Cell-type-specific genome editing with a microRNA-responsive CRISPR-Cas9 switch / マイクロRNA応答性CRISPR-Cas9スイッチを用いた細胞種特異的なゲノム編集

Hirosawa, Moe

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(医科学) / 甲第21689号 / 医科博第93号 / 新制||医||1036(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 斎藤 通紀, 教授 中川 一路, 教授 竹内 理 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

CRISPR-Cas9 system

microRNA (miRNA)

genome editing

synthetic biology

491

Precise genomic deletions and insertions via paired prime editing for crop bioengineering

Moreno-Ramírez, Jose Luis

08 1900

CRISPR/Cas has been developed for targeted mutagenesis in diverse species, including plants. However, precise genome editing via homology-directed repair (HDR) is inefficient in plants, limiting our ability to make large deletions or insertions in the plant genomes. Prime editing increases the control over the desired editing and allows the precise introduction of all types of mutations, including insertion, deletions, and all possible base conversions, albeit at low efficiencies. Here, we designed a dual prime editing system to generate large deletions and precise insertions of sequences by repairing template complementarity. We coupled dual pegRNA with Cas9 nickase (nCas9) to generate deletions and insertions. In another modality, we used dual pegRNA with wild-type Cas9 to generate double-stranded breaks to improve the editing at the targeted sites. We tested dual pegRNAs to delete the last exon in OsCCD7, delete the microRNA targeted sequence in OsIPA, and insert the T7 promoter in the 3'UTR of OsALS. Our results showed a high frequency of targeted insertion of the T7 promoter sequence in the 3'UTR of OsALS with wtCas9 and nCas9. Sanger sequencing analysis showed partial deletions at the targeted locus. Further improvements in the designs of pegRNAs will increase the precise genome insertions and deletions in plants.

Genome editing

Prime editing

Crop improvement

Targeted mutagenesis

Establishment of a practical gene knock-in system and its application in medaka / メダカにおける実用的なノックインシステムの確立とその応用

Murakami, Yu

23 March 2020

京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第22503号 / 農博第2407号 / 新制||農||1077(附属図書館) / 学位論文||R2||N5283(農学部図書室) / 京都大学大学院農学研究科応用生物科学専攻 / (主査)教授 佐藤 健司, 教授 澤山 茂樹, 准教授 豊原 治彦 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM

Genome editing

CRISPR/Cas9 system

Knock-in

Bioreactor

Vitellogenin

Medaka

610

Translational modulation through CRISPR-Cas-mediated genome editing

Ambrosini, Chiara

17 December 2021

More than 300 human conditions, ranging from cancer predisposition to developmental and neurological mendelian disorders, are caused by haploinsufficiency (HI), a genetic condition by which mutational inactivation of a single allele leads to reduced protein levels and is enough to produce the disease phenotype. Therefore, translational enhancement of the spare allele could exert a therapeutic effect. Here we propose a novel approach for the potential rescue of haploinsufficiency disease loci based on the insertion of specific single nucleotide changes in the Kozak sequence. Since this sequence controls translation by regulating start codon recognition, we aimed at identifying and introducing specific nucleotide variations to enhance translation and rescue haploinsufficiency. To do so, we used CRISPR-Cas base editors, able to generate single nucleotide changes in genomic DNA without the need of a donor DNA and without creating double-strand breaks. We performed a high-throughput screening to evaluate the strength of the Kozak sequences of 231 haploinsufficient genes. We compared the translational efficiency of each wild-type sequence to that of several variants using FACS-seq, which combines fluorescence-activated cell sorting and high-throughput DNA sequencing. We thus selected 5 candidate genes (PPARGC1B, FKBP6, GALR1, NRXN1, and NCF1) and several nucleotide variations able to up-regulate translation. Finally, we used CRISPR-Cas base editors to reproduce the most efficient variants of NCF1 in a cell model relevant for the associated haploinsufficient disease and verified the increase of protein levels. This study proposes a novel therapeutic strategy to rescue haploinsufficiency and sheds new insights into the regulatory mechanisms underlying the translational process. On a broader level, the possibility of modulating gene expression by acting exclusively on translation expands the CRISPR-Cas genome editing applications.

Settore BIO/13 - Biologia Applicata

Studies on the mechanisms underlying the acquisition of competence for metamorphosis in the silkworm, Bombyx mori / カイコにおける蛹化能力獲得機構の解析

Inui, Tomohiro

25 September 2023

京都大学 / 新制・課程博士 / 博士(農学) / 甲第24912号 / 農博第2575号 / 新制||農||1102(附属図書館) / 京都大学大学院農学研究科応用生物科学専攻 / (主査)教授 大門 高明, 教授 松浦 健二, 准教授 小野 肇 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM

insect metamorphosis

juvenile hormone

ecdysone

microRNA

genome editing

610

Novel approaches to treat mitochondrial complex-I mediated defects in disease

Perry, Justin Bradley

25 April 2019

Dysfunction within complex I (CI) of the mitochondrial electron transport system has been implicated in a number of disease states ranging from cardiovascular diseases to neuro-ophthalmic indications. Herein, we provide three novel approaches to model and study the impacts of injury on the function of CI. Cardiovascular ischemia/reperfusion (I/R) injury has long been recognized as a leading contributor to CI dysfunction. Aside from the physical injury that occurs in the tissue during the ischemic period, the production of high levels of reactive oxygen species (ROS) upon reperfusion, led by reverse electron transport (RET) from CI, causes significant damage to the cell. With over 700,000 people in the US set to experience an ischemic cardiac event annually, the need for a pharmacological intervention is paramount. Unfortunately, current pharmacological approaches to treat I/R related injury are limited and the ones that have shown efficacy have often done so with mixed results. Among the current approaches to treat I/R injury antioxidants have shown some promise to help preserve mitochondrial function and assuage tissue death. The studies described herein have provided new, more physiologically matched, methods for assessing the impact of potential therapeutic interventions in I/R injury. With these methods we evaluated the efficacy of the coenzyme-Q derivative idebenone, a proposed antioxidant. Surprisingly, in both chemically induced models of I/R and I/R in the intact heart, we see no antioxidant-based mechanism for rescue. The mechanistic insight we gained from these models of I/R injury directed us to further examine CI dysfunction in greater detail. Through the use of two cutting edge genetic engineering approaches, CRISPR/Cas9 and Artificial Site-specific RNA Endonucleases (ASRE), we have been able to directly edit the mitochondria to accurately model CI dysfunction in disease. The use of these genetic engineering technologies have provided first in class methods for modeling three unique mitochondrial diseases. The culmination of these projects has provided tremendous insight into the role of CI in disease and have taken a significant step towards elucidating potential therapeutic avenues for targeting decrements in mitochondrial function. / Doctor of Philosophy / Within the mitochondria, “the powerhouse of the cell,” exists a series of five enzyme complexes that produce 90% of the energy for our cells need to function. The largest of these enzymes, complex I (CI), plays an important role in ensuring proper mitochondrial function. Injury to CI contributes to a number of diseases, but surprisingly few options exist to treat complex I. One of the most prevalent forms of CI dysfunction can be seen in ischemia/ reperfusion injury, a form of which is most commonly recognized as a heart attack. Surprisingly, the American Heart Association reports that in the next year over 700,000 people in the US will suffer from an ischemic event. With such a profound impact on the population, the need for new therapeutic developments is extremely high. Some current therapeutic approaches have been shown to be effective at treating cardiac dysfunction, but few address the dysfunction that occurs in the mitochondria. Here we test both a method for modeling these ischemia/reperfusion-based injuries and a potential therapeutic for treating these injuries within the context of CI dysfunction. We further evaluate CI dysfunction by using both established genetic engineering approaches as well as a completely new method to model CI disease. Through the use of two cutting edge genetic engineering approaches, we have been able to directly edit components of the mitochondria to accurately model CI dysfunction in disease. The use of these genetic engineering technologies have provided a first-in-class method for modeling three unique mitochondrial diseases. The culmination of these projects has provided tremendous insight into the role of CI in disease and have taken a significant step towards elucidating potential therapeutic avenues for targeting decrements in mitochondrial function.

Mitochondria

Ischemia/Reperfusion

Mitochondrial Disease

Genome Editing

Idebenone

Nuclear Localization of Proteins and Genome Editing in the Oomycete Phytophthora sojae

Fang, Yufeng

15 November 2016

Oomycetes are fungi-like eukaryotic microorganisms, which are actually phylogenetic relatives of diatoms and brown algae, within the kingdom Stramenopila. Many oomycete species, mainly in the genera Phytophthora, Pythium and downy mildews, are devastating plant pathogens that cause multibillion-dollar losses to agriculture annually in the world. Some oomycetes are also animal pathogens, causing severe losses in aquaculture and fisheries, and occasionally causing dangerous infections of humans. Phytophthora species, represented by the Irish Potato Famine pathogen P. infestans and the soybean pathogen P. sojae, are arguably the most destructive pathogens of dicotyledonous plants among the oomycete species and thus have been extensively studied. This dissertation focuses on the model oomycete pathogen P. sojae to investigate specific aspects of its molecular biology and establish an efficient genetic manipulation tool. Specifically, in Chapter 1, I briefly introduce the basic concepts of oomycete biology and pathology, and summarize the experimental techniques used for studies of oomycete genetics over the past two decades. Because the approach to studying fungi and oomycetes are similar (indeed they were incorrectly placed in the same taxonomic group until recently), a special section reviews the emerging genome editing technology CRISPR/Cas system in these organisms together. Chapter 2 and Chapter 3 focus on one of the most important intracellular activities, nuclear localization of proteins, and describe the characterization of nuclear localization signals (NLSs) in P. sojae. This focus stemmed from my early work on genome editing in P. sojae, when I discovered that conventional NLS signals from SV40 used to target the TAL effector nuclease (TALEN) to the nucleus worked poorly in P. sojae. In the first part of this work (Chapter 2), I used confocal microscopy to identify features of nuclear localization in oomycetes that differ from animals, plants and fungi, based on characterization of two classes of nuclear localization signals, cNLS and PY-NLS, and on characterization of several conserved nuclear proteins. In the second part (Chapter 3), I determined that the nuclear localization of the P. sojae bZIP1 transcription factor is mediated by multiple weak nuclear targeting motifs acting together. In Chapter 4 and Chapter 5, I describe my implementation of nuclease-based technology for genetic modification and control of P. sojae. In Chapter 4, I describe the first use of the CRISPR system in an oomycete, including its use to validate the function of a host specificity gene. This is of particular importance because molecular techniques such as gene knockouts and gene replacements, widely used in other organisms, were not previously possible in oomycetes. The successful implementation of CRISPR provides a major new research capability to the oomycete community. Following up on the studies described in Chapter 4, in Chapter 5, I describe the generalization and simplification of the CRISPR/Cas9 expression strategy in P. sojae as well as methods for mutant screening. I also describe several optimized methodologies for P. sojae manipulation based on my 5 years of experience with P. sojae. / Ph. D.

Oomycetes

Phytophthora sojae

nuclear localization signals

CRISPR/Cas9

genome editing

An Exploration of the Properties of Repair Template DNA that Promote Precision Genome Editing

Ghanta, Krishna S.

03 August 2021

CRISPR/Cas9 induced DNA breaks can be precisely repaired by cellular homology-directed repair (HDR) pathways using exogenously provided template DNA (donor). However, the full potential of precision editing is hindered in many model systems by low cutting efficiencies, low HDR efficiencies and, cytotoxicity related to Cas9 and donor DNA. In this thesis, I address these challenges and present methods that we developed to increase HDR efficiencies in multiple model organisms. In Caenorhabditis elegans, we show that by reducing toxicity high editing efficiencies can be achieved with single stranded oligonucleotide (ssODN) donors. We demonstrate that melting dsDNA donors dramatically improves the knock-in efficiencies of longer (1kb) edits. In addition, we describe 5′-terminal modifications to the donor molecules that further increase the frequency of precision editing. With our methodology a single optimally injected animal can yield more than 100 Green Fluorescent Protein (GFP) positive progeny, dramatically enhancing efficiency of genome editing. Next, we demonstrate the generality of 5′ modified donors by extending our studies to human cell cultures and mice zygotes. In mammalian models, 2′OMe-RNA modifications consistently increase HDR efficiencies by several fold over unmodified donors. Furthermore, end-modified donors exhibited a striking reduction in end-joining reactions including reduced concatemer formation and reduced direct ligation into the host genome. Our study demonstrates that HDR can be improved without inhibiting competing end-joining pathways and provides a platform to identify new chemical modifications that could further increase the potency and efficacy of precision genome editing.

C. elegans

CRISPR

Genome editing

HDR

Donor DNA

Precision genome editing

Chemical Modifications

Modified donors

5′ modifications

TEG modifications

melted donors.

Biotechnology

Genetics

Molecular Biology

Molecular Genetics

A toolkit for analysis of gene editing and off-target effects of engineered nucleases

Fine, Eli Jacob

27 May 2016

Several tools were developed to help researchers facilitate clinical translation of the use of engineered nucleases towards their disease gene of interest. Two major issues addressed were the inability to accurately predict nuclease off-target sites by user-friendly \textit{in silico} methods and the lack of a high-throughput, sensitive measurement of gene editing activity at endogenous loci. These objectives were accomplished by the completion of the following specific aims. An online search interface to allow exhaustive searching of a genome for potential nuclease off-target sites was implemented. Previously discovered off-target sites were collated and ranking algorithms developed that preferentially score validated off-target sites higher than other predictions. HEK-293T cells transfected with newly developed TALENs and ZFNs targeting the beta-globin gene were analyzed at the off-target sites predicted by the tool. Many samples of genomic DNA from cells treated with different ZFNs and TALENs were analyzed for off-target effects to generate a greatly expanded training set of bona fide off-target sites. Modifications to the off-target prediction algorithm parameters were evaluated for improvement through Precision-Recall analysis and several other metrics. An analysis pipeline was developed to process SMRT reads to simultaneously measure the rates of different DNA repair mechanisms by directly examining the DNA sequences. K562 cells were transfected with different types of nucleases and donor repair templates in order to optimize conditions for repairing the beta-globin gene. This work will have significant impact on future studies as the methods developed herein allow other laboratories to optimize nuclease-based therapies for single gene disorders.

Genome editing

Genome engineering

Engineered nucleases

Off-target effects

TALENs

ZFNs

CRISPR

Cas9

Gene therapy

Genetic Correction of Duchenne Muscular Dystrophy using Engineered Nucleases

Ousterout, David Gerard

January 2014

<p>Duchenne muscular dystrophy (DMD) is a severe hereditary disorder caused by a loss of dystrophin, an essential musculoskeletal protein. Decades of promising research have yielded only modest gains in survival and quality of life for these patients and there have been no approved gene therapies for DMD to date. There are two significant hurdles to creating effective gene therapies for DMD; it is difficult to deliver a replacement dystrophin gene due to its large size and current strategies to restore the native dystrophin gene likely require life-long administration of a gene-modifying drug. This thesis presents a novel method to address these challenges through restoring dystrophin expression by genetically correcting the native dystrophin gene using engineered nucleases that target one or more exons in a mutational hotspot in exons 45-55 of the dystrophin gene. Importantly, this hotspot mutational region collectively represents approximately 62% of all DMD mutations. In this work, we utilize various engineered nuclease platforms to create genetic modifications that can correct a variety of DMD patient mutations.</p><p>Initially, we demonstrate that genome editing can efficiently correct the dystrophin reading frame and restore protein expression by introducing micro-frameshifts in exon 51, which is adjacent to a hotspot mutational region in the dystrophin gene. Transcription activator-like effector nucleases (TALENs) were engineered to mediate highly efficient gene editing after introducing a single TALEN pair targeted to exon 51 of the dystrophin gene. This led to restoration of dystrophin protein expression in cells from DMD patients, including skeletal myoblasts and dermal fibroblasts that were reprogrammed to the myogenic lineage by MyoD. We show that our engineered TALENs have minimal cytotoxicity and exome sequencing of cells with targeted modifications of the dystrophin locus showed no TALEN-mediated off-target changes to the protein coding regions of the genome, as predicted by in silico target site analysis. </p><p>In an alternative approach, we capitalized on the recent advances in genome editing to generate permanent exclusion of exons by using zinc-finger nucleases (ZFNs) to selectively remove sequences important in specific exon recognition. This strategy has the advantage of creating predictable frame restoration and protein expression, although it relies on simultaneous nuclease activity to generate genomic deletions. ZFNs were designed to remove essential splicing sequences in exon 51 of the dystrophin gene and thereby exclude exon 51 from the resulting dystrophin transcript, a method that can potentially restore the dystrophin reading frame in up to 13% of DMD patients. Nucleases were assembled by extended modular assembly and context-dependent assembly methods and screened for activity in human cells. Selected ZFNs had moderate observable cytotoxicity and one ZFN showed off-target activity at two chromosomal loci. Two active ZFN pairs flanking the exon 51 splice acceptor site were transfected into DMD patient cells and a clonal population was isolated with this region deleted from the genome. Deletion of the genomic sequence containing the splice acceptor resulted in the loss of exon 51 from the dystrophin mRNA transcript and restoration of dystrophin expression in vitro. Furthermore, transplantation of corrected cells into the hind limb of immunodeficient mice resulted in efficient human dystrophin expression localized to the sarcolemma. </p><p>Finally, we exploited the increased versatility, efficiency, and multiplexing capabilities of the CRISPR/Cas9 system to enable a variety of otherwise challenging gene correction strategies for DMD. Single or multiplexed sgRNAs were designed to restore the dystrophin reading frame by targeting the mutational hotspot at exons 45-55 and introducing either intraexonic small insertions and deletions, or large deletions of one or more exons. Significantly, we generated a large deletion of 336 kb across the entire exon 45-55 region that is applicable to correction of approximately 62% of DMD patient mutations. We show that, for selected sgRNAs, CRISPR/Cas9 gene editing displays minimal cytotoxicity and limited aberrant mutagenesis at off-target chromosomal loci. Following treatment with Cas9 nuclease and one or more sgRNAs, dystrophin expression was restored in Duchenne patient muscle cells in vitro. Human dystrophin was detected in vivo following transplantation of genetically corrected patient cells into immunodeficient mice. </p><p>In summary, the objective of this work was to develop methods to genetically correct the native dystrophin as a potential therapy for DMD. These studies integrate the rapid advances in gene editing technologies to create targeted frameshifts that restore the dystrophin gene around patient mutations in non-essential coding regions. Collectively, this thesis presents several gene editing methods that can correct patient mutations by modification of specific exons or by deletion of one or more exons that results in restoration of the dystrophin reading frame. Importantly, the gene correction methods described here are compatible with leading cell-based therapies and in vivo gene delivery strategies for DMD, providing an avenue towards a cure for this devastating disease.</p> / Dissertation

Biomedical engineering

CRISPR/Cas9

Duchenne muscular dystrophy

Gene correction

Genome editing

TALE nucleases

Zinc-finger nucleases