Development of crispr-based programmable transcriptional regulators and their applications in plants
- Autores: Sara Selma García
- Directores de la Tesis: Diego Vicente Orzáez Calatayud (dir. tes.), María Purificación Lisón Párraga (tut. tes.)
- Lectura: En la Universitat Politècnica de València ( España ) en 2022
- Idioma: español
- Tribunal Calificador de la Tesis: Javier Pozueta Romero (presid.), Alberto Carbonell Olivares (secret.), Daniel Matías Zurbriggen (voc.)
- Programa de doctorado: Programa de Doctorado en Biotecnología por la Universitat Politècnica de València
- Materias:
- Enlaces
- Tesis en acceso abierto en: RiuNet
- Resumen
Plant Synthetic Biology aims to redesign plants to acquire novel traits and functionalities through orthogonal regulatory circuits. To achieve this goal, new molecular tools with the capacity of interacting with endogenous factors in a potent and specific manner must be developed. CRISPR/Cas9 emerged as promising tools which combine a customizable DNA-binding activity through the catalytically inactivated version of Cas9 protein (dCas9) with the possibility to anchor autonomous transcriptional activation domains (TADs) to its structure to achieve a specific regulation of the gene expression. The Programmable Transcriptional Activators (PTAs) could act as specific, orthogonal and versatile processor components in the development of new genetic circuits in plants. In search for optimized dCas9-PTAs, a combinatorial evaluation of different dCas9 architectures with a catalogue of various TADs was performed. The best resulting tool of this comparison, named dCasEV2.1, is based on the scRNA strategy and the combination of EDLL and VPR activation domains with a multiplexable gRNA2.1 loop, which is a mutated version of the previously described gRNA2.0. In this work, the dCasEV2.1 programable activator was proved to be a strong and specific tool, achieving higher activation rates than other available dCas9 strategies in plants. Unprecedented activation rates were observed targeting endogenous genes in N. benthamiana, accompanied by strict genome-wide specificity that makes this tool suitable to perform a tight regulation of complex regulatory networks. As a proof of concept, a design of four activation programs to activate different branches of the flavonoid pathway and obtain specific metabolic enrichments in N. benthamiana leaves was performed. The metabolic analysis on the dCasEV2.1 metabolically reprogrammed leaves revealed a selective enrichment of the targeted metabolites and their glycosylated derivatives that correlated with the activation program employed. These results demonstrate that dCasEV2.1 is a powerful tool for metabolic engineering and a key component in genetic circuits aimed at reprogramming metabolic fluxes. Finally, based on dCasEV2.1, we developed an optimized Viral Induced Gene Regulation (VIGR) system that makes use of a Potato Virus X (PVX) vector for the delivery of the gRNA-encoded CRISPR activation programs. This approach offers a way to control the plant transcriptome through a spray-based systemic delivery of CRISPR components to adult plants. The new PVX-VIGR system led to strong transcriptional activation in several endogenous target genes, including three selected MYB-like transcription factors. Specific MYB activations lead to distinctive metabolic profiles, showing that the potential applications of the dCasEV2.1 tool in plants include the obtention of custom metabolic profiles using a spray-based delivery of gRNA-encoded transcriptional reprogramming instructions. In sum, this thesis provides novel tools for strong, orthogonal and programmable transcriptional activation in plants, with an expanded toolbox for the delivery of the activation programs.
