Applications and expression of proteins encoded by the yeast 2#mu# plasmid

Snaith, Michael

January 1994

No description available.

572.8

Genome engineering

Biochemical analysis of the site specific recombinases of yeasts and of bacteriophage P1

Ringrose, Leonie Helen

January 1998

No description available.

572

Genome engineering

Design and optimization of engineered nucleases for genome editing applications

Lin, Yanni

07 January 2016

Genome editing mediated by engineered nucleases, including Transcription Activator-Like Effector Nucleases (TALENs) and Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) / CRISPR-associated (Cas) systems, holds great potential in a broad range of applications, including biomedical studies and disease treatment. In addition to creating cell lines and disease models, this technology allows generation of well-defined, genetically modified cells and organisms with novel characteristics that can be used to cure diseases, study gene functions, and facilitate drug development. However, achieving both high efficiency and high specificity remains a major challenge in nuclease-based genome editing. The objectives of this thesis were to optimize the design of TALENs to achieve high on-target cleavage activity, and analyze the off-target effect of CRISPR/Cas to help achieve high specificity. Based on experimental evaluation of >200 TALENs, we compared three different TALEN architectures, proposed new TALEN design rules, and developed a Scoring Algorithm for Predicting TALEN Activity (SAPTA) to identify optimal target sites with high activity. We also performed a systematic study to demonstrate the off-target cleavage by CRISPR/Cas9 when DNA sequences contain insertions or deletions compared to the RNA guide strand. Our results strongly indicate the need to perform comprehensive off-target analysis, and suggest specific guidelines for reducing potential off-target cleavage of CRISPR/Cas9 systems. The studies performed in this thesis work provide important insight and powerful tools for the optimization of engineered nucleases in genome editing, thus making a significant contribution to biomedical engineering and medical applications.

Genome engineering

Genome editing

TALENs

CRISPRs

Toward Multiplex Genome Engineering in Mammalian Cells

Rios Villanueva, Xavier

10 October 2015

Given the explosion in human genetic data, new high-throughput genetic methods are necessary for studying variants and elucidating their role in human disease. In Chapter I, I will expand on this concept and describe current methods for genetically modifying human cells. In E. coli, Multiplex Automatable Genome Engineering (MAGE) is a powerful tool that enables the targeting of multiple genomic loci simultaneously with synthetic oligos that are recombined at high frequencies in an optimized strain. MAGE as a method has two components: organism-specific optimization of oligo recombination parameters and a protein capable of increasing recombination frequencies.

Genetics

Biophysics

Genome Engineering

recombination

Synthetic Biology

Profiling and Improving the Specificity of Site-Specific Nucleases

Guilinger, John Paul

07 June 2014

Programmable site-specific endonucleases are useful tools for genome editing and may lead to novel therapeutics to treat genetic diseases. TALENs can be designed to cleave chosen DNA sequences. To better understand TALEN specificity and engineer TALENs with improved specificity, we profiled 30 unique TALENs with varying target sites, array length, and domain sequences for their ability to cleave any of 1012 potential off-target DNA sequences using in vitro selection and high-throughput sequencing. Computational analysis of the selection results predicted 76 off-target substrates in the human genome, 16 of which were accessible and modified by TALENs in human cells. The results collectively suggest that (i) TALE repeats bind DNA relatively independently; (ii) longer TALENs are more tolerant of mismatches, yet are more specific in a genomic context; and (iii) excessive DNA-binding energy can lead to reduced TALEN specificity in cells. We engineered a TALEN variant, Q3, that exhibits equal on-target cleavage activity but 10-fold lower average off-target activity in human cells. Our results demonstrate that identifying and mutating residues that contribute to non-specific DNA-binding can yield genome engineering agents with improved DNA specificities.

Biochemistry

Cas9

genome engineering

nuclease

specificity

TALEN

Highly Active Zinc Finger Nucleases by Extended Modular Assembly

Bhakta, Mital Subhash

January 2012

C2H2-zinc fingers (ZFs) are commonly found in transcription factors that code for nearly 3% of gene products in the human genome. ZF proteins are commonly involved in gene regulation during development, cell differentiation, and tumor suppression. Each "finger" is a domain composed of approximately 30 amino acids. Since the discovery of these domains over 25 years ago, several groups have contributed to the structural and biochemical knowledge to understand their DNA-binding properties. Taking advantage of the simplicity of manipulating the DNA-binding potential of a ZF, the technology has now evolved to make sequence-specific Zinc Finger Nucleases (ZFNs), Artificial Transcription Factors (ATFs), Zinc Finger Recombinases, and DNA detection tools. ZFPs have been used for various applications, ranging from regulating genes by ZF-ATFs to manipulating genomes in diverse organisms. ZFNs have remarkably revolutionized the field of genome engineering. ZFN-modified T-cells have now advanced into human clinical trials for cell-based therapies as a treatment against HIV. Despite the advances in the ZFN technology, one of the challenges in the field is obtaining effective ZFNs using publicly available tools. The traditional method of synthesizing custom ZF arrays was using modular assembly (MA). In this method, preselected ZFs from publicly available one-finger archives can be assembled modularly to make long arrays. MA of ZFNs provides a rapid method to create proteins that can recognize a broad spectrum of DNA sequences. However, three- and four-finger arrays often fail to produce active nucleases. The low success rate of MA ZF arrays was attributed to the fact that they suffer from finger-finger incompatibility referred to as context-dependent effects. However, we hypothesized that the low affinity of MA arrays was the limiting factor. The work presented in this dissertation describes our efforts at addressing these fundamental methodological challenges. We developed the Extended Modular Assembly method that overcomes the limitations of both the previous Modular Assembly. We performed a systematic investigation of number and composition of modules on ZFN activity and analyzed ZFN specificity both in vitro and in vivo. Our current experiments apply the ZFNs produced by our method to study the role of genetic variation in human disease.

Zinc finger nuclease

Pharmaceutical Sciences

Extended Modular Assembly

Genome Engineering

Targeted Gene Repression Technologies for Regenerative Medicine, Genomics, and Gene Therapy

Thakore, Pratiksha Ishwarsinh

January 2016

<p>Gene regulation is a complex and tightly controlled process that defines cell function in physiological and abnormal states. Programmable gene repression technologies enable loss-of-function studies for dissecting gene regulation mechanisms and represent an exciting avenue for gene therapy. Established and recently developed methods now exist to modulate gene sequence, epigenetic marks, transcriptional activity, and post-transcriptional processes, providing unprecedented genetic control over cell phenotype. Our objective was to apply and develop targeted repression technologies for regenerative medicine, genomics, and gene therapy applications. We used RNA interference to control cell cycle regulation in myogenic differentiation and enhance the proliferative capacity of tissue engineered cartilage constructs. These studies demonstrate how modulation of a single gene can be used to guide cell differentiation for regenerative medicine strategies. RNA-guided gene regulation with the CRISPR/Cas9 system has rapidly expanded the targeted repression repertoire from silencing single protein-coding genes to modulation of genes, promoters, and other distal regulatory elements. In order to facilitate its adaptation for basic research and translational applications, we demonstrated the high degree of specificity for gene targeting, gene silencing, and chromatin modification possible with Cas9 repressors. The specificity and effectiveness of RNA-guided transcriptional repressors for silencing endogenous genes are promising characteristics for mechanistic studies of gene regulation and cell phenotype. Furthermore, our results support the use of Cas9-based repressors as a platform for novel gene therapy strategies. We developed an in vivo AAV-based gene repression system for silencing endogenous genes in a mouse model. Together, these studies demonstrate the utility of gene repression tools for guiding cell phenotype and the potential of the RNA-guided CRISPR/Cas9 platform for applications such as causal studies of gene regulatory mechanisms and gene therapy.</p> / Dissertation

Biomedical engineering

CRISPR/Cas9

Epigenome editing

Gene regulation

Genome engineering

Redirecting the cellular information flow with programmable dCas9-based chimeric receptors

Baeumler, Toni Andreas

January 2018

Signal integration and transduction by cell-surface receptors is a complex, multi-layered process resulting in tight regulation of downstream mediators, which in turn elicit pre-defined native cellular responses. The modular architecture of transmembrane receptors provides a unique opportunity for engineering de novo sensor/effector circuits, enabling the development of custom cellular functions for research and therapeutic applications. The signal transduction module of most existing chimeric receptors consists of either native intracellular domains or effectors domains fused to non-programmable DNA binding proteins. Therefore, these receptors can only engage in natural signalling pathways or drive the expression of artificial, pre-integrated transgenes. By harnessing the programmability of a nuclease deficient CRISPR/Cas9 (dCas9) signal transduction module and leveraging the evolutionarily optimised ligand-sensing capacity of native receptors, I have created a novel class of dCas9-based synthetic receptors (dCas9-synR). I demonstrate that an optimised split dCas9-based core architecture and custom protease-based signal release mechanism can be standardised across multiple classes of extracellular domains to engineer receptor tyrosine kinase (RTK)-based and G-protein-coupled receptor (GPCR)-based chimeric receptors. dCas9-synRTK and dCas9-synGPCR integrate a broad variety of input signals (peptides, proteins, lipids, sugars) with highly specific and robust activation of any custom output transcriptional programme in an agonist dose-dependent manner. Finally, to showcase the therapeutic potential of dCas9-synRs, I used them to convert a pro-angiogenic signal into an anti-angiogenic response, deploy a chemokine/cytokine programme in response to tumour-enriched biomolecules, and induce insulin expression following glucose stimulation. The performance of dCas9-synRs and their unique versatility in redirecting the information flow makes them ideally suited to engineer designer cells capable of sensing specific disease markers and in turn drive various therapeutic programmes.

610

Studies in bacterial genome engineering and its applications

Enyeart, Peter James

12 August 2015

Many different approaches exist for engineering bacterial genomes. The most common current methods include transposons for random mutagenesis, recombineering for specific modifications in Escherichia coli, and targetrons for targeted knock-outs. Site-specific recombinases, which can catalyze a variety of large modifications at high efficiency, have been relatively underutilized in bacteria. Employing these technologies in combination could significantly expand and empower the toolkit available for modifying bacteria. Targetrons can be adapted to carry functional genetic elements to defined genomic loci. For instance, we re-engineered targetrons to deliver lox sites, the recognition target of the site-specific recombinase, Cre. We used this system on the E. coli genome to delete over 100 kilobases, invert over 1 megabase, insert a 12-kilobase polyketide-synthase operon, and translocate a 100 kilobase section to another site over 1 megabase away. We further used it to delete a 15-kilobase pathogenicity island from Staphylococcus aureus, catalyze an inversion of over 1 megabase in Bacillus subtilis, and simultaneously deliver nine lox sites to the genome of Shewanella oneidensis. This represents a powerful, versatile, and broad-host-range solution for bacterial genome engineering. We also placed lox sites on mariner transposons, which we leveraged to create libraries of millions of strains harboring rearranged genomes. The resulting data represents the most thorough search of the space of potential genomic rearrangements to date. While simple insertions were often most adaptive, the most successful modification found was an inversion that significantly improved fitness in minimal media. This approach could be pushed further to examine swapping or cutting and pasting regions of the genome, as well. As potential applications, we present work towards implementing and optimizing extracellular electron transfer in E. coli, as well as mathematical models of bacteria engineered to adhere to the principles of the economic concept of comparative advantage, which indicate that the approach is feasible, and furthermore indicate that economic cooperation is favored under more adverse conditions. Extracellular electron transfer has applications in bioenergy and biomechanical interfaces, while synthetic microbial economics has applications in designing consortia-based industrial bioprocesses. The genomic engineering methods presented above could be used to implement and optimize these systems. / text

Microbiology

Genome engineering

Targetrons

Transposons

Cre

Site-specific recombinases

CRISPR-Cas: Development and applications for mammalian genome editing

Ran, Fei Ann

04 June 2015

The ability to introduce targeted modifications into genomes and engineer model organisms holds enormous promise for biomedical and technological applications, and has driven the development of tools such as zinc finger nucleases (ZFNs) and transcription activator-like effector nucleases (TALENs). To facilitate genome engineering in mammalian cells, we have engineered the CRISPR (clustered regularly interspaced short palindromic repeats)-Cas9 programmable nuclease systems from Streptococcus pyogenes SF370 (SpCas9) and S. thermophilus LMD-9 (St1Cas9) for mouse and human cell gene editing through heterologous expression of the minimal protein and RNA components. We have demonstrated that Cas9 nucleases can be guided by several short RNAs (sgRNAs) to introduce double stranded breaks (DSB) in the mammalian genome and induce efficient, multiplexed gene modification through non-homologous end-joining-mediated indels or homology-directed repair. Furthermore, we have engineered SpCas9 into a nicking enzyme (SpCas9n) to facilitate recombination while minimizing mutagenic DNA repair processes, and show that SpCas9n can be guided by pairs of appropriately offset sgRNAs to induce DSBs with high efficiency and specificity. In collaboration with Drs. Osamu Nureki and Hiroshi Nishimasu at the University of Tokyo, we further report the crystal structure of SpCas9 in complex with the sgRNA and target DNA, and elucidate the structure-function relationship of the ribonucleoprotein complex. Finally, through a metagenomic screen of orthologs, we have identified an additional small Cas9 from Staphylococcus aureus subsp. aureus (SaCas9) that cleaves mammalian endogenous DNA with high efficiency. SaCas9 can be packaged into adeno-associated virus for effective gene modification in vivo. Together, these technologies open up exciting possibilities for applications across basic science, biotechnology, and medicine.

Biochemistry

Biology

Molecular biology

Cas9

CRISPR

Genome Engineering