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61	Biomolecular Analysis by Dual-Tag Microarrays and Single Molecule Amplification Ericsson, Olle January 2008 (has links) <p>Padlock probes and proximity ligation are two powerful molecular tools for detection of nucleic acids and proteins, respectively. Both methods result in the formation of DNA reporter molecules upon recognition of specific target molecules. These reporter molecules can be designed to include tag sequences that can be analyzed by techniques for nucleic acid analysis. Herein, I present a dual-tag microarray (DTM) platform that is suitable for high-performance analyses of DNA reporter molecule libraries, generated by padlock and proximity probing reactions. The DTM platform was applied for analysis of mRNA transcripts using padlock probes, and of cytokines using proximity ligation. The platform drastically improved specificity of detection, and it allowed precise measurements of proteins and nucleic acids over wide dynamic ranges.</p><p>The thesis also presents two techniques for multi-probe analyses of biomolecules: the triple-specific proximity ligation assay (3PLA) for protein analyses, and the spliceotyping assay for mRNA analyses. 3PLA allows highly specific measurements of as little as hundreds of target protein molecules by interrogating three target epitopes simultaneously. In spliceotyping the exon composition of individual transcripts are represented as a series of tag sequences in DNA reporter molecules, via a series of target-dependent ligation reactions. Next, the splicing patterns along individual transcripts can be revealed by amplified single molecule detection and step-wise decoding.</p> Molecular medicine Microarray proximity ligation Padlock probe Rolling circle amplification Splicing single molecule Molekylärmedicin
62	Application of proximity Ligation for Detection of Proteins, Biomolecular Interactions, and Single Copies of Pathogens Gustafsdottir, Sigrun Margret January 2006 (has links) Proximity ligation is a recently established technique that can provide answers to questions about the concentration, localization, interactions, modifications and functions of proteins. The method enables sensitive protein measurements with a detection limit in the low femtomolar range in complex biological samples. In proximity ligation, the challenge of detecting specific proteins is converted to the analysis of specific DNA sequences. Proximity probes containing oligonucleotide extensions are designed to bind pairwise to target proteins, and to form amplifiable tag sequences upon ligation when brought in proximity. Protocols for the conversion of monoclonal or polyclonal antibodies into proximity probes through the attachment of oligonucleotide sequences are described in the thesis. In addition, the thesis describes the adaptation of the proximity ligation technology for detection of microbial pathogens, analysis of interactions between proteins and nucleic acids, and of inhibition of receptor-ligand interactions. Nucleic acid amplification allows specific detection of pathogens with single-copy sensitivity. There are many circumstances, however, when analysis of pathogen surface antigens or the antibody response can provide increased diagnostic value. Proximity ligation reactions were used to measure numbers of virus and bacteria by detection of viral or bacterial surface proteins. Detection sensitivities similar to those of nuclear acid-based detection reactions were achieved directly in infected samples for a parvovirus and for an intracellular bacterium. Biological processes are orchestrated by interactions of proteins with molecules in their environment, and investigations of interactions between proteins and other biomolecules are thus of great importance. Protocols were established for very specific and sensitive homogeneous-phase analysis of interactions between proteins and specific nucleic acid sequences. Finally, the proximity ligation mechanism was used to monitor interactions between VEGF-A and two of its receptors, VEGFR-1 and VEGFR-2, and to characterize the effects of agents disrupting this interaction. Molecular medicine Proximity ligation Cytokines Microbial pathogens Protein-DNA interactions Drug screening Molekylärmedicin
63	Biomolecular Analysis by Dual-Tag Microarrays and Single Molecule Amplification Ericsson, Olle January 2008 (has links) Padlock probes and proximity ligation are two powerful molecular tools for detection of nucleic acids and proteins, respectively. Both methods result in the formation of DNA reporter molecules upon recognition of specific target molecules. These reporter molecules can be designed to include tag sequences that can be analyzed by techniques for nucleic acid analysis. Herein, I present a dual-tag microarray (DTM) platform that is suitable for high-performance analyses of DNA reporter molecule libraries, generated by padlock and proximity probing reactions. The DTM platform was applied for analysis of mRNA transcripts using padlock probes, and of cytokines using proximity ligation. The platform drastically improved specificity of detection, and it allowed precise measurements of proteins and nucleic acids over wide dynamic ranges. The thesis also presents two techniques for multi-probe analyses of biomolecules: the triple-specific proximity ligation assay (3PLA) for protein analyses, and the spliceotyping assay for mRNA analyses. 3PLA allows highly specific measurements of as little as hundreds of target protein molecules by interrogating three target epitopes simultaneously. In spliceotyping the exon composition of individual transcripts are represented as a series of tag sequences in DNA reporter molecules, via a series of target-dependent ligation reactions. Next, the splicing patterns along individual transcripts can be revealed by amplified single molecule detection and step-wise decoding. Molecular medicine Microarray proximity ligation Padlock probe Rolling circle amplification Splicing single molecule Molekylärmedicin
64	DNA Tools and Microfluidic Systems for Molecular Analysis Jarvius, Jonas January 2006 (has links) Improved methods are needed to interrogate the genome and the proteome. Methods with high selectivity, wide dynamic range, and excellent precision, capable of simultaneously analyzing many biomolecules are required to decipher cellular function. This thesis describes a molecular and microfluidic toolbox designed with those criteria in mind. It also presents a tool for graphical representation of nucleic acid sequences. Proximity ligation is a novel protein detection method that requires dual and proximate binding of two oligonucleotide-tagged affinity reagents to a protein or protein complex in order to elicit a signal. The responses from such recognition reactions are the formation of specific nucleic acid reporter molecules that are subsequently amplified and quantitatively detected. A scalable microfluidic platform suitable for fluorescence detection, cell culture, and actuation is also described. The platform uses rapid injection molding to produce microstructures in thermoplastic materials. By applying a thin layer of silica to the structures, a lid made of silicone rubber coated onto a thermoplastic support can be covalently bonded to generate enclosed channels. A method is presented for precise biomolecule counting, termed “amplified single-molecule detection”. The method preserves the discrete nature of biomolecules, converting specific molecular recognition events to fluorescence-labeled micrometer-sized objects that are enumerated in microfluidic channels. I also present a novel microarray-based detection method. To attain high selectivity and a wide dynamic range, the method is based on dual recognition with enzymatic discrimination and amplification. Upon target recognition in solution, DNA probes are subjected to thousand-fold amplification in solution, followed by selective detection on arrays and another hundred-fold amplification of reporter molecule created from the first amplification reaction. Lastly, I describe a novel graphical representation of nucleic acid sequences using TrueType fonts that can be of value for visual inspection of DNA sequences and for teaching purposes Molecular medicine Proximity ligation Microfluidics Single molecule detection Microarray Bonding Molekylärmedicin
65	Heterocyclic Diamidines Induce Sequence Dependent Topological Changes in DNA; A Study Using Gel Electrophoresis Tevis, Denise Susanne 17 April 2009 (has links) Diamidines are a class of compounds that target the minor groove of DNA and have antiparasitic and antimicrobial properties. Their mechanism of action has not been fully elucidated, but may include changes in DNA topology. In this study we have investigated such changes using methods of gel electrophoresis including ligation ladders and cyclization assays. We found that topology changes were sequence dependent. Compounds typically caused non-anomalously migrating ATATA sequences to migrate as if they were bent, while A5 sequences that normally migrated anomalously became less so in the presence of certain diamidines. Select compounds induced changes in cyclization efficiency that were also sequence dependent; DB75 significantly abolished cyclization in A5 containing sequences but enhanced it in sequences containing ATATA sites. Minor groove binders Cyclization assay DNA topology Ligation ladders PAGE Heterocyclic diamidines
66	Application of Proximity Ligation Assay for Multidirectional Studies on Transforming Growth Factor-β Pathway Zieba, Agata January 2012 (has links) A comprehensive understanding of how the body and all its components function is essential when this knowledge is exploited for medical purposes. The achievements in biological and medical research during last decades has provided us with the complete human genome and identified signaling pathways that governs the cellular processes that facilitates the development and maintenance of higher order organisms. This has brought about the realization that diseases such as cancer is a consequence of genomic aberrations that effects these signaling pathways, endowing cancer cells with the capacity to circumvent homeostasis by acquiring features like self-sustained proliferation and insensitivity to apoptosis. The increased understanding of biology and medicine has been made possible by the development of advanced methods to carry out biological and clinical analyses. The demands of a method often differ regarding in what context it will be applied. It may be acceptable for method to be laborious and time consuming if it is used in basic research, but for medical purposes molecular methods need to be fast and straightforward to perform. Innovative technologies should preferentially address the demands of both researchers and clinicians and provide data not possible to obtain by other methods. An example of such a method is the in situ proximity ligation assay (in situ PLA). In this thesis I have used this method to determine the activity status, at the single-cell level, of the transforming growth factor-β (TGF-β) signaling pathway and activating protein-1 (AP-1) family of transcription factors. Both of these pathways are frequently involved in cancer development and progression. In addition to this research I herein also present further modifications of in situ PLA, and analyses thereof, to increase the utility and resolution of this assay. proximity ligation TGF-β signaling Smad single cell analysis cell cycle context-dependent signaling CRC
67	Development of novel multiplexed systems for in situ PLA Broberg, John January 2011 (has links) The in situ proximity ligation assay (in situ PLA) is an immunoassay that enables directvisualisation of single protein targets or protein interactions in cell or tissue samples. This project revolves around designing and introducing several novel multiplexable components tobe used in conjunction with Olink Bioscience's Duolink product line. In this report, a novel in silico approach to DNA oligomer interaction design is presented. Using this in silico method, a multiplexed system of DNA oligomers has been designed andevaluated using in situ PLA and fluorescence microscopy. Proximity ligation assay PLA Multiplex Immunoassay Rolling circle amplification RCA in situ DNA sequence design
68	Evaluation and development of reagents and improved protocol for flow cytometry readout using in situ PLA Ohlsson, Sandra January 2011 (has links) The diagnosis of cancer today is obsolete, depending upon pattern recognition and non-quantifiable data. The time consuming diagnosis is often performed on biopsies, fixed using non standardised procedures, and leaves room for dubious results. The diagnosis is also invasive, exposing patients to risk of infections and discomfort due to the need of tissue samples. The knowledge about changes in protein expression levels related to cancer can instead be utilized to generate a new diagnostic tool. By adapting the in situ proximity ligation assay (in situ PLA) to cells in solution, it is possible to detect proteins, or protein interactions, within cells without the need for tissue samples. Since the method is both highly sensitive and specific, it delivers reliable results. In this report, the in situ PLA method for cells in solution is combined with flow cytometry readout. Hence, a new and less invasive diagnostic tool for cancer, delivering highly accurate high throughput single cell analysis, may be on the rise. in situ proximity ligation assay in situ PLA flow cytometry diagnostic method cancer
69	Développement de méthodes combinatoires pour la découverte de ligands à base de cyclopeptides. Duléry, Vincent 14 December 2007 (has links) (PDF) La chimie combinatoire est un moyen efficace pour découvrir des molécules biologiquement actives. Dans ce travail, nous avons exploré deux approches combinatoires différentes pour synthétiser des bibliothèques de cyclopeptides. Tout d'abord, nous avons développé une stratégie basée sur l'assemblage aléatoire et chimiosélectif de biomolécules sur un châssis peptidique. Cette approche réalisée en solution a permis de générer des bibliothèques d'hétéroglycoclusters et de sélectionner les meilleurs ligands par colonne d'affinité portant une lectine modèle, la Concanavaline A. Dans une seconde approche, des bibliothèques de peptides cycliques ont été préparées par la méthode split and mix. Celles-ci ont été conçues et décodées selon l'algorithme mis au point dans le groupe du Pr. Reymond (Berne, Suisse) qui permet d'attribuer la séquence de chaque peptide sans marquage et de manière quasi-unique. Ces bibliothèques ont été criblées sur le support avec la vitamine B12 et la Caseine Kinase 2. [CHIM:OTHE] Chemical Sciences/Other Chimie combinatoire peptides oligosaccharides ligation chimiosélective hétéroglycoclusters multivalence chromatographie d'affinité split and mix
70	Design and evolution of synthetic biological systems Tabor, Jeffrey Jay 04 May 2015 (has links) The study of biology has undergone a fundamental change due to advancements in genetic engineering, DNA synthesis and DNA sequencing technologies. As opposed to the traditional dissective mentality of discovering genes via genetics, describing genetic behaviors through biochemistry, and then drawing diagrams of functional networks, researchers now have the potential (albeit limited) to construct novel biological molecules, networks, and even whole organisms with user-defined specifications. We have engineered novel catalytic DNAs (deoxyribozymes) with the ability to 'read' an input DNA sequence and then 'write' (by ligation) a separate DNA sequence which can in turn be detected sensitively. In addition, the deoxyribozymes can read unnatural (synthetic) nucleotides and write natural sequence information. Such simple nanomachines could find use in a variety of applications, including the detection of single nucleotide polymorphisms in genomic DNA or the identification of difficult to detect (short) nucleic acids such as microRNAs. As an extension of in vitro biological engineering efforts, we aimed to construct novel signal transduction systems in vivo. To this end, we used directed evolution to generate a catalytic RNA (ribozyme) capable of creating genetic memory in E. coli. In the end we evolved an RNA which satisfied the conditions of our genetic screen. Rather than maintaining genetic memory, however, the RNA increased relative cellular gene expression by minimizing the translational burden it imposed on the host cell. Interestingly, detailed mutational analysis of the evolved RNA led us to new studies on the relationship between ribosome availability and stochasticity in cellular gene expression, an effect that had frequently been alluded to in the literature, yet never examined. We have also taken a more canonical approach to the forward engineering of biological systems with unnatural behaviors. To this end, we designed a protein-based synthetic genetic circuit that allows a community of E. coli to function as biological film, capable of capturing and recapitulating a projected light pattern at high resolution (theoretically 100 mexapixels). The ability to control bacterial gene expression at high resolution could be used to ‘print’ complex bio-materials or deconvolute signaling pathways through precise spatial and temporal control of regulatory states. / text Catalytic DNAs Ligation Deoxyribozymes Signal transduction RNA E. coli Synthetic genetic circuit

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