Global ETD Search

61	Analysis of genetic relatedness using DNA microarrays Welander, Jenny January 2009 (has links) <p>Analysis of genetic relatedness is of great importance in forensic casework such as immigration and identification cases. The conventional methods for relationship testing are not sufficient in the most complicated cases, because more genetic markers are required to obtain results with satisfactory statistical security. This study demonstrates that microarrays, which can be used to genotype thousands of single nucleotide polymorphisms (SNPs), could be a promising solution to this problem. The microarray technique used in this study performed very well on blood samples and also worked well in combination with whole genome amplification, but did not generate any results when used on severely degraded materials.</p><p>Markers suitable for relatedness analysis were selected from the microarray and were successfully tested on families with known genetic relations. Although a maximum of 64 autosomal markers were used, there is a great potential of selecting the hundreds or thousands of markers that may be required in some cases of relatedness investigation.</p> Microarray DNA chip Single nucleotide polymorphism Genetic relatedness Linkage Bioengineering Bioteknik Genteknik inkl. funktionsgenomik
62	Population genetic analyses in the orchid genus <i>Gymnadenia</i> : a conservation genetic perspective Gustafsson, Susanne January 2003 (has links) <p>Small populations are facing a particular risk of extinction due to a lack of appropriate genetic diversity and associated negative effects, factors dealt with in the discipline of conservation genetics. Many orchid species exhibit characteristics that make them a perfect study object in the scope of conservation genetics. The aim with this thesis was to investigate genetic structure at different levels in two orchid species <i>Gymnadenia conopsea</i>, geographically widespread, although diminishing and <i>G. odoratissima</i> with a long history of being rare. Microsatellite markers, developed in and used in studies of <i>G. conopsea</i> were also used in the study of <i>G. odoratissima</i>.</p><p>Populations of <i>G. conopsea</i> expressed high levels of genetic variation and a certain amount of gene flow, although investigated mating pattern in a small population indicated non-random mating among individuals, with the majority of pollen exchange between near neighbours, and noticeable levels of geitonogamous pollinations. Further a pronounced year to year variation in flowering frequency among individuals was found. </p><p>It was also discovered that flowering time variants (early and late) within the species <i>G. conopsea</i> were highly differentiated and seem to have had a more ancient historical separation than the separation between the two different species, <i>G. conopsea</i> and <i>G. odoratissima. </i></p><p>Levels of genetic variation in the rare congener, <i>G. odoratissima</i> differed between island and mainland populations where the more numerous island populations expressed larger levels of genetic variation and were less differentiated compared to the few remaining and genetically depauperated mainland populations.</p><p>Uppsala University Library, Box 510, 75120, Uppsala, Sweden </p> Genetic engineering Orchidaceae Gymnadenia conservation microsatellites genetic structure mating pattern Genteknik Genteknik inkl. funktionsgenomik
63	Population genetic analyses in the orchid genus Gymnadenia : a conservation genetic perspective Gustafsson, Susanne January 2003 (has links) Small populations are facing a particular risk of extinction due to a lack of appropriate genetic diversity and associated negative effects, factors dealt with in the discipline of conservation genetics. Many orchid species exhibit characteristics that make them a perfect study object in the scope of conservation genetics. The aim with this thesis was to investigate genetic structure at different levels in two orchid species Gymnadenia conopsea, geographically widespread, although diminishing and G. odoratissima with a long history of being rare. Microsatellite markers, developed in and used in studies of G. conopsea were also used in the study of G. odoratissima. Populations of G. conopsea expressed high levels of genetic variation and a certain amount of gene flow, although investigated mating pattern in a small population indicated non-random mating among individuals, with the majority of pollen exchange between near neighbours, and noticeable levels of geitonogamous pollinations. Further a pronounced year to year variation in flowering frequency among individuals was found. It was also discovered that flowering time variants (early and late) within the species G. conopsea were highly differentiated and seem to have had a more ancient historical separation than the separation between the two different species, G. conopsea and G. odoratissima. Levels of genetic variation in the rare congener, G. odoratissima differed between island and mainland populations where the more numerous island populations expressed larger levels of genetic variation and were less differentiated compared to the few remaining and genetically depauperated mainland populations. Uppsala University Library, Box 510, 75120, Uppsala, Sweden Genetic engineering Orchidaceae Gymnadenia conservation microsatellites genetic structure mating pattern Genteknik Genteknik inkl. funktionsgenomik
64	Transcriptome and Proteome Analysis using Signature Tags Agaton, Charlotta January 2003 (has links) With the full sequence of the human genome now available, anexciting era in biomedical research has started. The sequenceprovides information about all our genes and greatly increasesthe scope to compare genetic activities in different cells, toanalyze genetic variation between individuals and betweendifferent species and, most importantly, to investigatesystematically the whole genome in a gene-by-gene manner, andthus increase our understanding of gene function. This thesis describes studies in which developments weremade in several areas of functional genomics. Messenger RNAlevels were analyzed by the use of an amplification procedure,in which the 3´-ends of the transcripts were selected inorder to amplify the mRNA population in an unbiased fashion. Bysonicating cDNA originating from expressed mRNA, uniformlysized representatives of the transcripts,signaturetags, were obtained. The mRNA levels in the original mRNApopulation correlated well with the levels in the amplifiedmaterial, as verified by microarray analysis and realtimequantitative PCR. The expressed transcripts can be identifiedusing pyrosequencing, by comparing the obtained sequenceinformation from the signature tags to information contained invarious sequence databases. In one of the articles, the use ofpyrosequencing is illustrated by efforts to find genes involvedin the disease progression of atherosclerosis. More challenging than the study of mRNA levels is to analyzewhen, where and how proteins fulfill their wide-ranging rolesin all the various cellular processes. Proteins are morecomplex biomolecules than mRNA, each having unique properties.Current techniques for studying proteins need much improvement,and are often limited to investigations of a specific portionof the proteome. One approach for studying the whole proteomeis to systematically generate reagents with specific affinityfor the proteins encoded by the genome, one by one. Theaffinity reagents can be used as flags for their targets,providing a flag-specific detection system, so that the targetproteins can be sub-cellularly localized in the majority ofhuman tissues in an array format. One of the articles includedin the thesis presents a pilot project for large-scale affinityreagent production. The aim was to provide a sound basis forwhole proteome studies, but as a pilot study this investigationwas limited to the proteins encoded by human chromosome 21. Allputative genes on the chromosome were subjected to antibodygeneration in a systematic manner. Small, uniform, and easilyproduced representative portions of the full-length proteinswere expressed. These were denotedProtein EpitopeSignature Tagsand were designed to be unique for theirfull-length counterparts. The antibodies were produced inrabbits and two of the articles in the thesis discuss differentapproaches for affinity purification of the antibodies toachieve the highest possible specificity towards the targets.The resultingmono-specific, but stillmulti-epitope, antibodies can be used for a widerange of additional biochemical studies, such as protein arrayand protein pull-out analyses. <b>Keywords:</b>functional genomics, 3´-end signaturetags, pyrosequencing, amplification, PrEST, chromosome 21,polyclonal antibodies, dual expression, affinitypurification. functional genomics 3´-end signature tags pyrosequencing amplification PrEST chromosome 21 polyclonal antibodies dual expression affinity purification
65	Mining the transcriptome - methods and applications Wirta, Valtteri January 2006 (has links) Regulation of gene expression occupies a central role in the control of the flow of genetic information from genes to proteins. Regulatory events on multiple levels ensure that the majority of the genes are expressed under controlled circumstances to yield temporally controlled, cell and tissue-specific expression patterns. The combined set of expressed RNA transcripts constitutes the transcriptome of a cell, and can be analysed on a large-scale using both sequencing and microarray-based methods. The objective of this work has been to develop tools for analysis of the transcriptomes (methods), and to gain new insights into several aspects of the stem cell transcriptome (applications). During recent years expectations of stem cells as a resource for treatment of various disorders have emerged. The successful use of endogenously stimulated or ex vivo expanded stem cells in the clinic requires an understanding of mechanisms controlling their proliferation and self-renewal. This thesis describes the development of tools that facilitate analysis of minute amounts of stem cells, including RNA amplification methods and generation of a cDNA array enriched for genes expressed in neural stem cells. The results demonstrate that the proposed amplification method faithfully preserves the transcript expression pattern. An analysis of the feasibility of a neurosphere assay (in vitro model system for study of neural stem cells) clearly shows that the culturing induces changes that need to be taken into account in design of future comparative studies. An expressed sequence tag analysis of neural stem cells and their in vivo microenvironment is also presented, providing an unbiased large-scale screening of the neural stem cell transcriptome. In addition, molecular mechanisms underlying the control of stem cell self-renewal are investigated. One study identifies the proto-oncogene Trp53 (p53) as a negative regulator of neural stem cell self-renewal, while a second study identifies genes involved in the maintenance of the hematopoietic stem cell phenotype. To facilitate future analysis of neural stem cells, all microarray data generated is publicly available through the ArrayExpress microarray data repository, and the expressed sequence tag data is available through the GenBank. / QC 20100927 transcriptome gene expression profiling EST microarray RNA amplification stem cells neurosphere Genteknik inkl. funktionsgenomik
66	Analysis of genetic relatedness using DNA microarrays Welander, Jenny January 2009 (has links) Analysis of genetic relatedness is of great importance in forensic casework such as immigration and identification cases. The conventional methods for relationship testing are not sufficient in the most complicated cases, because more genetic markers are required to obtain results with satisfactory statistical security. This study demonstrates that microarrays, which can be used to genotype thousands of single nucleotide polymorphisms (SNPs), could be a promising solution to this problem. The microarray technique used in this study performed very well on blood samples and also worked well in combination with whole genome amplification, but did not generate any results when used on severely degraded materials. Markers suitable for relatedness analysis were selected from the microarray and were successfully tested on families with known genetic relations. Although a maximum of 64 autosomal markers were used, there is a great potential of selecting the hundreds or thousands of markers that may be required in some cases of relatedness investigation. Microarray DNA chip Single nucleotide polymorphism Genetic relatedness Linkage Bioengineering Bioteknik Genteknik inkl. funktionsgenomik
67	Development of quantitative PCR methods for diagnosis of bacterial vaginosis and vaginal yeast infection Eiderbrant, Kristina January 2011 (has links) Vaginitis is a vaginal infection which affects many women all over the world. The disorder is characterized by an infection of the vaginal area which can cause problems like abnormal vaginal discharge, itching and redness. The two most common causes of vaginitis are bacterial vaginosis and Candida vaginitis. The prevalence of bacterial vaginosis in Sweden is around 10-20 % and approximately 75 % of all women will once in their lifetime suffer from vaginal yeast infection. The clinical symptoms of vaginal infections are not specific and the diagnosis methods of bacterial vaginosis and Candida vaginitis are subjective and depended on the acuity of the clinician. Due to the lack of standardized and objective diagnostic tools, misdiagnosis and consequently incorrect treatment may occur. As vaginal infections and symptoms impact greatly of women´s quality of life and vaginitis have been associated with serious public health consequences, it is essential to diagnose and treat the conditions correctly. Hence, there is a great need of better methods of diagnosing these conditions. The aim of this master thesis was to develop quantitative species-specific real-time PCR assays to use in diagnosing the two most common causes of vaginitis i.e. bacterial vaginosis and Candida vaginitis. Potential markers for bacterial vaginosis (Atopobium vaginae, BVAB2, Gardnerella vaginalis, Lactobacillus crispatus, Lactobacillus gasseri, Lactobacillus jensenii, Lactobacillus iners, Megasphaera type 1, Megasphaera type 2, Mobiluncus curtisii, Mobiluncus mulieris and Leptotrichia/Sneathia species) and Candida vaginitis (Candida albicans, Candida glabrata, Candida parapsilosis and Candida tropicalis) were chosen. Primers and probes were designed and tested on reference strains and vaginal samples. Single- and multiplex PCR reactions were successfully optimized with the designed oligonucleotides. Furthermore, standard curves with excellent linearity were created and covered more than five orders of magnitude. These developed quantitative species-specific real-time PCR assays will, in a prospective medical validation, quantify 300 vaginal samples from women visiting the RFSU Clinic in Stockholm. Vaginitis bacterial vaginosis Candida Lactobacillus real-time PCR Bioengineering Bioteknik Genteknik inkl. funktionsgenomik
68	Alteration of transcription by non-coding elements in the human genome Conley, Andrew Berton 27 June 2012 (has links) The human genome contains ~1.5% coding sequence, with the remaining 98.5% being non-coding. The functional potential of the majority of this non-coding sequence remains unknown. Much of this non-coding sequence is derived from transposable element (TE) sequences. These TE sequences contain their own regulatory information, e.g. promoter and transcription factor binding sites. Given the large number of these sequences, over 4 million in the human genome, it would be expected that the regulatory information that they contain would affect the expression of nearby genes. This dissertation describes research that characterizes that alternation of and contribution to the human transcriptome by non-coding elements, including TE sequences. Gene regulation Human genomics Antisense transcription Chromatin Transposable elements Functional genomics Human genome Human gene mapping Gene mapping
69	Functional genomic analysis of cell cycle progression in human tissue culture cells Kittler, Ralf 19 October 2006 (has links) (PDF) The eukaryotic cell cycle orchestrates the precise duplication and distribution of the genetic material, cytoplasm and membranes to daughter cells. In multicellular eukaryotes, cell cycle regulation also governs various organisatorial processes ranging from gametogenesis over multicellular development to tissue formation and repair. Consequently, defects in cell cycle regulation provoke a variety of human cancers. A global view of genes and pathways governing the human cell cycle would advance many research areas and may also deliver novel cancer targets. Therefore this work aimed on the genome-wide identification and systematic characterisation of genes required for cell cycle progression in human cells. I developed a highly specific and efficient RNA interference (RNAi) technology to realize the potential of RNAi for genome-wide screening of the genes essential for cell cycle progression in human tissue culture cells. This approach is based on the large-scale enzymatic digestion of long dsRNAs for the rapid and cost-efficient generation of libraries of highly complex pools of endoribonuclease-prepared siRNAs (esiRNAs). The analysis of the silencing efficiency and specificity of esiRNAs and siRNAs revealed that esiRNAs are as efficient for mRNA degradation as chemically synthesized siRNA designed with state-of-the-art design algorithms, while exhibiting a markedly reduced number of off-target effects. After demonstrating the effectiveness of this approach in a proof-of-concept study, I screened a genome-wide esiRNA library and used three assays to generate a quantitative and reproducible multi-parameter profile for the 1389 identified genes. The resulting phenotypic signatures were used to assign novel cell cycle functions to genes by combining hierarchical clustering, bioinformatics and proteomic data mining. This global perspective on gene functions in the human cell cycle presents a framework for the systematic documentation necessary for the understanding of cell cycle progression and its misregulation in diseases. The identification of novel genes with a role in human cell cycle progression is a starting point for an in-depth analysis of their specific functions, which requires the validation of the observed RNAi phenotype by genetic rescue, the study of the subcellular localisation and the identification of interaction partners of the expressed protein. One strategy to achieve these experimental goals is the expression of RNAi resistant and/or tagged transgenes. A major obstacle for transgenesis in mammalian tissue culture cells is the lack of efficient homologous recombination limiting the use of cultured mammalian cells as a real genetic system like yeast. I developed a technology circumventing this problem by expressing an orthologous gene from a closely related species including its regulatory sequences carried on a bacterial artificial chromosome (BAC). This technology allows physiological expression of the transgene, which cannot be achieved with conventional cDNA expression constructs. The use of the orthologous gene from a closely related species confers RNAi resistance to the transgene allowing the depletion of the endogenous gene by RNAi. Thus, this technology mimics homologous recombination by replacing an endogenous gene with a transgene while maintaining normal gene expression. In combination with recombineering strategies this technology is useful for RNAi rescue experiments, protein localisation and the identification of protein interaction partners in mammalian tissue culture cells. In summary, this thesis presents a major technical advance for large-scale functional genomic studies in mammalian tissue culture cells and provides novel insights into various aspects of cell cycle progression. (Die Druckexemplare enthalten jeweils eine CD-ROM als Anlagenteil: 217 MB: Movies, Rohdaten - Nutzung: Referat Informationsvermittlung der SLUB) functional genomics RNA interference cell cycle Funktionelle Genomik RNA-Interferenz Zellzyklus ddc:570 rvk:WE 2500 Genomik RNS-Interferenz Zellzyklus
70	Transcriptome and Proteome Analysis using Signature Tags Agaton, Charlotta January 2003 (has links) <p>With the full sequence of the human genome now available, anexciting era in biomedical research has started. The sequenceprovides information about all our genes and greatly increasesthe scope to compare genetic activities in different cells, toanalyze genetic variation between individuals and betweendifferent species and, most importantly, to investigatesystematically the whole genome in a gene-by-gene manner, andthus increase our understanding of gene function.</p><p>This thesis describes studies in which developments weremade in several areas of functional genomics. Messenger RNAlevels were analyzed by the use of an amplification procedure,in which the 3´-ends of the transcripts were selected inorder to amplify the mRNA population in an unbiased fashion. Bysonicating cDNA originating from expressed mRNA, uniformlysized representatives of the transcripts,signaturetags, were obtained. The mRNA levels in the original mRNApopulation correlated well with the levels in the amplifiedmaterial, as verified by microarray analysis and realtimequantitative PCR. The expressed transcripts can be identifiedusing pyrosequencing, by comparing the obtained sequenceinformation from the signature tags to information contained invarious sequence databases. In one of the articles, the use ofpyrosequencing is illustrated by efforts to find genes involvedin the disease progression of atherosclerosis.</p><p>More challenging than the study of mRNA levels is to analyzewhen, where and how proteins fulfill their wide-ranging rolesin all the various cellular processes. Proteins are morecomplex biomolecules than mRNA, each having unique properties.Current techniques for studying proteins need much improvement,and are often limited to investigations of a specific portionof the proteome. One approach for studying the whole proteomeis to systematically generate reagents with specific affinityfor the proteins encoded by the genome, one by one. Theaffinity reagents can be used as flags for their targets,providing a flag-specific detection system, so that the targetproteins can be sub-cellularly localized in the majority ofhuman tissues in an array format. One of the articles includedin the thesis presents a pilot project for large-scale affinityreagent production. The aim was to provide a sound basis forwhole proteome studies, but as a pilot study this investigationwas limited to the proteins encoded by human chromosome 21. Allputative genes on the chromosome were subjected to antibodygeneration in a systematic manner. Small, uniform, and easilyproduced representative portions of the full-length proteinswere expressed. These were denotedProtein EpitopeSignature Tagsand were designed to be unique for theirfull-length counterparts. The antibodies were produced inrabbits and two of the articles in the thesis discuss differentapproaches for affinity purification of the antibodies toachieve the highest possible specificity towards the targets.The resultingmono-specific, but stillmulti-epitope, antibodies can be used for a widerange of additional biochemical studies, such as protein arrayand protein pull-out analyses.</p><p><b>Keywords:</b>functional genomics, 3´-end signaturetags, pyrosequencing, amplification, PrEST, chromosome 21,polyclonal antibodies, dual expression, affinitypurification.</p> functional genomics 3´-end signature tags pyrosequencing amplification PrEST chromosome 21 polyclonal antibodies dual expression affinity purification

Search results