A PERTURBATION CELL ATLAS OF HUMAN INDUCED PLURIPOTENT STEM CELLS

Overview

Journal bioRxiv

Date 2024 Nov 22

PMID 39574586

Authors

Sami Nourreddine

Yesh Doctor

Amir Dailamy

Antoine Forget

Yi-Hung Lee

Becky Chinn

Hammza Khaliq

Benjamin Polacco

Monita Muralidharan

Emily Pan

Yifan Zhang

Alina Sigaeva

Jan Niklas Hansen

Jiahao Gao

Jillian A Parker

Kirsten Obernier

Timothy Clark

Jake Y Chen

Christian Metallo

Emma Lundberg

Trey Ideker

Nevan Krogan

Prashant Mali

Affiliations

Soon will be listed here.

Abstract

Towards comprehensively investigating the genotype-phenotype relationships governing the human pluripotent stem cell state, we generated an expressed genome-scale CRISPRi Perturbation Cell Atlas in KOLF2.1J human induced pluripotent stem cells (hiPSCs) mapping transcriptional and fitness phenotypes associated with 11,739 targeted genes. Using the transcriptional phenotypes, we created a minimum distortion embedding map of the pluripotent state, demonstrating rich recapitulation of protein complexes, such as strong co-clustering of MRPL, BAF, SAGA, and Ragulator family members. Additionally, we uncovered transcriptional regulators that are uncoupled from cell fitness, discovering potential novel pluripotency (JOSD1, RNF7) and metabolic factors (ZBTB41). We validated these findings via phenotypic, protein-interaction, and metabolic tracing assays. Finally, we propose a contrastive human-cell engineering framework (CHEF), a machine learning architecture that learns from perturbation cell atlases to predict perturbation recipes that achieve desired transcriptional states. Taken together, our study presents a comprehensive resource for interrogating the regulatory networks governing pluripotency.

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