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BISER: fast characterization of segmental duplication structure in multiple genome assembliesIseric, Hamza January 2021 (has links)
The increasing availability of high-quality genome assemblies raised interest in the characterization of genomic architecture. Major architectural elements, such as common repeats and segmental duplications (SDs), increase genome plasticity that stimulates further evolution by changing the genomic structure and inventing new genes. Optimal computation of SDs within a genome requires quadratic-time local alignment algorithms that are impractical due to the size of most genomes. Additionally, to perform evolutionary analysis, one needs to characterize SDs in multiple genomes and find relations between those SDs and unique (non-duplicated) segments in other genomes. A na ̈ıve approach consisting of multiple sequence alignment would make the optimal solution to this problem even more impractical. Thus there is a need for fast and accurate algorithms to characterize SD structure in multiple genome assemblies to better understand the evolutionary forces that shaped the genomes of today. Here we introduce a new approach, BISER, to quickly detect SDs in multiple genomes and identify elementary SDs and core duplicons that drive the formation of such SDs. BISER improves earlier tools by (i) scaling the detection of SDs with low homology (75%) to multiple genomes while introducing further 10–34× speed-ups over the existing tools, and by (ii) characterizing elementary SDs and detecting core duplicons to help trace the evolutionary history of duplications to as far as 300 million years. / Graduate
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Systematic Analysis of Duplications and Deletions in the Malaria Parasite P. falciparum: A DissertationDeConti, Derrick K. 15 April 2015 (has links)
Duplications and deletions are a major source of genomic variation. Duplications, specifically, have a significant impact on gene genesis and dosage, and the malaria parasite P. falciparum has developed resistance to a growing number of anti-malarial drugs via gene duplication. It also contains highly duplicated families of antigenically variable allelic genes. While specific genes and families have been studied, a comprehensive analysis of duplications and deletions within the reference genome and population has not been performed. We analyzed the extent of segmental duplications (SD) in the reference genome for P. falciparum, primarily by a whole genome self alignment. We discovered that while 5% of the genome identified as SD, the distribution within the genome was partition clustered, with the vast majority localized to the subtelomeres. Within the SDs, we found an overrepresentation of genes encoding antigenically diverse proteins exposed to the extracellular membrane, specifically the var, rifin, and stevor gene families. To examine variation of duplications and deletions within the parasite populations, we designed a novel computational methodology to identify copy number variants (CNVs) from high throughput sequencing, using a read depth based approach refined with discordant read pairs. After validating the program against in vitro lab cultures, we analyzed isolates from Senegal for initial tests into clinical isolates. We then expanded our search to a global sample of 610 strains from Africa and South East Asia, identifying 68 CNV regions. Geographically, genic CNV were found on average in less than 10% of the population, indicating that CNV are rare. However, CNVs at high frequency were almost exclusively duplications associated with known drug resistant CNVs. We also identified the novel biallelic duplication of the crt gene – containing both the chloroquine resistant and sensitive allele. The synthesis of our SD and CNV analysis indicates a CNV conservative P. falciparum genome except where drug and human immune pressure select for gene duplication.
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Investigation of Mechanics of Mutation and Selection by Comparative SequencingZody, Michael C., January 2009 (has links)
Diss. (sammanfattning) Uppsala : Uppsala universitet, 2009.
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The Action of natural selection in recently duplicated genesLorente Galdós, Maria Belén 11 November 2011 (has links)
Identification of signatures of positive selection has long been a major issue for
understanding the unique features of any given species. However, only a fraction of
human genes have been interrogated. Genes within segmental duplications are usually
omitted due to the limitations of draft genome assemblies and the methodological
reliance on accurate gene trees. In this work, we show the feasibility of a new method
that does not need accurate gene trees or individual high-quality assemblies. We applied
the concept to study exon evolution in the human genome, identifying 74 exons with
evidence for rapid coding sequence evolution during human and Old World monkey
evolution. Our results suggest abundant accelerated coding sequence evolution within
duplicated regions of the genome and provide a more comprehensive view of the role of
selection on the human genome. / La identificación de señales debidas a la acción de la selección positiva es de gran
relevancia para desvelar características únicas de las especies. A pesar de ello, solo una
fracción de genes humanos han sido analizados. Los genes incluidos en duplicaciones
segmentarias son normalmente ignorados debido a limitaciones impuestas por la
naturaleza preliminar de los genomas distintos al humano, así como por la dependencia
en adecuados árboles filogenéticos. En este proyecto, demostramos la viabilidad de un
nuevo método que no necesita árboles filogenéticos correctos ni ensamblajes de
genomas de alta calidad. Hemos aplicado el concepto al genoma humano y hemos
identificado 74 exones que muestran evidencia de haber evolucionado más rápidamente
desde la separación de los humanos y los monos del viejo mundo. Nuestros resultados
sugieren que ha habido abundante evolución acelerada dentro de las regiones duplicadas
y ofrece una visión más esclarecedora del rol de la selección en la evolución del genoma
humano.
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Mutation and Genome EvolutionYampolsky, L. Y. 14 April 2016 (has links)
Genome composition and architecture is shaped by two types of processes: those that introduce heritable changes (mutagenesis) and those that determine the fate of such changes in the populations (genetic drift and selection). Chemical and biological properties of mutagenesis determines the frequencies at which different type of mutations occur, which, in turn, determines their rates of fixation by drift and affects the spectrum of mutations available for selection to operate on. As the result, genomes of living organisms carry many signatures mutagenesis.
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Evolució molecular i estudi funcional de gens localitzats a les duplicacions segmentàries de la regió 7q11.23Antonell Boixader, Anna 20 April 2006 (has links)
En aquest treball es presenta l'evolució molecular i estudi funcional de gens localitzats a les duplicacions segmentàries de la regió 7q11.23, implicada en la Síndrome de Williams-Beuren (SWB). S'ha datat l'aparició d'aquestes duplicacions en els últims 25 milions d'anys d'evolució i s'ha proposat un model evolutiu amb reordenaments específics i mecanismes de generació. Correlacions clínico-moleculars en els pacients amb la SWB han permès determinar que l'haploinsuficiència per NCF1, un gen localitzat a les duplicacions, és un factor protector per hipertensió. S'ha proposat un model patogènic per la hipertensió, implicant l'oxidasa NAD(P)H i estrès oxidatiu, suggerint que noves estratègies terapèutiques podrien ser utilitzades. A més, s'ha caracteritzat parcialment la funció de GTF2IRD2, un altre gen de les duplicacions. GTF2IRD2 interacciona amb altres factors de transcripció relacionats, té una localització subcel·lular variable i no s'uneix a ADN. Aquests resultats contribueixen a conèixer millor els mecanismes mutacionals i patogènics de la SWB. / This work presents the molecular evolution along with the functional analysis of the genes located in the segmental duplications flanking the 7q11.23 region, involved in Williams-Beuren syndrome (WBS). The generation of the segmental duplications has been dated to the last 25 million years of evolution and an evolutionary model with specific rearrangements and mechanisms has been proposed. Clinical-molecular correlations in WBS patients have allowed to determine that haploinsufficiency at NCF1, a gene located in the duplications, is a protective factor for hypertension. A pathogenic model for hypertension has been proposed, implicating NAD(P)H oxidase and oxidative stress, and suggesting that novel therapeutic strategies could be used. In addition, the functional characterization of another gene of the duplications, GTF2IRD2, has been partially achieved. GTF2IRD2 has been shown to interact with other related transcription factors, to display variable subcellular localization and to lack DNA binding properties. These results contribute to a better knowledge of the mutational and pathogenic mechanisms of the WBS.
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