Project description:Eukaryotic cells use numerous mechanisms to ensure that no segment of their DNA is re-replicated within a single cell cycle. Despite longstanding speculation that such tight regulation is needed to protect cells from genomic alterations, this notion has never been experimentally tested. Here we show that even just transient and limited re-replication in Saccharomyces cerevisiae can strongly induce the critical first step of gene amplification, increasing gene copy number from one to two or more. The amplified units, or amplicons, consist of large internal chromosomal segments that are bounded by Ty repetitive elements and are intrachromosomally arrayed at their endogenous locus in direct head-to-tail orientation. The presence of hybrid Ty elements at inter-amplicon junctions together with the dependence of amplification on RAD52 indicate that in budding yeast these re-replication-induced gene amplifications (RRIGA) are mediated by homologous recombination between re-replicated non-allelic repetitive elements. These results finally establish the importance of stringent replication control for genome stability and suggest that re-replication should now be considered as a possible contributor to gene copy number changes in fields as diverse as cancer biology, evolution, and human genetics. The arrays in this series are primary comparative genomic hybridizations to determine genomic changes after re-replication or other genomic stresses. Genomic DNA was purified from reference Saccharomyces cerevisiae cells or survivors of re-replication or other genomic stresses, differentially labeled with Cy3 and Cy5, and competitively hybridized to a spotted microarray containing ORF and intergenic PCR products. Cy5/Cy3 ratios are normalized so that the average ratio of all elements was 1. A small number of the arrays were used to determine the extent and location of re-replication under different conditions. For those, genomic DNA was purified from non-replicating and re-replicating cells and treated as above. Series contains a total of 203 hybridizations.

Project description:Eukaryotic cells use numerous mechanisms to ensure that no segment of their DNA is re-replicated within a single cell cycle. Despite longstanding speculation that such tight regulation is needed to protect cells from genomic alterations, this notion has never been experimentally tested. Here we show that even just transient and limited re-replication in Saccharomyces cerevisiae can strongly induce the critical first step of gene amplification, increasing gene copy number from one to two or more. The amplified units, or amplicons, consist of large internal chromosomal segments that are bounded by Ty repetitive elements and are intrachromosomally arrayed at their endogenous locus in direct head-to-tail orientation. The presence of hybrid Ty elements at inter-amplicon junctions together with the dependence of amplification on RAD52 indicate that in budding yeast these re-replication-induced gene amplifications (RRIGA) are mediated by homologous recombination between re-replicated non-allelic repetitive elements. These results finally establish the importance of stringent replication control for genome stability and suggest that re-replication should now be considered as a possible contributor to gene copy number changes in fields as diverse as cancer biology, evolution, and human genetics.

Project description:The antihelmintic drug ABZ and its metabolites belong to the chemical family of benzimidazoles (BZM) that act as potent tubulin polymerization inhibitors, suggesting a potential re-direction of BZMs for cancer therapy. Applying UV-Vis spectrometry we here demonstrate ABZ as a DNA intercalator. This insight led us to determine the primary mode of ABZ action in mammalian cells. As revealed by RNA sequencing, ABZ did neither grossly affect replication as analyzed by survival and replication stress signaling, nor the transcriptome. Actually, unbiased transcriptome analysis revealed a marked cell cycle signature in ABZ exposed cells. Indeed, short-term exposure to ABZ arrested mammalian cells in G2/M cell cycle stages associated with frequent gains and losses of chromatin. Cellular analyses revealed ABZ as a potent mammalian spindle poison for normal and malignant cells, explaining the serious chromosome segregation defects. Since chromosomal aberrations promote both cancer development and cell death, we determined if besides its general cytotoxicity, ABZ could predispose to tumor development. As measured by loss of heterozygosity (LOH) in vitro and in vivo ABZ was found as a potent inducer of LOH and accelerator of chromosomal missegregation.

Project description:To ensure equal replication of the genome in every eukaryotic cell cycle, replication origins fire only once each S phase and do not fire after passive replication. Failure in these controls can lead to local amplification, contributing to genome instability and the development of cancer. To identify features of replication origins important for such amplification, we have investigated origin firing and local genome amplification in the presence of excess helicase loaders Cdc18 and Cdt1 in fission yeast. We find that S phase controls are attenuated and coordination of origin firing is lost, resulting in local amplification. Specific origins are necessary for amplification but act only within a permissive chromosomal context. Origins associated with amplification are highly AT-rich, fire efficiently and early during mitotic S phase, and are located in large intergenic regions. We propose that these features predispose replication origins to re-fire within a single S phase, or to remain active after passive replication.

Project description:The cdc45 protein was originally identified in Saccharomyces cerevisiae and shown to be essential for initiation of eukaryotic DNA replication. Subsequent isolation and characterisation of the corresponding genes from fission yeast, Xenopus and mammals also support a replication role for the protein in these species. They further suggest that during the course of its function cdc45 interacts with a number of other replication proteins, including minichromosome maintenance proteins, the origin recognition complex and DNA polymerase alpha. We have cloned the gene coding for cdc45 protein from Drosophila melanogaster. We have analysed the expression pattern of the cdc45 protein throughout the cell cycle and the life cycle using a combination of indirect immunofluorescence and subcellular fractionation. Our data show that cellular localisation and developmental regulation of the protein is consistent with a role in DNA replication. DmCdc45 is predominantly expressed in proliferating cells. In addition, its subcellular location is nuclear during interphase and the protein shows association with chromatin. The chromatin-associated form of the protein shows a post-translational modification, which may be involved in control of the action of the protein. DmCdc45 shows interactions with mcm proteins, however, the interactions detected show some specificity, perhaps suggesting a preferential association with particular mcm proteins. In addition we show that a stoichiometric mcm interaction may not be obligatory for the function of cdc45 in follicle cell replication, because, unlike the mcm proteins, DmCdc45 localises to the chorion amplification foci in the follicle cells of the ovary.

Project description:We exploit the unusual genome organization of the ciliate cell to analyze the control of specific gene amplification during a nuclear differentiation process. Ciliates contain two types of nuclei within one cell, the macronucleus and the micronucleus; and after sexual reproduction a new macronucleus is formed from a micronuclear derivative. During macronuclear differentiation, most extensive DNA reorganization, elimination, and fragmentation processes occur, resulting in a macronucleus containing short DNA molecules (nanochromosomes) representing individual genetic units and each being present in high copy number. It is believed that these processes are controlled by small nuclear RNAs but also by a template derived from the old macronucleus. We first describe the exact copy numbers of selected nanochromosomes in the macronucleus, and define the timing during nuclear differentiation at which copy number is determined. This led to the suggestion that DNA processing and copy number control may be closely related mechanisms. Degradation of an RNA template derived from the macronucleus leads to significant decrease in copy number, whereas injection of additional template molecules results in an increase in copy number and enhanced expression of the corresponding gene. These observations can be incorporated into a mechanistic model about an RNA-dependent epigenetic regulation of gene copy number during nuclear differentiation. This highlights that RNA, in addition to its well-known biological functions, can also be involved in the control of gene amplification.

Project description:Aptazymes are small, ligand-dependent self-cleaving ribozymes that function independently of transcription factors and can be customized for induction by various small molecules. Here, we introduce these artificial riboswitches for regulation of DNA and RNA viruses. We hypothesize that they represent universally applicable tools for studying viral gene functions and for applications as a safety switch for oncolytic and live vaccine viruses. Our study shows that the insertion of artificial aptazymes into the adenoviral immediate early gene E1A enables small-molecule-triggered, dose-dependent inhibition of gene expression. Aptazyme-mediated shutdown of E1A expression translates into inhibition of adenoviral genome replication, infectious particle production, and cytotoxicity/oncolysis. These results provide proof of concept for the aptazyme approach for effective control of biological outcomes in eukaryotic systems, specifically in virus infections. Importantly, we also demonstrate aptazyme-dependent regulation of measles virus fusion protein expression, translating into potent reduction of progeny infectivity and virus spread. This not only establishes functionality of aptazymes in fully cytoplasmic genetic systems, but also implicates general feasibility of this strategy for application in viruses with either DNA or RNA genomes. Our study implies that gene regulation by artificial riboswitches may be an appealing alternative to Tet- and other protein-dependent gene regulation systems, based on their small size, RNA-intrinsic mode of action, and flexibility of the inducing molecule. Future applications range from gene analysis in basic research to medicine, for example as a safety switch for new generations of efficiency-enhanced oncolytic viruses.

Project description:BackgroundPolyoxypeptin A was isolated from a culture broth of Streptomyces sp. MK498-98 F14, which has a potent apoptosis-inducing activity towards human pancreatic carcinoma AsPC-1 cells. Structurally, polyoxypeptin A is composed of a C₁₅ acyl side chain and a nineteen-membered cyclodepsipeptide core that consists of six unusual nonproteinogenic amino acid residues (N-hydroxyvaline, 3-hydroxy-3-methylproline, 5-hydroxypiperazic acid, N-hydroxyalanine, piperazic acid, and 3-hydroxyleucine) at high oxidation states.ResultsA gene cluster containing 37 open reading frames (ORFs) has been sequenced and analyzed for the biosynthesis of polyoxypeptin A. We constructed 12 specific gene inactivation mutants, most of which abolished the production of polyoxypeptin A and only ΔplyM mutant accumulated a dehydroxylated analogue polyoxypeptin B. Based on bioinformatics analysis and genetic data, we proposed the biosynthetic pathway of polyoxypeptin A and biosynthetic models of six unusual amino acid building blocks and a PKS extender unit.ConclusionsThe identified gene cluster and proposed pathway for the biosynthesis of polyoxypeptin A will pave a way to understand the biosynthetic mechanism of the azinothricin family natural products and provide opportunities to apply combinatorial biosynthesis strategy to create more useful compounds.

Project description:Gene expression can be controlled in genetically modified cells by employing an inducer/promoter system where presence of the inducer molecule regulates the timing and level of gene expression. By applying the principles of controlled release, it should be possible to control gene expression on a biomaterial surface by the presence or absence of inducer release from the underlying material matrix, thus avoiding alternative techniques that rely upon uptake of relatively labile DNA from material surfaces. To evaluate this concept, a modified ecdysone-responsive gene expression system was transfected into B16 murine cells and the ability of an inducer ligand, which was released from elastomeric poly(ester urethane) urea (PEUU), to initiate gene expression was studied. The synthetic inducer ligand was first loaded into PEUU to demonstrate extended release of the bioactive molecule at various loading densities over a one year period in vitro. Patterning films of PEUU variably-loaded with inducer resulted in spatially controlled cell expression of the gene product (green fluorescent protein, GFP). In porous scaffolds made from PEUU by salt leaching, where the central region was exclusively loaded with inducer, cells expressed GFP predominately in the loaded central regions whereas expression was minimal in outer regions where ligand was omitted. This scaffold system may ultimately provide a means to precisely control progenitor cell commitment in a spatially-defined manner in vivo for soft tissue repair and regeneration.

Project description:UnlabelledPolydnaviruses are large, double-stranded DNA viruses that are beneficial symbionts of parasitoid wasps. Polydnaviruses in the genus Bracovirus (BVs) persist in wasps as proviruses, and their genomes consist of two functional components referred to as proviral segments and nudivirus-like genes. Prior studies established that the DNA domains where proviral segments reside are amplified during replication and that segments within amplified loci are circularized before packaging into nucleocapsids. One DNA domain where nudivirus-like genes are located is also amplified but never packaged into virions. We recently sequenced the genome of the braconid Microplitis demolitor, which carries M. demolitor bracovirus (MdBV). Here, we took advantage of this resource to characterize the DNAs that are amplified during MdBV replication using a combination of Illumina and Pacific Biosciences sequencing approaches. The results showed that specific nucleotide sites identify the boundaries of amplification for proviral loci. Surprisingly, however, amplification of loci 3, 4, 6, and 8 produced head-to-tail concatemeric intermediates; loci 1, 2, and 5 produced head-to-head/tail-to-tail concatemers; and locus 7 yielded no identified concatemers. Sequence differences at amplification junctions correlated with the types of amplification intermediates the loci produced, while concatemer processing gave rise to the circularized DNAs that are packaged into nucleocapsids. The MdBV nudivirus-like gene cluster was also amplified, albeit more weakly than most proviral loci and with nondiscrete boundaries. Overall, the MdBV genome exhibited three patterns of DNA amplification during replication. Our data also suggest that PacBio sequencing could be useful in studying the replication intermediates produced by other DNA viruses.ImportancePolydnaviruses are of fundamental interest because they provide a novel example of viruses evolving into beneficial symbionts. All polydnaviruses are associated with insects called parasitoid wasps, which are of additional applied interest because many are biological control agents of pest insects. Polydnaviruses in the genus Bracovirus (BVs) evolved ~100 million years ago from an ancestor related to the baculovirus-nudivirus lineage but have also established many novelties due to their symbiotic lifestyle. These include the fact that BVs are transmitted only vertically as proviruses and produce replication-defective virions that package only a portion of the viral genome. Here, we studied Microplitis demolitor bracovirus (MdBV) and report that its genome exhibits three distinct patterns of DNA amplification during replication. We also identify several previously unknown features of BV genomes that correlate with these different amplification patterns.