CHAPTER 3 EPIGENETICS OF CANCER
Cancer is a disease involving the failure of function of regulatory genes that control normal cellular homeostasis. The key roles of mutational processes in the generation of human cancer have been identified in the past decades. More recently the potential for epigenetic processes to complement genetic changes has been realized. In addition to multiple mutations, almost all human cancers contain substantial epigenetic abnormalities that cooperate with genetic lesions to generate the cancer phenotype. Epigenetic aberrations arise early in carcinogenesis preceding gene mutations and therefore provide targets for early detection. Epimutations may be reversed by drug treatments, providing the opportunity to design epigenetic therapies. This chapter will describe the role of epigenetic processes in cancer etiology and discuss their potential as biomarkers for early detection of cancer and precancerous lesions and their promise for drug development.
EPIGENETIC PROCESSES Epigenetic processes are essential to ensure the appropriate packaging of the genome to fit within the confines of the mammalian nucleus, while maintaining its functionality. DNA is not found as a naked molecule in the nucleus but is wrapped up in nucleosomes composed of histone octamers and 146 base pairs (bp) of DNA, which are the fundamental building blocks of chromatin. Epigenetics is fundamental to organismal development: pluripotent cells arising at fertilization progressively lose their plasticity as they move through the consecutive differentiation steps necessary for embryogenesis. The recent development of whole epigenome approaches allows for the appreciation of the plethora of epigenomic processes that occur during development and the understanding of their role in activation and silencing of regulatory pathways. The development of “next generation” sequencing approaches coupled with chromatin immunoprecipitation permits assessment of the distribution of the chemical “marks” imparted on the chromatin proteins and DNA. These epigenetic marks include DNA methylation and histone modifications (Table 3.1) and allow the orchestration of activation and silencing pathways. The marks or chemical modifications are placed on the chromatin components by enzymes such as methyltransferases and some of them can be removed by other enzymes (Table 3.1). While we are just beginning to understand the potential roles of specific chemical marks in ensuring the mitotically heritable variation in cell metabolism, which does not involve direct changes in the DNA sequence itself, the key role of a subset of these marks in controlling the potential for gene expression is becoming apparent (Table 3.1). The fundamental process of DNA methylation applies methyl groups to cytosine residues in CpG dinucleotides to form 5-methylcytosine catalyzed by three DNA methyltransferase enzymes (DNMT1, DNMT3a, DNMT3b).1 Methylation
patterns, once established, can be faithfully copied over a protracted period of time. The CpG dinucleotide is asymmetrically distributed in human DNA with about half of human genes containing CpG-rich regions termed “CpG islands” at their transcriptional start sites (TSS). Mostly, CpG islands are not methylated and genes are switched on or off without changing the methylation status of the CpG sites within islands. However, in certain physiologic situations such as X-chromosome inactivation or genomic imprinting, the CpG islands do become methylated in a manner that ensures permanent silencing due to the inherent mitotic heritability of the DNA methylation patterns. In contrast, embryonic stem cells keep genes quiet but poised for later expression during differentiation by using histone marks that are easier to reverse than DNA methylation to accomplish this purpose.2 The histone tails that protrude from the histone octamer, containing 146 bp of DNA in the nucleosome, are also modulated by enzymes and have functional significance for gene expression.3 Acetylation of the lysine residues (particularly lysines 9 and 14) is strongly associated with gene expression and is highly localized to the TSS of genes. The overall level of lysine modification in chromatin is dictated by opposing enzyme functions involving histone acetyltransferases (HATs) and histone deacetylases (HDACs), which apply or remove acetyl groups on lysine residues, respectively. The level of acetylation correlates with the level of expression, and HDACs have received considerable attention as potential drug targets. The TSS of human genes are also marked by the presence of three methyl groups on the lysine 4 residue of histone H3 (H3K4me3). Overexpression of enzymes that attach the methyl groups to this residue has profound implications for human cancer development. Trimethylation of histone H3 lysine 9 (H3K9me3) or lysine 27 (H3K27me3) is associated with gene repression (Table 3.1). The H3K9me3 is applied by several different methyltransferases, including G9a, and is associated with abnormally silenced methylated CpG islands. The H3K27me3 mark is applied by an enzyme of the polycomb repression complex 2, histone-lysine N-methyltransferase (EZH2), and aberrant activity of this enzyme is associated with human cancer development. Figure 3.1 depicts the positions of a small subset of the possible modifications on the histone H3 protein in the context of nucleosomes. Although there are other modifications such as phosphorylation, ubiquitination, and sumolation of this and other histones, the discussion here is restricted to methylation and acetylation, since their function and potential for drug development is currently best understood. The various modifications can be interpreted by other proteins (not shown) sometimes called “readers,” which modify local chromatin structure to either stimulate or repress gene expression. Still other proteins (also not shown), such as histone deacetylases or histone demethylases, can remove the modifications in response to cellular and environmental signals, resulting in a dynamic state.
MOLECULAR BIOLOGY OF CANCER
PETER A. JONES AND KARIN B. MICHELS
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