Global ETD Search

1	Accessing Genetic Variation by Microarray Technology Lindroos, Katarina January 2002 (has links) Microarray technology is a promising approach for the simultaneous analysis of multiple single nucleotide polymorphisms (SNPs), which are the most abundant form of genetic variation. In this thesis enzyme-assisted microarray-based methods were developed to improve the accuracy and genotype discrimination power of the current methods for SNP genotyping. The improved technology was applied for analysing recessively inherited disease mutations, for Y-chromosomal SNPs in a population study, for an evolutionary analysis of SNPs in flycatchers and for multiplexed quantitative determination of SNP-allele frequencies in pooled DNA samples. A robust attachment chemistry for immobilising oligonucleotides on glass surface was established, based on an evaluation of eight covalent coupling methods. A four-colour fluorescence detection strategy, which enabled a multiplexed quantitative analysis for as little as 2% of a minority allele frequency in pooled samples was generated. Twenty-five Y-chromosomal SNPs were screened in a collection of 300 samples from five Finno-Ugric-speaking populations using minisequencing on microarrays. In these populations six distinct haplotypes were defined by the six SNPs that were polymorphic. Data from five microsatellite markers was combined with the SNP data, revealing shared Y-chromosomal haplotypes between the Finns and the Saami, indicating, in accordance with earlier data, at least two founding Y-chromosomal lineages in these populations. Database screening and subsequent validation of 125 potential SNPs in the highly repetitive type 1 interferon genes and genes coding for proteins in the interferon-related regulatory pathways revealed 25 informative SNPs in the Finnish and Swedish populations. These SNPs were included in a panel for microarray based genotyping that should find a variety of applications in genetic studies due to the important immunoregulatory functions of the IFN family. The significance of sex-chromosome evolution on speciation was investigated in two naturally hybridising flycatcher species (N=459) by analysing a panel of 20 SNPs using minisequencing on microarrays. A strong selection against gene flow across the species boundary of sex-linked genes was observed, as well as a sex-chromosomal influence on male plumage characteristics that have previously been shown to reinforce isolation in these birds. The results suggest a major role for sex-chromosome-mediated isolation of the two flycatcher species. Medical sciences microarrays SNPs minisequencing four-colour detection allele frequency population study evolutionary biology MEDICIN OCH VÅRD MEDICINE MEDICIN
2	Accessing Genetic Variation by Microarray Technology Lindroos, Katarina January 2002 (has links) <p>Microarray technology is a promising approach for the simultaneous analysis of multiple single nucleotide polymorphisms (SNPs), which are the most abundant form of genetic variation. In this thesis enzyme-assisted microarray-based methods were developed to improve the accuracy and genotype discrimination power of the current methods for SNP genotyping. The improved technology was applied for analysing recessively inherited disease mutations, for Y-chromosomal SNPs in a population study, for an evolutionary analysis of SNPs in flycatchers and for multiplexed quantitative determination of SNP-allele frequencies in pooled DNA samples. </p><p>A robust attachment chemistry for immobilising oligonucleotides on glass surface was established, based on an evaluation of eight covalent coupling methods. A four-colour fluorescence detection strategy, which enabled a multiplexed quantitative analysis for as little as 2% of a minority allele frequency in pooled samples was generated. </p><p>Twenty-five Y-chromosomal SNPs were screened in a collection of 300 samples from five Finno-Ugric-speaking populations using minisequencing on microarrays. In these populations six distinct haplotypes were defined by the six SNPs that were polymorphic. Data from five microsatellite markers was combined with the SNP data, revealing shared Y-chromosomal haplotypes between the Finns and the Saami, indicating, in accordance with earlier data, at least two founding Y-chromosomal lineages in these populations.</p><p>Database screening and subsequent validation of 125 potential SNPs in the highly repetitive type 1 interferon genes and genes coding for proteins in the interferon-related regulatory pathways revealed 25 informative SNPs in the Finnish and Swedish populations. These SNPs were included in a panel for microarray based genotyping that should find a variety of applications in genetic studies due to the important immunoregulatory functions of the IFN family.</p><p>The significance of sex-chromosome evolution on speciation was investigated in two naturally hybridising flycatcher species (N=459) by analysing a panel of 20 SNPs using minisequencing on microarrays. A strong selection against gene flow across the species boundary of sex-linked genes was observed, as well as a sex-chromosomal influence on male plumage characteristics that have previously been shown to reinforce isolation in these birds. The results suggest a major role for sex-chromosome-mediated isolation of the two flycatcher species.</p> Medical sciences microarrays SNPs minisequencing four-colour detection allele frequency population study evolutionary biology MEDICIN OCH VÅRD MEDICINE MEDICIN
3	Evaluation of New Technologies for Forensic DNA Analysis Divne, Anna-Maria January 2005 (has links) <p>DNA samples from crime scenes or mass disasters are often limited and degraded which limits the possibility of successful traditional STR analysis. Moreover, there is a need to decrease the turnaround time in criminal investigations. These circumstances require a wider set of assays and technologies to be investigated for potential use in forensic DNA analysis, which has been explored in this thesis work. DNA analysis can also provide a useful tool in forensic pathology investigations. </p><p>In a search for mutations involved in The Sudden Infant death Syndrome (SIDS), the entire mitochondrial genome was sequenced in six SIDS infants and shorter mtDNA regions were analysed in paraffin-embedded tissues from an additional 14 SIDS cases. In this sample material no mutations associated with SIDS were found that could explain the death of these infants. </p><p>To reduce time, cost and effort related to sequencing of the mtDNA HVI/HVII regions in caseworks, a HVI/HVII mtDNA linear array assay was used as a pre-screening for exclusions of suspects or evidence samples. Using this assay, 56% of the samples involved in casework analysis could be excluded before sequencing was undertaken.</p><p>The possibility to use the new array technology was explored in a SNP assay targeting both mtDNA and nuclear SNPs. The system relies on minisequencing in solution prior to hybridisation to tag arrays. Using this system, we demonstrate a rapid, highly multiplexable and flexible array-format for SNP analysis.</p><p>The properties of the Pyrosequencing technology being a fast and user-friendly assay was utilised in a study to investigate the possibility to use this method for limited and degraded samples. Ten STR loci, overlapping with standardised kits, were genotyped in 114 Swedish individuals. We found additional variation and higher resolution of repeats at some of these loci that are not detected using standard fragment analysis.</p> Genetics STR SNP SIDS mtDNA HVI/HVII SSOP linear array minisequencing tag arrays Pyrosequencing Genetik Clinical genetics Klinisk genetik
4	Large-Scale Genotyping for Analysis of the Type I Interferon System in Autoimmune Diseases Sigurdsson, Snaevar January 2006 (has links) <p>Single nucleotide polymorphisms (SNPs) are the most common form of genetic variation. We developed a novel multiplexed method for SNP genotyping based on four-color fluorophore tag-microarray minisequencing. This method allows simultaneous genotyping of 80 samples and up to 200 SNPs in any allele combination. In study I we set up the method for a panel of SNPs from genes in the type I interferon system, and applied it in study III. In study II we used the technique to genotype SNPs from the coding region of the mitochondrial genome. A panel of 150 SNPs was genotyped in 265 individuals representing nine different populations. We demonstrated that the multiplexed SNP genotyping method for mitochondrial DNA increases the power of forensic identification in combination with sequencing of the hypervariable region of mitochondrial DNA. </p><p>In study III we performed a genetic association study of SNPs in genes related to the type I Interferon system in Systemic Lupus Erythematosus (SLE). SLE is a chronic autoimmune inflammatory disease with a complex etiology. The SNPs were genotyped in DNA samples from Swedish, Finnish, and Icelandic patients with SLE, unaffected family members, and unrelated controls. The analysis identified SNPs in two genes, the tyrosine kinase 2 (TYK2) and interferon regulatory factor 5 (IRF5) genes that are highly associated with SLE with p-values <10<sup>-7</sup> for joint linkage and association. </p><p>Study IV describes the analysis of the TYK2 and IRF5 SNPs in a large Rheumatoid Arthritis (RA) sample cohort. We found that SNPs in the IRF5 gene were significantly associated with RA with a p-value = 0.00008. In contrast, we did not detect an association with SNPs in the TYK2 gene. These findings demonstrate that SLE and RA may have a common genetic background in the case of IRF5, while the TYK2 variants appear to be unique for SLE. </p> Molecular medicine Minisequencing SNP Microarray Polymorphism Mitochondria Systemic Lupus Erythematosus Rheumatoid Arthritis Association study Type I interferon Genotyping Molekylärmedicin
5	Analysis of Nucleotide Variations in Non-human Primates Rönn, Ann-Charlotte January 2007 (has links) <p>Many of our closest relatives, the primates, are endangered and could be extinct in a near future. To increase the knowledge of non-human primate genomes, and at the same time acquire information on our own genomic evolution, studies using high-throughput technologies are applied, which raises the demand for large amounts of high quality DNA.</p><p>In study I and II, we evaluated the multiple displacement amplification (MDA) technique, a whole genome amplification method, on a wide range of DNA sources, such as blood, hair and semen, by comparing MDA products to genomic DNA as templates for several commonly used genotyping methods. In general, the genotyping success rate from the MDA products was in concordance with the genomic DNA. The quality of sequences of the mitochondrial control region obtained from MDA products from blood and non-invasively collected semen samples was maintained. However, the readable sequence length was shorter for MDA products.</p><p>Few studies have focused on the genetic variation in the nuclear genes of non-human primates. In study III, we discovered 23 new single nucleotide polymorphisms (SNPs) in the Y-chromosome of the chimpanzee. We designed a tag-microarray minisequencing assay for genotyping the SNPs together with 19 SNPs from the literature and 45 SNPs in the mitochondrial DNA. Using the microarray, we were able to analyze the population structure of wild-living chimpanzees.</p><p>In study IV, we established 111 diagnostic nucleotide positions for primate genera determination. We used sequence alignments of the nuclear epsilon globin gene and apolipoprotein B gene to identify positions for determination on the infraorder and Catarrhini subfamily level, respectively, and sequence alignments of the mitochondrial 12S rRNA (MT-RNR1) to identify positions to distinguish between genera. We designed a microarray assay for immobilized minisequencing primers for genotyping these positions to aid in the forensic determination of an unknown sample.</p> Molecular genetics SNP genotyping primate chimpanzee whole genome amplification multiple displacement amplification minisequencing microarray Y-chromosome mitochondria Genetik
6	Evaluation of New Technologies for Forensic DNA Analysis Divne, Anna-Maria January 2005 (has links) DNA samples from crime scenes or mass disasters are often limited and degraded which limits the possibility of successful traditional STR analysis. Moreover, there is a need to decrease the turnaround time in criminal investigations. These circumstances require a wider set of assays and technologies to be investigated for potential use in forensic DNA analysis, which has been explored in this thesis work. DNA analysis can also provide a useful tool in forensic pathology investigations. In a search for mutations involved in The Sudden Infant death Syndrome (SIDS), the entire mitochondrial genome was sequenced in six SIDS infants and shorter mtDNA regions were analysed in paraffin-embedded tissues from an additional 14 SIDS cases. In this sample material no mutations associated with SIDS were found that could explain the death of these infants. To reduce time, cost and effort related to sequencing of the mtDNA HVI/HVII regions in caseworks, a HVI/HVII mtDNA linear array assay was used as a pre-screening for exclusions of suspects or evidence samples. Using this assay, 56% of the samples involved in casework analysis could be excluded before sequencing was undertaken. The possibility to use the new array technology was explored in a SNP assay targeting both mtDNA and nuclear SNPs. The system relies on minisequencing in solution prior to hybridisation to tag arrays. Using this system, we demonstrate a rapid, highly multiplexable and flexible array-format for SNP analysis. The properties of the Pyrosequencing technology being a fast and user-friendly assay was utilised in a study to investigate the possibility to use this method for limited and degraded samples. Ten STR loci, overlapping with standardised kits, were genotyped in 114 Swedish individuals. We found additional variation and higher resolution of repeats at some of these loci that are not detected using standard fragment analysis. Genetics STR SNP SIDS mtDNA HVI/HVII SSOP linear array minisequencing tag arrays Pyrosequencing Genetik Clinical genetics Klinisk genetik
7	Large-Scale Genotyping for Analysis of the Type I Interferon System in Autoimmune Diseases Sigurdsson, Snaevar January 2006 (has links) Single nucleotide polymorphisms (SNPs) are the most common form of genetic variation. We developed a novel multiplexed method for SNP genotyping based on four-color fluorophore tag-microarray minisequencing. This method allows simultaneous genotyping of 80 samples and up to 200 SNPs in any allele combination. In study I we set up the method for a panel of SNPs from genes in the type I interferon system, and applied it in study III. In study II we used the technique to genotype SNPs from the coding region of the mitochondrial genome. A panel of 150 SNPs was genotyped in 265 individuals representing nine different populations. We demonstrated that the multiplexed SNP genotyping method for mitochondrial DNA increases the power of forensic identification in combination with sequencing of the hypervariable region of mitochondrial DNA. In study III we performed a genetic association study of SNPs in genes related to the type I Interferon system in Systemic Lupus Erythematosus (SLE). SLE is a chronic autoimmune inflammatory disease with a complex etiology. The SNPs were genotyped in DNA samples from Swedish, Finnish, and Icelandic patients with SLE, unaffected family members, and unrelated controls. The analysis identified SNPs in two genes, the tyrosine kinase 2 (TYK2) and interferon regulatory factor 5 (IRF5) genes that are highly associated with SLE with p-values <10-7 for joint linkage and association. Study IV describes the analysis of the TYK2 and IRF5 SNPs in a large Rheumatoid Arthritis (RA) sample cohort. We found that SNPs in the IRF5 gene were significantly associated with RA with a p-value = 0.00008. In contrast, we did not detect an association with SNPs in the TYK2 gene. These findings demonstrate that SLE and RA may have a common genetic background in the case of IRF5, while the TYK2 variants appear to be unique for SLE. Molecular medicine Minisequencing SNP Microarray Polymorphism Mitochondria Systemic Lupus Erythematosus Rheumatoid Arthritis Association study Type I interferon Genotyping Molekylärmedicin
8	Analysis of Nucleotide Variations in Non-human Primates Rönn, Ann-Charlotte January 2007 (has links) Many of our closest relatives, the primates, are endangered and could be extinct in a near future. To increase the knowledge of non-human primate genomes, and at the same time acquire information on our own genomic evolution, studies using high-throughput technologies are applied, which raises the demand for large amounts of high quality DNA. In study I and II, we evaluated the multiple displacement amplification (MDA) technique, a whole genome amplification method, on a wide range of DNA sources, such as blood, hair and semen, by comparing MDA products to genomic DNA as templates for several commonly used genotyping methods. In general, the genotyping success rate from the MDA products was in concordance with the genomic DNA. The quality of sequences of the mitochondrial control region obtained from MDA products from blood and non-invasively collected semen samples was maintained. However, the readable sequence length was shorter for MDA products. Few studies have focused on the genetic variation in the nuclear genes of non-human primates. In study III, we discovered 23 new single nucleotide polymorphisms (SNPs) in the Y-chromosome of the chimpanzee. We designed a tag-microarray minisequencing assay for genotyping the SNPs together with 19 SNPs from the literature and 45 SNPs in the mitochondrial DNA. Using the microarray, we were able to analyze the population structure of wild-living chimpanzees. In study IV, we established 111 diagnostic nucleotide positions for primate genera determination. We used sequence alignments of the nuclear epsilon globin gene and apolipoprotein B gene to identify positions for determination on the infraorder and Catarrhini subfamily level, respectively, and sequence alignments of the mitochondrial 12S rRNA (MT-RNR1) to identify positions to distinguish between genera. We designed a microarray assay for immobilized minisequencing primers for genotyping these positions to aid in the forensic determination of an unknown sample. Molecular genetics SNP genotyping primate chimpanzee whole genome amplification multiple displacement amplification minisequencing microarray Y-chromosome mitochondria Genetik
9	Using Minisequencing Technology for Analysing Genetic Variation in DNA and RNA Fredriksson, Mona January 2005 (has links) <p>In this thesis, the four-color fluorescence tag-microarray minisequencing system pioneered by our group was further developed and applied for analysing genetic variation in human DNA and RNA. A SNP marker panel representing different chromosomal regions was established and used for identification of informative SNP markers for monitoring chimerism after stem cell transplantation (SCT). The success of SCT was monitored by measuring the allelic ratios of informative SNPs in follow-up samples from nine patients with leukaemia. The results agreed with data obtained using microsatellite markers. Further the same SNP marker panel was used for evaluation of two whole genome amplification methods, primer extension preamplification (PEP) and multiple displacement amplification (MDA) in comparison with genomic DNA with respect to SNP genotyping success and accuracy in tag-array minisequencing. Identical results were obtained from MDA products and genomic DNA.</p><p>The tag-microarray minisequencing system was also established for multiplexed quantification of imbalanced expression of SNP alleles. Two endothelial cell lines and a panel of ten coding SNPs in five genes were used as model system. Six heterozygous SNPs were genotyped in RNA (cDNA) from the cell lines. Comparison of the relative amounts of the SNPs alleles in cDNA to heterozygote SNPs in genomic DNA displayed four SNPs with significant imbalanced expression between the SNP alleles. Finally, the tag-array minisequencing system was modified for detection of splice variants in mRNA from five leukaemia cell lines. A panel of 20 cancer-related genes with 74 alternatively splice variants was screened. Over half of the splice variants were detected in the cell lines, and similar alternative splicing patterns were observed in each cell line. The results were verified by size analysis of the PCR product subjected to the minisequencing primer extension reaction. The data from both methods agreed well, evidencing for a high sensitivity of our system.</p> Molecular medicine microarray minisequencing molecular medicine single nucleotide polymorphism stem cell transplantation whole genome amplification allelic imbalance alternative splicing Molekylärmedicin
10	Using Minisequencing Technology for Analysing Genetic Variation in DNA and RNA Fredriksson, Mona January 2005 (has links) In this thesis, the four-color fluorescence tag-microarray minisequencing system pioneered by our group was further developed and applied for analysing genetic variation in human DNA and RNA. A SNP marker panel representing different chromosomal regions was established and used for identification of informative SNP markers for monitoring chimerism after stem cell transplantation (SCT). The success of SCT was monitored by measuring the allelic ratios of informative SNPs in follow-up samples from nine patients with leukaemia. The results agreed with data obtained using microsatellite markers. Further the same SNP marker panel was used for evaluation of two whole genome amplification methods, primer extension preamplification (PEP) and multiple displacement amplification (MDA) in comparison with genomic DNA with respect to SNP genotyping success and accuracy in tag-array minisequencing. Identical results were obtained from MDA products and genomic DNA. The tag-microarray minisequencing system was also established for multiplexed quantification of imbalanced expression of SNP alleles. Two endothelial cell lines and a panel of ten coding SNPs in five genes were used as model system. Six heterozygous SNPs were genotyped in RNA (cDNA) from the cell lines. Comparison of the relative amounts of the SNPs alleles in cDNA to heterozygote SNPs in genomic DNA displayed four SNPs with significant imbalanced expression between the SNP alleles. Finally, the tag-array minisequencing system was modified for detection of splice variants in mRNA from five leukaemia cell lines. A panel of 20 cancer-related genes with 74 alternatively splice variants was screened. Over half of the splice variants were detected in the cell lines, and similar alternative splicing patterns were observed in each cell line. The results were verified by size analysis of the PCR product subjected to the minisequencing primer extension reaction. The data from both methods agreed well, evidencing for a high sensitivity of our system. Molecular medicine microarray minisequencing molecular medicine single nucleotide polymorphism stem cell transplantation whole genome amplification allelic imbalance alternative splicing Molekylärmedicin

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