Abstract
Breast cancer is a leading malignancy among women with higher western countries, suggesting significant role for environmental factors in developing breast cancer. Recently, epigenetic modifications such as aberrant methylation and acetylation of genes and histones have been shown to play a critical role in breast cancer development. There are several articles published in the recent years with the major epigenetic signatures of breast cancer genes. Therefore compiling these information could lead to a greater understanding of the development of breast cancer and novel approaches for chemoprevention. Here we have provided different modes of epigenetic regulation including DNA methylation, histone modification, polycomb group of proteins, and non-coding RNAs. In addition, we have provided information on chemotherapeutic drugs that act through regulation of epigenetics and have progressed to clinical trials. Most importantly, we have analyzed the epigenetic regulation in the chemotherapy resistant breast cancer stem cell population. Furthermore, the epigenetic regulatory mechanisms of various breast cancer related genes are discussed in detail. Taken together, in this review we have discussed the current understanding of the modes of epigenetic regulation, and the epigenetic signatures seen in breast cancer.
Access provided by Autonomous University of Puebla. Download chapter PDF
Similar content being viewed by others
Keywords
10.1 Introduction
Breast cancer is a leading malignancy among women, and has long evaded attempts at prevention. In spite of early detection and improved treatment, every year nearly 250,000 women discover that they have invasive breast cancer [1]. Roughly 58,000 more will be diagnosed with early cases of the disease and about 40,000 will die [2]. The incidence of breast cancers is much higher in western countries than that in other parts of the world, suggesting a significant role for environmental factors in developing breast cancer. Genetic and epigenetic alterations have both been shown to play an important role in breast carcinogenesis. The former is irreversible while the epigenetic changes are reversible. Epigenetic malfunctions are manifested through aberrant methylation and acetylation of genes and histones involved in normal tissue development, leading to activation or silencing gene expression. Thus numerous molecular events could go awry because of epigenetic malfunctions. The advancement in the science of epigenetics has led to a greater understanding of how breast cancer forms, resulting in the discovery of novel approaches for chemoprevention. Specifically, identifying DNA methyltransferases and histone deacetylases that control epigenetic modifications has resulted in utilizing these enzymes as primary targets for epigenetic therapy. In this review, we will discuss the current understanding of the modes of epigenetic regulation, and the epigenetic signatures seen in breast cancer.
10.2 History of Epigenetics
Epigenetics is the study of changes in phenotype or gene expression caused by mechanisms other than those that alter the DNA sequence. In 1942, Conrad Waddington coined the term epigenetics; he derived the name from a Greek word epigenesis, a theory of development [3]. In 1969, Griffith and Mahler were the first to suggest that DNA methylation might have an important biological role on gene expression, and that changes in DNA methylation might explain how genes are turned on and off [4]. A few years later, in 1975, Sager and Kitchin proposed that there are enzymes in eukaryotic organisms that restrict unmodified DNA [5]. Since then it has become apparent that changes in DNA methylation might play important role during carcinogenesis [6]. More recently, this has expanded to other types of modification, including histone modifications [7].
10.3 Types of Epigenetic Regulation in Breast Cancer
The interesting aspect of epigenetic alteration of DNA is that such changes are heritable but does not alter nucleotide sequence. This is in contrast to a genetic change where the nucleotide changes. Furthermore, unlike genetic changes, epigenetic modifications are potentially reversible; this aspect gives the potential for therapy against cancer. The science of epigenetics has explained how nutrients and drugs can change the cancer cell cycle [8, 9]. Epigenetics causes the organism’s genes to behave differently, such as the changes seen when cells differentiate or become malignant.
Different modes of epigenetic regulation have been observed in breast cancers including (1) DNA methylation (stable and long term repression), (2) histone modification (dynamic and can be changed upon stimulation), (3) polycomb group of proteins (maintain the silenced state of developmental regulators), and (4) Non-coding RNAs (microRNA, small nucleolar RNA, repeat-associated small interfering RNA) (Fig. 10.1). In this chapter, we will describe each one of these regulatory mechanisms (Table 10.1).
10.3.1 DNA Methylation
DNA methylation, a major mode of epigenetic regulation occurs on cytosine residues of CpG dinucleotides [10]. DNA methylation affects the packing of chromatin and the architecture of the nucleus thereby critically regulating gene expression. CpG islands are regions of at least 500 bp and have more than 55 % GC content [11]. CpG islands have mostly been identified within promoter regions, and methylation within this region makes the DNA inaccessible and no longer recognizable by the transcriptional machinery resulting in gene silencing. A methyl group is added to the cytosine ring by DNA methyltransferases by an enzymatic transfer from the methyl donor S-adenosylmethionine to the carbon-5 position of cytosine [12]. Surprisingly, according to Antequera and Bird, approximately half of all genes in the human (~45,000 genes) contain CpG islands [13]. Various studies have clearly shown that about 70–80 % of CpG sites in the human genome are methylated. DNA-cytosine methyltransferase-1 (DNMT1) was the first methyltransferase to be identified [14]. Subsequent studies have suggested that the DNA methyltransferase 1 (DNMT1) plays a key role in the maintenance and restoration of methylation after DNA replication, while DNMT3A and DNMT3B initiate de novo methylation and establish new DNA methylation patterns [15].
In general, normal cells are hypomethylated, while in cancer cells hypermethylation is frequent leading to silencing of tumor suppressor genes. Retinoblastoma gene was characterized to be the first tumor suppressor gene and also they are the first to be identified as hypermethylated. The importance of promoter hypermethylation has been characterized using demethylating agents 5-aza-2′-deoxycytidine to reactivate the genes in cancer cell lines. DNA methylation has been shown to play important role in normal development e.g. development of fertilized egg into an embryo. Apart from this, nearly 45 % of the human genome has repetitive sequences and loss of methylation of these sequences is thought to account for most of the global hypomethylation observed in all human cancers. Hypermethylation of the CpG promoter regions, in the tumor suppressor genes, results in gene silencing and therefore resulting in the oncogenic transformation. These changes have been shown to account for various cancers including breast cancer development. Methylation inactivates the transcription; demethylation may result in transcriptional interference and dysregulation of normal gene expression, leading to destabilization and chromosomal translocations.
There are several genes that are silenced by promoter methylation during breast cancer development. Here, we have attempted to comprehensively provided the list of genes that are hypermethylated at the promoter region during breast cancer development.
10.3.2 Cell Signaling Genes That Are Hypermethylated During Breast Cancer
10.3.2.1 Secreted Frizzled-Related Proteins (SFRPs)
Wnt signaling plays a significant role in development of various types of cancer and inhibiting the pathway hinders the progression of tumorigenesis [16]. Secreted frizzled-related proteins (SFRPs), a family of proteins that include SFRP1 to SFRP5, are extracellular antagonists for Wnt signaling [17]. These proteins are shown to sequester Wnt molecules at the cell surface membrane and thereby regulate the Wnt signaling pathway during breast cancer development [18]. Several reports have also suggested that increased nuclear and cytoplasmic accumulation of β-catenin is due to disruption of SFRPs and Wnt equilibrium in the breast tumor tissues [19]. Subsequent studies have demonstrated that SFRP1 and SFRP5 genes are targets for the promoter hypermethylation leading to inactivation [20, 21]. Moreover, promoter hypermethylation is associated with unfavorable prognosis in breast cancer.
10.3.2.2 Estrogen Receptor (ER)
Estrogens are hormones that play a key role in the growth and development of breast cancers. Estrogens mediate its action through intracellular estrogen receptors (ER) [22]. There are two estrogen receptors ER-α and ER-β, which are encoded by ESR1 and 2 genes, respectively [23]. Estrogen receptors can also function as transcription factors to regulate the expression of target genes. In breast cancers, ER-α methylation is a predictive marker for response to hormone therapy [24]. Importantly, up to a third of the breast cancers lack ER-α at the time of diagnosis and a significant proportion of cancer patients who are initially ER-α positive become ER-α negative during tumor progression [25]. Initially it is thought that these changes are due to genetic alterations such as deletion or mutation; however, recent studies have demonstrated that there is DNA methylation in the promoter region [26]. The ER-α gene, located at chromosome 6q25.1, has CpG rich regions in both its promoter and the first exon [27]. While these CpG rich regions are unmethylated in normal breast tissues and in ER-positive breast cancer, it is methylated in ~50 % of the unselected primary breast cancers and most of the ER-negative breast cancer cell lines [28]. However, treatment with methyltransferase inhibitors such as 5-aza-cytidine (5-aza-C) and 5-aza-deoxycytidine (5-aza-dC) results in partial demethylation and restoration of ER mRNA expression and protein [29]. This has been further confirmed by various studies where it was observed that DNMT1 expression at both RNA and protein levels in ER-negative breast cancer cell lines are significantly increased compared with their ER-positive counterparts.
10.3.2.3 Retinoic Acid Receptor β2 (RARβ2)
RARβ2 gene is a member of the nuclear receptor superfamily [30]. There are six receptors (RARα, -β and -γ and retinoid X receptors-α, -β and -γ) in this family and all of them are ligand activated transcription factors [31]. RARβ gene, located at chromosome 3p24, has been implicated in playing an important role in limiting the growth of various tumors, including breast cancer [32]. Methylation of CpG islands in the RARβ2 promoter region is one of the factors linked to downregulation of its expression in breast cancer [33]. Furthermore, methylation of the RARβ promoter has been shown in several RARβ2-negative human breast cancer cell lines and in about one-third of unselected primary breast cancer specimens, a result of which is decreased or complete loss of RARβ2 expression [34]. However, treatment with 5-aza-dC can partially restore RARβ2 expression further confirming the promoter methylation mediated suppression of its transcription [35].
10.3.2.4 Aplasia Ras Homolog Member I (ARHI)
The Ras-related novel tumor suppressor gene aplasia Ras homolog member I (ARHI; also known as DIRAS3) encodes a small GTPase with 60 % homology to Ras and Rap. The expression of this tumor suppressor is down regulated in 40 % of DCIS and 70 % of invasive breast cancers [36]. Furthermore, reexpression of ARHI protein suppresses clonogenic growth of breast cancer cells, inhibits their invasiveness, and induces apoptosis. There are three CpG islands in the ARHI gene. The first two CpG islands are located in the promoter region, while the third CpG island is located in the coding region [37]. Furthermore, hypermethylation of the second CpG island within the promoter region results in the complete loss of ARHI expression in breast cancer cells [38].
10.3.3 DNA Damage Response Genes That Are Methylated During Breast Cancer
10.3.3.1 BRCA1
The BRCA1 gene located at chromosome 17q21, is a well-known breast cancer susceptibility gene [39]. Inhibition of BRCA1 expression through antisense oligonucleotides increases the proliferation of normal and malignant mammary cells while overexpression of wild-type BRCA1 suppresses MCF-7 breast cancer cell tumorigenesis in mice [40]. Inherited mutations in the BRCA1 gene account for one-half of inherited breast carcinomas. However, in contrast to other tumor suppressor genes, somatic mutations in this gene have not been reported, despite the high degree of LOH at the locus in breast cancers [41]. Subsequent studies of the BRCA1 promoter region demonstrated increased methylation in 11 % of sporadic breast cancer cases, which was inversely correlated with expression of both ER and progesterone receptor [42]. Additionally, BRCA1 promoter methylation is associated with medullary and mucinous subtypes [43]. Moreover, while BRCA1 was unmethylated in normal tissues and in various breast cancer cell lines, two xenograft studies from two of these cell lines demonstrated increased promoter methylation and the concomitant loss of transcript [44]. In addition, the study demonstrated that loss of heterozygosity could happen through the aberrant methylation of the second allele. Finally, BRCA1 methylation is observed only in breast and ovarian cancers but not in tumors of colon or liver or leukemia, supporting a tissue-specific event for the process.
10.3.3.2 ANKRD11
The ankryin repeat domain-containing protein ANKRD11, a co-activator for p53 is a putative tumor suppressor gene in breast cancer. Downregulation of ANKRD11 is associated with breast tumorigenesis [45]. The promoter region of ANKRD11 is loaded with CpG-rich regions, and analysis of this region demonstrated that high levels of methylation in 40 % of breast tumors but not in normal breast tissues or normal blood samples. Moreover, treatment of breast cancer cell lines with DNA demethylating agents results in upregulation of ANKRD11 expression suggesting that promoter DNA methylation plays a key role in downregulating the protein expression.
10.3.3.3 Mismatch Repair Genes MLH1 and MSH2
Loss of genomic stability is associated with a variety of diseases, particularly cancer. Of the many proteins that maintain genomic integrity, two important ones are the mismatch repair genes MLH1 and MSH2 [46]. Analysis of these mismatch repair genes in locally advanced breast cancers demonstrated that hypermethylation of the MLH1 gene in 43.5 % of patients with primary breast cancer, of whom 66.9 % had locally advanced breast cancer (stages IIIA to IIIC) [47]. Similarly, there was hypermethylation of the MSH 2 gene in 16 % of primary breast cancer cases. Of these patients, 21.3 % had locally advanced breast cancer [48].
10.3.4 Cell Cycle and Apoptosis Genes That Methylated During Breast Cancer
10.3.4.1 Ras Association Domain Family 1A Gene (RASSF1A)
RASSF1A gene, located within the 120 kb 3p21.3 minimal homozygous deletion region is epigenetically inactivated in cancers, suggesting a tumor suppressor function for the protein [49]. The protein is 55 % homologous to Nore1, a noncatalytic protein identified by its ability to bind selectively to active Ras [50]. Forced ectopic expression of RASSF1A in cancer cells reduced colony formation, suppressed anchorage-independent growth and inhibited tumor formation in nude mice [51]. More importantly, methylation in the RASSF1A gene is highly correlated with breast cancer risk, atypical cytology and benign breast disease requiring biopsy [52]. With respect to age, RASSF1A gene methylation has been noted to increase linearly between the ages of 32 and 55 [53]. In microdissected breast tissue, Lehmann et al. showed that the RASSF1A promoter was methylated in all epithelial hyperplasia and papilloma samples and in 83 % of ductal carcinoma in situ, suggesting methylation of RASSF1A promoter as a new marker for nonphysiological epithelial proliferation in the breast [54]. The study also found that in most cases of progression to invasive growth, epigenetic inactivation takes place before invasive growth develops, an observation confirmed by Pasquali et al., who observed a progressive gain of methylation for RASSF1A from normal to hyperplasia acquiring statistical significance at CIS and invasive carcinoma [55]. Functionally, one thing that RASSF1A does is it influences G1-S cell cycle checkpoint by regulating the levels of cyclin D1 protein. Reduced RASSF1A expression due to epigenetic silencing leads to accumulation of cyclin D1, which may represent an important mechanism for overriding cell cycle control under conditions of increased cell cycle pressure [56].
10.3.4.2 Cyclin D2 (CCND2)
CCND2 is a member of the D-type cyclins, implicated in cell cycle regulation, differentiation, and malignant transformation [57]. It should be noted that cyclin D2 is not expressed in the majority of breast cancer cell lines, whereas abundant expression can be detected human mammary epithelial cells with a finite lifespan [58]. Also, loss of CCND2 expression caused by methylation is an early event in breast cancer tumorigenesis. Hypermethylation of the CpG island in the promoter can be detected by methylation-specific PCR in most breast cancers, and this has been associated with silencing of cyclin D2 gene expression. Promoter hypermethylation was also detected in ductal carcinoma in situ, suggesting that loss of cyclin D2 expression is an early event in tumorigenesis [59]. Furthermore, methylation of CCND2 has been correlated with poor prognosis, implying that CCND2 has a tumor suppressor function.
10.3.4.3 Cyclin D/CDK4 Complex Inhibitor (CDKN2/p16)
Frequent LOH and homozygous deletion has suggested the presence of tumor suppressor genes in chromosome 9p21 [60]. One such gene in this locus is inhibitor of the cyclin D/CDK4 complex (CDKN2/p16), which is frequently deleted in human cancer cell lines. The protein binds to CDK4 and CDK6, and blocks Gl to S transition by inhibiting cyclin-D-dependent phosphorylation of the Rb protein and maintains its binding to the E2F transcriptional factor [61]. Since the initial reports of homozygous deletion, numerous studies have shown varying, but in general much less frequent, abnormalities of p16 in primary tumors of these cancers. For example, although the rate of homozygous deletions ranged from 40 to 60 % of breast cancer cell lines, neither homozygous deletion nor point mutations were observed frequently in primary breast carcinomas [62]. Furthermore, certain neoplasms, such as prostate and colon cancer, have not been found to harbor homozygous deletions in established cell lines. However, de novo methylation of the 5′ CpG lsland is a frequent mode of suppressing CDKN2/p16 expression, and also firmly demonstrate that CDKN2/p16 is one of the most frequently altered genes in human neoplasia.
10.3.4.4 Retinoblastoma Protein-Interacting Zinc Finger Gene RIZ1
RIZ was first isolated in a functional screening for Rb-binding proteins, and was also independently isolated as DNA-binding protein MTB-Zf, GATA3 transcription factor-binding protein G3B, and a coactivator of estrogen receptor. RIZ contains the canonical Rb-binding motif LXCXE and the nuclear hormone receptor-binding motif LXXLL [63]. In addition, RIZ contains a novel protein methyltransferase domain, called the PR domain or SET domain, which is present in ~50 human genes [64]. Two products of the gene exist: (a) RIZ1, which contains the PR domain; and (b) RIZ2, which lacks the domain. RIZ1 but not RIZ2 has tumor-suppressive properties [65]. The RIZ1 gene maps to chromosome 1p36, a region commonly deleted in more than a dozen different types of human cancers. RIZ1 expression, but not RIZ2 expression, is commonly silenced in many types of human tumors, including breast cancer, liver cancer, colon cancer, neuroblastoma, melanoma, lung cancer, and osteosarcoma through DNA methylation. Further studies are required to determine specific sites of methylation in the gene.
10.3.4.5 TMS1
TMS1 belongs to a growing family of apoptotic signaling molecules that contain a CARD domain [66]. This domain is found within the prodomain of a number of caspases, and oligomerization with upstream CARD-containing regulatory proteins mediates their cleavage and activation. Other CARD-containing proteins with known roles in apoptosis include the Caenorhabditis elegans CED-3 and CED-4, the human homologue of CED-4, apoptotic protease activating factor-1, the cellular and viral inhibitors of apoptosis, the cellular homologue of herpes virus EHV2 E10 protein, BCL10, and several proteins involved in the activation of NF-kB. The protein was found to act during the initiation phase of an apoptotic pathway, coupling death receptors at the cell surface or intrinsic death signals to the activation of the caspase cascade. Earlier studies suggest that the gene encoding TMS1 is silenced by DNA methylation [67].
10.3.4.6 14-3-3-σ
14-3-3-σ is a member of a superfamily of proteins that are responsible for instituting cell cycle checkpoint in response to DNA damage [68]. Several lines of evidence have demonstrated that hypermethylation of the 14-3-3-σ gene occurs in 91 % of primary breast cancers and is strongly associated with loss of 14-3-3-σ gene expression. Hypermethylation of the 14-3-3-σ gene occurs in a CpG-rich region that extends from the transcriptional initiation site to the middle of the coding region. Bisulfite genomic sequencing of the 500-bp region showed that it is consistently and densely methylated in cell lines and primary breast tumors. This dense methylation just downstream of its transcriptional start site is strongly associated with gene silencing. Further proof of methylation silencing was obtained when treatment with 5-aza-dC resulted in demethylation of the CpG island and reactivation of gene expression [69]. Moreover, 14-3-3-σ expression is undetectable in 94 % (45/48) of breast tumors. Subsequent studies have clearly demonstrated that CpG island methylation is the epigenetic event that is largely responsible for silencing of the 14-3-3-σ gene and occurs in a majority of breast cancers.
10.3.5 Other Genes That Are Hypermethylated in Breast Cancers
10.3.5.1 Death-Associated Protein Kinase (DAP-Kinase)
DAP-kinase is a 160-kDa serine/threonine, microfilament-bound kinase recently shown to be involved in γ-interferon-induced apoptosis [70]. Tumor invasiveness and aggressiveness has been associated with hypermethylation of a CpG island in the promoter region of the gene. In a small series of B-cell malignancies, a similar finding of methylation of the DAP-kinase CpG was also described, suggesting that hypermethylation of the DAP-kinase gene and loss of γ-interferon-mediated apoptosis may be important in the development of B-cell malignancies [71]. Cell lines derived from these cancers also demonstrate reduced or DAP-kinase gene expression, and reexpression can be seen following treatment with a DNA demethylating drug such as 5-aza-dC [72].
10.3.5.2 ID4
ID4 is the most recently discovered member of the Inhibitor of DNA binding/Inhibitor of differentiation family of transcription factors [73]. ID proteins contain a helix-loop- helix (HLH) domain enabling interaction with other basic helix-loop-helix (bHLH)-proteins. Following heterodimerization with those transcription factors, ID proteins act as dominant negative inhibitors of gene transcription [74]. In addition, ID proteins can bind to other important non-bHLH transcription factors such as the retinoblastoma protein (RB) or the paired box (PAX)-proteins, thereby regulating important pathways in cell proliferation and differentiation [75]. Furthermore, ID4 is an important factor for the development of the nervous system. In this regard, the ID4 gene is highly expressed in migrating postmitotic neurons, in Purkinje cells, as well as in the adult cerebellum. Since ID proteins regulate fundamental cellular processes, a link of ID dysregulation with human carcinogenesis has been recently postulated. ID1 and ID2 are overexpressed in several human tumor cancers including pancreatic cancer and colorectal adenocarcinomas, suggesting a putative oncogeneic function for these two proteins [76]. However, ID3 and ID4 expression is reduced in several tumor types such as ovarian adenocarcinomas. In human breast tissue ID4 mRNA was found to be constitutively expressed in normal mammary epithelial cells, but suppressed in estrogen receptor ER-positive breast carcinomas and pre-neoplastic lesions. A human ribozyme library-based inverse genomics approach revealed that ID4 might act as a negative regulator of the common tumor suppressor gene BRCA1. Moreover, ID4 expression levels were decreased in BRCA1/ER-positive breast cancer specimens, suggesting that ID4 participates in molecular events regulating ER and BRCA1 expression. Recently, it has become very evident that promoter methylation plays a decisive role in the expression of these genes in cancer. Aberrant hypermethylation of the ID4 gene promoter was associated with an increased risk for lymph node metastasis [77].
10.3.5.3 Paired-Like Homeodomain Transcription Factor 2 (PITX2)
PITX2 acts as a transcription factor and are shown to regulate procollagen lysyl hydroxylase gene expression. Furthermore, this protein is involved in the development of organs [78]. Hypermethylation of the PITX2 promoter is associated with a high risk of recurrence in node-negative, steroid hormone receptor-positive breast cancer following tamoxifen adjuvant therapy [79]. In addition, DNA hypermethylation of eight candidate genes (BMP4, LMX1A, BARX1, FGF4, NR5A1, LHX4, ZNF1A1, and CCND2) linked to the PITX2 signal transduction pathway was found to be significantly associated with patient outcome [80].
10.3.5.4 Adenomatosis Polyposis Coli (APC)
The APC gene product modulates β-catenin function by binding to the protein and driving it to ubiquitin-proteosomal degradation [81]. Genetic and epigenetic alterations in APC, a tumor suppressor gene originally implicated in colon cancer have been reported in many malignancies including breast cancers. A study of 76 breast cancer patients by Liu and colleagues has demonstrated that APC gene methylation correlated positively with TNM staging and negatively with protein expression [82]. Lee et al. reported that methylation occurs in the APC promoter in 42 % of breast cancer aspiration fluid samples. However, the gene was unmethylated in the aspiration fluids from normal breast tissue in patients with breast cancer and all benign breast disease patients in their cohort [83].
10.3.5.5 GSTP1
Glutathione (GSH) and its corresponding cytosolic GSTs are involved in the detoxification pathway of xenobiotics and chemotherapeutic agents [84]. They catalyze intracellular detoxification reactions by conjugating chemically reactive electrophiles to GSH, inactivating electrophilic carcinogens. The GSTs, encoded by several different genes at different loci, have been classified into α, μ, π and θ families. The π-class GST, encoded by the GSTP1 gene, on chromosome 11, is of particular importance in breast cancer [85, 86]. In cultured breast cancer cell lines an inverse relationship between GSTP1 and ER gene expression has been reported, i.e. GSTP1 was expressed in ER-negative but not in ER-positive lines, although the underlying mechanism is unclear. Treatment of the GSTP1-negative cell line MCF-7 with 5-aza-dC induces de novo synthesis of π-class protein. In addition, GSTP1 promoter methylation has been associated with gene inactivation in about 30 % of primary breast carcinomas, and this correlates with PR expression. It is postulated that methylation-associated inactivation of GSTP1 can result in adenine or guanine mutation by estrogen metabolites-DNA adduct formation and lead to genetic instability [87].
10.3.5.6 TIMP3
TIMP3 belongs to a family of molecules that inhibit the proteolytic activity of matrix metalloproteinases [88]. The protein can suppress primary tumor growth via its effects on tumor development, angiogenesis, invasion and metastasis. TIMP3 is methylated in ~30 % of human breast cancer cell lines and also in ~30 % of primary breast tumors [89]. Hypermethylation of 5′CpG island in TIMP3 promoter has been observed in normal and benign (ALH) lesions and in DCIS and tumor lesions, implicating TIMP3 as an early event. Furthermore, 5-aza-dC treatment has been shown to induce TIMP3 expression supporting a role for epigenetic mechanism in TIMP3 gene regulation [90].
10.3.5.7 Progesterone Receptor (PR)
Progesterone receptor (PR) is a classical estrogen-regulated gene [91]. Receptor status is important in classification of breast cancers. The PR gene encodes two isoforms, hPRA (79 kDa) and hPRB (109 kDa), which differ in both their N-terminal sequences and biological activities. The PR gene, located at chromosome 11q13, also has a CpG island in its first exon [92]. PR gene methylation has been demonstrated in ~40 % of PR-negative breast tumors and PR-negative breast cancer cell lines [93]. Additional proof of the functional role for CpG island methylation was obtained when treatment of PR-negative MDA-MB-231 cells with 5-aza-dC in the presence of estrogen led to partial demethylation of the PR CpG island and re-expression of PR gene [94].
10.3.5.8 E-Cadherin
The E-cadherin gene, located at chromosome 16q22.1, encodes a cell-surface adhesion protein that is important in maintaining cell–cell adhesion in epithelial tissues [95]. Considerable evidence shows that loss of expression and function of E-cadherin protein contributes to increased proliferation, invasion and metastasis in breast cancer. This also correlates with decreased patient survival. While mutations and deletions clearly play a role in loss of the E-cadherin expression and function, several studies have also demonstrated that epigenetic silencing of the E-cadherin gene by 5′CpG methylation occurs in human breast cancer cell lines as well as about 50 % of unselected primary breast cancers [96]. Recent studies have demonstrated that hyper methylation of the E-cadherin CpG island was evident in about 30 % of ductal carcinomas in situ and increased significantly in nearly 60 % of metastatic lesions [97].
10.3.5.9 LAMA3
Interaction between epithelial cells and extracellular matrix is important for the structural integrity and specialized function of breast epithelium. Two way signaling occurs via extracellular proteins (laminins) and their transmembrane receptors, the integrins. Hemidesmosomes are structures used by normal epithelia to adhere to basement membrane. The major structural proteins of the hemidesmosomes are the integrins and its ligand laminin 5 (LN5). In lobular and ductal structures of the breast, both myoepithelial and luminal cells has hemidesmosomes. LN5 is specific to epithelium, and it is a heterotrimeric protein member of the laminin family and consists of three polypeptide chains α3, β3, and γ2, which are the products of three different genes LAMA3, LAMB3, and LAMC2. The chains are assembled in a coiled cruciate-like structure, which is deposited in the basement membrane [98]. Silencing of LAMA3 gene by methylation plays an important role in pathogenesis of breast cancers [99].
10.3.5.10 Klotho
Klotho is a single pass transmembrane protein, associated with premature aging and acts as a potent inhibitor of insulin receptor [100]. Its expression is reduced associated during breast cancer development. Methylation of its promoter region and silencing of its expression has been reported to occur at the early stages of breast cancer [101].
10.3.5.11 Slit2
The Slit family comprises large ECM 3 secreted and membrane-associated glycoproteins [102]. Human Slits (SLIT1, SLIT2, and SLIT3) are candidate ligands for the repulsive guidance receptors, the ROBO gene family. The SLIT2 gene has been mapped to chromosome 4p15.2, and studies have shown that the putative SLIT2 receptor, is methylated in some breast tumors [103]. In addition, Slit2 promoter hypermethylation is detected in tissue and serum samples from breast cancer patients [104] Furthermore, ectopic expression of SLIT2 in several breast cancer cell lines suppressed growth and reduced colony formation abilities.
10.3.5.12 Caveolin-1 (Cav1)
Cav1 is a ubiquitous scaffolding protein that coats plasma membrane invaginations termed caveolae in various cell types [105]. The Cav1 gene is located in the locus D7S522 of human chromosome 7q31.1, a region that is frequently deleted in human cancers, implicating Caveolin-1 as a tumor suppressor [106]. Aberrant promoter methylation of Cav1 gene is associated with reduced of expression, and occurs at the precancerous stage [107].
10.3.5.13 Lost-On-Transformation 1 (LOT1)
LOT1 is a growth suppressor gene localized on chromosome 6 at band q24–25, which is a frequent site for loss of heterozygosity in many solid tumors [108]. The gene encodes a nuclear transcription factor and is strongly regulated by the activation of the epidermal growth factor receptor-signaling pathway [109]. Earlier studies have identified CpG islands in the upstream sequences of exon 1 and in the promoter region, suggesting the potential for DNA methylation [110]. In addition, recent reports have demonstrated that the gene is located within a maternally imprinted chromosomal region, and the gene is methylated. Moreover, breast cancer cell lines have high levels of CpG methylation in its promoter region.
10.3.5.14 Sulfotransferase 1A1 (SULT1A1)
SULT1A subfamily of sulfotransferases is an important phase II xenobiotic metabolizing enzyme that mediates the sulfonation of drugs, carcinogens, and steroids [111]. Specifically, SULT1A1 plays a significant role in the sulfoconjugation of xenobiotics, such as p-nitrophenol, N hydroxy-heterocyclic and -aromatic amines, and endogenous compounds such as di-iodothyronine and estrogens. The CpG methylation rate of the SULT1A1 gene in breast cancer was shown to be denser than in normal and benign tissues [112].
10.3.5.15 Cystatin E/M (CST6)
Cystatin M or E/M (encoded by the CST6 gene) is an endogenous inhibitor of lysosomal cysteine proteases that functions to protect cells against uncontrolled proteolysis. CST6 has been shown to be involved in the degradation of components of connective tissues and basement membranes in vitro, and aberrant expression and activity of these proteases accompany cancer invasion and metastasis in vivo [113]. Absence of CST6 expression is believed to result in increased proteolysis of tissue architecture, facilitating the spread of cancer cells. Studies have established a strong link between CST6 promoter hypermethylation and loss of CST6 expression in breast cancer [114].
10.3.5.16 WW Domain Containing Oxidoreductase (WWOX)
WWOX is a tumor suppressor gene spanning a genomic region of f1 Mb located at chromosome 16q23.3-24.1, a region with a high incidence of loss of heterozygosity (LOH) in breast, prostate, and other cancers [115]. The area is highly methylated in breast cancers, resulting in reduced gene expression. Similarly, a significantly greatly reduced levels of WWOX gene expression was observed in MDA-MB-231 cells, which was determined to be partly due to the methylation of the CpG islands [116].
10.3.5.17 Dickkopf-3 (DKK3)
Dickkopf genes (DKK) encode a class of extracellular signaling molecules. Together, they control cell fate during embryonic development and regulate tissue homeostasis in adults. There are four DKK members, DKK1–DKK4. While DKK1, DKK2 and DKK4 antagonize canonical Wnt/β-catenin signaling at the membrane, DKK3 functions in antagonizing nuclear β-catenin levels. DKK3 expression is frequently lost in human cancer tissues because of aberrant 5′-cytosine methylation within its promoter region including in breast cancers [117].
10.3.5.18 CCAAT/Enhancer Binding Protein D (CEBPD)
C/EBPs are a highly conserved family of leucine zipper proteins that regulate cell growth and differentiation in multiple organs [118]. Specifically, C/EBPδ functions to initiate and maintain growth arrest of mammary epithelial cells [119]. Loss of function alterations in C/EBPδ gene expression has been reported in human breast cancer and in rodent carcinogen-induced mammary tumors [120]. This has been associated with C/EBPdelta gene promoter hyper- and site specific-methylation [121].
10.3.5.19 Deleted in U Twenty Twenty (DUTT1)
DUTT1is a member of NCM family of receptors was mapped at human 3p12 [122]. DUTT1 protein consists of an ectodomain of five Ig domains and three-fibronectin type III repeats. It also contains a single transmembrane segment and a long cytoplasmic domain that does not contain any recognizable motifs except proline-rich repeat and sequences of low compositional complexities as predicted by the SMART program. The gene is frequently deleted in breast cancer. In addition, the gene can be hypermethylated in breast cancer and its expression reactivated by 5-aza-dC treatment [123].
10.4 Histone Modification
Histones are proteins that assemble and have DNA wrapped around them. There are four histones, with the core histones present as octamers (2 each of 4 core histones) as well as two linker histones H1 and H5. For many years it has been known that post-translational modifications of histone tails determine, in part, which regions of the genome are an open and thus transcriptionally active conformation, and which are closed and thus transcriptionally inactive. Histone tails determines whether the region will be in an actively transcribed state or in an inactive state. Histone modifications can result in alteration of the chromatin structure for transcription machinery or recruiting regulatory proteins. Histones can be modified by methylation, acetylation, ribosylation, ubiquitination, sumoylation, and phosphorylation, which can result in either an increase in transcription or in gene silencing [124]. There are several reports confirming that cancers have altered patterns of histone modifications, chief among them being histone acetylation, histone methylation and histone phosphorylation. Recently, the aberrant histone methylation has been shown to result in cancer-specific loss of expression of surrounding genes. In breast cancer, abnormal histone modification in combination with DNA hypermethylation is frequently associated with epigenetic silencing of tumor suppressor genes and genomic instability [125]. Understanding the mechanisms of dysregulation of histone tail post-translational modifications and their contribution to breast tumorigenesis is critically important in the development of novel targeted therapy for breast cancer patients.
10.4.1 Histone Acetyltransferases
The acetylation of lysine residues on the N-terminus of histones is generally associated with active gene transcription. The HATs can be grouped into three main families based on their sequence similarities: Gcn5/PCAF, p300/CBP and the MYST family of HAT proteins [126]. Most HATs are present as part of large protein complexes and act as transcriptional coactivators. Many of them have also been shown to acetylate proteins other than histones.
10.4.2 Histone Deacetylases
HDACs promote gene repression through removal of acetyl groups from lysine residues in histone tails. At least 18 HDAC genes have been recognized in the human genome, grouped into three main classes based on sequence homology to the yeast counterparts Rpd3, Hda1 and Sir2/Hst [127, 128]. HDACs act mostly as part of large multiprotein complexes that function as transcriptional corepressors. HDAC family is divided into zinc-dependent enzymes (classes I, IIa, IIb, and IV, of which there are 11 subtype enzymes) and zinc-independent enzymes (class III, also called sirtuins), which require NAD+ for their catalytic activity [129]. Pruitt and colleagues demonstrated that inhibition of class III HDAC SIRT1 using a pharmacologic inhibitor, splitomicin, or siRNA reactivates epigenetically silenced SFRP1, SFRP2, E- cadherin, and CRBP1 genes in human breast cancer cells [130].
HDACs remove the acetyl groups from histone lysine tails and are thought to facilitate transcriptional repression by decreasing the level of histone acetylation. Like HATs, HDACs also have non-histone targets. Several HDACs have been found to be involved in breast cancer. HDAC1 and HDAC4 are overexpressed in breast cancers [131]. In ER-positive MCF-7 cells, expression of HDAC6 was increased after being treated by estradiol, and the elevated HDAC6 could deacetylate alpha-tubulin and increase cell motility [132]. In contrast, ER antagonist tamoxifen (TAM) or ICI 182,780 prevents estradiol-induced HDAC6 upregulation, and then reduces cell motility [133]. Moreover, patients with high levels of HDAC6 tend to be more responsive to endocrine treatment than those with low levels, indicating that the levels of HDAC6 expression might be used both as a marker of endocrine responsiveness and also as a prognostic indicator in breast cancer. Studies have also suggested that sirtuins SIRT3 and SIRT7 are overexpressed in breast cancer [134].
10.4.3 Histone Methyltransferases
Methylation of arginine and lysine residues in histones is involved in the regulation of a wide range of processes including gene activity, chromatin structure and epigenetic memory. Arginine can be either mono- or dimethylated, and in symmetric or asymmetric configurations. Lysine can be in mono-, di- or trimethylated forms. Commonly, lysine methylation at H3K9, H3K27 and H4K20 is associated with gene silencing, whereas methylation at H3K4, H3K36 and H3K79 is associated with gene activation [135].
10.4.3.1 Histone Lysine Methyltransferase (HKMTs)
Histone lysine methylation is a reversible process, dynamically regulated by both lysine methyltransferases and demethylases. Methylation occurs on histone H3 at ε-amino group of lysines 4, 9, 14, 27, 36, and 79 and on histone H4 at lysines 20 and 59 [136]. In general, methylation at H3K4 or H3K36, mono-methylations of H3K27, H3K9, H4K20, H3K79, and H2BK5 are associated with transcriptional activation, whereas trimethylations of H3K27, H3K9 H3K79, and H4K20 are linked to transcriptional repression [137].
Histone methylation is regulated in breast cancer in an even more complicated manner than histone acetylation via a large number of chromosomal remodeling regulatory complexes. Modification of H3K4 methylation is catalyzed by the Trithorax group of histone methyltransferases, including SET1 and MLL [138]. The activity of Trithorax proteins is balanced by the opposing effects of the Polycomb group factors, another important histone methyltransferase family that mediates methylation usually associated with epigenetic gene silencing [139].
10.4.3.2 Histone Arginine Methyltransferase (HRMTs)
The protein arginine methyltransferase (PRMT) family is the main HRMTs that act on histones. They are classified into four groups depending on the type of methylarginine they generate: Type I PRMTs (PRMT1, PRMT2, PRMT3, PRMT4, PRMT6 and PRMT8) catalyze the formation of ω-NG, monomethylarginines (MMA) and NG-asymmetric dimethylarginines (aDMA); Type II PRMTs (PRMT5, PRMT7 and PRMT9) catalyze the formation of MMA and ω-NG, N′G-symmetric dimethylarginines (sDMA); Type III PRMTs catalyze only the monomethylation of arginine residues in proteins; Type IV PRMTs catalyze the methylation at delta (Δ) nitrogen atom of arginine residues [140, 141]. Similar to HKMTs, evidence for the involvement of HRMTs in human cancers is weak. Underexpression of PRMT1 has been reported in breast cancer [142]. PRMT4, also known as coactivator-associated arginine methyltransferase-1 (CARM1), is a coactivator for nuclear receptors and is overexpressed in breast cancers [143]. PRMT4 plays an essential role in estrogen induced cell cycle progression in the MCF-7 breast cancer cells. When stimulated with estrogen, the E2F1 promoter is subjected to PRMT4-dependent dimethylation on H3R17, and this recruitment of PRMT4 by ERα are dependent on the presence of the NCOA3 [144].
10.4.4 Histone Demethylases
It used to be thought that histone methylation was a permanent and irreversible histone modification. However, more recent studies have identified enzymes with the ability to demethylate the methylated histone lysine/arginine residues via amine oxidation, hydroxylation or deamination. The histone demethylases could be divided into three distinct classes. The first class (petidylarginine deaminase 4, PADI4) converts a methyl-lysine to citrulline. The second class (lysine-specific demethylase 1, LSD1) reverses histone H3K4 and H3K9 modifications by an oxidative demethylation reaction. The third class of demethylases is the family of Jumonji C (JmjC)-domain containing histone demethylases (JHDMs). In contrast to LSD1, JHDMs can demethylate all three methylated states (mono- di- and tri-methylated lysine). Until now, JHDMs have been found to demethylate H3K36 (JHDM1), H3K9 (JHDM2A) and H3K9/K27 (JHDM3 and JMJD2A-D) [145]. Histone demethylase JARID1B (PLU-1) is overexpressed in breast cancers but expressed very low in normal adult tissues, and it is essential for the proliferation of the MCF-7 cells and for the nude mice tumor growth of mammary carcinoma cells. Several target genes of JARID1B have also been identified to be associated with proliferation of breast cancer, such as 14–3–3σ, BRCA1, CAV1, and HOXA5 [146]. LSD1 could be a coactivator in the ER signaling. JMJD1C expression is decreased in breast cancer tissues compared with normal breast tissues, suggesting that it might be a tumor suppressor [147].
10.4.5 Histone Phosphorylation in Breast Cancer
Phosphorylation event of histone is thought to have a role in chromatin remodeling and in transcription, and therefore could potentially be associated with the human cancer development. Phosphorylation of H3 on S10 and S28 is essential not only during mitotic chromosome condensation but also in transcriptional activation of immediate early genes. When MCF7 cells were treated with phorbol ester, the number of H3 pS10 foci was increased, and were positioned next to actively transcribed regions in the nucleus. Seemingly, these nuclear sites represent the nuclear location of genes that are induced or in a competent state. Therefore, growth factors stimulating the Ras/MAPK and increasing H3 pS10 at transcriptionally active loci may contribute to aberrant gene expression and breast cancer progression [148].
10.4.6 Other Histone Modifications in Breast Cancer
Apart from acetylation, methylation and phosphorylation, there are some other modifications of histones occur. These epigenetic changes include ubiquitination/sumoylation, ADP-ribosylation, deamination, and proline isomerization. However, their function and mechanism is not clear, some studies have showed that they are also associated with breast cancer and other human cancers.
Regulation of the expression of genes by phosphorylated and undersumoylated PRs is a novel form of hormone independent PR action that is predicted to contribute to breast cancer cell growth and survival [149]. Recently, E3 ubiquitin ligase has been shown to play important role in breast carcinogenesis. Ubiquitin-mediated protein degradation plays an important role in many cancer-related cellular processes. E3s play crucial role because they control the specificity of the substrate. Gathering evidence suggests that genetic and expression alteration of E3s plays important role in breast carcinogenesis [150]. Sumoylation of histone also seem to govern chromatin structure and function to mediate transcriptional repression and gene silencing [151].
10.5 Polycomb Group (PcG) Proteins
The Polycomb gene was discovered about 60 years ago as a mutation inducing a particular homeotic phenotype. Later studies indicated that Polycomb is a general repressor of homeotic genes [152]. Genes with similar functions were identified and grouped under the name Polycomb group (PcG) genes. These genes have demonstrated epigenetic regulation of genes during development and differentiation. These proteins function to maintain a silenced state of developmental regulators. The PcG genes encode subunits, which are part of the polycomb repressive complex. Furthermore, these PcG genes are closely associated with coordinated regulation of histone modification and methylation, thus inter connecting the various epigenetic mechanisms. The Polycomb Repressive Complex 1 (PRC1) plays a crucial role in reading histone methylation marks and silencing target genes [153]. PRC1 can be recruited to chromatin by the PC chromodomain-mediated recognition of the H3K27me3 mark, which is deposited by PRC2. PRC1 components can also repress transcription without directly contacting transcription factors. Isolation of a core PRC1 complex, called PCC, that contains PC, PH, PSC and dRING1, revealed that these four PcG proteins are sufficient to inhibit ATP- dependent chromatin remodeling by the SWI/SNF complex, a homolog of the Drosophila BRM complex.
The Polycomb group (PcG) comprises several proteins that form multiprotein complexes, 2–5 MDa in size, that regulate gene activity at the chromatin level. The first components of Drosophila PcG were identified in 1980s and after several years it was recognized in mammalian cells, indicating strong evolutionary conservation [154]. PcG proteins, along with the counteracting Trithorax group (TrxG) proteins, were initially recognized as part of the memory system that transmission of cell identities throughout cell division [155]. PcG protein expression appears to be tightly regulated during normal cell proliferation and differentiation. While the expression, of PcG is frequently dysregulated in several cancer types [156]. Several PcG genes regulate self-renewal of specific stem cells, suggesting a link between the maintenance of cell homeostasis and carcinogenesis [157]. Bmi-1 was initially identified as an oncogene that cooperated with c-Myc in the generation of mouse pre-B-cell lymphomas [158]. It is also considered to be the first functional mammalian PcG protooncogene, and has been implicated in axial patterning, hematopoiesis, cell cycle regulation, and senescence. Data obtained in mice and in vitro studies have indicated that Bmi-1 protein regulates the INK4a/ARF locus, which encodes two unrelated tumor suppressors, p16INK4a and p19ARF (p14ARF in humans), which act in the two main cell cycle control pathways (pRb and p53, respectively) [159]. However, the effect of Bmi-1 overexpression on the inactivation of the INK4a/ARF transcripts in human tumorigenesis is unclear. One study demonstrated that although high levels of Bmi-1 were frequently observed in tumors, they did not correlate with downregulation of p16INK4a or p14ARF. A correlation between c-Myc and Bmi-1 expression levels has been shown; however, tumors showing elevated expression of both genes were not associated to a worse prognosis.
10.6 Non-coding RNAs
Many non-coding RNAs such as microRNA, small nucleolar RNAs, and repeat-associated small interfering RNA have been shown to alter transcription. MicroRNAs are small non-coding RNAs of approximately 22 nucleotides [160]. Several genes that are responsible for breast cancer progression are shown to be targeted by microRNAs, for example, miR-199b-5p was shown to inhibit HER2 expression by directly targeting its 3′-untranslated region (3′UTR) in breast cancer cells [161].
10.6.1 MicroRNAs Inhibit Target mRNA Translation
Initial studies on miRNAs suggested that these small non-coding RNAs inhibit mRNA translation, with perfect or near perfect complimentarity inducing mRNA degradation, while imperfect binding resulting in inhibition of translation [162]. Oncogenic microRNAs are also called as OncomiRs and they have been shown to promote breast cancer. These include miR-10 family, which regulate Hox transcripts [163]. In case of breast cancer, miR-10 family is reported to be involved both in the development and metastasis through miR-10a and miR-10b, respectively. Expression of miR-21 is negatively correlated with expression of PTEN in breast cancer and also correlates with advanced stage and metastasis and poor survival [164]. Finally, miR-17 ~ 92 cluster is a polycistron and is located in a region of DNA that is amplified in various cancer. The expression of miR-17–5p is increased in invasive MDA-MB-231 cells but not in non-invasive MCF-7 breast cancer cells [165]. Ectopic expression of this miRNA in MCF-7 cells can lead to more invasive and migratory phenotypes by targeting HBP1/β-catenin pathway. Similarly, down regulation of miR-17–5p suppresses the migration and invasion of MDA-MB-231 cells in vitro.
There are also tumor suppressor microRNAs. The Let-7 family includes members that affect muscle formation, cell adhesion and regulation of gene expression and development [166]. Let-7 expression is lost in breast cancer at an early stage of disease progression in breast cancer. Similarly, the miR-200 family is lost in invasive breast cancer cell lines with mesenchymal phenotypes and also in regions of metaplastic breast cancer specimens lacking E-cadherin. The miR-200 family has been shown to regulate PLCG1, Bmi1, TGF-β2, FAP-1, ZEB and Suz12, hence acting as tumors suppressor [167, 168]. The expression of miR-205 is restricted to basal epithelium of normal mammary ducts and lobules, but its expression is reduced or lost in tumor [169]. Ectopic expression of miR-205 in breast cancer cells inhibits invasion, proliferation and anchorage independent growth, in part through direct targeting of Her3 and VEGF-A [170]. In addition, miR-145, is significantly downregulated in breast cancer specimen compared with normal breast tissue [171]. Furthermore, miR-145 can directly target estrogen receptor-α (ER-α) protein expression through direct interaction and promotes apoptosis in both ER-α positive and wild type TP53-expressing breast cancer cells.
Breast cancer metastatic related microRNAs, there are miRNAs that promote the metastasis in breast cancer include miR-9, miR-10b, miR-21, miR-29a, miR-155 and miR-373/520 family. On the other hand there are microRNAs reported to suppress metastasis and they are, miR-7, miR-17/20, miR-22, miR-30, miR-31, miR-126, miR-145, miR-146, miR-193b, miR-205, miR-206, miR-335, miR-448, miR-661 and let-7 [172].
10.6.2 MicroRNA Control of Epigenetic Mechanisms
Both miRNAs, and small interfering RNAs (siRNAs) are involved in both DNA methylation and histone modifications. Maison et al. showed that RNAse treatment can abolish the localization of methylated H3 lysine 9 and HP1 to pericentromeric chromatin [173]. Fukagawa et al. demonstrated that Dicer-related RNAi machinery is necessary for the formation of heterochromatin structure [174]. Furthermore, miR22, miR206, and miR-221/222 regulate ER-α expression in breast cancer [175]. MicroRNAs can target genes coding for enzymes responsible for histone modification (EZH2) and DNA methylation (DNMT3A and DNMT3B) [176]. miR-101 and miR-26a target the EZH2 mRNA 3′UTR and inhibits its translation [177].
Studies from Shimono et al. reported that 37 miRNAs are differentially expressed in CD44+/CD24-/low breast cancer stem cells as compared with non-tumorigenic cancer cells. In particular, three clusters, miR-200c-141, miR-200b-200a-429 and miR-183–96–182, are significantly down regulated. Furthermore, loss of p53 leads to a decreased level of miR-200c and an increase in the expression of EMT and stemness markers, leading to the development of a high tumor grade [178]. In addition, Han and colleagues isolated ALDH1+ and CD44+/CD24-/low cells from MCF-7 parental cells and found that HIF-1α and miR-21 are upregulated in the stem-like cells [179]. Moreover, reduction in miR-21 expression by antagomir leads to reversal of EMT, downregulation of HIF-1α, as well as suppression of invasion and migration. This indicates that miR-21 regulates EMT transition in breast cancer stem cells as well as HIF-1α overexpression.
10.6.3 Epigenetic Control of MicroRNA Expression
While microRNAs regulate epigenetic mechanisms, microRNA expression itself can be regulated in a similar manner. Interestingly, CpG island methylations in miRNA regions influence miRNA function, thereby altering the processes of tumorigenesis [180]. Nearly half of all identified miRNAs are associated with CpG sites, and studies revealed methylation levels at several miRNA loci across normal and malignant cell lines [181]. Silencing of miRNA gene expression due to hypermethylation is also a feature of several cancers. MicroRNAs can trigger transcriptional silencing via chromatin remodeling [182]. Tumor suppressor miRNAs could undergo aberrant DNA methylation accompanied by histone modifications associated with transcriptional inactivation. Interestingly, miR-124a silencing by DNA methylation was accompanied by the absence of active histone markers, such as acetylation of histone H3, acetylation of histone H4, trimethylation of histone H3-lysine 4, and occupancy by MBDs such as MeCP2 and MBD2 [183]. The epigenetic regulation of miR-196a-2 in breast cancer development has also been studied. Hypermethylation of a CpG island 700 bp upstream of the miR-196a-2 precursor promoter was associated with reduced breast cancer risk [181]. Putative targets for the microRNA include HOXD10, LSP1 and TOX3. HOXD10 is a target for initiation of breast cancer invasion and metastasis, LSP1 and TOX3 (TNRC9) were identified as novel breast cancer susceptibility markers in large-scale whole-genome association studies [184]. Furthermore, miR335 locus on 7q32.2 is a selective metastasis suppressor and tumor initiation suppressor locus in human breast cancer. In fact, miR-335 regulates a set of genes that regulate metastasis [185]. This locus also undergoes epigenetic hypermethylation in every patient metastatic cell population. In addition, genetic deletion of miR-335 is a common event in human breast cancer [185]. There are several other miRNAs that are regulated by hypermethylation of the promoter region including miR-9-1 (targets transcription factor REST and its partner CoREST), miR-124a3, miR-148, and miR663 [186].
10.7 Epigenetics and Cancer Stem Cells
Cancer stem cells (CDCs) are relatively rare subpopulation of cells within a tumor that has the ability to initiate new tumor growth and have the capacity to self-renewal, the use of key regulatory pathways and establishment of dynamic epigenetic profiles. Compared to normal adult stem cells, CSCs will have higher proliferative rates and less dependence to stem cell niche. They may give rise to cellular heterogeneity in the tumor by initiating epigenetic reprogramming, this is because most of the currently known markers including CD44, Bmi1, ALDH1, CD133, and EPCAM have been shown to be regulated by either DNA methylation or histone modifications [187]. Furthermore, analysis of DNA methylation profile of CSCs, suggest that epigenetic markers of stemness of CSCs resemble embryonic stem cells rather than the adult normal stem cells pattern. The major problem with cancer chemotherapy is the development of resistance to the drugs, especially in CSCs; therefore understanding the epigenetic profile of these CSCs will provide us new avenues for developing new therapeutics for breast cancer.
10.8 Epigenetic Modifier Drugs Against Breast Cancer
There are many drugs in clinical trials for breast cancer that are epigenetic modifiers (Table 10.2), most of which come under the classification of HDAC inhibitors. Vorinostat a hydroxamic acid is being used as a single agent or in combination with tamoxifen, aromatase inhibitor, paclitaxel, carboplatin, trastuzumab, ixabepilone, lapatinib [188]. Another HDAC inhibitor in the breast cancer clinical trial is Entinostat, which comes under Benzamide sub class, this agent is being combined with exemestane, Anastrozole and lapatinib [188].
10.8.1 Nucleoside Analogs
There are several nucleoside analogue methylation inhibitors such as 5-azacytidine, 5-aza-2′-deoxycytidine, 5′-fluro-2′-deoxycytidine and Zebularine. These inhibitors affect DNA synthesis and are implicated to regulate DNA methylation. The formation of covalent complexes with DNMTs results in depletion of the enzyme and finally, a reversal of the methylation pattern. The non-nucleoside analogues are shown to inhibit DNA methylation by binding directly to the catalytic region of the DNMT without incorporating into DNA. RG108, was shown to inhibit DNA methyltransferase [189], however, it has not entered clinical trials. A non-toxic antisense oligonucleotide, MG98 has been shown to prevent translation of DNMT1 mRNA by hybridizing to the 3′UTR of the DNMT1 mRNA [190]. In addition, NVP-LAQ824, a derivative of a compound derived from the sponge Psseudoceratina purpurea called Psammapalin, inhibits both DNMTs and HDACs [191]. Furthermore, there are several other agents such as Decitabine and SGI-110 that are nucleoside analogues that inhibit DNMT [188, 192]. The green tea compound epigallocatechin-3 gallate (EGCG) has also been shown to reduce DNA methylation and increase transcription of tumor suppressor genes [193]. Currently, EGCG is being tested in clinical trial [194].
10.8.2 Histone Deacetylation Inhibitors
These are agents that inhibit histone deacetylase enzymes leading to increased acetylation in histones and resulting in altered cellular processes that have become defective in cancerous cells. The compounds are divided into short chain fatty acids, hydroxamic acids, cyclic tetrapeptides and benzamides. Currently, there are several HDAC inhibitors in clinical development for treatment of variety of cancers.
10.8.3 Short Chain Fatty Acids (SCFA)
HDAC inhibition by SCFAs was first demonstrated using butyrate resulting in hyperacetylate of histones H3 and H4 [195]. Valproic acid and phenylbutyrate is now used clinically as histone deacetylase inhibitor for breast cancer [196]. They induce proteosomal degradation of HDAC2 by inhibiting the catalytic activity of class I HDACs.
10.8.4 Hydroxamic Acids
Trichostatin A is an HDAC inhibitor that can inhibit the viability of breast cancer cells [197]. Suberoylanilide hydroxamic acid (SAHA) is another molecule that has been shown to inhibit both class I and II HDAC enzymes [198]. SAHA has FDA approval for treating cutaneous manifestations of lymphoma patients. Furthermore, there are other drugs such as Panobinostat, Belinostat, CHR-3996, Tefinostat, JNJ-26481585 that have entered the clinical studies [188].
10.8.5 Cyclic Tetrapeptides
Trapoxin accumulates highly acetylated core histones [199]. Even low concentrations of trapoxin can bind to histone deacetylase through epoxide moiety and inhibit deacetylation of acetylated histones [200]. Despsipeptide, a bicyclic peptide increases p53 expression in breast cancer cells [201]. In addition, CHAP, cyclic hydroxamic acid-containing peptide has been shown to inhibit HDAC [202]. Apicidin, a cyclic tetrapeptide increases the levels of acetylated histone H3 and H4 in breast cancer cells [203].
10.8.6 Benzamides
There are many benzamides that are either in clinical trials or are in preclinical testing. Entinostat (MS-275) treatment results in hyperacetylation of nuclear histones in various tumor cells [204]. This class I HDAC selective inhibitor is currently being used in the phase II clinical trials for triple negative breast cancers. In addition, Mocetinostat (MGCD-0103), a class-selective HDAC inhibitor with IC50s in the submicromolar range has entered clinical trials, although not for breast cancers [188]. Finally, N-acetyldinaline (CI-994), another histone deacetylase inhibitor with a substituted benzamide derivative causes accumulation of acetylated histones [205]. The combination of current therapy with these novel inhibitors can result in successful treatment of breast cancer.
10.9 Conclusion
Over the last decade our knowledge on hypermethylation of DNA sequences and histone modifications along with Polycomb group proteins and microRNAs, and their epigenetic role in regulation of breast cancer gene expression has been increased tremendously. However, much needs to be done to understand the exact mechanisms initiating these changes during tumor development and progression. There may be a critical cross talk between the genetics and epigenetics, which has to be studied thoroughly to enhance our understanding of breast cancer initiation and progression. Identifying the epigenetic signature of breast cancer and the molecular mechanisms will definitely enhance the treatment opportunity.
References
Sikora MJ, Jankowitz RC, Dabbs DJ, Oesterreich S (2012) Invasive lobular carcinoma of the breast: patient response to systemic endocrine therapy and hormone response in model systems. Steroids pii: S0039-128X(12):00302–00309
Krontiras H, Bramlett R, Umphrey H (2013) How do I screen patients for breast cancer? Curr Treat Options Oncol 14(1):88–96
Holliday R (2006) Epigenetics: a historical overview. Epigenetics 1:76–80
Zovkic IB, Sweatt JD (2013) Epigenetic mechanisms in learned fear: implications for PTSD. Neuropsychopharmacology 38:77–93
Sager R, Kitchin R (1975) Selective silencing of eukaryotic DNA. Science 189:426–433
Chandler LA, DeClerck YA, Bogenmann E, Jones PA (1986) Patterns of DNA methylation and gene expression in human tumor cell lines. Cancer Res 46:2944–2949
Wakim BT, Aswad GD (1994) Ca(2+)-calmodulin-dependent phosphorylation of arginine in histone 3 by a nuclear kinase from mouse leukemia cells. J Biol Chem 269:2722–2727
Nystrom M, Mutanen M (2009) Diet and epigenetics in colon cancer. World J Gastroenterol 15:257–263
Mense SM, Hei TK, Ganju RK, Bhat HK (2008) Phytoestrogens and breast cancer prevention: possible mechanisms of action. Environ Health Perspect 116:426–433
Gavery MR, Roberts SB (2010) DNA methylation patterns provide insight into epigenetic regulation in the Pacific oyster (Crassostrea gigas). BMC Genomics 11:483
Takai D, Jones PA (2002) Comprehensive analysis of CpG islands in human chromosomes 21 and 22. Proc Natl Acad Sci U S A 99:3740–3745
Laird PW (2003) The power and the promise of DNA methylation markers. Nat Rev Cancer 3:253–266
Antequera F, Bird A (1999) CpG islands as genomic footprints of promoters that are associated with replication origins. Curr Biol 9:R661–R667
Bestor T, Laudano A, Mattaliano R, Ingram V (1988) Cloning and sequencing of a cDNA encoding DNA methyltransferase of mouse cells. The carboxyl-terminal domain of the mammalian enzymes is related to bacterial restriction methyltransferases. J Mol Biol 203:971–983
Athanasiadou R, de Sousa D, Myant K, Merusi C, Stancheva I et al (2010) Targeting of de novo DNA methylation throughout the Oct-4 gene regulatory region in differentiating embryonic stem cells. PLoS One 5:e9937
Howe LR, Brown AM (2004) Wnt signaling and breast cancer. Cancer Biol Ther 3:36–41
Kawano Y, Kypta R (2003) Secreted antagonists of the Wnt signalling pathway. J Cell Sci 116:2627–2634
Bovolenta P, Esteve P, Ruiz JM, Cisneros E, Lopez-Rios J (2008) Beyond Wnt inhibition: new functions of secreted Frizzled-related proteins in development and disease. J Cell Sci 121:737–746
Veeck J, Noetzel E, Bektas N, Jost E, Hartmann A et al (2008) Promoter hypermethylation of the SFRP2 gene is a high-frequent alteration and tumor-specific epigenetic marker in human breast cancer. Mol Cancer 7:83
Veeck J, Niederacher D, An H, Klopocki E, Wiesmann F et al (2006) Aberrant methylation of the Wnt antagonist SFRP1 in breast cancer is associated with unfavourable prognosis. Oncogene 25:3479–3488
Veeck J, Geisler C, Noetzel E, Alkaya S, Hartmann A et al (2008) Epigenetic inactivation of the secreted frizzled-related protein-5 (SFRP5) gene in human breast cancer is associated with unfavorable prognosis. Carcinogenesis 29:991–998
Nilsson S, Makela S, Treuter E, Tujague M, Thomsen J et al (2001) Mechanisms of estrogen action. Physiol Rev 81:1535–1565
Goulart AC, Zee RY, Pradhan A, Rexrode KM (2009) Associations of the estrogen receptors 1 and 2 gene polymorphisms with the metabolic syndrome in women. Metab Syndr Relat Disord 7:111–117
Mann M, Cortez V, Vadlamudi RK (2011) Epigenetics of estrogen receptor signaling: role in hormonal cancer progression and therapy. Cancers (Basel) 3:1691–1707
Bandyopadhyay A, Wang L, Chin SH, Sun LZ (2007) Inhibition of skeletal metastasis by ectopic ERalpha expression in ERalpha-negative human breast cancer cell lines. Neoplasia 9:113–118
Ottaviano YL, Issa JP, Parl FF, Smith HS, Baylin SB et al (1994) Methylation of the estrogen receptor gene CpG island marks loss of estrogen receptor expression in human breast cancer cells. Cancer Res 54:2552–2555
Melki JR, Vincent PC, Clark SJ (1999) Concurrent DNA hypermethylation of multiple genes in acute myeloid leukemia. Cancer Res 59:3730–3740
Yang X, Yan L, Davidson NE (2001) DNA methylation in breast cancer. Endocr Relat Cancer 8:115–127
Ferguson AT, Vertino PM, Spitzner JR, Baylin SB, Muller MT et al (1997) Role of estrogen receptor gene demethylation and DNA methyltransferase. DNA adduct formation in 5-aza-2′deoxycytidine-induced cytotoxicity in human breast cancer cells. J Biol Chem 272:32260–32266
Picard E, Seguin C, Monhoven N, Rochette-Egly C, Siat J et al (1999) Expression of retinoid receptor genes and proteins in non-small-cell lung cancer. J Natl Cancer Inst 91:1059–1066
Guleria RS, Choudhary R, Tanaka T, Baker KM, Pan J (2011) Retinoic acid receptor-mediated signaling protects cardiomyocytes from hyperglycemia induced apoptosis: role of the renin-angiotensin system. J Cell Physiol 226:1292–1307
Yang Q, Mori I, Shan L, Nakamura M, Nakamura Y et al (2001) Biallelic inactivation of retinoic acid receptor beta2 gene by epigenetic change in breast cancer. Am J Pathol 158:299–303
Bean GR, Scott V, Yee L, Ratliff-Daniel B, Troch MM et al (2005) Retinoic acid receptor-beta2 promoter methylation in random periareolar fine needle aspiration. Cancer Epidemiol Biomarkers Prev 14:790–798
Widschwendter M, Berger J, Hermann M, Muller HM, Amberger A et al (2000) Methylation and silencing of the retinoic acid receptor-beta2 gene in breast cancer. J Natl Cancer Inst 92:826–832
Liu Z, Zhang L, Ding F, Li J, Guo M et al (2005) 5-Aza-2′-deoxycytidine induces retinoic acid receptor-beta(2) demethylation and growth inhibition in esophageal squamous carcinoma cells. Cancer Lett 230:271–283
Yuan J, Luo RZ, Fujii S, Wang L, Hu W et al (2003) Aberrant methylation and silencing of ARHI, an imprinted tumor suppressor gene in which the function is lost in breast cancers. Cancer Res 63:4174–4180
Fujii S, Luo RZ, Yuan J, Kadota M, Oshimura M et al (2003) Reactivation of the silenced and imprinted alleles of ARHI is associated with increased histone H3 acetylation and decreased histone H3 lysine 9 methylation. Hum Mol Genet 12:1791–1800
Feng W, Shen L, Wen S, Rosen DG, Jelinek J et al (2007) Correlation between CpG methylation profiles and hormone receptor status in breast cancers. Breast Cancer Res 9:R57
Powell SN, Kachnic LA (2003) Roles of BRCA1 and BRCA2 in homologous recombination, DNA replication fidelity and the cellular response to ionizing radiation. Oncogene 22:5784–5791
Burga LN, Hu H, Juvekar A, Tung NM, Troyan SL et al (2011) Loss of BRCA1 leads to an increase in epidermal growth factor receptor expression in mammary epithelial cells, and epidermal growth factor receptor inhibition prevents estrogen receptor-negative cancers in BRCA1-mutant mice. Breast Cancer Res 13:R30
Locke I, Kote-Jarai Z, Bancroft E, Bullock S, Jugurnauth S et al (2006) Loss of heterozygosity at the BRCA1 and BRCA2 loci detected in ductal lavage fluid from BRCA gene mutation carriers and controls. Cancer Epidemiol Biomarkers Prev 15:1399–1402
Catteau A, Harris WH, Xu CF, Solomon E (1999) Methylation of the BRCA1 promoter region in sporadic breast and ovarian cancer: correlation with disease characteristics. Oncogene 18:1957–1965
Esteller M, Silva JM, Dominguez G, Bonilla F, Matias-Guiu X et al (2000) Promoter hypermethylation and BRCA1 inactivation in sporadic breast and ovarian tumors. J Natl Cancer Inst 92:564–569
Wei M, Grushko TA, Dignam J, Hagos F, Nanda R et al (2005) BRCA1 promoter methylation in sporadic breast cancer is associated with reduced BRCA1 copy number and chromosome 17 aneusomy. Cancer Res 65:10692–10699
Lim SP, Wong NC, Suetani RJ, Ho K, Ng JL et al (2012) Specific-site methylation of tumour suppressor ANKRD11 in breast cancer. Eur J Cancer 48:3300–3309
Parc Y, Boisson C, Thomas G, Olschwang S (2003) Cancer risk in 348 French MSH2 or MLH1 gene carriers. J Med Genet 40:208–213
Mackay HJ, Cameron D, Rahilly M, Mackean MJ, Paul J et al (2000) Reduced MLH1 expression in breast tumors after primary chemotherapy predicts disease-free survival. J Clin Oncol 18:87–93
Westenend PJ, Schutte R, Hoogmans MM, Wagner A, Dinjens WN (2005) Breast cancer in an MSH2 gene mutation carrier. Hum Pathol 36:1322–1326
Chow LS, Lo KW, Kwong J, To KF, Tsang KS et al (2004) RASSF1A is a target tumor suppressor from 3p21.3 in nasopharyngeal carcinoma. Int J Cancer 109:839–847
van der Weyden L, Adams DJ (2007) The Ras-association domain family (RASSF) members and their role in human tumourigenesis. Biochim Biophys Acta 1776:58–85
Burbee DG, Forgacs E, Zochbauer-Muller S, Shivakumar L, Fong K et al (2001) Epigenetic inactivation of RASSF1A in lung and breast cancers and malignant phenotype suppression. J Natl Cancer Inst 93:691–699
Euhus DM, Bu D, Milchgrub S, Xie XJ, Bian A et al (2008) DNA methylation in benign breast epithelium in relation to age and breast cancer risk. Cancer Epidemiol Biomarkers Prev 17:1051–1059
Peters I, Vaske B, Albrecht K, Kuczyk MA, Jonas U et al (2007) Adiposity and age are statistically related to enhanced RASSF1A tumor suppressor gene promoter methylation in normal autopsy kidney tissue. Cancer Epidemiol Biomarkers Prev 16:2526–2532
Lehmann U, Langer F, Feist H, Glockner S, Hasemeier B et al (2002) Quantitative assessment of promoter hypermethylation during breast cancer development. Am J Pathol 160:605–612
Pizzi S, Azzoni C, Bottarelli L, Campanini N, D’Adda T et al (2005) RASSF1A promoter methylation and 3p21.3 loss of heterozygosity are features of foregut, but not midgut and hindgut, malignant endocrine tumours. J Pathol 206:409–416
Jagadeesh S, Sinha S, Pal BC, Bhattacharya S, Banerjee PP (2007) Mahanine reverses an epigenetically silenced tumor suppressor gene RASSF1A in human prostate cancer cells. Biochem Biophys Res Commun 362:212–217
Liu SC, Bassi DE, Zhang SY, Holoran D, Conti CJ et al (2002) Overexpression of cyclin D2 is associated with increased in vivo invasiveness of human squamous carcinoma cells. Mol Carcinog 34:131–139
Evron E, Umbricht CB, Korz D, Raman V, Loeb DM et al (2001) Loss of cyclin D2 expression in the majority of breast cancers is associated with promoter hypermethylation. Cancer Res 61:2782–2787
Brooks J, Cairns P, Zeleniuch-Jacquotte A (2009) Promoter methylation and the detection of breast cancer. Cancer Causes Control 20:1539–1550
Serrano M, Hannon GJ, Beach D (1993) A new regulatory motif in cell-cycle control causing specific inhibition of cyclin D/CDK4. Nature 366:704–707
Vermeulen K, Van Bockstaele DR, Berneman ZN (2003) The cell cycle: a review of regulation, deregulation and therapeutic targets in cancer. Cell Prolif 36(3):131–149
Taneja P, Frazier DP, Kendig RD, Maglic D, Sugiyama T et al (2009) MMTV mouse models and the diagnostic values of MMTV-like sequences in human breast cancer. Expert Rev Mol Diagn 9:423–440
Du Y, Carling T, Fang W, Piao Z, Sheu JC et al (2001) Hypermethylation in human cancers of the RIZ1 tumor suppressor gene, a member of a histone/protein methyltransferase superfamily. Cancer Res 61:8094–8099
Huang S, Shao G, Liu L (1998) The PR domain of the Rb-binding zinc finger protein RIZ1 is a protein binding interface and is related to the SET domain functioning in chromatin-mediated gene expression. J Biol Chem 273:15933–15939
Liu ZY, Wang JY, Liu HH, Ma XM, Wang CL et al (2012) Retinoblastoma protein-interacting zinc-finger gene 1 (RIZ1) dysregulation in human malignant meningiomas. Oncogene. doi:10.1038/onc.2012.155
Conway KE, McConnell BB, Bowring CE, Donald CD, Warren ST et al (2000) TMS1, a novel proapoptotic caspase recruitment domain protein, is a target of methylation-induced gene silencing in human breast cancers. Cancer Res 60:6236–6242
Stimson KM, Vertino PM (2002) Methylation-mediated silencing of TMS1/ASC is accompanied by histone hypoacetylation and CpG island-localized changes in chromatin architecture. J Biol Chem 277:4951–4958
Ferguson AT, Evron E, Umbricht CB, Pandita TK, Chan TA et al (2000) High frequency of hypermethylation at the 14-3-3 sigma locus leads to gene silencing in breast cancer. Proc Natl Acad Sci U S A 97:6049–6054
Lal G, Padmanabha L, Provenzano M, Fitzgerald M, Weydert J et al (2008) Regulation of 14-3-3sigma expression in human thyroid carcinoma is epigenetically regulated by aberrant cytosine methylation. Cancer Lett 267:165–174
Kimchi A (1999) DAP kinase and DAP-3: novel positive mediators of apoptosis. Ann Rheum Dis 58(Suppl 1):I14–I19
Katzenellenbogen RA, Baylin SB, Herman JG (1999) Hypermethylation of the DAP-kinase CpG island is a common alteration in B-cell malignancies. Blood 93:4347–4353
Bai T, Tanaka T, Yukawa K, Umesaki N (2006) A novel mechanism for acquired cisplatin-resistance: suppressed translation of death-associated protein kinase mRNA is insensitive to 5-aza-2′-deoxycitidine and trichostatin in cisplatin-resistant cervical squamous cancer cells. Int J Oncol 28:497–508
Noetzel E, Veeck J, Niederacher D, Galm O, Horn F et al (2008) Promoter methylation-associated loss of ID4 expression is a marker of tumour recurrence in human breast cancer. BMC Cancer 8:154
Norton JD (2000) ID helix-loop-helix proteins in cell growth, differentiation and tumorigenesis. J Cell Sci 113(Pt 22):3897–3905
Roberts EC, Deed RW, Inoue T, Norton JD, Sharrocks AD (2001) Id helix-loop-helix proteins antagonize pax transcription factor activity by inhibiting DNA binding. Mol Cell Biol 21:524–533
Wilson JW, Deed RW, Inoue T, Balzi M, Becciolini A et al (2001) Expression of Id helix-loop-helix proteins in colorectal adenocarcinoma correlates with p53 expression and mitotic index. Cancer Res 61:8803–8810
Umetani N, Mori T, Koyanagi K, Shinozaki M, Kim J et al (2005) Aberrant hypermethylation of ID4 gene promoter region increases risk of lymph node metastasis in T1 breast cancer. Oncogene 24:4721–4727
Campione M, Acosta L, Martinez S, Icardo JM, Aranega A et al (2002) Pitx2 and cardiac development: a molecular link between left/right signaling and congenital heart disease. Cold Spring Harb Symp Quant Biol 67:89–95
Martens JW, Margossian AL, Schmitt M, Foekens J, Harbeck N (2009) DNA methylation as a biomarker in breast cancer. Future Oncol 5:1245–1256
Hartmann O, Spyratos F, Harbeck N, Dietrich D, Fassbender A et al (2009) DNA methylation markers predict outcome in node-positive, estrogen receptor-positive breast cancer with adjuvant anthracycline-based chemotherapy. Clin Cancer Res 15:315–323
MacDonald BT, Tamai K, He X (2009) Wnt/beta-catenin signaling: components, mechanisms, and diseases. Dev Cell 17:9–26
Liu Z, Yang L, Cui DX, Liu BL, Zhang XB et al (2007) Methylation status and protein expression of adenomatous polyposis coli (APC) gene in breast cancer. Ai Zheng 26:586–590
Lee A, Kim Y, Han K, Kang CS, Jeon HM et al (2004) Detection of tumor markers including carcinoembryonic antigen, APC, and cyclin D2 in fine-needle aspiration fluid of breast. Arch Pathol Lab Med 128:1251–1256
Esteller M, Corn PG, Urena JM, Gabrielson E, Baylin SB et al (1998) Inactivation of glutathione S-transferase P1 gene by promoter hypermethylation in human neoplasia. Cancer Res 58:4515–4518
Cairns J, Wright C, Cattan AR, Hall AG, Cantwell BJ et al (1992) Immunohistochemical demonstration of glutathione S-transferases in primary human breast carcinomas. J Pathol 166:19–25
Gilbert L, Elwood LJ, Merino M, Masood S, Barnes R et al (1993) A pilot study of pi-class glutathione S-transferase expression in breast cancer: correlation with estrogen receptor expression and prognosis in node-negative breast cancer. J Clin Oncol 11:49–58
Cavalieri EL, Stack DE, Devanesan PD, Todorovic R, Dwivedy I et al (1997) Molecular origin of cancer: catechol estrogen-3,4-quinones as endogenous tumor initiators. Proc Natl Acad Sci U S A 94:10937–10942
Weber BH, Vogt G, Pruett RC, Stohr H, Felbor U (1994) Mutations in the tissue inhibitor of metalloproteinases-3 (TIMP3) in patients with Sorsby’s fundus dystrophy. Nat Genet 8:352–356
Cameron EE, Bachman KE, Myohanen S, Herman JG, Baylin SB (1999) Synergy of demethylation and histone deacetylase inhibition in the re-expression of genes silenced in cancer. Nat Genet 21:103–107
Bachman KE, Herman JG, Corn PG, Merlo A, Costello JF et al (1999) Methylation-associated silencing of the tissue inhibitor of metalloproteinase-3 gene suggest a suppressor role in kidney, brain, and other human cancers. Cancer Res 59:798–802
Pathiraja TN, Shetty PB, Jelinek J, He R, Hartmaier R et al (2011) Progesterone receptor isoform-specific promoter methylation: association of PRA promoter methylation with worse outcome in breast cancer patients. Clin Cancer Res 17:4177–4186
Law ML, Kao FT, Wei Q, Hartz JA, Greene GL et al (1987) The progesterone receptor gene maps to human chromosome band 11q13, the site of the mammary oncogene int-2. Proc Natl Acad Sci U S A 84:2877–2881
Li L, Lee KM, Han W, Choi JY, Lee JY et al (2010) Estrogen and progesterone receptor status affect genome-wide DNA methylation profile in breast cancer. Hum Mol Genet 19:4273–4277
Ferguson AT, Lapidus RG, Davidson NE (1998) Demethylation of the progesterone receptor CpG island is not required for progesterone receptor gene expression. Oncogene 17:577–583
Wang GY, Lu CQ, Zhang RM, Hu XH, Luo ZW (2008) The E-cadherin gene polymorphism 160C- > A and cancer risk: a HuGE review and meta-analysis of 26 case-control studies. Am J Epidemiol 167:7–14
Caldeira JR, Prando EC, Quevedo FC, Neto FA, Rainho CA et al (2006) CDH1 promoter hypermethylation and E-cadherin protein expression in infiltrating breast cancer. BMC Cancer 6:48
Nass SJ, Herman JG, Gabrielson E, Iversen PW, Parl FF et al (2000) Aberrant methylation of the estrogen receptor and E-cadherin 5′ CpG islands increases with malignant progression in human breast cancer. Cancer Res 60:4346–4348
Giannelli G, Antonaci S (2000) Biological and clinical relevance of Laminin-5 in cancer. Clin Exp Metastasis 18:439–443
Sathyanarayana UG, Padar A, Suzuki M, Maruyama R, Shigematsu H et al (2003) Aberrant promoter methylation of laminin-5-encoding genes in prostate cancers and its relationship to clinicopathological features. Clin Cancer Res 9:6395–6400
Kurosu H, Ogawa Y, Miyoshi M, Yamamoto M, Nandi A et al (2006) Regulation of fibroblast growth factor-23 signaling by klotho. J Biol Chem 281:6120–6123
Rubinek T, Shulman M, Israeli S, Bose S, Avraham A et al (2012) Epigenetic silencing of the tumor suppressor klotho in human breast cancer. Breast Cancer Res Treat 133:649–657
Nguyen Ba-Charvet KT, Brose K, Ma L, Wang KH, Marillat V et al (2001) Diversity and specificity of actions of Slit2 proteolytic fragments in axon guidance. J Neurosci 21:4281–4289
Shivapurkar N, Virmani AK, Wistuba II, Milchgrub S, Mackay B et al (1999) Deletions of chromosome 4 at multiple sites are frequent in malignant mesothelioma and small cell lung carcinoma. Clin Cancer Res 5:17–23
Dallol A, Da Silva NF, Viacava P, Minna JD, Bieche I et al (2002) SLIT2, a human homologue of the Drosophila Slit2 gene, has tumor suppressor activity and is frequently inactivated in lung and breast cancers. Cancer Res 62:5874–5880
Vallejo J, Hardin CD (2005) Expression of caveolin-1 in lymphocytes induces caveolae formation and recruitment of phosphofructokinase to the plasma membrane. FASEB J 19:586–587
Engelman JA, Zhang XL, Lisanti MP (1998) Genes encoding human caveolin-1 and -2 are co-localized to the D7S522 locus (7q31.1), a known fragile site (FRA7G) that is frequently deleted in human cancers. FEBS Lett 436:403–410
Syeed N, Hussain F, Husain SA, Siddiqi MA (2012) 5′-CpG island promoter hypermethylation of the CAV-1 gene in breast cancer patients of Kashmir. Asian Pac J Cancer Prev 13:371–375
Abdollahi A, Bao R, Hamilton TC (1999) LOT1 is a growth suppressor gene down-regulated by the epidermal growth factor receptor ligands and encodes a nuclear zinc-finger protein. Oncogene 18:6477–6487
Abdollahi A, Gruver BN, Patriotis C, Hamilton TC (2003) Identification of epidermal growth factor-responsive genes in normal rat ovarian surface epithelial cells. Biochem Biophys Res Commun 307:188–197
Abdollahi A, Pisarcik D, Roberts D, Weinstein J, Cairns P et al (2003) LOT1 (PLAGL1/ZAC1), the candidate tumor suppressor gene at chromosome 6q24-25, is epigenetically regulated in cancer. J Biol Chem 278:6041–6049
Hempel N, Wang H, LeCluyse EL, McManus ME, Negishi M (2004) The human sulfotransferase SULT1A1 gene is regulated in a synergistic manner by Sp1 and GA binding protein. Mol Pharmacol 66:1690–1701
Kwon MS, Kim SJ, Lee SY, Jeong JH, Lee ES et al (2006) Epigenetic silencing of the sulfotransferase 1A1 gene by hypermethylation in breast tissue. Oncol Rep 15:27–32
Qiu J, Ai L, Ramachandran C, Yao B, Gopalakrishnan S et al (2008) Invasion suppressor cystatin E/M (CST6): high-level cell type-specific expression in normal brain and epigenetic silencing in gliomas. Lab Invest 88:910–925
Rivenbark AG, Jones WD, Coleman WB (2006) DNA methylation-dependent silencing of CST6 in human breast cancer cell lines. Lab Invest 86:1233–1242
Bednarek AK, Laflin KJ, Daniel RL, Liao Q, Hawkins KA et al (2000) WWOX, a novel WW domain-containing protein mapping to human chromosome 16q23.3-24.1, a region frequently affected in breast cancer. Cancer Res 60:2140–2145
Wang X, Chao L, Jin G, Ma G, Zang Y et al (2009) Association between CpG island methylation of the WWOX gene and its expression in breast cancers. Tumour Biol 30:8–14
Veeck J, Bektas N, Hartmann A, Kristiansen G, Heindrichs U et al (2008) Wnt signalling in human breast cancer: expression of the putative Wnt inhibitor Dickkopf-3 (DKK3) is frequently suppressed by promoter hypermethylation in mammary tumours. Breast Cancer Res 10:R82
Yu X, Si J, Zhang Y, Dewille JW (2010) CCAAT/Enhancer Binding Protein-delta (C/EBP-delta) regulates cell growth, migration and differentiation. Cancer Cell Int 10:48
O’Rourke JP, Newbound GC, Hutt JA, DeWille J (1999) CCAAT/enhancer-binding protein delta regulates mammary epithelial cell G0 growth arrest and apoptosis. J Biol Chem 274:16582–16589
Si J, Yu X, Zhang Y, DeWille JW (2010) Myc interacts with Max and Miz1 to repress C/EBPdelta promoter activity and gene expression. Mol Cancer 9:92
Tang D, Sivko GS, DeWille JW (2006) Promoter methylation reduces C/EBPdelta (CEBPD) gene expression in the SUM-52PE human breast cancer cell line and in primary breast tumors. Breast Cancer Res Treat 95:161–170
Xian J, Aitchison A, Bobrow L, Corbett G, Pannell R et al (2004) Targeted disruption of the 3p12 gene, Dutt1/Robo1, predisposes mice to lung adenocarcinomas and lymphomas with methylation of the gene promoter. Cancer Res 64:6432–6437
Dallol A, Forgacs E, Martinez A, Sekido Y, Walker R et al (2002) Tumour specific promoter region methylation of the human homologue of the Drosophila Roundabout gene DUTT1 (ROBO1) in human cancers. Oncogene 21:3020–3028
Cohen I, Poreba E, Kamieniarz K, Schneider R (2011) Histone modifiers in cancer: friends or foes? Genes Cancer 2:631–647
Dumitrescu RG (2012) DNA methylation and histone modifications in breast cancer. Methods Mol Biol 863:35–45
Miremadi A, Oestergaard MZ, Pharoah PD, Caldas C (2007) Cancer genetics of epigenetic genes. Hum Mol Genet 16 Spec No 1:R28–R49
Ellis L, Hammers H, Pili R (2009) Targeting tumor angiogenesis with histone deacetylase inhibitors. Cancer Lett 280:145–153
Mottet D, Castronovo V (2010) Histone deacetylases: anti-angiogenic targets in cancer therapy. Curr Cancer Drug Targets 10:898–913
Lawson M, Uciechowska U, Schemies J, Rumpf T, Jung M et al (2010) Inhibitors to understand molecular mechanisms of NAD(+)-dependent deacetylases (sirtuins). Biochim Biophys Acta 1799:726–739
Pruitt K, Zinn RL, Ohm JE, McGarvey KM, Kang SH et al (2006) Inhibition of SIRT1 reactivates silenced cancer genes without loss of promoter DNA hypermethylation. PLoS Genet 2:e40
Witt O, Deubzer HE, Milde T, Oehme I (2009) HDAC family: what are the cancer relevant targets? Cancer Lett 277:8–21
Tran AD, Marmo TP, Salam AA, Che S, Finkelstein E et al (2007) HDAC6 deacetylation of tubulin modulates dynamics of cellular adhesions. J Cell Sci 120:1469–1479
Saji S, Kawakami M, Hayashi S, Yoshida N, Hirose M et al (2005) Significance of HDAC6 regulation via estrogen signaling for cell motility and prognosis in estrogen receptor-positive breast cancer. Oncogene 24:4531–4539
Ashraf N, Zino S, Macintyre A, Kingsmore D, Payne AP et al (2006) Altered sirtuin expression is associated with node-positive breast cancer. Br J Cancer 95:1056–1061
Sims RJ 3rd, Nishioka K, Reinberg D (2003) Histone lysine methylation: a signature for chromatin function. Trends Genet 19:629–639
Lee DY, Teyssier C, Strahl BD, Stallcup MR (2005) Role of protein methylation in regulation of transcription. Endocr Rev 26:147–170
Barski A, Cuddapah S, Cui K, Roh TY, Schones DE et al (2007) High-resolution profiling of histone methylations in the human genome. Cell 129:823–837
Zhou Y, Kim J, Yuan X, Braun T (2011) Epigenetic modifications of stem cells: a paradigm for the control of cardiac progenitor cells. Circ Res 109:1067–1081
Onodera A, Yamashita M, Endo Y, Kuwahara M, Tofukuji S et al (2010) STAT6-mediated displacement of polycomb by trithorax complex establishes long-term maintenance of GATA3 expression in T helper type 2 cells. J Exp Med 207:2493–2506
Niewmierzycka A, Clarke S (1999) S-Adenosylmethionine-dependent methylation in Saccharomyces cerevisiae. Identification of a novel protein arginine methyltransferase. J Biol Chem 274:814–824
Bachand F (2007) Protein arginine methyltransferases: from unicellular eukaryotes to humans. Eukaryot Cell 6:889–898
Scorilas A, Black MH, Talieri M, Diamandis EP (2000) Genomic organization, physical mapping, and expression analysis of the human protein arginine methyltransferase 1 gene. Biochem Biophys Res Commun 278:349–359
El Messaoudi S, Fabbrizio E, Rodriguez C, Chuchana P, Fauquier L et al (2006) Coactivator-associated arginine methyltransferase 1 (CARM1) is a positive regulator of the Cyclin E1 gene. Proc Natl Acad Sci U S A 103:13351–13356
Iberg AN, Espejo A, Cheng D, Kim D, Michaud-Levesque J et al (2008) Arginine methylation of the histone H3 tail impedes effector binding. J Biol Chem 283:3006–3010
Klose RJ, Yamane K, Bae Y, Zhang D, Erdjument-Bromage H et al (2006) The transcriptional repressor JHDM3A demethylates trimethyl histone H3 lysine 9 and lysine 36. Nature 442:312–316
Lu PJ, Sundquist K, Baeckstrom D, Poulsom R, Hanby A et al (1999) A novel gene (PLU-1) containing highly conserved putative DNA/chromatin binding motifs is specifically up-regulated in breast cancer. J Biol Chem 274:15633–15645
Wolf SS, Patchev VK, Obendorf M (2007) A novel variant of the putative demethylase gene, s-JMJD1C, is a coactivator of the AR. Arch Biochem Biophys 460:56–66
Espino PS, Li L, He S, Yu J, Davie JR (2006) Chromatin modification of the trefoil factor 1 gene in human breast cancer cells by the Ras/mitogen-activated protein kinase pathway. Cancer Res 66:4610–4616
Daniel AR, Knutson TP, Lange CA (2009) Signaling inputs to progesterone receptor gene regulation and promoter selectivity. Mol Cell Endocrinol 308:47–52
Chen Y, Dai X, Haas AL, Wen R, Wang D (2006) Proteasome-dependent down-regulation of activated Stat5A in the nucleus. Blood 108:566–574
Shiio Y, Eisenman RN (2003) Histone sumoylation is associated with transcriptional repression. Proc Natl Acad Sci U S A 100:13225–13230
Grimaud C, Negre N, Cavalli G (2006) From genetics to epigenetics: the tale of Polycomb group and trithorax group genes. Chromosome Res 14:363–375
Farcas AM, Blackledge NP, Sudbery I, Long HK, McGouran JF et al (2012) KDM2B links the Polycomb Repressive Complex 1 (PRC1) to recognition of CpG islands. Elife 1:e00205
Satijn DP, Hamer KM, den Blaauwen J, Otte AP (2001) The polycomb group protein EED interacts with YY1, and both proteins induce neural tissue in Xenopus embryos. Mol Cell Biol 21:1360–1369
Francis NJ, Kingston RE (2001) Mechanisms of transcriptional memory. Nat Rev Mol Cell Biol 2:409–421
Raaphorst FM, Otte AP, van Kemenade FJ, Blokzijl T, Fieret E et al (2001) Distinct BMI-1 and EZH2 expression patterns in thymocytes and mature T cells suggest a role for Polycomb genes in human T cell differentiation. J Immunol 166:5925–5934
Nakauchi H, Oguro H, Negishi M, Iwama A (2005) Polycomb gene product Bmi-1 regulates stem cell self-renewal. Ernst Schering Res Found Workshop 85–100
Jacobs JJ, Scheijen B, Voncken JW, Kieboom K, Berns A et al (1999) Bmi-1 collaborates with c-Myc in tumorigenesis by inhibiting c-Myc-induced apoptosis via INK4a/ARF. Genes Dev 13:2678–2690
Silva J, Garcia JM, Pena C, Garcia V, Dominguez G et al (2006) Implication of polycomb members Bmi-1, Mel-18, and Hpc-2 in the regulation of p16INK4a, p14ARF, h-TERT, and c-Myc expression in primary breast carcinomas. Clin Cancer Res 12:6929–6936
Cai X, Cullen BR (2007) The imprinted H19 noncoding RNA is a primary microRNA precursor. RNA 13:313–316
Chen F, Yu Z, Baoyu G (2013) MiR-199b-5p targets HER2 in breast cancer cells. J Cell Biochem. doi:10.1002/jcb.24487
van Rooij E (2011) The art of microRNA research. Circ Res 108:219–234
Tehler D, Hoyland-Kroghsbo NM, Lund AH (2011) The miR-10 microRNA precursor family. RNA Biol 8:728–734
Huang GL, Zhang XH, Guo GL, Huang KT, Yang KY et al (2008) Expression of microRNA-21 in invasive ductal carcinoma of the breast and its association with phosphatase and tensin homolog deleted from chromosome expression and clinicopathologic features. Zhonghua Yi Xue Za Zhi 88:2833–2837
Li H, Bian C, Liao L, Li J, Zhao RC (2011) miR-17-5p promotes human breast cancer cell migration and invasion through suppression of HBP1. Breast Cancer Res Treat 126:565–575
Wang X, Cao L, Wang Y, Liu N, You Y (2012) Regulation of let-7 and its target oncogenes (Review). Oncol Lett 3:955–960
Gregory PA, Bert AG, Paterson EL, Barry SC, Tsykin A et al (2008) The miR-200 family and miR-205 regulate epithelial to mesenchymal transition by targeting ZEB1 and SIP1. Nat Cell Biol 10:593–601
Iliopoulos D, Lindahl-Allen M, Polytarchou C, Hirsch HA, Tsichlis PN et al (2010) Loss of miR-200 inhibition of Suz12 leads to polycomb-mediated repression required for the formation and maintenance of cancer stem cells. Mol Cell 39:761–772
Wu H, Zhu S, Mo YY (2009) Suppression of cell growth and invasion by miR-205 in breast cancer. Cell Res 19:439–448
Iorio MV, Casalini P, Piovan C, Di Leva G, Merlo A et al (2009) microRNA-205 regulates HER3 in human breast cancer. Cancer Res 69:2195–2200
Spizzo R, Nicoloso MS, Lupini L, Lu Y, Fogarty J et al (2010) miR-145 participates with TP53 in a death-promoting regulatory loop and targets estrogen receptor-alpha in human breast cancer cells. Cell Death Differ 17:246–254
Singh R, Mo YY (2013) Role of microRNAs in breast cancer. Cancer Biol Ther 14
Maison C, Bailly D, Peters AH, Quivy JP, Roche D et al (2002) Higher-order structure in pericentric heterochromatin involves a distinct pattern of histone modification and an RNA component. Nat Genet 30:329–334
Fukagawa T, Nogami M, Yoshikawa M, Ikeno M, Okazaki T et al (2004) Dicer is essential for formation of the heterochromatin structure in vertebrate cells. Nat Cell Biol 6:784–791
Di Leva G, Gasparini P, Piovan C, Ngankeu A, Garofalo M et al (2010) MicroRNA cluster 221-222 and estrogen receptor alpha interactions in breast cancer. J Natl Cancer Inst 102:706–721
Fabbri M, Garzon R, Cimmino A, Liu Z, Zanesi N et al (2007) MicroRNA-29 family reverts aberrant methylation in lung cancer by targeting DNA methyltransferases 3A and 3B. Proc Natl Acad Sci U S A 104:15805–15810
Friedman JM, Liang G, Liu CC, Wolff EM, Tsai YC et al (2009) The putative tumor suppressor microRNA-101 modulates the cancer epigenome by repressing the polycomb group protein EZH2. Cancer Res 69:2623–2629
Shimono Y, Zabala M, Cho RW, Lobo N, Dalerba P et al (2009) Downregulation of miRNA-200c links breast cancer stem cells with normal stem cells. Cell 138:592–603
Han M, Wang Y, Liu M, Bi X, Bao J et al (2012) MiR-21 regulates epithelial-mesenchymal transition phenotype and hypoxia-inducible factor-1alpha expression in third-sphere forming breast cancer stem cell-like cells. Cancer Sci 103:1058–1064
Pavicic W, Perkio E, Kaur S, Peltomaki P (2011) Altered methylation at microRNA-associated CpG islands in hereditary and sporadic carcinomas: a methylation-specific multiplex ligation-dependent probe amplification (MS-MLPA)-based approach. Mol Med 17:726–735
Hoffman AE, Zheng T, Yi C, Leaderer D, Weidhaas J et al (2009) microRNA miR-196a-2 and breast cancer: a genetic and epigenetic association study and functional analysis. Cancer Res 69:5970–5977
Aliya N, Rahman S, Khan ZK, Jain P (2012) Cotranscriptional chromatin remodeling by small RNA species: an HTLV-1 perspective. Leuk Res Treat 2012:984754
Wong KY, So CC, Loong F, Chung LP, Lam WW et al (2011) Epigenetic inactivation of the miR-124-1 in haematological malignancies. PLoS One 6:e19027
Hu Z, Chen J, Tian T, Zhou X, Gu H et al (2008) Genetic variants of miRNA sequences and non-small cell lung cancer survival. J Clin Invest 118:2600–2608
Png KJ, Yoshida M, Zhang XH, Shu W, Lee H et al (2011) MicroRNA-335 inhibits tumor reinitiation and is silenced through genetic and epigenetic mechanisms in human breast cancer. Genes Dev 25:226–231
Lustberg MB, Ramaswamy B (2011) Epigenetic therapy in breast cancer. Curr Breast Cancer Rep 3:34–43
Friel AM, Zhang L, Curley MD, Therrien VA, Sergent PA et al (2010) Epigenetic regulation of CD133 and tumorigenicity of CD133 positive and negative endometrial cancer cells. Reprod Biol Endocrinol 8:147
Connolly R, Stearns V (2012) Epigenetics as a therapeutic target in breast cancer. J Mammary Gland Biol Neoplasia 17:191–204
Brueckner B, Garcia Boy R, Siedlecki P, Musch T, Kliem HC et al (2005) Epigenetic reactivation of tumor suppressor genes by a novel small-molecule inhibitor of human DNA methyltransferases. Cancer Res 65:6305–6311
Davis AJ, Gelmon KA, Siu LL, Moore MJ, Britten CD et al (2003) Phase I and pharmacologic study of the human DNA methyltransferase antisense oligodeoxynucleotide MG98 given as a 21-day continuous infusion every 4 weeks. Invest New Drugs 21:85–97
Atadja P, Gao L, Kwon P, Trogani N, Walker H et al (2004) Selective growth inhibition of tumor cells by a novel histone deacetylase inhibitor, NVP-LAQ824. Cancer Res 64:689–695
Li Q, Bartlett DL, Gorry MC, O’Malley ME, Guo ZS (2009) Three epigenetic drugs up-regulate homeobox gene Rhox5 in cancer cells through overlapping and distinct molecular mechanisms. Mol Pharmacol 76:1072–1081
Fang MZ, Wang Y, Ai N, Hou Z, Sun Y et al (2003) Tea polyphenol (-)-epigallocatechin-3-gallate inhibits DNA methyltransferase and reactivates methylation-silenced genes in cancer cell lines. Cancer Res 63:7563–7570
Moyers SB, Kumar NB (2004) Green tea polyphenols and cancer chemoprevention: multiple mechanisms and endpoints for phase II trials. Nutr Rev 62:204–211
Cho HJ, Kim SY, Kim KH, Kang WK, Kim JI et al (2009) The combination effect of sodium butyrate and 5-Aza-2′-deoxycytidine on radiosensitivity in RKO colorectal cancer and MCF-7 breast cancer cell lines. World J Surg Oncol 7:49
Gottlicher M, Minucci S, Zhu P, Kramer OH, Schimpf A et al (2001) Valproic acid defines a novel class of HDAC inhibitors inducing differentiation of transformed cells. EMBO J 20:6969–6978
Kim SH, Kang HJ, Na H, Lee MO (2010) Trichostatin A enhances acetylation as well as protein stability of ERalpha through induction of p300 protein. Breast Cancer Res 12:R22
Xu WS, Perez G, Ngo L, Gui CY, Marks PA (2005) Induction of polyploidy by histone deacetylase inhibitor: a pathway for antitumor effects. Cancer Res 65:7832–7839
Kijima M, Yoshida M, Sugita K, Horinouchi S, Beppu T (1993) Trapoxin, an antitumor cyclic tetrapeptide, is an irreversible inhibitor of mammalian histone deacetylase. J Biol Chem 268:22429–22435
Monneret C (2005) Histone deacetylase inhibitors. Eur J Med Chem 40:1–13
Liu Y, Liggitt D, Fong S, Debs RJ (2006) Systemic co-administration of depsipeptide selectively targets transfection enhancement to specific tissues and cell types. Gene Ther 13:1724–1730
Furumai R, Komatsu Y, Nishino N, Khochbin S, Yoshida M et al (2001) Potent histone deacetylase inhibitors built from trichostatin A and cyclic tetrapeptide antibiotics including trapoxin. Proc Natl Acad Sci U S A 98:87–92
Park H, Im JY, Kim J, Choi WS, Kim HS (2008) Effects of apicidin, a histone deacetylase inhibitor, on the regulation of apoptosis in H-ras-transformed breast epithelial cells. Int J Mol Med 21:325–333
Saito A, Yamashita T, Mariko Y, Nosaka Y, Tsuchiya K et al (1999) A synthetic inhibitor of histone deacetylase, MS-27-275, with marked in vivo antitumor activity against human tumors. Proc Natl Acad Sci U S A 96:4592–4597
Riva L, Blaney SM, Dauser R, Nuchtern JG, Durfee J et al (2000) Pharmacokinetics and cerebrospinal fluid penetration of CI-994 (N-acetyldinaline) in the nonhuman primate. Clin Cancer Res 6:994–997
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2013 Springer Science+Business Media Dordrecht
About this chapter
Cite this chapter
Anant, S., Dhar, A., Ramalingam, S. (2013). Epigenetic Signatures of Breast Cancer Genes. In: Sarkar, F. (eds) Epigenetics and Cancer. Springer, Dordrecht. https://doi.org/10.1007/978-94-007-6612-9_10
Download citation
DOI: https://doi.org/10.1007/978-94-007-6612-9_10
Published:
Publisher Name: Springer, Dordrecht
Print ISBN: 978-94-007-6611-2
Online ISBN: 978-94-007-6612-9
eBook Packages: Biomedical and Life SciencesBiomedical and Life Sciences (R0)