Sequence-Specific DNA Detection Utilizing Custom-Designed Zinc Finger Proteins

Ooi, Aik Teong

January 2007

DNA diagnostics are important technologies in molecular and cellular biology. By allowing identification of specific sequences, DNA-based diagnostics potentially provide more accurate and rapid results than protein- or antigen-based diagnostics, primarily because phenotypic changes come much later than changes in genotype. Despite this advantage, there are fewer diagnostic or imaging systems that target DNA than those targeting proteins, antibodies, or antigens.Each type of DNA-based diagnostic has its own, unique set of limitations; however, most can be attributed to issues related to sequence restriction, signal detection, specificity, or some combination thereof. For example, while PCR-based methods allow amplification and assessment of specific DNA sequences, they lack the ability to report information of specific cells, or cell types, within the heterogeneous pool of cells typically found in a tumor biopsy. In addition, none of the currently available DNA detection methods has the potential to be utilized in living cells, a disadvantage which limits the potential applications.The work presented here describes the design and development of a new methodology for the detection of specific double-stranded DNA sequences. This detection method is based on the concept that two inactive fragments of a reporter protein, each coupled to engineered zinc finger DNA-binding motifs, are able to reassemble and form an active complex in the presence of a predefined DNA sequence. This system, designated sequence-enabled reassembly (SEER), can achieve single base-pair specificity, and has the potential to be utilized in living cells.In this dissertation, we discuss the efforts from constructing to refining the system, as well as the future applications of SEER in diagnostics and therapeutics. Chapter I will provide an introduction to DNA detection methods, on which the principles of the SEER system are based. Chapter II describes the design and construction of an enzymatic SEER system, SEER-LAC, using beta-lactamase as the enzyme. In Chapter III, we outline the in vitro characterization of the SEER-LAC system, followed by its optimization in Chapter IV. Chapter V illustrates the efforts to develop SEER system for mammalian cell culture applications. In the final chapter, the future developments and applications of SEER are discussed.

Zinc finger proteins

Protein fragments complementation

DNA diagnostics

Sequence-enabled reassembly (SEER)

Sensing of Small Molecules, Biomarkers, and Pathogens using Unique Plasmonic Assay Platforms

Cary, ReJeana

27 September 2020

No description available.

Analytical Chemistry

point-of-care diagnostics

localized surface plasmon resonance

nanoparticle arrays

Analytical chemistry

Rapid DNA diagnostics

Flexible plastic substrates

Achieving High Catalytic Efficiency in Nucleic Acid-Templated Reactions by a Loss-of-Affinity Principle

Gluhacevic von Krüchten, Dino

30 October 2023

Die Entwicklung von enzymfreien, isothermen Nachweisverfahren für Nukleinsäuren, die mit der PCR konkurrieren können, ist seit langem ein Ziel. Eine potenzielle Strategie besteht darin, Nukleinsäure-templierte Reaktionen zu verwenden, bei denen das Templat (Analyt) als Katalysator fungiert und das Signal verstärkt. Die derzeitig verwendeten Strategien, wie Ligations- oder Transferreaktionen, sind jedoch in ihrer Empfindlichkeit aufgrund des Effekts der Produktinhibierung begrenzt. Um dies zu überwinden, müssen die Reaktanten nicht nur sequenzspezifisch an die DNA oder RNA binden, sondern die Produkte müssen sich auch von der DNA oder RNA wieder lösen können. Diese Arbeit stellt ein neues Paradigma für Nukleinsäure templierte Reaktionen vor: Das Loss-of-Affinity Prinzip. In diesem Prinzip werden Produkte generiert, die eine geringere Affinität zum Templat aufweisen als die Reaktanten. Dadurch wird die Produktinhibierung verhindert. Im ersten Teil dieser Arbeit wurde das Loss-of-Affinity Prinzip mit triplexbildenden, spaltbaren bis-PNA Sonden untersucht. Diese erfuhren eine C-O-Bindungsspaltung, ausgelöst durch die katalytische Photoreduktion eines Rutheniumkomplexes. Nach mehreren Optimierungsrunden zeigte eine 10-mer bis-PNA Sonde eine beeindruckende katalytische Effizienz. Diese Ergebnisse zeigen, dass das Loss-of-Affinity Prinzip zur Überwindung der Produktinhibierung genutzt werden kann. Die verwendeten bis-PNAs zeigten jedoch eine stark unspezifische Bindung. Im zweiten Teil dieser Arbeit wurden die bis-PNA Sonden gegen PNA- und GPNA-Spermin Sonden ausgetauscht, um das Problem der unspezifischen Bindung zu überwinden. Die PNA- und GPNA Spermin Sonden zeigten die wahrscheinlich effizientesten, bisher bekannten Nukleinsäure templierten Reaktionen, welchee die meisten natürlichen Enzyme übertrafen. Darüber hinaus zeigten sie eine ausgezeichnete Sequenzspezifität. / Developing enzyme-free isothermal detection methods of nucleic acids that can challenge PCR has been a long-standing goal. One potential strategy revolves around nucleic acid-templated reactions, in which the template (analyte) can act as a catalyst and amplify the signal. However, current strategies such as ligation reactions or functional group interconversions are plagued by product inhibition, which limits the sensitivity. To overcome this, the reactants must not only bind to DNA or RNA in a sequence-specific manner, but the products must also be able to detach from the DNA or RNA. This work introduces a new paradigm to nucleic acid-templated reactions, the loss-of-affinity principle, which yields products that have a lower template affinity than the reactants. This prevents product inhibition. In the first part of this work, the loss-of-affinity principle was explored with triplex-forming immolative bis-PNA probes that underwent a C-O bond cleavage upon catalytic photoreduction using a ruthenium complex. After several rounds of optimization, a 10-mer bis-PNA demonstrated an impressive catalytic efficiency. These results demonstrate that the loss-of-affinity principle can be used to overcome product inhibition. However, the bis-PNAs demonstrated highly non-specific binding. In the second part of this work, the bis-PNAs were replaced with PNA- and GPNA-spermine probes to address the issue of non-specific binding. The PNA- and GPNA-spermine probes exhibited probably the most efficient nucleic acid-templated reactions to date, outperforming most natural enzymes. In addition, they demonstrated excellent sequence specificity.

Bioorganische Chemie

DNA-Diagnostik

Nukleinsäure vermittelte Reaktionen

Transkriptom aktivierte Krebstherapie

Bioorganic Chemistry

DNA-Diagnostics

Transcriptome-Activated cancer therapy

Nucleic acid-templated reactions

ddc:540