Project description:Tumors represent dynamically evolving populations of mutant cells, and many advances have been made in understanding the biology of their progression. However, key unresolved questions remain about the conditions that support their initial transformation, which cannot be easily captured in patient populations but are instead modeled using transgenic cellular or animal systems. Here, we used extensive patient atlas data to define common features of the tumor DNA methylation landscape as they compare to healthy human cells and used this benchmark to screen 21 engineered human and mouse models for their ability to reproduce these patterns. Notably, we find that genetically induced cellular transformation can trigger global changes in DNA methylation levels that are consistent with extensive proliferation but rarely recapitulate the widespread de novo methylation of Polycomb targets as found in clinical samples. Our results raise pertinent questions about the relationship between genetic and epigenetic aspects of tumorigenesis and provide an important molecular reference for evaluating existing as well as newer tumor models.

Project description:Direct genetic transformation bypasses tumor-associated DNA methylation alterations

Project description:Direct genetic transformation bypasses tumor-associated DNA methylation alterations (RRBS)

Project description:Direct genetic transformation bypasses tumor-associated DNA methylation alterations (target enrichment)

Project description:Inter-individual variability in DNA methylation has been hypothesized to contribute to complex phenotypes through epigenetic modulation of gene expression levels. Population epigenetic studies have been examining differences in DNA methylation in a variety of accessible tissues for association with specific diseases or exposures, but relatively little is known about how this inter-individual variation differs between tissues. This study presents an analysis of global DNA methylation differences between matched peripheral blood mononuclear cells and buccal epithelial cells; specifically it examines differential DNA methylation, probe-wise DNA methylation variance, and how methylation relates to a number of demographic factors across the two tissues. We found that peripheral blood mononuclear cells have overall higher DNA methylation than buccal epithelial cells, and regions of the genome that are differently methylated between the tissues tend to have low CpG density. We also discovered that although both tissues show extensive probe-wise variability, the specific regions and magnitude of variability differed between tissues. Finally, we observed that while both buccal epithelial and peripheral mononuclear blood cell DNA methylation was associated with gender, only methylation of the latter was associated with body mass index. The work presented here offers insight into variability of DNA methylation between individuals and across tissues and the suitability of buccal epithelial and peripheral mononuclear cells for the biological questions explored by epigenome-wide association studies in human populations. This cohort consist of genomic DNA extracted from the peripheral blood mononuclear cells and buccal epithelial cells of 25 individuals, bisulphite converted and hybridized to the Illumina GoldenGate Methylation Cancer Panel for genome wide DNA methylation profiling

Project description:Plants of different ploidy levels are separated by a strong postzygotic hybridization barrier that is established in the endosperm. Deregulated parent-of-origin specific genes are causal for the response to interploidy hybridizations, revealing an epigenetic basis of this phenomenon. In this study we present evidence that paternal hypomethylation can bypass the interploidy hybridization barrier by alleviating the requirement of the epigenetic Polycomb Repressive Complex 2 (PRC2) in the endosperm. Bypass of the barrier is mediated by suppressed expression of imprinted genes. We show that hypomethylated pollen causes redistribution of CHG methylation to PRC2 target genes, revealing that different epigenetic modifications can functionally substitute for each other. Our work presents a method and the underlying mechanism for the generation of viable triploids, providing an impressive example for the potential of epigenome manipulations for plant breeding. Examination of DNA methylation in Arabidopsis endosperm, embryo, and pollen, and gene expression in seeds

Project description:Inter-individual variability in DNA methylation has been hypothesized to contribute to complex phenotypes through epigenetic modulation of gene expression levels. Population epigenetic studies have been examining differences in DNA methylation in a variety of accessible tissues for association with specific diseases or exposures, but relatively little is known about how this inter-individual variation differs between tissues. This study presents an analysis of global DNA methylation differences between matched peripheral blood mononuclear cells and buccal epithelial cells; specifically it examines differential DNA methylation, probe-wise DNA methylation variance, and how methylation relates to a number of demographic factors across the two tissues. We found that peripheral blood mononuclear cells have overall higher DNA methylation than buccal epithelial cells, and regions of the genome that are differently methylated between the tissues tend to have low CpG density. We also discovered that although both tissues show extensive probe-wise variability, the specific regions and magnitude of variability differed between tissues. Finally, we observed that while both buccal epithelial and peripheral mononuclear blood cell DNA methylation was associated with gender, only methylation of the latter was associated with body mass index. The work presented here offers insight into variability of DNA methylation between individuals and across tissues and the suitability of buccal epithelial and peripheral mononuclear cells for the biological questions explored by epigenome-wide association studies in human populations.

Project description:We intend to establish an efficient method for plasma cfDNA extraction and Bisulfite transformation to facilitate the detection of DNA methylation status using multiplex fluorescence PCR. Meanwhile, we expect to identify several plasma methylation markers that can be highly sensitive for multi-cancer detection. Finally, we will provide a pan-cancer blood test that is easy to operate, low cost, accurate and easy to promote.

Project description:We present cell line SET-2 as potential model system for DNA methylation analysis. This cell line was established from a patient with essential thrombocythemia at megakaryoblastic transformation and carries the JAK2 V617F mutation. Cell line SET-2 carries the DNMT3A R882H mutation, recurrent in cytogenetically normal AML.

Project description:Real-world networks are neither regular nor random, a fact elegantly explained by mechanisms such as the Watts-Strogatz or the Barabási-Albert models, among others. Both mechanisms naturally create shortcuts and hubs, which while enhancing the network's connectivity, also might yield several undesired navigational effects: They tend to be overused during geodesic navigational processes-making the networks fragile-and provide suboptimal routes for diffusive-like navigation. Why, then, networks with complex topologies are ubiquitous? Here, we unveil that these models also entropically generate network bypasses: alternative routes to shortest paths which are topologically longer but easier to navigate. We develop a mathematical theory that elucidates the emergence and consolidation of network bypasses and measure their navigability gain. We apply our theory to a wide range of real-world networks and find that they sustain complexity by different amounts of network bypasses. At the top of this complexity ranking we found the human brain, which points out the importance of these results to understand the plasticity of complex systems.