Berekeningsmethoden voor het supersone stromingsveld van een pijlvleugel met subsone voorrand met een deelstroomvlak als romp

Aerospace Engineerin

Listening to the silent genes: Transgene silencing, gene regulation and pathogen control.

By capitalizing on the initially puzzling observations of unpredictable transgene silencing and variable expression, plant scientists have pioneered research into a novel type of epigenetic regulation, termed homology-dependent gene silencing. This silencing process has implications for natural mechanisms of gene expression in plants and other eukaryotes, and has branched out into studies of reversible DNA modifications; RNA metabolism, transport and processing; and host responses to plant viruses, viroids and transposable elements. The analysis of transgene silencing systems has enriched our understanding of other epigenetic phenomena, including paramutation, as well as heterosis and genome evolution. This research is also highly relevant to the biotechnology industry, which is interested in avoiding unwanted transgene silencing in genetically engineered lines and in exploiting various types of silencing to inactivate specific genes. Homology-dependent gene silencing can also be used in high-throughput approaches for functional genomics

Physical mapping of the globin gene deletion in (δβ)° - thalassaemia

We have constructed a physical map of restriction endonuclease cleavage sites in the (δ+β)-globin gene region in the DNA of patients with (δβ)°-thalassaemia. This map shows that a 10 kb deletion has occurred in (δβ)°-thalassaemia to remove the entire β-globin gene and the 3′ portion of the δ-globin gene. The 5′ terminus of the deletion is in the large intron of the δ-globin gene and the 3′ terminus 1.8 kb to the 3′-side of the β-globin gene. A similar deletion of about 7 kb has been described previously in the DNA of patients with Hb Lepore; the 5′ terminus of the deletion is also in the δ-globin gene but the 3′ terminus is in the β-globin gene. Comparison of the foetal (γ) globin gene expression in adults with (δβ)°-thalassaemia and Hb Lepore suggests that the 3′ extragenic regions of the β-globin gene contain DNA sequences involved in the regulation of γ-globin gene expression

Zebrafish as a model to study the role of DNA methylation in environmental toxicology

Environmental epigenetics is a rapidly growing field which studies the effects of environmental factors such as nutrition, stress, and exposure to compounds on epigenetic gene regulation. Recent studies have shown that exposure to toxicants in vertebrates is associated with changes in DNA methylation, a major epigenetic mechanism affecting gene transcription. Zebra fish, a well-known model in toxicology and developmental biology, are emerging as a model species in environmental epigenetics despite their evolutionary distance to rodents and humans. In this review, recent insights in DNA methylation during zebra fish development are discussed and compared to mammalian models in order to evaluate zebra fish as a model to study the role of DNA methylation in environmental toxicology. Differences exist in DNA methylation reprogramming during early development, whereas in later developmental stages, tissue distribution of both 5-methylcytosine and 5-hydroxymethylcytosine seems more conserved between species, as well as basic DNA (de)methylation mechanisms. All DNA methyl transferases identified so far in mammals are present in zebra fish, as well as a number of major demethylation pathways. However, zebra fish appear to lack some methylation pathways present in mammals, such as parental imprinting. Several studies report effects on DNA methylation in zebra fish following exposure to environmental contaminants, such as arsenic, benzo[a]pyrene, and tris(1,3-dichloro-2-propyl)phosphate. Though more research is needed to examine heritable effects of contaminant exposure on DNA methylation, recent data suggests the usefulness of the zebra fish as a model in environmental epigenetics. © 2014 Springer-Verlag Berlin Heidelberg

Position-dependent methylation and transcriptional silencing of transgenes in inverted T-DNA repeats: implications for post-transcriptional silencing of homologous host genes in plants

Posttranscriptional silencing of chalcone synthase (Chs) genes in petunia transformants occurs by introducing T-DNAs that contain a promoter-driven or promoterless Chs transgene. With the constructs we used, silencing occurs only by T-DNA loci which are composed of two or more T-DNA copies that are arranged as inverted repeats (IRs). Since we are interested in the mechanism by which these IR loci induce silencing, we have analyzed different IR loci and nonsilencing single-copy (S) T-DNA loci with respect to the expression and methylation of the transgenes residing in these loci. We show that in an IR locus, the transgenes located proximal to the IR center are much more highly methylated than are the distal genes. A strong silencing locus composed of three inverted T-DNAs bearing promoterless Chs transgenes was methylated across the entire locus. The host Chs genes in untransformed plants were moderately methylated, and no change in methylation was detected when the genes were silenced. Run-on transcription assays showed that promoter-driven transgenes located proximal to the center of a particular IR are transcriptionally more repressed than are the distal genes of the same IR locus. Transcription of the promoterless Chs transgenes could not be detected. In the primary transformant, some of the IR loci were detected together with an unlinked S locus. We observed that the methylation and expression characteristics of the transgenes of these S loci were comparable to those of the partner IR loci, suggesting that there has been cross talk between the two types of loci. Despite the similar features, S loci are unable to induce silencing, indicating that the palindromic arrangement of the Chs transgenes in the IR loci is critical for silencing. Since transcriptionally silenced transgenes in IRs can trigger posttranscriptional silencing of the host genes, our data are most consistent with a model of silencing in which the transgenes physically interact with the homologous host gene(s). The interaction may alter epigenetic features other than methylation, thereby impairing the regular production of mRNA