CANDIDATE. I am a physician and Instructor in the Division of Reproductive Endocrinology and Infertility at Beth Israel Deaconess Medical Center (BIDMC). A K08 Award will provide me with the necessary training and experience to become an independent investigator in germ cell (GC) biology, with a focus on the gene regulatory networks underlying human gametogenesis. BACKGROUND. How a small subset of cells in the developing human and non-human primate embryo acquires competency to form the germ line and ultimately mature into functional gametes while maintaining its potential for pluripotency is among the least understood questions in biology. In particular, the gene regulatory networks and epigenetic remodeling, which govern competence for the GC fate during specification of early (primordial) germ cells (PGCs) in the peri-gastrulating period, remain unknown. Knowledge of the underlying mechanisms will allow the development of more efficient differentiation protocols for GCs from pluripotent stem cells (PSCs) in vitro. In addition, it will allow the investigation of the link between epigenetic dysregulation during GC specification and critical human disorders such as pregnancy loss, congenital defects and common late-onset diseases such as infertility, diabetes, drug addiction and cancer. RESEARCH. The objective for this K08 is to identify and validate the key gene regulatory elements (GREs) governing induction of competence for the GC fate and the differentiation of PGCs during cynomolgus gastrulation. Our central hypothesis is that epigenetic priming of key GREs in incipient mesoderm mediates developmental competence during germ lineage specification from the pluripotent state. This research will pursue two specific aims: (1) to identify putative GREs underlying developmental competence for the GC fate through epigenetic footprinting (2) to identify the subset of these GREs functioning as key determinants of GC competence and differentiation using massively parallel reporter assays (MPRA) and CRISPR epigenome editing mediated loss of function experiments. In the future, these results will provide the platform to use epigenome editing as a tool to improve the efficiency of GC specification, for trans-differentiation of GCs from somatic cells and to study the effect of epimutations on developmental outcomes in GCs and embryos using animal models. MENTORING. My primary mentor, Dr. Kevin Eggan, is an expert in stem cell biology at the Harvard Stem Cell Center. I have assembled a multi-disciplinary mentoring team across the Harvard network: Dr. Alex Meissner (an expert in epigenetics and epigenomics), Dr. Steve McCarroll (a leader in genomics and bioinformatics). TRAINING. The research objectives are supported by a training plan that includes hands-on lab training as well as formal and hands-on didactics in bioinformatics and the analysis of large genomic datasets alongside a strong institutional commitment at BIDMC and the grant review and support program through Harvard Catalyst.
How the germ lineage arises during embryonic development and ultimately generates mature gametes is one of the least understood questions in biology and important for our understanding of developmental defects as well as genetic and epigenetic disorders. Our goal is to define the epigenetic mechanism underlying induction of developmental competence for the germ cell fate and the specification of primordial germ cells during cynomolgus gastrulation to ultimately study the genetic and epigenetic factors affecting human germ line function and their relationship with human disease. Thus, the proposed research is relevant to the NIH?s mission that pertains to ?developing fundamental knowledge that will reduce the burden of birth defects and infertility? and fits several of NICHD?s high priority research areas. ! !
