Chromatin Dynamics in Pluripotency and Differentiation: A Dissertation

Abstract

Different cell types in multi-cellular organisms heritably maintain different gene expression patterns despite carrying the same genome; a phenomenon termed epigenetics. It is widely believed that the packaging state of the genome, known as chromatin structure, carries epigenetic information. How chromatin states are inherited and how chromatin structure changes during development, moreover how different epigenomes, such as chromatin and DNA modifications communicate with each other during these processes are important questions. Accordingly, understanding the mechanisms that govern pluripotency and differentiation requires details of chromatin dynamics. The major goal of my doctoral thesis was to understand the genome wide view of chromatin dynamics in embryonic stem cells. My studies centered on two aspects of chromatin dynamics in mouse embryonic stem cells—localization and function of two antagonistic chromatin regulators and genome-wide histone variant dynamics. In the first part, we examined the roles of several chromatin regulators whose loss affects the pluripotent state of ES cells. We found that two such regulators, Mbd3 and Brg1, control a large number of genes in ES cells via antagonistic effects on promoter nucleosome occupancy. Moreover, we found that both Mbd3 and Brg1 play key roles in the biology of 5-hydroxymethylcytosine (5hmC), a newly identified DNA modification. Mbd3, which was named by homology to known cytosine methyl binding domains, yet does not bind methylcytosine in vitro, co-localized in ES cells with 5hmC. Furthermore, Mbd3 localization was lost in knockdown cells lacking the major 5mC hydroxylase, Tet1. Our results suggest, contrary to current dogma, that 5hmC is more than just an intermediate in cytosine demethylation pathways, that it may regulate genes via the Mbd3/NuRD complex. Finally, we showed that both Mbd3 and Brg1 are themselves required for normal levels of 5hmC in vivo, identifying a feedback loop between 5hmC and Mbd3. Together, our results identified a possible effector for 5hmC, thereby suggesting a functional role for this DNA modification. Moreover, Brg1 and Mbd3 can now be added to the growing list of regulators with opposite effects on ES cell gene expression, suggesting that pairs of antagonistic chromatin binding proteins may be a common phenomenon in ES cell transcription regulation (Yildirim et al., Cell 2011). The second part of my dissertation concerns the dynamics of several histone variants. Seminal studies in the Henikoff lab showed that certain histone variants are replaced throughout the cell cycle, in contrast to the predominant replication-coupled mode of histone assembly. Work in yeast and flies showed that rapid histone turnover occurs at epigenetically-regulated genomic regions, such as chromatin boundary elements or Polycomb/Trithorax binding sites. Notably, promoter regions of actively transcribed genes exhibit rapid turnover, suggesting that histone turnover may have an important role in gene regulation,…