Global ETD Search

41	Molecular study of Metal Tolerance Protein 1(MTP1) and Plant Defensins Type I (PDF1) gene sub-families : inference on their role in evolution of zinc hypertolerance in Arabidopsis halleri / Molecular study of Metal Tolerance Protein 1(MTP1) and Plant Defensins Type I (PDF1) gene sub-families : contribution à la compréhension des mécanismes moléculaires évolutifs liés à l'acquisition de la tolérance au zinc chez Arabidopsis halleri Shahzad, Zaigham 09 July 2010 (has links) A. halleri, est une espèce modèle pour l'étude des mécanismes moléculaires liés à l'évolution des caractères d'hypertolérance au zinc et d'hyperaccumulation de ce métal, car elle est phylogénétiquement proche d'A. thaliana qui est sensible au zinc et non-accumulatrice. Dans ce travail, nous avons caractérisé comparativement chez A. thaliana et chez A. halleri, deux sous-familles de gènes liés à l'homéostasie du zinc et ou à sa tolérance: Metal Tolérance Protein 1 (MTP1) et Plant Defensin type I (PDF1). Notre analyse génomique montre que le nombre de ces gènes est plus élevé chez A. halleri que chez A. thaliana confortant l'hypothèse actuelle reliant les duplications de gènes chez A. halleri à l'acquisition de son caractère d'hypertolérance. Mais, les résultats de nos études fonctionnelles ne vont pas dans ce sens, car ils montrent que, par exemple, certaines protéines AhMTP1 et AhPDF1 induisent une tolérance au zinc faible voire nulle lorsqu'elles sont testées dans la levure. Mais le résultat le plus marquant est que les transcrits de plusieurs gènes AhMTP1 et AhPDF1 ne sont pas détectables ou bien sont faiblement accumulés dans la plante. Nos résultats montrent donc que les gènes de ces sous-familles ne sont pas équivalents en ce qui concerne leur fonction dans la tolérance au zinc suggérant ainsi qu'ils sont le sujet de devenirs évolutifs différents. En dehors de leur contribution à la compréhension des mécanismes moléculaires qui sous-tendent l'évolution de la tolérance au zinc chez A. halleri, nos travaux sont également porteurs de développements biotechnologiques appliqués au zinc dans les domaines de la phytoremédiation et de la biofortification / A. halleri, is a model species to study molecular evolutionary mechanisms related to zinc hypertolerance and hyperaccumulation, due to its close relatedness with A. thaliana which is zinc sensitive and non-accumulator. Here, we comparatively characterised in both species, two zinc homeostasis and/or zinc tolerance related genes sub-families: the Metal Tolerance Protein 1 (MTP1) and the Plant defensins type I (PDF1). Genomic analyses revealed that the copy number of these genes is increased in A. halleri compared to A. thaliana. It was thus tempting to relate the acquisition of zinc hypertolerance in A. halleri to these gene duplications. However, the assumption was invalidated by functional analyses. For instance, some of the AhMTP1 or AhPDF1 proteins induced weak or no zinc tolerance to yeast. More importantly, transcripts of many AhMTP1 or AhPDF1 genes were either not accumulated or were very poorly expressed in A. halleri. These results indicate that different members of these gene sub-families are not equally functional. It is thus expected that these gene duplicates are undergoing different evolutionary fates regarding zinc tolerance. Besides helping to understand the molecular evolutionary mechanisms, studying zinc-related genes in A. halleri may also help developing strategies like phytoremediation and biofortification. Arabidopsis Hypertolérance au zinc Évolution Duplication de gène Mtp1 Pdf1 Arabidopsis Zinc hypertolerance Evolution Gene duplication Mtp1 Pdf1
42	Evolutionary Analysis of the Insulin-Relaxin Gene Family from the Perspective of Gene and Genome Duplication Events / Ewolucyjna Analiza Rodziny Genów Insulin-Relaksyn z Perspektywy Duplikacji Genu i Genomu Olinski, Robert Piotr January 2007 (has links) <p>Paralogs arise by duplications and belong to families. Ten paralogs (insulin; <i>IGF-1</i> and <i>-2</i>; <i>INSL3-6</i> and 3-relaxins) constitute the human insulin-relaxin family. The aim of this study was to outline the duplications that gave rise to the vertebrate insulin-relaxin genes and the chromosomal regions in which they reside. Neurotrophin and Trk-receptor families with more than 300, otherwise unrelated, families had paralogs in the regions hosting insulin/relaxin genes, defining two quadruplicate paralogy-regions, namely: insulin/IGF and INSL/relaxin paralogons. Thereby, the localization of insulin/relaxins in human shows that these regions were formed during two genome duplications at the stem of the vertebrates.</p><p>We characterized insulin-like genes (<i>INS-L1</i>, <i>-L2</i> and <i>-L3</i>) in the <i>Ciona intestinalis</i> genome, a species that split from the chordate lineage before the genome duplications. Conserved synteny between the Ciona region hosting the <i>INS-Ls</i> and two human paralogons as well as linkage of the actual paralogons, suggest that a segmental duplication gave rise to the entire region prior to the genome duplications. Synteny together with gene and protein structures demonstrate that <i>INS-L1</i> is orthologous to the vertebrate <i>INSLs</i>/relaxins, <i>INS-L2</i> to insulins and <i>INS-L3</i> to <i>IGFs</i>. This indicates that pro-orthologs of the insulin-relaxin family were formed before Ciona. Our analysis also implies that the INSL/relaxin ancestor switched receptor from tyrosine kinase- to GPCR-type. This probably occurred after the Ciona-stage, but before the genome duplications.</p><p>Using genes residing within the analyzed human paralogons that were present in a chromosomal region in the Ciona-human ancestor, we identified 37 segments with conserved synteny between the <i>Drosophila melanogaster</i> and human genomes. Orthologs residing in Ciona-, sea urchin- and the fly syntenic segments imply that such segments approximate an ancestral region from which the human paralogons originated.</p><p>To conclude, the human paralogons are remnants of genome duplications that in addition to segmental- and single duplications, shaped the extant vertebrate genomes. Using the quadruplicate paralogy-regions we were able to deduce duplication events of the insulin-relaxin genes and their chromosomal regions.</p> Neurosciences insulin relaxin insulin-like protein gene duplication paralogous region Ciona intestinalis conserved synteny ortholog Drosophila melanogaster Neurovetenskap
43	Evolutionary Analysis of the Insulin-Relaxin Gene Family from the Perspective of Gene and Genome Duplication Events / Ewolucyjna Analiza Rodziny Genów Insulin-Relaksyn z Perspektywy Duplikacji Genu i Genomu Olinski, Robert Piotr January 2007 (has links) Paralogs arise by duplications and belong to families. Ten paralogs (insulin; IGF-1 and -2; INSL3-6 and 3-relaxins) constitute the human insulin-relaxin family. The aim of this study was to outline the duplications that gave rise to the vertebrate insulin-relaxin genes and the chromosomal regions in which they reside. Neurotrophin and Trk-receptor families with more than 300, otherwise unrelated, families had paralogs in the regions hosting insulin/relaxin genes, defining two quadruplicate paralogy-regions, namely: insulin/IGF and INSL/relaxin paralogons. Thereby, the localization of insulin/relaxins in human shows that these regions were formed during two genome duplications at the stem of the vertebrates. We characterized insulin-like genes (INS-L1, -L2 and -L3) in the Ciona intestinalis genome, a species that split from the chordate lineage before the genome duplications. Conserved synteny between the Ciona region hosting the INS-Ls and two human paralogons as well as linkage of the actual paralogons, suggest that a segmental duplication gave rise to the entire region prior to the genome duplications. Synteny together with gene and protein structures demonstrate that INS-L1 is orthologous to the vertebrate INSLs/relaxins, INS-L2 to insulins and INS-L3 to IGFs. This indicates that pro-orthologs of the insulin-relaxin family were formed before Ciona. Our analysis also implies that the INSL/relaxin ancestor switched receptor from tyrosine kinase- to GPCR-type. This probably occurred after the Ciona-stage, but before the genome duplications. Using genes residing within the analyzed human paralogons that were present in a chromosomal region in the Ciona-human ancestor, we identified 37 segments with conserved synteny between the Drosophila melanogaster and human genomes. Orthologs residing in Ciona-, sea urchin- and the fly syntenic segments imply that such segments approximate an ancestral region from which the human paralogons originated. To conclude, the human paralogons are remnants of genome duplications that in addition to segmental- and single duplications, shaped the extant vertebrate genomes. Using the quadruplicate paralogy-regions we were able to deduce duplication events of the insulin-relaxin genes and their chromosomal regions. Neurosciences insulin relaxin insulin-like protein gene duplication paralogous region Ciona intestinalis conserved synteny ortholog Drosophila melanogaster Neurovetenskap
44	Signaling mechanisms and developmental function of fibroblast growth factor receptors in zebrafish Kolanczyk, Maria Elzbieta 19 May 2009 (has links) (PDF) Fibroblast growth factor (Fgf) signaling plays multiple inductive roles during development of vertebrates (Itoh 2007). Some Fgfs, such as Fgf8, are locally secreted and signal over a long range to provide positional information in the target tissue (Scholpp and Brand 2004). Fgf ligands signal in a receptor-dependent manner via tyrosine kinase receptors, four of which have been so far identified. Fgf8 signaling was shown to depend both on receptor activation as well as endocytosis. The specificity of Fgf ligands and receptors as well as the function of receptors in the control of the Fgf signaling range have been, however, largely unclear. In this study, we show that the putative Fgf8 receptor Fgfr1 is duplicated in zebrafish and that it acts redundantly in the formation of the posterior mesoderm. Also, in overexpression studies we confirm the notion that receptor endocytosis influences Fgf8 signaling range. Through TILLING mutant recovery and morpholino knockdown studies we also show that Fgfr2 is required for growth and skeletal development in zebrafish, whereas Fgfr4 is required for pectoral fin specification and growth. fibroblast growth factors zebrafish endocytosis Fgf8 Fgfr1 gene duplication Fgf Zebrafisch Endocytosis Fgf8 Fgfr1 Genduplizierung ddc:570 rvk:WG 1750
45	Genomic and transcriptomic variation in blood stage Plasmodium falciparum / Mok, Bobo, January 2007 (has links) Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 4 uppsatser.
46	Differential expression of recent gene duplicates in developmental tissues of Arabidopsis thaliana Owens, Sarah Marie. January 2009 (has links) Title from first page of PDF document. Includes bibliographical references (p. 20-23).
47	Prediction of mammalian essential genes based on sequence and functional features Kabir, Mitra January 2017 (has links) Essential genes are those whose presence is imperative for an organism's survival, whereas the functions of non-essential genes may be useful but not critical. Abnormal functionality of essential genes may lead to defects or death at an early stage of life. Knowledge of essential genes is therefore key to understanding development, maintenance of major cellular processes and tissue-specific functions that are crucial for life. Existing experimental techniques for identifying essential genes are accurate, but most of them are time consuming and expensive. Predicting essential genes using computational methods, therefore, would be of great value as they circumvent experimental constraints. Our research is based on the hypothesis that mammalian essential (lethal) and non-essential (viable) genes are distinguishable by various properties. We examined a wide range of features of Mus musculus genes, including sequence, protein-protein interactions, gene expression and function, and found 75 features that were statistically discriminative between lethal and viable genes. These features were used as inputs to create a novel machine learning classifier, allowing the prediction of a mouse gene as lethal or viable with the cross-validation and blind test accuracies of ∼91% and ∼93%, respectively. The prediction results are promising, indicating that our classifier is an effective mammalian essential gene prediction method. We further developed the mouse gene essentiality study by analysing the association between essentiality and gene duplication. Mouse genes were labelled as singletons or duplicates, and their expression patterns over 13 developmental stages were examined. We found that lethal genes originating from duplicates are considerably lower in proportion than singletons. At all developmental stages a significantly higher proportion of singletons and lethal genes are expressed than duplicates and viable genes. Lethal genes were also found to be more ancient than viable genes. In addition, we observed that duplicate pairs with similar patterns of developmental co-expression are more likely to be viable; lethal gene duplicate pairs do not have such a trend. Overall, these results suggest that duplicate genes in mouse are less likely to be essential than singletons. Finally, we investigated the evolutionary age of mouse genes across development to see if the morphological hourglass pattern exists in the mouse. We found that in mouse embryos, genes expressed in early and late stages are evolutionarily younger than those expressed in mid-embryogenesis, thus yielding an hourglass pattern. However, the oldest genes are not expressed at the phylotypic stage stated in prior studies, but instead at an earlier time point - the egg cylinder stage. These results question the application of the hourglass model to mouse development. 572
48	Utilizace trehalózy u orchidejí: evoluce genů trehalázy / Utilization of trehalose in orchids: evolution of trehalase genes Šoch, Jan January 2017 (has links) All orchid species studied so far have been shown to participate in orchideoid mycorrhizal symbiosis. Morover, this symbiosis is absolutely vital component of their life cycle. Exchange of nutrients occurs between symbionts where the fungi provides the orchid with energy and carbon supply at least in its early developmental stages. This study focuses on the possible role of trehalose in this transfer. In vitro experiments have showed in five species from three different subfamilies of Orchidaceae family that they can utilize trehalose comparably with sucrose and glucose. Thus, the ability of trehalose utilization seems to be conserved among orchids. Trehalase enzyme activity was localized histochemically in orchid mycorrhizas. The activity strongly colocalized with colonized tissue supporting a hypothesis that trehalose transfer occurs in this site and is mediated by trehalase. Using bioinformatic methods, trehalase gene duplications were identified in many taxons of Embryophyta including three orchid species. Interestingly, highest number of trehalase gene copies was identified in genome of orchid Dactylorhiza majalis. Trehalose utilization, high trehalase activity in mycorrhizas and trehalase gene duplications in some orchids together indicate that trehalose transfer in orchid myccorhizas...
49	Differential expression of recent gene duplicates in developmental tissues of <i>Arabidopsis thaliana</i> Owens, Sarah Marie 14 August 2009 (has links) No description available. Botany Genetics Molecular Biology Gene duplication recent gene duplicates differential expression gene expression unlinked duplicates expression divergence
50	An analysis of salmonid RNA sequences and implications for salmonid evolution Brown, Gordon David 01 April 2008 (has links) This work addresses two areas of computational biology: automation of sequence processing and an assessment of the evidence for a hypothesized salmonid genome based on an analysis of a set of expressed sequence tags. Three problem areas in sequence processing are addressed in the first half of the work. Chapter 3 describes an accurate technique for trimming of vector, adapter and poly(A) sequence. Chapter 4 suggests methods for verifying the accuracy of assembled mRNA transcripts despite a large number of chimeras in the cDNA clone libraries. Chapter 5 is concerned with the problem of estimating the number of transcripts in a tissue or cDNA library, concluding that computational and statistical techniques are inadequate to estimate the quantity accurately. The hypothesized salmonid genome duplication has been widely accepted since 1984. If it occurred, it should have left evidence in the form of many paralogous pairs of genes, all at approximately the same degree of sequence divergence. To assess this question, several hundred thousand ESTs were assembled into transcripts, compared to each other to find homologs, and the evolutionary distances of the homologs represented as a histogram. Evidence of a single evolutionary event was not seen. The same procedure was applied to Xenopus laevis, which has a well-established recent genome duplication, and Danio rerio, which is known not to have had one. In those cases, the evidence for or against a genome duplication appeared exactly as predicted. The conclusion is that if the salmonid genome duplication occurred, some force altered its evolutionary development subsequently to mask the duplication, but also that a genome duplication is not necessary to explain the observed pattern of homolog distances. salmonids evolution RNA analysis genome duplication gene duplication

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