Imaging Cell Lineage with a Synthetic Digital Recording System

Author: Edmonds, KeHuan Kuo

Year: 2022

Degree: Dissertation (Ph.D.)

Advisor: Elowitz, Michael B.

Committee Members: Hay, Bruce A.; Elowitz, Michael B.; Lois, Carlos; Sternberg, Paul W.; Cai, Long

Option: Biology

DOI: 10.7907/a4m3-m603

Abstract

In multicellular organisms, the lineage history and spatial organization of cells both play pivotal roles in cell fate determination during development, homeostasis, and disease. Investigating lineage relationships alongside cell state and space would provide a fundamental understanding of these biological processes. Current lineage tracking approaches rely on the progressive accumulation of either naturally-occurring somatic mutations or experimentally introduced markers. In most cases, these marks are then read out by sequencing, discarding the spatial information of the cells. To address this vital gap in our toolkit, we developed a new synthetic lineage tracking system that allows us to image single-cell lineage history. This system, termed integrase-editable memory by engineered mutagenesis with optical in situ readout (intMEMOIR), uses serine integrases to stochastically and irreversibly edit a synthetic memory array, generating up to 59,049 different outcomes that can be unambiguously distinguished by fluorescence in situ hybridization (FISH). We evaluated the reconstruction accuracy of our system in mouse embryonic stem (mES) cells and disentangled the relative contribution of lineage and space to cell fate determination in Drosophila brain development, establishing the foundation for an expandable synthetic microscopy-readable system. In this thesis, Chapter 1 introduces the importance of cell lineage and spatial organization to cell fate determination, and includes a brief history of the existing technologies of the lineage tracking field. Chapter 2 describes our characterization and demonstration of the intMEMOIR system. Finally, Chapter 3 discusses design principles for robust, serine-integrase-based recording systems and suggests future directions for intMEMOIR.

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