An organoid CRISPRi screen revealed that SOX9 primes human fetal lung tip progenitors to receive WNT and RTK signals

The balance between self-renewal and differentiation in human fetal lung epithelial progenitors controls the size and function of the adult organ. Moreover, progenitor cell gene regulation networks are employed by both regenerating and malignant lung cells, where modulators of their effects could po...

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Published inbioRxiv
Main Authors Sun, Dawei, Oriol Llora Batlle, Jelle Van Den Ameele, Thomas, John Christopher, He, Peng, Lim, Kyungtae, Tang, Walfred, Xu, Chufan, Meyer, Kerstin B, Teichmann, Sarah A, Marioni, John, Jackson, Stephen P, Brand, Andrea H, Rawlins, Emma L
Format Paper
LanguageEnglish
Published Cold Spring Harbor Cold Spring Harbor Laboratory Press 27.01.2022
Cold Spring Harbor Laboratory
Edition1.1
Subjects
Cell self-renewal
Developmental Biology
Fetuses
Gene regulation
Lungs
Organoids
Progenitor cells
Sox9 protein
Stem cells
Transcription factors
Wnt protein
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ISSN2692-8205
2692-8205
DOI10.1101/2022.01.27.478034

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Abstract The balance between self-renewal and differentiation in human fetal lung epithelial progenitors controls the size and function of the adult organ. Moreover, progenitor cell gene regulation networks are employed by both regenerating and malignant lung cells, where modulators of their effects could potentially be of therapeutic value. Details of the molecular networks controlling human lung progenitor self-renewal remain unknown. We performed the first CRISPRi screen in primary human lung organoids to identify transcription factors controlling progenitor self-renewal. We show that SOX9 promotes proliferation of lung progenitors and inhibits precocious airway differentiation. Moreover, by identifying direct transcriptional targets using Targeted DamID we place SOX9 at the centre of a transcriptional network which amplifies WNT and RTK signalling to stabilise the progenitor cell state. In addition, the proof-of-principle CRISPRi screen and Targeted DamID tools establish a new approach for using primary human organoids to elucidate detailed functional mechanisms underlying normal development and disease. Competing Interest Statement The authors have declared no competing interest.
AbstractList The balance between self-renewal and differentiation in human fetal lung epithelial progenitors controls the size and function of the adult organ. Moreover, progenitor cell gene regulation networks are employed by both regenerating and malignant lung cells, where modulators of their effects could potentially be of therapeutic value. Details of the molecular networks controlling human lung progenitor self-renewal remain unknown. We performed the first CRISPRi screen in primary human lung organoids to identify transcription factors controlling progenitor self-renewal. We show that SOX9 promotes proliferation of lung progenitors and inhibits precocious airway differentiation. Moreover, by identifying direct transcriptional targets using Targeted DamID we place SOX9 at the centre of a transcriptional network which amplifies WNT and RTK signalling to stabilise the progenitor cell state. In addition, the proof-of-principle CRISPRi screen and Targeted DamID tools establish a new approach for using primary human organoids to elucidate detailed functional mechanisms underlying normal development and disease. A pooled CRISPRi screen in human fetal lung organoids identified transcription factors controlling progenitor cell self-renewal. SOX9 promotes tip progenitor cell proliferation and supresses precocious airway differentiation. Targeted DamID (TaDa) identified SOX9 direct binding targets, revealing that SOX9 lies at the intersection of WNT and RTK signalling. SOX9 and ETVs co-regulate the human fetal lung progenitor self-renewal programme.
The balance between self-renewal and differentiation in human fetal lung epithelial progenitors controls the size and function of the adult organ. Moreover, progenitor cell gene regulation networks are employed by both regenerating and malignant lung cells, where modulators of their effects could potentially be of therapeutic value. Details of the molecular networks controlling human lung progenitor self-renewal remain unknown. We performed the first CRISPRi screen in primary human lung organoids to identify transcription factors controlling progenitor self-renewal. We show that SOX9 promotes proliferation of lung progenitors and inhibits precocious airway differentiation. Moreover, by identifying direct transcriptional targets using Targeted DamID we place SOX9 at the centre of a transcriptional network which amplifies WNT and RTK signalling to stabilise the progenitor cell state. In addition, the proof-of-principle CRISPRi screen and Targeted DamID tools establish a new approach for using primary human organoids to elucidate detailed functional mechanisms underlying normal development and disease. Competing Interest Statement The authors have declared no competing interest.
Author Oriol Llora Batlle
Jelle Van Den Ameele
Sun, Dawei
Xu, Chufan
Jackson, Stephen P
Thomas, John Christopher
He, Peng
Meyer, Kerstin B
Rawlins, Emma L
Teichmann, Sarah A
Marioni, John
Lim, Kyungtae
Tang, Walfred
Brand, Andrea H
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Snippet The balance between self-renewal and differentiation in human fetal lung epithelial progenitors controls the size and function of the adult organ. Moreover,...
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SubjectTerms Cell self-renewal
Developmental Biology
Fetuses
Gene regulation
Lungs
Organoids
Progenitor cells
Sox9 protein
Stem cells
Transcription factors
Wnt protein
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Title An organoid CRISPRi screen revealed that SOX9 primes human fetal lung tip progenitors to receive WNT and RTK signals
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