The goal of this project is to define the genetic and epigenetic signature that distinguishes human primordialgerm cells (PGCs) from human embryonic stem cells (hESCs) with a specific focus on trimethylation (me3)of histone H3 lysine (K) 27, and function of the Polycomb Group (PcG) proteins on PGC formation. HumanESCs are the only genetically malleable human cell-based model for examining human germ cell formation.Germ cell derivation from the epiblast requires a delicate balance involving expression of pluripotent genes(such as NANOG and OCT4), suppression of somatic genes (such as HOXB1 and BRACHYURY) andfunctional unipotency to exclusively form gametes. Loss of germ line unipotency results in germ celltumorigenesis. Therefore, disruption of the balance of factors that regulate germ cell derivation results inadverse clinical outcomes. In previous work Dr. Clark has shown that derivation of human germ cells fromhESCs varies between independently derived lines. Her preliminary data now reveals that this can becorrelated with differences in transcription of germ cell specific genes in undifferentiated ESCs as well asdifferential methylation of H3K27me3 at promoters of germ cell-expressed loci. In this Project, Dr Clark willcontinue her research on the role of the PcG proteins and H3K27me3 in modulating PGC formation in thefollowing specific Aims: 1) Evaluating H3K27me3 and X reactivation during PGC development in two lines offemale hESCs; 2) Deciphering the genome wide localization of H3K27me3 in four lines of hESCs, and PGCsderived from hESCs, and 3) Determining the function of the PcG repressive complex (PCR2) in PGCformation in four independently derived lines of hESCs. Sharing results on germ cell formation from hESCswith Projects 1 and 3 are essential to understanding hESC potential because the ability to form germ line issimultaneously reversed to form neural and hematopoietic lineages (loss of pluripotency and activation ofsomatic cell transcriptional programs). Thus identification of hESC lines that are capable of both faithfulgerm cell formation and robust somatic cell differentiation would constitute the best developmental modelsand therapeutic tools for future research.
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