Global ETD Search

61	Reproductive Consequences of CRISPR/Cas9-Based avp Knock-Out in Zebrafish (Danio rerio) Ramachandran, Divya 06 December 2022 (has links) The nonapeptide family of hormones is deeply conserved in evolution. In teleost fishes, as in all vertebrates, two nonapeptide families exist. These are vasotocin (avp) and oxytocin (oxt). While vasotocin has been shown to regulate individual aspects of reproductive physiology in several teleost species, an integrative assessment of its role on male and female reproduction is currently lacking even in widely used fish models, such as the zebrafish (Danio rerio). Taking advantage of the genetic tractability of the zebrafish, and its emerging status as model to study reproductive physiology, I generated avp -/- mutants using a CRISPR/Cas9 based approach to determine reproductive consequences in female and male zebrafish. Following the identification of a female-specific reproductive phenotype which manifests as a reduction in oocyte release and decreased quivering behaviour, I investigated the potential mechanistic basis at the level of the gonad. In avp -/- ovaries, significantly fewer eggs were present compared to WT fishes. When comparing the distribution of oocyte maturation stages, a significantly lower percentage of stage I and higher percentage of stage V oocytes was present in avp-/- ovaries. The altered distribution in oocyte maturation stages coincided with significant decreases in ovarian transcript abundance of nanos2, a germ-cell specific marker suggesting a possible role for Avp in germ-cell maintenance. Additionally, I observed a decrease in the ovarian concentration of the prostaglandin PGF2, which coincided with a reduction in ovarian transcript abundance of pla2g4ab, a paralogue of the phospholipase A2 involved in mobilizing arachidonic acid, a precursor of PGF2,. Together, these finding suggests a role for Avp in PGF2 -mediated ovulation. Because Avp has pleiotropic effects and may thus affect female reproductive physiology indirectly, we assessed somatic growth, a key regulator of sexual maturation in zebrafish, as well as aspects of the endocrine stress axis known to affect oocyte growth in avp -/- mutants. While avp -/- mutants did not exhibit differences in somatic growth up to sexual maturation or GSI, mutants exhibited hypercortisolism. While other zebrafish knock-out mutants exhibiting persistent hypercortisolism do not share the observed reproductive phenotype, future studies investigating potential contributions of pleiotropic Avp effects are nevertheless warranted. Overall, I demonstrate that avp, while not essential, affects female reproductive success, at least iii in part by regulating oocyte maturation. This finding is in line with the recent findings from other vertebrate and invertebrate species, suggesting an evolutionarily ancient role in these processes. It is anticipated that such novel insights into the regulation of female oocyte maturation have in addition to increasing our understanding of female reproduction, translational potential for captive breeding (aquaculture, species conservation) and ecotoxicology (insight into mode of action of specific EDCs). Nonapeptides CRISPR/Cas9 Courtship Behaviour Ovary
62	Characterization of CRISPR-Cas12a Novel Small Molecule Inhibitors Yinusa, Abadat 01 December 2022 (has links) Cas12a (Cpf1) is a representative type V-A CRISPR (Clustered Regularly Interspaced Short Palindromic Repeats) effector RNA-guided DNA endonuclease used widely for genome editing. Identification of Cas12a inhibitors is important for regulating gene editing, enhancing genome editing specificity, and safety for human therapeutics. This study used a fluorescence-based assay to screen diverse drug libraries at a core facility for potential small molecule candidates that can inhibit AsCas12a endonuclease activities. Further validation of the major hit compounds revealed that these small molecules inhibit Cas12a in vitro DNA cis and trans cleavage activities as well as gene editing in cells. IC50 values obtained from gene editing inhibition were even lower than primary screening reported IC50. We determined the impact of the small molecules on the thermal stability of Cas12a, possible binding sites, and binding affinity (Kd) using thermal denaturation experiments. Enzyme kinetics studies were used to investigate the effect of the inhibitors on ribonucleoprotein complex formation. The discovered molecules create a tool for achieving safer applications of CRISPR-Cas12a in biotechnology and therapeutics. Biotechnology CRISPR Endonuclease Gene Editing Inhibitors Therapeutics
63	CRISPR-Cas9 Mediated Gene Editing of Secondary Metabolite Gene Clusters in Fusarium graminearum Hicks, Carmen 14 December 2023 (has links) Fusarium graminearum is responsible for causing Fusarium head blight in cereals and maize imposing a significant impact in Canadian agriculture. While a handful of secondary metabolites produced by F. graminearum are recognized as contributors to disease virulence, the functions of numerous molecular products arising from biosynthetic gene clusters expressed during infection remain undiscovered. Presented here are the results of CRISPR-Cas9 mediated gene-deletion experiments disrupting core biosynthetic genes from four biosynthetic gene clusters with reported in-planta transcription: C08, C16, C13 and C70. Both wheat head infection assays and coleoptile infection assays were used to evaluate the pathology phenotypes of transformant strains illustrating potential links between C16 and pathogenicity. Culture medium screening experiments using transformant strains were profiled by UHPLC-HRMS and targeted MS2 experiments to confirm the associated secondary metabolite products and attempt to identify unknown secondary metabolites of the biosynthetic gene clusters. While C08 secondary metabolite remained elusive, confirmation of C16 secondary metabolites led to hypotheses regarding their potential connections to the inhibition of plant immune response and untargeted secondary metabolite profiling of the C13/C70 transformant strains suggests that this BGC may have significant implications for global secondary metabolite production. Fusarium graminearum Metabolomics CRISPR-Cas9 Secondary Metabolite
64	Caracterización funcional y aplicación biotecnológica de nuevos sistemas CRISPR–Cas identificados en ambientes naturales de la provincia de Alicante Esquerra, Belén 19 December 2022 (has links) Los sistemas de defensa de procariotas denominados CRISPR–Cas dan lugar a la formación de un complejo nucleoproteico compuesto por proteínas Cas y un ARN guía derivado de las regiones CRISPR que se encarga de interferir en la propagación de elementos genéticos móviles a través de la degradación mediada por nucleasas Cas de secuencias foráneas que coinciden con los ARN guía. La fácil reprogramación de la guía ha propiciado el desarrollo de un arsenal de herramientas para la modificación y manipulación de ácidos nucleicos, cuyas aplicaciones superan con creces la utilización implementada inicialmente para la proteína Cas9 de Streptococcus pyogenes como editor del ADN. En un intento de paliar las limitaciones encontradas en el uso de la Cas9 de S. pyogenes, que sigue siendo la herramienta CRISPR más empleada, el repertorio de nucleasas Cas disponibles ha aumentado considerablemente en los últimos años, en particular las pertenecientes a la clase 2. La actividad de corte inespecífico fuera de la diana, el requerimiento de un motivo concreto adyacente a la diana y su gran tamaño, que limita su administración celular, han motivado la búsqueda de nuevas nucleasas en datos genómicos y metagenómicos, así como la generación de variantes derivadas de proteínas nativas mediante evolución dirigida o ingeniería de proteínas. En la presente tesis, llevamos a cabo una búsqueda de sistemas CRISPR–Cas de clase 2 a partir de 10 metagenomas provenientes de tres ambientes previamente inexplorados en este sentido, dando como resultado la identificación de 107 sistemas pertenecientes a alguno de los subtipos descritos hasta la fecha. El análisis de las características de las proteínas Cas encontradas y su relación evolutiva con otras ortólogas empleadas en edición genética nos llevó a la selección de 9 candidatas para su caracterización funcional. Entre todas ellas, la proteína EH6Cas9 mostró actividad nucleasa sobre secuencias diana de ADN en E. coli, adyacentes al motivo 5’-NGG-3’. Con el fin de desarrollar una nueva herramienta de biología molecular, la simplificación del sistema nos llevó a diseñar un ARN guía sintético compatible con EH6Cas9. La caracterización bioquímica de la herramienta demostró que EH6Cas9 es una ADNasa metal dependiente, programable mediante guías de ARN, que muestra su máxima actividad frente a dianas adyacentes a la secuencia consenso 5’-NGGDT-3’ a temperaturas entre 25 °C y 37 °C. Finalmente, EH6Cas9 también demostró su aplicabilidad como herramienta de edición genética. En E. coli, EH6Cas9 mostró una gran eficacia como estrategia para la selección positiva de mutantes, mientras que en células de ratón indujo la formación de inserciones y deleciones en una secuencia diana, presentando características distintivas respecto a la Cas9 de S. pyogenes que la hacen especialmente indicada para aplicaciones de edición genética en eucariotas en las que se requiera una actividad nucleasa moderada y más restringida. CRISPR–Cas Cas9 Cas12 Edición genética
65	The Effect of Using CRISPR/Cas9 Treatment to Delete the Myostatin Protein In Vivo and In Vitro Cardone, Marco 01 January 2020 (has links) This thesis proposal shows the efficiency of different methods of Myostatin inhibition by using CRISPR/CAS9. With the data cataloged by this thesis, researchers will have a better understanding of what methods are better to achieve their goals. The data was collected by reading multiple scientific articles involving the usage of CRISPR/CAS9 to inhibit the Myostatin protein. The data collected from all the different studies were analyzed in the same categories. The experiment that used CRIPSR/CAS9 on in vitro specimens had a superior Myostatin inhibition overall, therefore presenting higher muscle mass. The method using CRISPR/CAS9 to inhibit the Myostatin in vivo and in vitro depends on what the researcher is trying to accomplish. By reading this thesis researchers can understand that if they choose to use an in vitro treatment the results would be way more severe than using an in vivo application treatment. CRISPR CAS9 MYOSTATIN MUSCLE INHIBITION Genetics and Genomics
66	Novel methods for detecting glycan receptors for influenza A virus and exploration of the function of the sialyltransferases on influenza viral infection Jiang, Kaijun 09 August 2019 (has links) Sialic acids (Sias) are receptors for influenza A viruses (IAVs). The influence of individual sialyltransferases on the Sias expressed is not understood. Also, sensitive methods to distinguish Sias on the cells are lacking. Our goals were to establish a method to detect Sias on the cell and to evaluate the importance of CMP-sialic acid transporter (SLC35A1) and ST6 beta-galactoside alpha-2,6-sialyltransferase 1 (ST6GAL1) for IAV infection. Aproximity ligation assay was established to detect and quantify Sias. Influenza virus silica acid receptor CRISPR PLA
67	Functional analysis of tcf21 and tbx20 in zebrafish Burg, Leonard January 2020 (has links) In response to cardiac cell death from an injury, zebrafish, as opposed to mammals, are able to regenerate new heart cells without significant scar tissue. Heart attacks, a leading cause of death in the United States, leave behind substantial scar tissue that weakens the heart and leads to a greater chance of a repeated cardiac event. Many genes and major molecular pathways are highly conserved from fish all the way to humans; thus, understanding how the regenerative process works in zebrafish may provide insight into potential therapies for heart attacks in humans. However, we must first understand how heart regeneration occurs in zebrafish at the molecular level. From the time of injury to a zebrafish heart through the completion of regeneration, we want to build a regulatory network showing which genes are up- or down-regulated and how they are interconnected. Transcription factors, such as tcf21 and tbx20, bind to regulatory elements of DNA and can either upregulate or downregulate nearby genes. To build this gene regulatory network, scientists use a technique called ChIP-seq that can determine where in the genome these transcription factors bind. Nearby genes are potential targets of their regulation, and we can validate these enhancers by testing differences in expression using a fluorescent protein reporter construct. ChIP-seq requires high quality antibodies capable of specifically recognizing the transcription factor of interest. These are rarely available. Because each different antibody that is used requires validation and optimization for ChIP-seq, it is not easy to scale up the collection of data for different transcription factors. One way to get around these problems is to express a tagged version of the transcription factor. The tag is recognizable by the same antibody; however, expressing the tagged transcription factor in this manner almost inevitably results in higher than normal levels of expression, leading to false positives in the ChIP-seq data. Using CRISPR/Cas9 technology to target and modify specific sequences in the genome, we developed a novel method to add an epitope tag to these transcription factors at their endogenous loci. This allows us to run ChIP-seq experiments with the transcription factor at physiological levels of expression. We can also use the same antibody to eliminate repeated validation and optimization steps. We have successfully tagged two genes that may be involved in heart regeneration, tcf21 and tbx20. tcf21 is expressed in the developing epicardium and is required for the proper development of the branchial arches. tbx20 is expressed in the cardiomyocytes and is required for the proper development of the heart, and it has also been shown to be upregulated in response to injury in the zebrafish. With tbx20, we have performed a successful ChIP-seq experiment and have tested several promising target genes. It is difficult to test if either tcf21 or tbx20 is required for regeneration, as both of these genes are essential for development and mutants do not survive. The solution to this problem is to engineer the gene so that it can be turned off at a specific time and in a specific cell type. A common method of this in the mouse model utilizes the Cre/loxP system: two loxP sites flank a required segment of a gene, and the introduction of the enzyme Cre deletes the DNA between them. Until CRISPRs this was not feasible in zebrafish, which lacked an efficient method of targeted modification in the genome. We adapted our method for integrating epitope tags to add the two loxP sites in the genome. We have made and tested a fully conditional mutant for tbx20, and we have put in the first of the two loxP sites for tcf21. / Biology Biology Genetics Conditional Mutagenesis Crispr Heart Zebrafish
68	Regulation of encystation in Giardia intestinalis Wochinger, Yevgeniya January 2024 (has links) Giardia intestinalis is a unicellular protozoan parasite, causing giardiasis – a gastro-intestinal disease of variable outcome and severity, in a broad range of mammalian species. The parasite has a comparatively simple life cycle with two stages, proliferative trophozoites and infectious cysts, as well as a reduced set of eukaryotic-specific organelles. Its metabolic pathways are simplified if compared to non-parasitic organisms. Giardia compensates for this apparent simplicity with unique inventions and complex regulation of metabolic processes. Transition from a fragile trophozoite to a protected, compact cyst is called encystation. This process starts upon changes in the growing conditions: cholesterol deprivation and elevated pH, and leads to changes in membrane lipids, elevated cAMP, and induction of encystation-specific gene expression, starting with activation of Myb-like protein expression. Within hours postencystation induction, cyst wall components (GalNAc and CWPs) are produced and transported to the cell membrane, flagella and adhesive disc are disassembled and stored in cytoplasm, followed by DNA replication and diplomixis. One of the encystation-specific upregulated genes in Giardia (assemblage A, isolate WB) is GL50803_1470 (termed ORF1470). Its predicted protein product has an Alba_2 domain, binding nucleic acids, presumably DNA. To study its function in G. intestinalis, we created knockout mutants, using CRISPR/Cas9 technique, Cas9- HA cell line and pGdelp-BbsI-B00826, with integrated pac- and gRNA cassettes. Transfected Giardia Cas9-HA cells were PCR verified for the complete knockout of the gene, encysted, and effect of ORF1470 was studied using cyst counting, morphometric analysis, cell imagining and Western blot for detection of CWPs. We have found minor phenotypical differences between the parental strain Cas9-HA and wild-type WB and ORF1470 deficient cells. Future plans are further experiments with obtained ΔORF1470 strains including further KO verification, visualization of ORF1470 product during encystation and determination of its binding site in the genome using ChIP-seq technology. Giardia CRISPR/Cas9 encystation ORF1470 Microbiology Mikrobiologi
69	Functional analysis of Poplar genes regulating flowering and vegetative growth Mahendra, Rienzy Ayeshan Rangajeewa 24 June 2019 (has links) Poplar (Populus spp. and hybrids) are used for pulp, paper and solid wood products. Furthermore, poplar is being developed as a dedicated biomass crop for biofuels and biomaterials. Thus, methods to accelerate genetic improvement to improve woody biomass yield, quality and optimal growth on marginal lands are of considerable interest. One approach is to identify genes that could be manipulated through breeding or biotechnology to achieve these goals. I studied two sets of candidate genes for improving biomass, growth and manipulating flowering time. First, I studied the functions of PopNAC154 and PopNAC156, co-orthologs of Arabidopsis SECONDARY CELL WALL NAC DOMAIN2 (SND2), which are putative regulators of wood cell wall synthesis, the source of lignocellulosic biomass. Second, I studied PopCEN1, PopCEN2, and PopBFT, members of the TERMINAL FLOWER1 (TFL1)/CENTRORADIALIS (CEN) gene family that act as flowering repressors in Arabidopsis and many plants. I studied INRA 717-1B (P. tremula x P. alba) transgenics with an artificial microRNA (AmiRNA) downregulating PopNAC154 and PopNAC156 (AmiSND2 trees). In a field trial, AmiSND2 trees showed higher mean height and diameter than wild-type (WT). We also observed that AmiSND2 transgenics showed delayed leaf senescence and leaf drop. After conducting controlled environment studies with AmiSND2 trees, I was able to confirm that downregulation of PopNAC154 and PopNAC156 genes does not alter the short daylength-induced bud set and growth cessation but it delays the low temperature induced leaf senescence and leaf drop. Further I was able to show that down regulation of the PopNAC154 and PopNAC156 genes resulted in significantly higher mean plant heights and delayed bud set compared to the WT plants under low soil nutrient conditions. Wood chemistry data analysis of field grown AmiSND2 trees showed that they have a significantly higher cellulose content a lower lignin content compared to that of the WT. Thus, these results show that downregulating the PopNAC154 and PopNAC156 genes has the potential to increase biomass yield and quality. In a previous study, simultaneous downregulation of PopCEN1 and PopCEN2 genes using RNA interference (RNAi) method caused poplar trees to flower only after two years of growth in the field. I used CRISPR/CAS9 method to knock-out each paralog individually as well as the related gene, PopBFT. The popcen1 mutant trees developed flowers even under in vitro conditions, but popcen2 mutants did not show an obvious phenotype. popbft mutant trees also did not show an obvious phenotype under standard growing conditions. However, when soil nutrient availability was allowed to deplete, the popbft mutants showed lower mean plant height compared to the WT and also showed lower root length and root volume under low Nitrogen conditions in an in vitro assay compared to the WT. These results prove that PopCEN1 gene is directly involved in repressing flowering in poplar and allele-specific mutation should be tested as an approach to accelerate breeding. PopCEN2 and PopBFT might not have a role in regulation of flowering time, and though additional studies are needed, PopBFT appears to have a role in regulating growth in response to nutrient availability. / Master of Science / Poplar (Populus spp. and hybrids) are used for pulp, paper and solid wood products. Furthermore, poplar is being developed as a dedicated biomass crop for biofuels and biomaterials. Genes control the woody biomass yield, and quality among all the other characteristics, thus, methods to accelerate genetic improvement to improve these characteristics is paramount. One approach is to identify genes that could be manipulated through breeding or biotechnology to achieve these goals. I studied two sets of candidate genes for improving biomass, growth and manipulating flowering time. First, I studied the functions of PopNAC154 and PopNAC156, genes which are putative regulators of wood cell wall synthesis, the source of lignocellulosic biomass. Second, I studied PopCEN1, PopCEN2, and PopBFT, genes that act as flowering repressors in Arabidopsis and many plants. I studied a genetically modified poplar, where PopNAC154 and PopNAC156 genes’ function were reduced. After subjecting these plants to shorter daylength periods and cold temperatures in controlled conditions I was able to show that decreased activity of the PopNAC154 and PopNAC156 genes causes the trees to slowdown the leaf senescence and retain their leaves under low temperature conditions compared to the genetically unaltered wildtype (WT) poplar. I was also able to show that decreased activity of the PopNAC154 and PopNAC156 genes allow the poplar plants to grow better than the WT plants under low soil nutrient conditions. I used gene editing to switch off PopCEN1, PopCEN2, and PopBFT genes. When PopCEN1 gene was switched off individually the young mutant trees flowered whereas normally trees take six to eight years to flower. However, when the PopCEN2, and PopBFT genes were switched off individually the resulting mutant plants did not show any signs of flowering. Hence, I was able to show that PopCEN1 gene is directly involved in repressing the flowering in poplar plants. In conclusion, my work identified PopNAC154 and PopNAC156 as candidate genes for manipulation by breeding or biotechnology to increase wood yield, and suggested ways to induce flowering to accelerate breeding through manipulation of PopCEN1. PopNAC154 PopNAC156 PopCEN1 PopCEN2 PopBFT CRISPR/CAS9
70	CRISPR-Hybrid: A CRISPR-mediated intracellular selection platform for RNA aptamers Su-Tobon, Qiwen January 2024 (has links) Thesis advisor: Jia Niu / In the last ten years, programmable CRISPR-Cas systems have been widely-used as genome editing tools for gene manipulation, epigenetic functionalization, and transcriptional regulation. Among them, fusing effector proteins directly to the Cas protein allows the resulting CRISPR machinery to direct these effector proteins to multiple sites of the same gene or multiple genes at once. Although they can be used to target multiple genetic loci simultaneously, these methods are often limited to applying one regulatory function (e.g., activation or repression) at a time. On the other hand, recruiting effector proteins via RNA aptamer-RNA-binding protein (RBP) recognition enabled multiplexed and multi-modular gene manipulations simultaneously. However, there are only a limited set of aptamer-RBP pairs that can function orthogonally and intracellularly, e.g., MS2 RNA aptamer with MS2 coat protein (MCP), and PP7 RNA aptamer with PP7 coat protein (PCP). The scarcity of orthogonal intracellular aptamer-RBP pairs imposes severe constraints on the CRISPR-mediated multifunctional manipulations of the genome and the epigenome. We established an intracellular selection platform for RNA aptamers, named CRISPR-Hybrid, and expanded the scope of aptamer-RBP toolkit for CRISPR transcription regulators. Using CRISPR-Hybrid, we successfully identified a highly active and specific aptamer for bacteriophage Qβ coat protein (QCP) in vivo, and characterized its binding affinity and specificity in vitro. We further validated the orthogonality of selected aptamer with QCP to other available intracellularly functional aptamer-RBP pairs including MS2-MCP and PP7-PCP in mammalian cells. Finally, we demonstrated the utility of this orthogonal pair in multiplexed and multi-modular regulations of endogenous genes. / Thesis (PhD) — Boston College, 2024. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry. aptamer CRISPR gene editing in vivo selection

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