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Gene packaging tells story of cancer development
December 05, 2008To decipher how cancer develops, Johns Hopkins Kimmel Cancer Center investigators say researchers must take a closer look at the packaging.
Specifically, their findings in the December 2, 2008, issue of PLoS Biology point to the three dimensional chromatin packaging around genes formed by tight, rosette-like loops of Polycomb group proteins (PcG). The chromatin packaging, a complex combination of DNA and proteins that compress DNA to fit inside cells, provides a repressive hub that keeps genes in a low expression state.
"We think the polycomb proteins combine with abnormal DNA methylation of genes to deactivate tumor suppressor genes and lock cancer cells in a primitive state," says Stephen B. Baylin, M.D., Virginia and D.K. Ludwig Professor of Oncology and senior author.
Prior to this discovery, investigators studying cancer genes, looked at gene silencing as a linear process across the DNA, as if genes were flat, one dimensional objects. Research did not take into account the way genes are packaged.
To better understand the role of the PcG packaging, the team compared embryonic cells to adult colon cancer cells. The gene studied in the embryonic cells was packaged by PcG proteins, in a low expression state, and had no DNA methylation. When the gene received signals for cells to mature, the PcG loops were disrupted and the gene was highly expressed. However, when the same gene was abnormally DNA methylated, as is the case in adult, mature colon cancer cells, the PcG packaging loops were tighter and there was no gene expression. "These tight loops touch and interact with many gene sites folding it into a structure that shuts off tumor suppressor genes," says Baylin. However, when the researchers removed DNA methylation from the cancer cells, the loops loosened somewhat, back to the state of an embryonic cell, and some gene expression was restored.
DNA methylation is a normal cellular process, but when it goes awry and genes are improperly methylated, it can shut down important tumor suppressing cell functions.
Demethylating agents, drugs that target and remove abnormal DNA methylation from genes, have been introduced as potential new cancer therapies. For these therapies to be fully effective, Baylin says, researchers may also need to look for agents that disrupt PcG loops.
Johns Hopkins Medical Institutions
Prior to this discovery, investigators studying cancer genes, looked at gene silencing as a linear process across the DNA, as if genes were flat, one dimensional objects. Research did not take into account the way genes are packaged.
To better understand the role of the PcG packaging, the team compared embryonic cells to adult colon cancer cells. The gene studied in the embryonic cells was packaged by PcG proteins, in a low expression state, and had no DNA methylation. When the gene received signals for cells to mature, the PcG loops were disrupted and the gene was highly expressed. However, when the same gene was abnormally DNA methylated, as is the case in adult, mature colon cancer cells, the PcG packaging loops were tighter and there was no gene expression. "These tight loops touch and interact with many gene sites folding it into a structure that shuts off tumor suppressor genes," says Baylin. However, when the researchers removed DNA methylation from the cancer cells, the loops loosened somewhat, back to the state of an embryonic cell, and some gene expression was restored.
DNA methylation is a normal cellular process, but when it goes awry and genes are improperly methylated, it can shut down important tumor suppressing cell functions.
Demethylating agents, drugs that target and remove abnormal DNA methylation from genes, have been introduced as potential new cancer therapies. For these therapies to be fully effective, Baylin says, researchers may also need to look for agents that disrupt PcG loops.
Johns Hopkins Medical Institutions
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DNA Methylation: Methods and Protocols (Methods in Molecular Biology) by Jörg Tost (Editor) Over the past few years, DNA methylation technologies and our knowledge of DNA methylation patterns have been advancing at a breathtaking pace. Due to this fact, DNA Methylation: Methods and Protocols, Second Edition completely revises, updates, and expands upon the popular first edition with the most current novel techniques, easier to use and more refined by the tested experience of leading experts. This revision reflects contemporary study of the subject: the analysis of gene-specific DNA methylation patterns has been complemented by genome-wide approaches, and epigenomics takes a central place. Written in the highly successful Methods in Molecular Biology™ series format, the chapters in this volume present brief introductions to the topics, lists of the necessary materials and... |
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DNA Methylation Microarrays: Experimental Design and Statistical Analysis (Chapman & Hall/Crc Biostatistics Series) by Sun-Chong Wang (Author), Art Petronis (Author) Providing an interface between dry-bench bioinformaticians and wet-lab biologists, DNA Methylation Microarrays: Experimental Design and Statistical Analysis presents the statistical methods and tools to analyze high-throughput epigenomic data, in particular, DNA methylation microarray data. Since these microarrays share the same underlying principles as gene expression microarrays, many of the analyses in the text also apply to microarray-based gene expression and histone modification (ChIP-on-chip) studies. After introducing basic statistics, the book describes wet-bench technologies that produce the data for analysis and explains how to preprocess the data to remove systematic artifacts resulting from measurement imperfections. It then explores differential methylation and... |
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DNA Methylation: Approaches and Applications by Manel Esteller (Editor) Understanding the complex roles of DNA methylation is currently an active field of research. DNA Methylation: Approaches and Applications presents the most current research on the impact of DNA methylation in human disease, particularly cancer. Written by leaders in the field, this state-of-art reference delineates the best techniques to use when addressing questions concerning the cytocine methylation status of genomic DNA. It includes concepts, experimental models, and clinical uses of demethylating agents. The book provides a balance between articles clarifying methodological details and more general review chapters that offer broad biological perspectives on DNA methylation. |
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DNA Methylation in Plants (Nova Biomedical) by Boris F. Vanyushin (Editor), Vasili V. Ashapkin (Editor) A high degree of nuclear DNA (nDNA) methylation is a specific feature of plant genomes, they do contain 5-methylcytosine (m5C) and N6-methyl adenine (m6A). More than 30 per cent m5C is located in CNG sequences. Specific changes in DNA methylation accompany the entire life of a plant starting from seed germination up to the death programmed or induced by various agents and factors of biological or abiotic nature. Modulation of DNA methylation is one of the possible modes of the hormonal action in plant. DNA methylation in plants is species-, tissue-, organelle- and age-specific; it is involved in the control of all genetic functions including transcription, replication, DNA repair, gene transposition and cell differentiation.DNA methylation is engaged in gene silencing and parental... |
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DNA Methylation Protocols (Methods in Molecular Biology) by Ken I. Mills (Editor), Bernie H. Ramsahoye (Editor) Univ. of Wales, Cardiff, UK. Covers new techniques currently available in the analysis of DNA methylation and methylases. For researchers. |
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Molecular Biology of DNA Methylation (Springer Series in Molecular Biology) by Roger L. P. Adams (Author), Roy H. Burdon (Author) | |
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Biochemistry and biology of DNA methylation: Proceedings of a Fogarty International Center conference held in Bethesda, Maryland, April 17-19, 1985 (Progress in clinical and biological research) by Liss (Publisher) | |
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