Global ETD Search

21	Like a Rolling Circle : Developing in-situ genotyping of chromosomal barcodes in the DuMPLING method Svahn, Fabian January 2021 (has links) DuMPLING is a newly developed high-throughput method to study singlecellphenotypes in a pooled and barcoded library using a microfluidicchip. The chip enables parallel biophysical measurements of singlecells, after which in-situ genotyping connects the cells to a certainstrain of the library. The method has been previously applied with abarcoded library, where genotyping was performed on barcodes presenton high copy number plasmids. In this project, I apply and developthe Rolling Circle Amplification method to amplify the signal frombarcodes present on the E. coli chromosome. A small librarycontaining three different chromosomal barcodes is investigated. Veryhigh efficiency of signal generation is achieved for the firstbarcode, good efficiency is achieved for the second, and no signal isachieved for the third. Genotyping is also successfully performed ona strain with two different barcodes present on the chromosome. Thegenotyping method described herein can be applied to screen foradditional barcodes that may be incorporated in a larger library thatin turn can be used to ask important biological questions, forexample using the high throughput DuMPLING method. Rolling circle amplification genotyping chromosomal barcodes RCA DuMPLING method DuMPLING barcoded libraries microfluidics Biochemistry and Molecular Biology Biokemi och molekylärbiologi
22	Single Molecule Detection : Microfluidic Automation and Digital Quantification Kühnemund, Malte January 2016 (has links) Much of recent progress in medical research and diagnostics has been enabled through the advances in molecular analysis technologies, which now permit the detection and analysis of single molecules with high sensitivity and specificity. Assay sensitivity is fundamentally limited by the efficiency of the detection method used for read-out. Inefficient detection systems are usually compensated for by molecular amplification at the cost of elevated assay complexity. This thesis presents microfluidic automation and digital quantification of targeted nucleic acid detection methods based on padlock and selector probes and rolling circle amplification (RCA). In paper I, the highly sensitive, yet complex circle-to-circle amplification assay was automated on a digital microfluidic chip. In paper II, a new RCA product (RCP) sensing principle was developed based on resistive pulse sensing that allows label free digital RCP quantification. In paper III, a microfluidic chip for spatial RCP enrichment was developed, which enables the detection of RCPs with an unprecedented efficiency and allows for deeper analysis of enriched RCPs through next generation sequencing chemistry. In paper IV, a smart phone was converted into a multiplex fluorescent imaging device that enables imaging and quantification of RCPs on slides as well as within cells and tissues. KRAS point mutations were detected (i) in situ, directly in tumor tissue, and (ii) by targeted sequencing of extracted tumor DNA, imaged with the smart phone RCP imager. This thesis describes the building blocks required for the development of highly sensitive low-cost RCA-based nucleic acid analysis devices for utilization in research and diagnostics. single molecule digital rolling circle amplification magnetic particle padlock probe microfluidics resistive pulse sensing lab on chip mobile phone microscopy enrichment sequencing
23	Proximity Ligation as a Universal Protein Detection Tool Gullberg, Mats January 2003 (has links) <p>Among the great challenges in biology are the precise quantification of specific sets of proteins and analyses of their patterns of interaction on a much larger scale than is possible today. </p><p>This thesis presents a novel protein detection technique - proximity ligation - and reports the development and application of a nucleic acid amplification technique, RCA. Proximity ligation converts information about the presence or co-localization of specific proteins to unique sets of nucleic acid sequences. For detection of target proteins or protein complexes the coincident binding by pairs or triplets of specific protein-binding reagents are required. Oligonucleotide-extensions attached to those binding reagents are joined by a DNA ligase and subsequently analyzed by standard molecular genetic techniques. The technique is shown to sensitively detect an assortment of proteins using different types of binders converted to proximity probes, including SELEX aptamers and mono- and polyclonal antibodies. I discuss factors important for using the technique to analyze many proteins simultaneously.</p><p>Quantification of target molecules requires precise amplification and detection. I show how rolling circle amplification, RCA, can be used for precise quantification of circular templates using modified molecular beacons with real-time detection. The combination of proximity-probe templated circularization and RCA results in a sensitive method with high selectivity, capable of visualizing individual immobilized proteins. This technique is used for localized detection of a set of individual proteins and protein complexes at sub-cellular resolution.</p> Molecular medicine Proximity ligation proteomics aptamer antibody molecular beacon rolling circle amplification Molekylärmedicin
24	Genetic Analyses using Rolling Circle or PCR Amplified Padlock Probes Banér, Johan January 2003 (has links) <p>Padlock probes are useful in a variety of genetic applications, some of which require that the probes are amplified in order to generate detectable signals. Two general padlock amplification methods, RCA and PCR, are discussed in this thesis.</p><p>The isothermal rolling circle amplification (RCA) mechanism is described in detail as well as how a target strand affects primer extension. A mechanism to resolve the topological constraint imposed by the target strand, to which a padlock probe has been linked, is also discussed. We also present a more powerful amplification technique, termed serial circle amplification, which provides a highly precise tool for nucleic acid studies. Rolling circle products are digested to unit lengths, and each monomer converted to new circular oligonucleotides that can serve as templates in consecutive rounds of RCA. The final products are single-stranded DNA molecules, readily available for hybridization-based detection, for instance using molecular beacons or array hybridization.</p><p>Padlock probes have the potential to be combined in large numbers for parallel gene analysis. A significant improvement of the level of multiplexed genotyping is presented using padlock probes and a molecular inversion strategy. Padlock probes containing common primer sequences along with locus-specific tag sequences were combined in multiplexed ligation reactions. After exonucleolytic selection for circular molecules, the probes were cleaved at uracil residues situated between the primer sequences, which facilitated release from the genomic DNA. A single PCR primer pair amplified all molecularly inverted probes, and the products were finally sorted on microarrays for simultaneous readout. Up to 1,500 genotypes could be detected in parallel, with sufficient signal strength for further scale-up. Finally, an application of the same parallel genotyping strategy is described where a set of padlock probes was used to study tumor induced immune responses. The distribution of TCR Vβ transcripts in tumor infiltrating T-cells and in normal control tissues were investigated in a microarray format.</p> Molecular medicine Padlock probes rolling circle amplification PCR genotyping microarray expression analysis Molekylärmedicin
25	Genetic Analyses using Rolling Circle or PCR Amplified Padlock Probes Banér, Johan January 2003 (has links) Padlock probes are useful in a variety of genetic applications, some of which require that the probes are amplified in order to generate detectable signals. Two general padlock amplification methods, RCA and PCR, are discussed in this thesis. The isothermal rolling circle amplification (RCA) mechanism is described in detail as well as how a target strand affects primer extension. A mechanism to resolve the topological constraint imposed by the target strand, to which a padlock probe has been linked, is also discussed. We also present a more powerful amplification technique, termed serial circle amplification, which provides a highly precise tool for nucleic acid studies. Rolling circle products are digested to unit lengths, and each monomer converted to new circular oligonucleotides that can serve as templates in consecutive rounds of RCA. The final products are single-stranded DNA molecules, readily available for hybridization-based detection, for instance using molecular beacons or array hybridization. Padlock probes have the potential to be combined in large numbers for parallel gene analysis. A significant improvement of the level of multiplexed genotyping is presented using padlock probes and a molecular inversion strategy. Padlock probes containing common primer sequences along with locus-specific tag sequences were combined in multiplexed ligation reactions. After exonucleolytic selection for circular molecules, the probes were cleaved at uracil residues situated between the primer sequences, which facilitated release from the genomic DNA. A single PCR primer pair amplified all molecularly inverted probes, and the products were finally sorted on microarrays for simultaneous readout. Up to 1,500 genotypes could be detected in parallel, with sufficient signal strength for further scale-up. Finally, an application of the same parallel genotyping strategy is described where a set of padlock probes was used to study tumor induced immune responses. The distribution of TCR Vβ transcripts in tumor infiltrating T-cells and in normal control tissues were investigated in a microarray format. Molecular medicine Padlock probes rolling circle amplification PCR genotyping microarray expression analysis Molekylärmedicin
26	Molecular Diagnostics Using Volume-Amplified Magnetic Nanobeads : Towards the Development of a Novel Biosensor System Strömberg, Mattias January 2009 (has links) Micro- or nanometer sized magnetic particles (beads) currently have a vast range of life science applications in, for example, bioseparation techniques, cancer therapy, development of contrast agents and biosensing techniques. In the latter field, magnetic beads offer several unique advantages, including minimal background signals, physical and chemical stability and low manufacturing costs. Because of these properties, magnetic biosensing techniques are potential candidates for low-cost, easy-to-use molecular diagnostic devices. This doctoral thesis focuses mainly on the proof of principle and further development of a new magnetic biosensor platform for detection of DNA targets, a potential candidate for a new generation of low-cost, easy-to-use diagnostic devices: the Volume-Amplified Magnetic Nanobead Detection Assay (VAM-NDA). The VAM-NDA principle combines target recognition by padlock probe ligation followed by rolling circle amplification (RCA) of the reacted probes with changes in Brownian relaxation behaviour of magnetic nanobeads (typically ~100 nm in diameter) induced by a change in hydrodynamic bead volume. More specifically, the RCA products (coils, typically ~1 μm in diameter) are detected magnetically by adding magnetic beads tagged with detection probes complementary to part of the repeating RCA-coil sequence. Thus, depending on the target concentration, a certain quantity of beads binds to the coils by base-pair hybridisation (bead immobilisation), resulting in a dramatic bead volume increase, which is then detected by measuring the complex magnetisation spectrum. Use of a commercial SQUID magnetometer for measuring complex magnetisation resulted in a detection limit in the low pM range for DNA targets with excellent quantification accuracy. Simultaneous multiplexing was also evaluated. The stability and aging of typical commercial ferrofluids (suspensions of magnetic beads) were investigated by measuring the complex magnetisation of and interbead interactions in oligonucleotide-functionalised ferrofluids. In summary, the bead surface characteristics were found to have a strong impact on the measured dynamic magnetic properties. Magnetic Biosensors Ferrofluid Biofunctionalisation Ferrofluidic Aging Interbead Interactions Magnetic Nanobeads Complex Magnetisation Brownian Relaxation Padlock Probes Rolling Circle Amplification Engineering physics Teknisk fysik
27	Readout Strategies for Biomolecular Analyses Göransson, Jenny January 2008 (has links) This thesis describes three readout formats for molecular analyses. A common feature in all works is probing techniques that upon specific target recognition ideally results in equimolar amounts of DNA circles. These are then specifically amplified and detected using any of the techniques presented herein. The first paper presents a method that enables homogeneous digital detection and enumeration of biomolecules, represented as fluorescence-labelled DNA macromolecules. This method offers precise measurements to be performed with a wide linear dynamic range. As an application, two closely related bacterial species were selectively detected. The second paper further investigates and optimizes the properties of the technique presented in paper one. The third paper demonstrates a platform that enables simultaneous quantitative analysis of large numbers of biomolecules. The array format and decoding scheme together propose a digital strategy for decoding of biomolecules. The array and the decoding procedure were characterized and evaluated for gene copy-number measurements. The fourth paper examines a new strategy for non-optical measurements of biomolecules. Characteristics of this technique are investigated, and compared to its optical equivalent, fluorescence polarization. Padlock probe Selector probe Rolling circle amplification Single molecule detection Amplified single molecule Random array
28	High Content Analysis of Proteins and Protein Interactions by Proximity Ligation Leuchowius, Karl-Johan January 2010 (has links) Fundamental to all biological processes is the interplay between biomolecules such as proteins and nucleic acids. Studies of interactions should therefore be more informative than mere detection of expressed proteins. Preferably, such studies should be performed in material that is as biologically and clinically relevant as possible, i.e. in primary cells and tissues. In addition, to be able to take into account the heterogeneity of such samples, the analyses should be performed in situ to retain information on the sub-cellular localization where the interactions occur, enabling determination of the activity status of individual cells and allowing discrimination between e.g. tumor cells and surrounding stroma. This requires assays with an utmost level of sensitivity and selectivity. Taking these issues into consideration, the in situ proximity-ligation assay (in situ PLA) was developed, providing localized detection of proteins, protein-protein interactions and post-translational modifications in fixed cells and tissues. The high sensitivity and selectivity afforded by the assay's requirement for dual target recognition in combination with powerful signal amplification enables visualization of single protein molecules in intact single cells and tissue sections. To further increase the usefulness and application of in situ PLA, the assay was adapted to high content analysis techniques such as flow cytometry and high content screening. The use of in situ PLA in flow cytometry offers the possibility for high-throughput analysis of cells in solution with the unique characteristics offered by the assay. For high content screening, it was demonstrated that in situ PLA can enable cell-based drug screening of compounds affecting post-translational modifications and protein-protein interactions in primary cells, offering superior abilities over current assays. The methods presented in this thesis provide powerful new tools to study proteins in genetically unmodified cells and tissues, and should offer exciting new possibilities for molecular biology, diagnostics and drug discovery. in situ proximity ligation flow cytometry high content screening rolling circle amplification in situ PLA single-cell single-molecule protein interactions drug screening post-translational modifications Molecular medicine Molekylär medicin
29	Application of Padlock Probe Based Nucleic Acid Analysis In Situ Henriksson, Sara January 2010 (has links) The great variation displayed by nucleic acid molecules in human cells, and the continuous discovery of their impact on life, consequently require continuous refinements of molecular analysis techniques. Padlock probes and rolling circle amplification offer single nucleotide discrimination in situ, a high signal-to-noise ratio and localized detection within cells and tissues. In this thesis, in situ detection of nucleic acids with padlock probes and rolling circle amplification was applied for detection of DNA in the single cell gel electrophoresis assay to detect nuclear and mitochondrial DNA. This assay is used to measure DNA damage and repair. The behaviour of mitochondrial DNA in the single cell gel electrophoresis assay has earlier been controversial, but it was shown herein that mitochondrial DNA diffuses away early in the assay. In contrast, Alu repeats remain associated with the nuclear matrix throughout the procedure. A new twelve gel approach was also developed with increased throughput of the single cell gel electrophoresis assay. DNA repair of three genes OGG1, XPD and HPRT and of Alu repeats after H2O2 induced damage was further monitored. All three genes and Alu repeats were repaired faster than total DNA. Finally, padlock probes and rolling circle amplification were applied for detection of the single stranded RNA virus Crimean Congo hemorrhagic fever virus. The virus was detected by first reverse transcribing RNA into cDNA.. The virus RNA together with its complementary RNA and the nucleocapsid protein were detected in cultured cells. The work presented here enables studies of gene specific damage and repair as well as viral infections in situ. Detection by ligation offers high specificity and makes it possible to discriminate even between closely related molecules. Therefore, these techniques will be useful for a wide range of applications within research and diagnostics. Padlock probe rolling circle amplification single cell gel electrophoresis assay comet assay Crimean Congo hemorrhagic fever virus Molecular medicine Molekylär medicin
30	Proximity Ligation as a Universal Protein Detection Tool Gullberg, Mats January 2003 (has links) Among the great challenges in biology are the precise quantification of specific sets of proteins and analyses of their patterns of interaction on a much larger scale than is possible today. This thesis presents a novel protein detection technique - proximity ligation - and reports the development and application of a nucleic acid amplification technique, RCA. Proximity ligation converts information about the presence or co-localization of specific proteins to unique sets of nucleic acid sequences. For detection of target proteins or protein complexes the coincident binding by pairs or triplets of specific protein-binding reagents are required. Oligonucleotide-extensions attached to those binding reagents are joined by a DNA ligase and subsequently analyzed by standard molecular genetic techniques. The technique is shown to sensitively detect an assortment of proteins using different types of binders converted to proximity probes, including SELEX aptamers and mono- and polyclonal antibodies. I discuss factors important for using the technique to analyze many proteins simultaneously. Quantification of target molecules requires precise amplification and detection. I show how rolling circle amplification, RCA, can be used for precise quantification of circular templates using modified molecular beacons with real-time detection. The combination of proximity-probe templated circularization and RCA results in a sensitive method with high selectivity, capable of visualizing individual immobilized proteins. This technique is used for localized detection of a set of individual proteins and protein complexes at sub-cellular resolution. Molecular medicine Proximity ligation proteomics aptamer antibody molecular beacon rolling circle amplification Molekylärmedicin

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