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The role of transposons in shaping plant genomes /Juretic, Nikoleta. January 2008 (has links)
Transposons, also known as transposable elements (TEs), are genetic elements capable of changing their location in the genome and amplifying in number. Because of their ability to cause mutations in the host genome, often with detrimental consequences to the host, yet avoid being eliminated by natural selection, transposons have been labeled selfish elements or genomic parasites. However, the advent of genomics has allowed the identification of numerous instances where transposons have played a crucial role in host genome evolution. In this thesis, I evaluate the extent to which transposons have influenced the genomes of their hosts, with an emphasis on plant genomes. I review the present knowledge of different mechanisms by which this is achieved and provide examples to illustrate them. Next, I tackle the problem of annotating transposons in the completed genomic sequence of domestic rice by comparing RepeatMasker, the standard approach used in transposon annotation, with an alternative approach employing hidden Markov models. In addition, I perform a genome-wide analysis of gene fragment capture by rice Mutator-like transposons. I conclude that, while this is a widespread phenomenon in rice, it is unlikely to represent a major force in generating novel protein-coding genes. Nevertheless, the duplicated gene fragments that are transcribed may playa role in the regulation of host genes they arose from via an RNAi-like mechanism. Finally, I conduct an in silico analysis of a gene family derived from a domesticated Mutator-like transposase, called MUSTANG (MUG), in conjunction with an experimental characterization of the MUG family in Arabidopsis. The results of the study indicate that the MUG family arose in a common ancestor of flowering plants and that the Arabidopsis genes AtMUG1 and/or AtMUG2 may act as global regulators of mitochondrial function. I conclude that our appreciation of the role of transposons in host function and evolution will undoubtedly continue to grow as our understanding of these processes deepens.
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AQX : a novel gene in plant ubiquinone biosynthesisStorey, Benjamin, 1973- January 2002 (has links)
C. elegans worms with mutations in the gene CLK-1 develop slowly and have an extended lifespan. CLK-1 encodes a mitochondrial protein that is responsible for the hydroxylation of 5-demethoxyubiquinone (DMQ), the penultimate step of ubiquinone (Coenzyme-Q or UQ) biosynthesis. Structural homologues of CLK-1 are found in mammals, fruit flies, yeast and some types of bacteria. Interestingly, however, there is no structural homologue of CLK-1 in the Arabidopsis genome and no plant homologue can be found in other sequence databases. Yeast with the CLK-1 homologue COQ7 deleted fail to grow on non-fermentable carbon sources. To identify a plant functional homologue of COQ7/CLK-1, an Arabidopsis cDNA expression library was screened for complementation of a yeast coq7 deletion mutant. A clone was identified that rescued the coq7 respiratory deficiency. Although the sequence of the encoded protein has no structural similarity to proteins in the COQ7/CLK-1 family, it contains a monooxygenase/hydroxylase domain that has sequence similarity with the E. coli DMQ hydroxylase encoded by the UBIF gene. Like the structural homologues of COQ7/CLK-1 found in other eukaryotes, the gene (AQX for 'Alternate Quinone monooXygenase') contains a likely mitochondrial targeting presequence at its N-terminus. HPLC analysis of quinone extracts from rescued cog7 strains does not detect ubiquinone, but instead shows another peak that may be DMQ. It is likely that AQX does not hydroxylate yeast DMQ effectively enough to generate detectable levels of UQ. A unique pathway for UQ biosynthesis in plants is proposed that is defined by AQX and Arabidopsis genes identified on the basis of homology to known E. coli and yeast UQ biosynthesis genes.
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AQX : a novel gene in plant ubiquinone biosynthesisStorey, Benjamin, 1973- January 2002 (has links)
No description available.
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The role of transposons in shaping plant genomes /Juretic, Nikoleta January 2008 (has links)
No description available.
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Rapid evolution of post-transcriptionally regulated RESTORER OF FERTILITY-LIKE genes in the genus ArabidopsisJogdeo, Sanjuro 22 June 2012 (has links)
The Pentatricopeptide Repeat (PPR) gene family produces RNA-binding proteins that target organellar transcripts. The PPR family is expanded in land plants, with nearly 450 genes identified in Arabidopsis thaliana. In plants with a Cytoplasmic Male Sterility (CMS) phenotype, members of the PPR family can act as a RESTORER OF FERTILITY (Rf) and are part of a subset of genes called RESTORER OF FERTILITY-LIKE (RFL). Unlike other PPR transcripts, RFL transcripts are targets of both microRNA (miRNA) and trans-acting siRNA (tasiRNA) and produce secondary siRNA after initial miRNA- or tasiRNA-guided cleavage. We utilized the A. lyrata genome assembly and high-throughput sequencing of small RNA to examine the evolutionary dynamics of the PPR gene family and the pattern of small RNA targeting of RFL transcripts. We found an expanded set of 539 PPR genes in A. lyrata, 51 of which were in the RFL group, often in multiple collinear copies when compared to their A. thaliana orthologs. In-species RFL paralogs appear to be more related to one another than to their collinear orthologs, which is possible evidence of gene conversion or ectopic recombination. miRNA targeting of RFL transcripts is largely conserved with nearly two-thirds of all target sites maintained. TasiRNA targeting was less conserved with roughly one-third of comparable validated tasiRNA targets maintained in both species. However, when clusters of potential tasiRNA targets were considered, roughly two-thirds of target sites are conserved. Production of secondary siRNA from A. lyrata PPR transcripts is less well defined than in A. thaliana, with strong signals coming from phases that are not concordant with the miRNA- or tasiRNA-guided cleavage sites. / Graduation date: 2013
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