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Active NON-SBIR/STTR RPGS NIH (US)

The Regulatory R-loops in Pluripotency, Early Development, and Tissue Homeostasis

$4.11M USD

Funder NATIONAL INSTITUTE OF GENERAL MEDICAL SCIENCES
Recipient Organization Columbia University Health Sciences
Country United States
Start Date Jul 05, 2024
End Date Apr 30, 2029
Duration 1,760 days
Number of Grantees 1
Roles Principal Investigator
Data Source NIH (US)
Grant ID 10939680
Grant Description

PROJECT SUMMARY R-loops are three-stranded nucleic acid structures composed of an RNA-DNA hybrid and a free single-stranded DNA. The opened DNA strands may lead to DNA damage; thus, R-loops are a risk factor for genome integrity. Improper R-loop accumulation contributes to abnormal human development and diseases. In contrast to the

detrimental effects of R-loops, growing evidence suggests that they also regulate gene transcription, mitosis, and homologous recombination, thus contributing to many fundamental physiological processes. The formation and resolution of R-loops must be tightly regulated. Therefore, the goal for the next five years of my research is

to investigate the mechanisms by which R-loops epigenetically regulate gene transcription in pluripotency, early development, and tissue homeostasis. My unpublished work in mouse ESCs (mESCs) strongly suggests that Zfp281 (human: ZNF281) is an R-loop-dependent transcription factor and recruits Tet1 and Brca2 for DNA

demethylation and DNA damage repair, respectively. We will explore the functions of R-loops as a DNA epigenetic regulator in the mouse naive-formative-primed pluripotent state transition through pathways that include Zfp281/Tet1-mediated R-loop formation for gene activation and Zfp281/Brca2-mediated R-loop

resolution for genome stability. In human development, naive human ESCs (hESCs) have a prolonged developmental plasticity and can differentiate into extraembryonic lineages. My unpublished work showed that ZNF281 is highly enriched in naive hESCs, with a widespread occupation of Polycomb repressive complex 2

(PRC2) and the repressive histone H3K27me3 mark at the extraembryonic master gene loci (e.g., GATA4, CDX2). Therefore, we will investigate the effects of R-loops and ZNF281 on PRC2-repressed low-transcription genes in naive hESCs and their differentiation into the human extraembryonic endoderm and trophectoderm

lineages. Moreover, we will investigate the relationship between DNA damage and genome-wide gains of ZNF281, PRC2, and H3K27me3 in naive hESCs. And last, we will develop a research program to explore R- loop functions in tissue homeostasis and in disease settings. We will focus on B-cell homeostasis, as evidence

shows that aberrant accumulation of R-loops accelerates the progression of diffuse large B-cell lymphoma (DLBCL), a disease originating from the malignant transformation of B-cells in the germinal center. My unpublished work showed that B-cell-specific Zfp281 conditional knockout mice had accumulated pre-/pro-B

cells in the bone marrow and had increased IgG1-expressing activated B-cells in the spleen upon immunization. Using the DLBCL lines and the Zfp281 deficiency mouse model, we will investigate the effects of abnormal R- loop accumulation induced by Zfp281 deficiency on B-cell development and the progression of B-cell lymphoma.

In summary, we aim to establish a coherent view of regulatory R-loops as DNA and histone epigenetic modifiers, as well as a potential risk factor if they are not properly resolved, in different cellular systems.

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Columbia University Health Sciences

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