1 also requires REV7, a TLS accessory protein that interacts with REV1 and other TLS polymerases. The N-terminal region of REV1 contains both the APC degron and an additional REV7-binding domain. Depletion of REV7 by RNA interference stabilizes REV1 by preventing polyubiquitination, whereas overexpression of REV7 augments REV1 degradation. Taken together, our findings suggest a role of REV7 in governing REV1 stability and interplay between TLS and APC-dependent proteolysis.

Human mitochondrial DNA helicase TWINKLE is both an unwinding and annealing helicase.

TWINKLE is a nucleus-encoded human mitochondrial (mt)DNA helicase. Point mutations in TWINKLE are associated with heritable neuromuscular diseases characterized by deletions in the mtDNA. To understand the biochemical basis of these diseases, it is important to define the roles of TWINKLE in mtDNA metabolism by studying its enzymatic activities. To this end, we purified native TWINKLE from Escherichia coli. The recombinant TWINKLE assembles into hexamers and higher oligomers, and addition of MgUTP stabilizes hexamers over higher oligomers. Probing into the DNA unwinding activity, we discovered that the efficiency of unwinding is greatly enhanced in the presence of a heterologous single strand-binding protein or a single-stranded (ss) DNA that is complementary to the unwound strand. We show that TWINKLE, although a helicase, has an antagonistic activity of annealing two complementary ssDNAs that interferes with unwinding in the absence of gp2.5 or ssDNA trap. Furthermore, only ssDNA and not double-stranded (ds)DNA competitively inhibits the annealing activity, although both DNAs bind with high affinities. This implies that dsDNA binds to a site that is distinct from the ssDNA-binding site that promotes annealing. Fluorescence anisotropy competition binding experiments suggest that TWINKLE has more than one ssDNA-binding sites, and we speculate that a surface-exposed ssDNA-specific site is involved in catalyzing DNA annealing. We propose that the strand annealing activity of TWINKLE may play a role in recombination-mediated replication initiation found in the mitochondria of mammalian brain and heart or in replication fork regression during repair of damaged DNA replication forks.

Developmental changes in DNA methylation of pollen mother cells of David lily during meiotic prophase I.

Epigenetic marks in the form of DNA methylation are involved in the development of germ cells and are important in the maintenance of fertility. However, the controlling system of the on-off switch for DNA methylation largely remains unclear. In this study, the extent of cytosine methylation during the meiotic prophase I in David lily is assessed using high pressure liquid chromatography to evaluate the DNA methylation rates. Comparing the degree of DNA methylation before, during, and after synizesis, both de novo methylation and demethylation occurred. Mainly the methylation level decreased by 21.3% (from 54.8 to 33.5%) during synizesis in the pollen mother cells. The developmental timing of genome-wide DNA methylation acquisition during pollen mother cell development is clarified in this paper. The relative amounts of 5-methyl-deoxycytidine of global methylation in leaf DNA in David lily were also higher than in other species reported.

A mathematical and computational approach for integrating the major sources of cell population heterogeneity.

Several approaches have been used in the past to model heterogeneity in bacterial cell populations, with each approach focusing on different source(s) of heterogeneity. However, a holistic approach that integrates all the major sources into a comprehensive framework applicable to cell populations is still lacking. In this work we present the mathematical formulation of a cell population master equation (CPME) that describes cell population dynamics and takes into account the major sources of heterogeneity, namely stochasticity in reaction, DNA-duplication, and division, as well as the random partitioning of species contents into the two daughter cells. The formulation also takes into account cell growth and respects the discrete nature of the molecular contents and cell numbers. We further develop a Monte Carlo algorithm for the simulation of the stochastic processes considered here. To benchmark our new framework, we first use it to quantify the effect of each source of heterogeneity on the intrinsic and the extrinsic phenotypic variability for the well-known two-promoter system used experimentally by Elowitz et al. (2002). We finally apply our framework to a more complicated system and demonstrate how the interplay between noisy gene expression and growth inhibition due to protein accumulation at the single cell level can result in complex behavior at the cell population level. The generality of our framework makes it suitable for studying a vast array of artificial and natural genetic networks. Using our Monte Carlo algorithm, cell population distributions can be predicted for the genetic architecture of interest, thereby quantifying the effect of stochasticity in intracellular reactions or the variability in the rate of physiological processes such as growth and division. Such in silico experiments can give insight into the behavior of cell populations and reveal the major sources contributing to cell population heterogeneity.

In vitro assays for studying helicase activities.

Unwinding of double-stranded DNA is required to create a single-stranded DNA template for essential DNA processes such as those involved in recombination, repair, and replication. A set of specialized enzymes called DNA helicases is dedicated to this purpose, catalyzing DNA strand separation by breaking hydrogen bonds and other noncovalent interactions that stably hold the two complementary DNA strands together. They use energy derived from the hydrolysis of nucleotide triphosphates for both bond breakage between complementary bases and translocation of a helicase enzyme along DNA. DNA unwinding activity catalyzed by a helicase usually exhibits a specific directionality (5' to 3' or 3' to 5') with respect to the DNA strand to which the enzyme is bound and moves. Unwinding activity ofa DNA helicase and its related properties can be easily measured in vitro using common lab equipment. We will describe the detailed methods and notes for preparation of various helicase substrates and in vitro helicase assays using the substrates prepared.

[Influence of membrane-active polyanions on various stages of the human cytomegalovirus life cycle in vitro].

Human cytomegalovirus (CMV), an agent of infection (CMVI), lethally dangerous for immune deficient neonates and adults was investigated in vitro as a target for a therapeutic effect of new membrane-active polyanionic compounds (MPC). Previous studies on the alicycle- and sulfate-modified carboxy-MPCs revealed a well-defined tendency of the anti-CMV activity amplification in parallel with increasing of the content of sulfate groups, enhancing the negative charge of the macromolecule. The dominating role of the electrostatic factor was confirmed by the highest activity of AS-688, compound with maximum sulfation among the tested MPCs. Its selectivity index (SI) of the CMVI inhibition in human diploid fibroblast cells reached 5450, 7500, 250 and 4286 in the microbicidal, viricidal, prophylactic and therapeutic schemes of the experiment respectively. The antiviral activity at the first, second and third schemes was explained by the polyanion-typical potential of electrostatic neutralization of the countercharged virions and prevention of the virus adsorption on the cell membranes (in competition with heparin sulfate, a cellular receptor of CMV), whereas the therapeutic effect required the ability of MPC to influence the intracellular stages of the CMV life cycle. The PCR and immunochemical assays revealed an inhibitory action of AS-688 on replication of the viral DNA and the following synthesis of the late viral protein gB with efficiency similar to that of gancyclovir (GCV). However, in contrast to GCV, acting as inhibitor of enzyme (viral RNA-polymerase) factor of the biosynthesis, the therapeutic activity of MPC could be interpreted by competition with viral RNA/DNA due to the specific character of the MPC molecular basis, initially constructed on the principle of nucleic acids backbone and charge adjustable imitation. This mechanism assuming reduction of the cytotoxicity risks, explained the experimentally observed fact of low cytotoxicity of MPCs and possible achievement of high SI. The MPC ability to penetrate into the cells without disruption of cellular membrane permeability was confirmed in experiments with the fluorescent-labeled derivate AS-679, structurally and functionally related to AS-688. In the light of the previously described HIV inhibiting properties of AS-688, AS-679 and MPC analogous, the results could be considered prospective in development of new highly effective agents for combined antiviral protection.

Structure and function of the c-myc DNA-unwinding element-binding protein DUE-B.

Local zones of easily unwound DNA are characteristic of prokaryotic and eukaryotic replication origins. The DNA-unwinding element of the human c-myc replication origin is essential for replicator activity and is a target of the DNA-unwinding element-binding protein DUE-B in vivo. We present here the 2.0A crystal structure of DUE-B and complementary biochemical characterization of its biological activity. The structure corresponds to a dimer of the N-terminal domain of the full-length protein and contains many of the structural elements of the nucleotide binding fold. A single magnesium ion resides in the putative active site cavity, which could serve to facilitate ATP hydrolytic activity of this protein. The structure also demonstrates a notable similarity to those of tRNA-editing enzymes. Consistent with this structural homology, the N-terminal core of DUE-B is shown to display both D-aminoacyl-tRNA deacylase activity and ATPase activity. We further demonstrate that the C-terminal portion of the enzyme is disordered and not essential for dimerization. However, this region is essential for DNA binding in vitro and becomes ordered in the presence of DNA.

Induction of replication in human corneal endothelial cells by E2F2 transcription factor cDNA transfer.

PURPOSE: Corneal endothelial cells in humans do not replicate to any meaningful extent. Diminishing density of the cell monolayer with age and in the disease states is a major cause of loss of corneal transparency. This study was conducted to test the hypothesis that overexpression of the transcription factor E2F2 results in replication in nonproliferating human corneal endothelial cells. METHODS: Whole human corneas were incubated for 2 hours in a solution of recombinant E1(-)/E3(-) adenovirus incorporating cDNA encoding E2F2 and green fluorescent protein (GFP) under control of a bidirectional promoter and subsequently maintained in ex vivo culture. Control specimens were incubated with an identical virus bearing the GFP sequence only, or virus-free medium. Efficiency of gene transfer and localization was examined by fluorescence microscopy. En face confocal microscopy of the corneal endothelial surface was used to image recombinant E2F2 expression. 5-bromodeoxyuridine (BrdU) incorporation was used to examine progression to the S phase. Changes in density of the corneal endothelium were quantified by specular microscopy and counting of trypan-blue-stained cells. Apoptosis was tested with a TUNEL assay. RESULTS: Recombinant proteins were expressed predominantly in the endothelium and in a high proportion of endothelial cells in the first week after exposure to virus, diminishing thereafter. Compared with the control, transduction with E2F2 resulted in progression from the G(1) to the S phase in a significant number of cells and in increased cell density. Apoptosis was not found to any significant extent. CONCLUSIONS: Overexpression of the transcription factor E2F2 in nonmitotic human corneal endothelial cells results in short-term expression, cell-cycle progression, and increased monolayer cell density.

Structural determinants of HIV-1 nucleocapsid protein for cTAR DNA binding and destabilization, and correlation with inhibition of self-primed DNA synthesis.

The nucleocapsid protein (NC) of human immunodeficiency virus type 1 (HIV-1) is formed of two highly conserved CCHC zinc fingers flanked by small basic domains. NC is required for the two obligatory strand transfers in viral DNA synthesis through its nucleic acid chaperoning properties. The first DNA strand transfer relies on NC's ability to bind and destabilize the secondary structure of complementary transactivation response region (cTAR) DNA, to inhibit self-priming, and to promote the annealing of cTAR to TAR RNA. To further investigate NC chaperone properties, our aim was to identify by fluorescence spectroscopy and gel electrophoresis, the NC structural determinants for cTAR binding and destabilization, and for the inhibition of self-primed DNA synthesis on a model system using a series of NC mutants and HIV-1 reverse transcriptase. NC destabilization and self-priming inhibition properties were found to be supported by the two fingers in their proper context and the basic (29)RAPRKKG(35) linker. The strict requirement of the native proximal finger suggests that its hydrophobic platform (Val13, Phe16, Thr24 and Ala25) is crucial for binding, destabilization and inhibition of self-priming. In contrast, only partial folding of the distal finger is required, probably for presenting the Trp37 residue in an appropriate orientation. Also, Trp37 and the hydrophobic residues of the proximal finger appear to be essential for the propagation of the melting from the cTAR ends up to the middle of the stem. Finally, both N-terminal and C-terminal basic domains contribute to cTAR binding but not to its destabilization.

Studies of the properties of human origin recognition complex and its Walker A motif mutants.

The eukaryotic six-subunit origin recognition complex (ORC) governs the initiation site of DNA replication and formation of the prereplication complex. In this report we describe the isolation of the wild-type Homo sapiens (Hs)ORC and variants containing a Walker A motif mutation in the Orc1, Orc4, or Orc5 subunit using the baculovirus-expression system. Coexpression of all six HsORC subunits yielded a stable complex containing HsOrc subunits 1-5 (HsORC1-5) with virtually no Orc6 protein (Orc6p). We examined the ATPase, DNA-binding, and replication activities of these complexes. Similar to other eukaryotic ORCs, wild-type HsORC1-5 possesses ATPase activity that is stimulated only 2-fold by single-stranded DNA. HsORC1-5 with a mutated Walker A motif in Orc1p contains no ATPase activity, whereas a similar mutation of either the Orc4 or Orc5 subunit did not affect this activity. The DNA-binding activity of HsORC1-5, using lamin B2 DNA as substrate, is stimulated by ATP 3- to 5-fold. Mutations in the Walker A motif of Orc1p, Orc4p, or Orc5p reduced the binding efficiency of HsORC1-5 modestly (2- to 5-fold). Xenopus laevis ORC-depleted extracts supplemented with HsORC1-5 supported prereplication complex formation and X. laevis sperm DNA replication, whereas the complex with a mutation in the Walker A motif of the Orc1, Orc4, or Orc5 subunit did not. These studies indicate that the ATP-binding motifs of Orc1, Orc4, and Orc5 are all essential for the replication activity associated with HsORC.

Evidence for an S-phase checkpoint regulating DNA replication after heat shock: a review.

Exposure of cells to heat inhibits a number of nuclear activities associated with semi-conservative replication of DNA including the incorporation of radiolabelled precursors into acid-insoluble DNA, the initiation of new replicons, the elongation of the DNA fibre at the replication fork, the synthesis and deposition of new histones into chromatin and the reorganization of nascent DNA into mature chromatin. These effects are likely to underlie the heat sensitivity of S-phase cells and may contribute to the radiosensitization observed in this phase of the cell cycle. While some of these effects may be explained as 'passive' consequences of heat-induced damage on chromatin structures experiments reviewed here point to the activation of a checkpoint as a contributing factor to the observed inhibition of DNA replication. Activation of a heat responsive S-phase checkpoint targets the activity of RPA via interaction with nucleolin. Nucleolin, a major nucleolar protein, is found normally sequestered in the nucleolus. Exposure of cells to heat causes a rapid translocation of nucleolin from the nucleolus into the nucleoplasm that enables RPA/nucleolin interaction. This interaction inhibits functions of RPA associated with the initiation of DNA replication and contributes to the immediate inhibition of DNA synthesis observed after heat shock. The results suggest that the nucleolus serves as a sequestration centre for the temporary inactivation of regulatory molecules, such as nucleolin, capable of regulating essential cellular functions after heat shock. It is speculated that this regulatory process is integrated in the network of responses that determine cell sensitivity to heat and that it may be involved in heat radiosensitization to killing as well.

DNA intercalators differentially affect chromatin structure and DNA replication in Xenopus egg extract.

In this paper, we describe a scheme utilizing the Xenopus egg extract system to simultaneously evaluate DNA-interacting drugs as potential anti-cancer agents and gain insights into the mechanisms of drug action. We studied two DNA intercalators, daunomycin (DM), a cancer chemotherapeutic, and ethidium bromide (EtBr), a compound with no reported therapeutic value. Consistent with our earlier report, we find that DM inhibits DNA replication in a concentration-dependent manner. In contrast, EtBr does not inhibit replication over the same concentration range. The environment in which drug-DNA interactions take place is an important determinant of the effect of the drug on DNA replication. While neither intercalator inhibits nuclear membrane assembly nor nuclear protein import, DM does disrupt chromatin structure at very low concentrations, whereas EtBr does not. This system may prove useful for large scale screening of DNA-interacting chemotherapeutic compounds in a cellular milieu.

First principles calculations of the pKa values and tautomers of isoguanine and xanthine.

The accurate replication of DNA requires the formation of complementary hydrogen bonds between a template base and the base moiety of an incoming deoxynucleotide-5'-triphosphate. Recent structural studies suggest that some DNA polymerases contribute additional constraints by interrogating the minor groove face of the incoming and template bases. Therefore, the hydrogen bond-donating or -accepting properties of the base pairing as well as minor groove faces of the bases could be important determinants of correct base selection. In this paper, we investigate two purines that could arise by endogenous damage of the normal DNA bases: isoguanine (which can be generated by the oxidation of adenine) and xanthine (which can be generated by the deamination of guanine). In both cases, the potential exists for the placement of a proton in the N3 position, converting the N3 position from a hydrogen bond acceptor to a donor. In this paper, we use first principles quantum mechanical methods (density functional theory using the B3LYP functional and the 6-31G++Gbasis set) to predict the ionization and tautomeric equilibria of both isoguanine and xanthine in the gas phase and aqueous solution. For isoguanine, we find that the N1H and N3H neutral tautomeric forms are about equally populated in aqueous solution, while the enol tauotomers are predominant in the gas phase. In contrast, we find that xanthine displays essentially no tautomeric shifts in aqueous solution but is nearly equally populated by both an anionic and a neutral form at physiological pH. To obtain these results, we carried out an extensive examination of the tautomeric and ionic configurations for both xanthine and isoguanine in solution and in the gas phase. The potential hydrogen-bonding characteristics of these damaged purines may be used to test predictions of the important components of base selection by different DNA polymerases during DNA replication.

Direct monitoring kinetic studies of DNA polymerase reactions on a DNA-immobilized quartz-crystal microbalance.

Catalytic reactions of DNA polymerase I from E. coli (Klenow fragment, KF) were monitored directly with a template/primer (40/25- or 75/25-mer)-immobilized 27-MHz quartz-crystal microbalance (QCM). The 27-MHz QCM is a very sensitive mass-measuring device in aqueous solution, as the frequency decreases linearly with increasing mass on the QCM electrode at the nanogram level. Three steps in polymerase reactions which include 1) binding of DNA polymerase to the primer on the QCM (mass increase); 2) elongation of complementary nucleotides along the template (mass increase); and 3) release of the enzyme from the completely polymerized DNA (mass decrease), could be monitored continuously from the time dependencies of QCM frequency changes. The binding constant (Ka) of KF to the template/primer DNA was 10(8)M(-1) (k(on) = 10(5)M(-1)s(-1) and k(off)= 10(-3)s(-1)), and decreased to 10(6)M(-1) (k'on = 10(4)M(-1)s(-1) and k'off = 10(-2)s(-1)) for completely polymerized DNA. This is due to the 10-fold decrease in binding rate constant (k(on)) and 10-fold increase in dissociation rate constant (k(off)) for completed DNA strands. Ka values depended slightly on the template and primer sequences. The kinetic parameters in the elongation process (k(cat) and Km) depended only slightly on the DNA sequences. The repair process during the elongation catalyzed by KF could also be monitored in real time as QCM frequency changes.

Immunoelectron microscopy of PCNA as an efficient marker for studying replication times and sites during pollen development.

Here we report for the first time the ultrastructural localization of DNA replication sites in the nucleus of plant cells and the timing of replication through the pollen developmental programme by proliferating cell nuclear antigen (PCNA) immunogold labelling. Replication sites were identified by labelling with anti-PCNA antibodies in fibrils of the interchromatin region close to the condensed chromatin, defining a perichromatin subdomain in the interchromatin space where DNA replication takes place. The same nuclear structures are decorated by anti-BrdU (5-bromo-2'-deoxyuridine) immunogold after short pulses of BrdU labelling. Double immunogold labelling for PCNA and DNA show colocalization on these perichromatin structures. PCNA immunoelectron microscopy also allows correlation of replicative activity with the dynamics of chromatin condensation. DNA replication was also monitored at different phases during pollen development by PCNA immunoelectron microscopy, revealing two peaks of DNA synthesis, at the beginning (early tetrad), and the end (late vacuolate), of microspore interphase. High-resolution autoradiography after [3H]thymidine incorporation also showed high replicative activity at the same two periods of microspore interphase. In the bicellular pollen grain, PCNA immunogold labelling revealed that DNA replication in the generative cell starts at an intermediate stage of pollen maturation, whereas the vegetative nucleus does not replicate and is arrested in G1. The use of anti-PCNA antibodies at the ultrastructural level is an easier, faster and more feasible method than the detection of in vivo-incorporated nucleotides, especially in plant systems with long cell cycles. PCNA immunogold labelling is, therefore, proposed as an efficient marker for mapping the sites and timing of replication at the electron microscopy level.

Overexpression of kin17 protein disrupts nuclear morphology and inhibits the growth of mammalian cells.

UVC or ionizing radiation of mammalian cells elicits a complex genetic response that allows recovery and cell survival. Kin17 gene, which is highly conserved among mammals, is upregulated during this response. Kin17 gene encodes a 45 kDa protein which binds to DNA and presents a limited similarity with a functional domain of the bacterial RecA protein. Kin17 protein is accumulated in the nucleus of proliferating fibroblasts and forms intranuclear foci. Using expression vectors, we show that overexpression of kin17 protein inhibits cell-cycle progression into S phase. Our results indicate that growth inhibition correlates with disruption of the nuclear morphology which seems to modify the intranuclear network required during the early steps of DNA replication. We report that a mutant encoding a protein deleted from the central domain of kin17 protein enhanced these effects whereas the deletion of the C-terminal domain considerably reduced them. These mutants will be used to elucidate the molecular mechanism by which kin17 protein alters cell growth and DNA replication.

Fibroblast response to rapid decompression and hyperbaric oxygenation.

INTRODUCTION: The cellular basis for symptoms associated with rapid decompression and the use of hyperbaric oxygenation treatment (HBO) is not established. METHODS: Image analysis, sulforhodamine B assay and bromodeoxyuridine (BrDU) incorporation were used to identify cellular changes associated with rapid decompression (RD) or hyperbaric oxygenation (HBO). Human fibroblasts were exposed to RD or HBO and compared with untreated cells. Immediately following treatment, the fraction of cells synthesizing DNA was measured by detection of cells incorporating the BrDU. At 1 d and 3 d following the treatments, total cell protein adherent to the bottom of wells was measured using a sulforhodamine B assay. Cell density was observed with light microscopy and quantified with image analysis. RESULTS: RD increased total protein significantly, (p < 0.05) relative to control, while HBO had less effect. The fraction of cells synthesizing DNA was increased by HBO and reduced by RD relative to control (p < 0.05). Image analysis showed that cell density at day 1 was: control>HBO>RD; and at day 3: RD>HBO>control, indicating an increase in proliferation induced by the treatments. CONCLUSION: This data shows that HBO and RD increase the proliferation of fibroblasts for 24 h following treatment. HBO increased DNA replication. While there was a decrease in DNA replication following RD, protein synthesis was enhanced.