Dynamics of epigenome and 3D genome in hematopoietic stem cell development

Chen, Changya

15 December 2017

Hematopoietic stem cell (HSC) development is accompanied by dynamic changes in the transcriptional program. How the corresponding transcriptional programs are related to the epigenetic mechanism is poorly understood. To fill this gap, we first profiled the transcriptomes and epigenomes using RNA-Seq and ChIP-Seq for five key developmental stages of HSC emergence in the mouse embryo. Using epigenetic markers, we identified novel 12,000~17,000 enhancers for each developmental stage. We applied a computational tool to link those enhancers to their target genes. Systematical analysis of enhancer-promoter (EP) pairs using network-based strategy reveals multiple novel key transcription factors for early specification of HSC in the mouse embryo. Second, we compared the 3D genome organization, epigenomes, and transcriptome of fetal and adult HSCs in the mouse. We found that higher-order genome structures are largely conserved between fetal and adult HSCs, including chromosomal compartments and topologically associating domains (TADs). However, chromatin interactions within TADs exhibit substantial differences. We found that promoters within 23% (242/1039) of TADs undergo interaction changes. Transcription factor motif analysis of HSC-specific enhancer-promoter loops suggests a role of KLF1 in mediating condition-specific enhancer looping and regulation of genes involved in cell cycle. Our result provides a comprehensive view of the differences in 3D genome organization, epigenome, and transcriptome between fetal and adult HSCs.

ChIP-Seq

enhancer-promoter interaction

epigenetics

genome organization

hematopoietic stem cells

transcriptional program

Genetics

From Population to Single Cells: Deconvolution of Cell-cycle Dynamics

Guo, Xin

January 2012

<p>The cell cycle is one of the fundamental processes in all living organisms, and all cells arise from the division of existing cells. To better understand the regulation of the cell cycle, synchrony experiments are widely used to monitor cellular dynamics during this process. In such experiments, a large population of cells is generally arrested or selected at one stage of the cycle, and then released to progress through subsequent division stages. Measurements are then taken in this population at a variety of time points after release to provide insight into the dynamics of the cell cycle. However, due to cell-to-cell variability and asymmetric cell division, cells in a synchronized population lose synchrony over time. As a result, the time-series measurements from the synchronized cell populations do not accurately reflect the underlying dynamics of cell-cycle processes.</p><p>In this thesis, we introduce a deconvolution algorithm that learns a more accurate view of cell-cycle dynamics, free from the convolution effects associated with imperfect cell synchronization. Through wavelet-basis regularization, our method sharpens signal without sharpening noise, and can remarkably increase both the dynamic range and the temporal resolution of time-series data. Though it can be applied to any such data, we demonstrate the utility of our method by applying it to a recent cell-cycle transcription time course in the eukaryote <italic>Saccharomyces cerevisiae</italic>. We show that our method more sensitively detects cell-cycle-regulated transcription, and reveals subtle timing differences that are masked in the original population measurements. Our algorithm also explicitly learns distinct transcription programs for both mother and daughter cells, enabling us to identify 82 genes transcribed almost entirely in the early G1 in a daughter-specific manner.</p><p>In addition to the cell-cycle deconvolution algorithm, we introduce <italic>DOMAIN</italic>, a protein-protein interaction (PPI) network alignment method, which employs a novel <italic>direct-edge-alignment</italic> paradigm to detect conserved functional modules (e.g., protein complexes, molecular pathways) from pairwise PPI networks. By applying our approach to detect protein complexes conserved in yeast-fly and yeast-worm PPI networks, we show that our approach outperforms two widely used approaches in most alignment performance metrics. We also show that our approach enables us to identify conserved cell-cycle-related functional modules across yeast-fly PPI networks.</p> / Dissertation

Bioinformatics

Computer science

cell cycle

deconvolution

intrinsically disordered regions

protein-protein interaction

transcriptional program