Global ETD Search

21	Development of Human Genome Editing Tools for the Study of Genetic Variations and Gene Therapies Yang, Luhan 18 October 2013 (has links) The human genome encodes information that instructs human development, physiology, medicine, and evolution. Massive amount of genomic data has generated an ever-growing pool of hypothesis. Genome editing, broadly defined as targeted changes to the genome, posits to deliver the promise of genomic revolution to transform basic science and personalized medicine. This thesis aims to contribute to this scientific endeavor with a particular focus on the development of effective human genome engineering tools. Biomedical engineering Biochemistry CRISPR/cas gene therapy human genome engineering TALE targeted nucleases
22	Genome Engineering Technologies to Change the Genetic Code Lajoie, Marc Joseph 25 February 2014 (has links) New technologies are making it possible to engineer organisms with fundamentally new and useful properties. In vivo genome engineering technologies capable of manipulating genomes from the nucleotide to the megabase scale were developed and applied to reassign the genetic code of Escherichia coli. Such genomically recoded organisms show promise for thwarting horizontal gene transfer with natural organisms, resisting viral infection, and expanding the chemical properties of proteins. Biology Genetic code Genetic isolation Genome engineering MAGE Recombination Virus resistance
23	Genome Engineering Technology and Its Application in Mammalian Cells Cong, Le 06 June 2014 (has links) The advancement of high-throughput, large-scale biochemical, biophysical, and genetic technologies has enabled the generation of massive amounts of biological data and allowed us to synthesize various types of biomaterial for engineering purposes. This enabled improved observational methodologies for us to navigate and locate, with unprecedented resolution, the potential factors and connections that may contribute to biological and biomedical processes. Nonetheless, it leaves us with the increasing demand to validate these observations to elucidate the actual causal mechanisms in biology and medicine. Due to the lack of powerful and precise tools to manipulate biological systems in mammalian cells, these efforts have not been able to progress at an adequate pace. Biology Molecular biology Genetics Bioengineering Cas9 CRISPR Genome Engineering Molecular Biology TAL effector
24	Development of the CRISPR nuclease Cas9 for high precision mammalian genome engineering Hsu, Patrick David January 2014 (has links) Recent advances in genome engineering technologies based on the CRISPR-associated RNA-guided endonuclease Cas9 are enabling the systematic interrogation of genome function. Analogous to the search function in modern word processors, Cas9 can be guided to specific locations within complex genomes by a short RNA search string. Using this system, DNA sequences within the endogenous genome and their functional outputs are now easily edited or modulated in virtually any organism of choice. Cas9-mediated genetic perturbation is simple and scalable, empowering researchers to elucidate the functional organization of the genome at the systems level and establish causal linkages between genetic variations and biological phenotypes. To facilitate successful and specific Cas9 targeting, we first optimize the guide RNAs (sgRNA) to significantly enhance gene editing efficiency and consistency. We also systematically characterize Cas9 targeting specificity in human cells to inform the selection of target sites and avoid off-target mutagenesis. We find that SpCas9 tolerates mismatches between guide RNA and target DNA at different positions in a sequence-dependent manner, sensitive to the number, position and distribution of mismatches. We also show that Cas9-mediated cleavage is unaffected by DNA methylation and that the dosage of Cas9 and sgRNA can be titrated to minimize off-target modification. Additionally, we provide a web-based software tool to guide the selection and validation of target sequences as well as off-target analyses. We next demonstrate that Cas9 nickase mutants can be used with paired guide RNAs to introduce targeted double-strand breaks. Because individual nicks in the genome are repaired with high fidelity, simultaneous nicking via appropriately offset guide RNAs can reduce off-target activity by over 1,500-fold in human cells. In collaboration with researchers at the University of Tokyo, we further identified a PAM-interacting domain of the Cas9 nuclease that dictates Cas9 target recognition specificity. Finally, we present protocols that provide experimentally derived guidelines for the selection of target sites, evaluation of cleavage efficiency and analysis of off-target activity. Beginning with target design, gene modifications can be achieved within as little as 1-2 weeks. Taken together, this work enables a variety of genome engineering applications from basic biology to biotechnology and medicine. Biomedical engineering Biology Cellular biology Cas9 CRISPR gene therapy genome editing genome engineering Patrick Hsu
25	Generating CRISPR-Cas9 genome-engineered human embryonic stem cell to model a genetic mechanism of asthma McManus, Sean 08 April 2016 (has links) Asthma is a major public health epidemic that presents a heavy burden on those who suffer from the disease. Little is currently understood about the genetic signature that distinguishes one type of asthma from another. Recently, the single nucleotide polymorphism (SNP) rs968567 was found to have a high degree of association in asthmatic patients (Sharma et al., 2014). This particular SNP is in the promoter region of the FADS2 gene that synthesizes the enzyme delta-6-desaturase (D6D). D6D mediates the formation of pro-inflammatory factors that lead to exacerbation of asthmatic symptoms. We engineered a novel, customized CRISPR-Cas9 construct to induce the SNP rs968567 in the HUES9 human embryonic stem cell (hESC) line. Our results show success in generating the custom CRISPR-Cas9 construct for use in stem cells, while efficiency in expressing the desired mutation in our cell line is currently being optimized. Disease modeling in the genomic era of medicine provides an opportunity for the development of personalized medical treatment. Future projects aim to differentiate stem cell lines edited with our CRISPR-Cas9 construct to lung progenitor cells to study the cellular phenotype of this mutation in context of asthma pathogenesis. Genetics CRISPR-Cas9 FADS2 hESCs Asthma Genome engineering Human embryonic stem cells
26	RNA-based engineering of inducible CRISPR-Cas9 transcription factors for de novo assembly of eukaryotic gene circuits Ferry, Quentin R. V. January 2017 (has links) Synthetic biology in mammalian cells holds great promise for reverse engineering biological processes and rewiring cellular behaviors for therapeutic purpose. An essential aspect in our ability to reprogram the cellular code is the availability of highly orthogonal, inducible transcriptional regulators. CRISPR-based strategies employing effector-domain tethering to the single guide RNA (sgRNA)-dCas9 complex have greatly advanced this field by allowing for precise activation or repression of any gene via simple sgRNA reprograming. However, the implementation of inducible CRISPR-based transcriptional regulators (CRISPR-TRs) has so far been restricted to dCas9 protein engineering and conditional effector tethering. Although elegant, these approaches are limited by dCas9 promiscuous loading of sgRNAs, which hinders their use for the creation of independent multi-gene transcriptional programs. To address this limitation, I have developed a modular framework for the rational design of inducible CRISPR-TR, based on simple and reversible modifications of the sgRNA sequence. At the core of this conceptual framework lies the ability to inactivate native sgRNAs by appending on their 5'-end a short RNA segment, which folds to form a spacer-blocking hairpin (SBH). Base-pairing between the extension and the sgRNA spacer prevents docking of the CRISPR-TR on-target, fully abrogating its activity. Subsequently, I have created inducible SBH variants (iSBH) by replacing the hairpin loop with conditional RNA cleaving units. Using a variety of sensing-loops, I was able to engineer a panel of switchable iSBH-sgRNAs, designed to activate specifically in the presence of protein, oligonucleotide, and small molecule inducers. Leveraging the versatility of this method, I demonstrate that iSBH-sgRNAs expression can be multiplexed to assemble synthetic gene circuits implementing parallel and orthogonal regulation of multiple endogenous gene targets. Finally, I have distilled the design principles derived throughout this project to develop a web tool that automates the creation of iSBH- sgRNAs. Already a valuable addition to the synthetic biology toolkit, iSBH-based inducibility should in theory also be applicate to all CRISPR-Cas9 derivatives (genome editing, epigenetic alteration, DNA labelling, etc.) as well as other newly characterized RNA-guide nucleases from the CRISPR family.
27	Development of CRISPR-RNA Guided Recombinases for Genome Engineering January 2018 (has links) abstract: Recombinases are powerful tools for genome engineering and synthetic biology, however recombinases are limited by a lack of user-programmability and often require complex directed-evolution experiments to retarget specificity. Conversely, CRISPR systems have extreme versatility yet can induce off-target mutations and karyotypic destabilization. To address these constraints we developed an RNA-guided recombinase protein by fusing a hyperactive mutant resolvase from transposon TN3 to catalytically inactive Cas9. We validated recombinase-Cas9 (rCas9) function in model eukaryote Saccharomyces cerevisiae using a chromosomally integrated fluorescent reporter. Moreover, we demonstrated cooperative targeting by CRISPR RNAs at spacings of 22 or 40bps is necessary for directing recombination. Using PCR and Sanger sequencing, we confirmed rCas9 targets DNA recombination. With further development we envision rCas9 becoming useful in the development of RNA-programmed genetic circuitry as well as high-specificity genome engineering. / Dissertation/Thesis / Masters Thesis Biology 2018 Molecular biology Biomedical engineering Genetics CRISPR Genetic Circuitry Genome Engineering Recombinases RNA-guided Synthetic Biology
28	Developing safe and controllable Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)-based therapies with design principles of synthetic biology January 2020 (has links) abstract: The CRISPR/Cas9 gene-editing tool is currently in clinical trials as the excitement about its therapeutic potential is exponentially growing. However, many of the developed CRISPR based genome engineering methods cannot be broadly translated in clinical settings due to their unintended consequences. These consequences, such as immune reactions to CRISPR, immunogenic adverse events following receiving of adeno-associated virus (AAV) as one of the clinically relevant delivery agents, and CRISPR off-target activity in the genome, reinforces the necessity for improving the safety of CRISPR and the gene therapy vehicles. Research into designing more advanced CRISPR systems will allow for the increased ability of editing efficiency and safety for human applications. This work 1- develops strategies for decreasing the immunogenicity of CRISPR/Cas9 system components and improving the safety of CRISPR-based gene therapies for human subjects, 2- demonstrates the utility of this system in vivo for transient repression of components of innate and adaptive immunity, and 3- examines an inducible all-in-one CRISPR-based control switch to pave the way for controllable CRISPR-based therapies. / Dissertation/Thesis / Doctoral Dissertation Biological Design 2020 Biomedical engineering Genetics Bioengineering AAV CRIPSR Gene Therapy Genome engineering Synthetic biology Transcriptinal repressor
29	In silico engineering and optimization of Transcription Activator-Like Effectors and their derivatives for improved DNA binding predictions. Piatek, Marek J. 12 1900 (has links) Transcription Activator-Like Effectors (TALEs) can be used as adaptable DNAbinding modules to create site-specific chimeric nucleases or synthetic transcriptional regulators. The central repeat domain mediates specific DNA binding via hypervariable repeat di-residues (RVDs). This DNA-Binding Domain can be engineered to bind preferentially to any user-selected DNA sequence if engineered appropriately. Therefore, TALEs and their derivatives have become indispensable molecular tools in site-specific manipulation of genes and genomes. This thesis revolves around two problems: in silico design and improved binding site prediction of TALEs. In the first part, a study is shown where TALEs are successfully designed in silico and validated in laboratory to yield the anticipated effects on selected genes. Software is developed to accompany the process of designing and prediction of binding sites. I expanded the functionality of the software to be used as a more generic set of tools for the design, target and offtarget searching. Part two contributes a method and associated toolkit developed to allow users to design in silico optimized synthetic TALEs with user-defined specificities for various experimental purposes. This method is based on a mutual relationship of three consecutive tandem repeats in the DNA-binding domain. This approach revealed positional and compositional bias behind the binding of TALEs to DNA. In conclusion, I developed methods, approaches, and software to enhance the functionality of synthetic TALEs, which should improve understanding of TALEs biology and will further advance genome-engineering applications in various organisms and cell types. Transcription Activator-Like Effector Genome engineering TALE binding code TALE target prediction Bioinformatics
30	Anti-CRISPR Proteins: Applications in Genome Engineering Lee, Jooyoung 14 July 2020 (has links) Clustered, regularly interspaced, short palindromic repeats and CRISPR-associated proteins (CRISPR-Cas) constitute a bacterial and archaeal adaptive immune system. The ongoing arms race between prokaryotic hosts and their invaders such as phages led to the emergence of anti-CRISPR proteins as countermeasures against the potent antiviral defense. Since the first examples of anti-CRISPRs were shown in a subset of CRISPR-Cas systems, we endeavored to uncover these naturally-occurring inhibitors that inactivate different types of CRISPR-Cas systems. In the first part of my thesis, we have identified and characterized Type II anti-CRISPR proteins that inactivate several Cas9 orthologs. We share mechanistic insights into anti-CRISPR inhibition and show evidence of its potential utility as an off-switch for Cas9-mediated mammalian genome editing. Although the RNA programmability of Cas9 enables facile genetic manipulation with great potential for biotechnology and therapeutics, limitations and safety issues remain. The advent of anti-CRISPR proteins presents opportunities to exploit the inhibitors to exert temporal, conditional, or spatial control over CRISPR. In the second part of my thesis, we demonstrate that anti-CRISPR proteins can serve as useful tools for Cas9 genome editing. In particular, we have demonstrated that anti-CRISPRs are effective as genome editing off-switches in the tissues of adult mammals, and we further engineered anti-CRISPR proteins to achieve tissue-specific editing in vivo. Taken together, my thesis research aimed to mine for natural anti-CRISPR protein inhibitors and repurpose these proteins to complement current Cas9 technologies in basic and clinical research. CRISPR anti-CRISPR genome engineering gene editing Biotechnology Genetics and Genomics Microbiology

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