PUCK: Primer Utilised CRISPR/Cas Knock-Ins for High Throughput Super-Resolution Microscopy

Dohrke, Jan-Niklas

von Jan-Niklas Dohrke

Dissertation

Datum der mündl. Prüfung:2024-11-06

Erschienen:2024-11-29

Betreuer:Prof. Dr. Stefan Jakobs

Gutachter:Prof. Dr. Stefan Jakobs

Gutachter:Prof. Dr. Peter Rehling

Zum Verlinken/Zitieren: http://dx.doi.org/10.53846/goediss-10892

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Name:Dissertation_Dohrke_11_11_24.pdf

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Description:Dissertation

Diese Datei ist bis 05.11.2025 gesperrt.

Zusammenfassung

Englisch

The insertion of tags into proteins via gene editing is a powerful tool for microscopy, enabling the comparative analysis of different proteins. The advent of CRISPR/Cas systems has greatly simplified gene editing and improved its success rate. However, current high-throughput CRISPR/Cas screens primarily focus on knock-out or activation screens, with large-scale knock-ins of tag sequences remaining underutilised due to their complexity and resource demands. This study introduces PUCK (Primer Utilised CRISPR/Cas Knock-ins), an innovative method that is cost-effective, rapid, and user-friendly for inserting any tag into any protein sequence, facilitating large-scale knock-ins. A comprehensive platform of robotic protocols was established to execute a pioneering knock-in screen targeting nearly all outer mitochondrial membrane proteins. Additionally, diffraction-unlimited STED microscopy was developed into a high-throughput method for screen evaluation. An advanced analysis pipeline, incorporating optimal-transport-based methods, was also introduced to enhance the reliability of colocalization measurements in high-resolution images. This work underscores the importance of genomic tags in microscopy-based research and establishes PUCK as a new tool for efficient knock-in development and high-throughput screening.

Keywords: Genomic Tagging; CRISPR/Cas; super-resolution microscopy; high-throughput screening; Automation; PCR