Introduction

Ovarian cancer has the worst mortality of all malignant gynecologic diseases. Improved understanding of the heterogeneous features of this disease, including distinct clinicopathological and molecular characteristics, are needed to develop individualized therapeutic strategies [1]. The most frequent histological subtype among epithelial ovarian cancers is high-grade serous adenocarcinoma (SAC). SAC develops de novo from the fallopian tube epithelium [2]. The majority of SACs exhibit rapid proliferation and are at an advanced stage at the time of diagnosis. Following surgical debulking and chemotherapy, most show a favorable response. TP53 mutations are present in 96% of SACs, leading to chromosomal instability [3, 4]. In contrast, ovarian clear cell carcinoma (CCC) has distinct clinical and biomolecular features as compared to the other subtypes of ovarian cancer. Properties of ovarian CCC include development associated with endometriosis, chemotherapeutic resistance and thromboembolism complications [5]. These characteristics, referred to as “ovarian CCC-likeness”, are affected in the carcinogenic process by a stressful inflammatory environment [6]. Mutations of ARID1A, a member of the SWI/SNF chromatin remodeling complex, occur in approximately half of ovarian CCC [6-8], and overexpression of HNF1B is a hallmark of ovarian CCC [5, 9]. Epigenetically, DNA methylation profiles of ovarian CCC also differ substantially from that of the other subtypes [10]. We hypothesize here that different histologic subtypes of ovarian cancer exhibit epigenetic or genetic dispositions. Several other cancers, including gastric and colon cancers, also show distinctive dispositions and develop in the same organs as certain subtypes of ovarian cancer. Elucidation of these dispositions will lead to advancement of novel biomarker development and help advance implementation of individualized therapies. In this article, we describe the clinical and biomolecular differences that define epigenetic and genetic dispositions in ovarian cancer, and how these might apply to other malignancies.

Epigenetic and genetic dispositions of ovarian cancer

Recent genome-wide technologies have allowed us to group malignancies based on genetic and epigenetic classifications. Ovarian SAC is initiated by TP53 mutations whereas ARID1A mutations are observed in the development of roughly half of ovarian CCC [3, 8]. In ovarian CCC, ARID1A and HNF1B have different functional roles. Mutations of tumor suppressor ARID1A contributes to carcinogenesis in several cancers, including ovarian cancer [11]. HNF1B function is central to the definition of the fundamental ovarian CCC-likeness characteristics. HNF1B influences thrombosis and glucose metabolism, in particular for cancer cells exhibiting the Warburg effect [12, 13]. The expression of HNF1B is epigenetically regulated by DNA methylation. Indeed, ovarian CCCs have unique methylation profiles that distinguish them from other histological subtypes of ovarian cancer [10]. In CCC, HNF1 pathway genes are activated by coordinate hypomethylation, while many genes belonging to the estrogen receptor (ER) network are suppressed by synchronous hypermethylation. Alterations in DNA methylation are thought to be an early event in cancer progression [14]. Genetic inactivation of ARID1A initiates carcinogenesis while epigenetic alterations contribute to biological phenotypes as well as progression of ovarian CCC. On the other hand, TP53 mutations initiate carcinogenesis and also contribute to the rapid growth that characterizes ovarian SAC. In terms of biomolecular features, SAC with TP53 mutations are dominated by copy number alterations [4]. To help distinguish these biological characteristics, we refer to SAC as having a genetic disposition while CCC has an epigenetic disposition (Figure 1).

Overview of the features that contribute to epigenetic and genetic dispositions

Figure 1. Overview of the features that contribute to epigenetic and genetic dispositions An epigenetic disposition develops in a stressful microenvironmental context, whereas a genetic disposition is dominated by TP53 mutations and chromosomal instability. An epigenetic disposition is associated with ARID1A mutations and the Warburg effect, which is also epigenetically regulated.

The biological features of several malignancies arising in other organs lends itself to their classification as having an epigenetic or genetic disposition. Aberrant DNA methylation is frequently observed in cancers associated with chronic inflammation and infection with viruses or other pathogenic microorganisms, such as Epstein– Barr virus, Helicobacter pylori, hepatitis B or C viruses or human papilloma virus. Genome-wide assessments have led to the identification of novel genetic mutations and epigenetic subclassifications. Kai et. al. showed hypermethylation, representing an epigenetic disposition, is observed in microsatellite instability (MSI) and Epstein- Barr virus (EBV) subgroups of gastric cancer, but not in intestinal and diffuse subtypes of gastric tumors. Intestinal and diffuse subgroups frequently exhibit TP53 mutations (56%) without increased DNA methylation, conforming to a genetic disposition of gastric cancer [15, 16]. The diffuse subtype of gastric cancer involves chromosomal alterations similar to ovarian SAC [17]. Alteration of DNA methylation is an earlier event, preceding chromosomal instability during hepatocarcinogenesis with chronic inflammation and/or persistent viral infection [18]. Some colorectal cancers have a high frequency of DNA methylation in specific CpG islands, referred to as the “CpG island methylator phenotype” (CIMP) [19]. Epigenetic profiling identified three DNA methylation- based subgroups of colorectal cancer: CIMP-high, CIMP- low and CIMP-negative [19-22]. The CIMP-high subgroup is associated with MSI (80%) and BRAF mutations (53–100%) as well as rare KRAS and TP53 mutations (0–18% and 11%, respectively), indicating an epigenetic disposition. The CIMP-low subgroup is characterized by a high rate of KRAS mutations (45–92%) and lower rates of MSI, BRAF, or TP53 mutations (0, 0–4, and 31–38% respectively), suggesting a mixed genetic and epigenetic disposition. CIMP-negative cases have a high frequency of TP53 mutations (71–74%), copy-number alterations [23] and rare MSI (12%) or mutations of BRAF (0–2%) or KRAS (9–33%), representing the genetic disposition subgroup in colorectal cancer. Together these findings suggest that an epigenetic disposition may be involved in some inflammation-induced cancers, while subtypes that are overrepresented by TP53 mutations demonstrate a genetic disposition. These biomolecular features are summarized in Table 1.

Table 1. Epigenetic and genetic dispositions of malignancies from different organs

CancerSubtypesMolecular features
Ovarian cancerEpigenetic disposition
Clear cell carcinoma
ARID1A mutations (46–57%)
HNF1B hypomethylation
ER pathway hypermethylation
Genetic disposition
High-grade serous adenocarcinoma
TP53 mutations (96%)
Chromosomal instability
Gastric cancerEpigenetic disposition
Microsatellite instability (MSI) type
Hypermethylation
MSI
ARID1A mutations (83%)
Epstein-Barr virus (EBV) typeHypermethylation
ARID1A mutations (73%)
Genetic disposition
Intestinal and diffuse type
(MSI stable, no EBV type)
TP53 mutations (56%)
Chromosomal instability
Colorectal cancerEpigenetic disposition
CIMP-high
Hypermethylation
MSI (80%)
BRAF mutations (53–100%)
ARID1A mutations (39%)
CIMP-lowKRAS mutations (45–92%)
Genetic disposition
CIMP-negative
TP53 mutations (71–74%)
Chromosomal instability
Hepatocellular cancerEpigenetic disposition
HBV, HCV infected
ARID1A mutations (10–17%)

ARID1A mutations in the epigenetic disposition phenotype

ARID1A belongs to the SWI/SNF (SWItch/Sucrose NonFermentable) complex, whose members have ATPase activities and regulate transcription by altering chromatin structure. The SWI/SNF complex is composed of 13– 15 subunits including ARID1A, BRG1 and SNF5. The ARID1A/BRG1 complex interacts directly with p53 to effect tumor suppressor functions regulated by cell cycle-related genes [11]. Interestingly, ARID1A mutations are found in cancers with an epigenetic disposition, which include EBV and MSI groups in gastric cancer and the CIMP-high subtype in colorectal cancer (73–83% and 39%, respectively) [15, 24]. In gastric cancer, ARID1A mutations are significantly increased in TP53 wild type as opposed to TP53 mutated cases. Those tumors with ARID1A alterations tend to have prolonged, recurrence- free survival [15]. Hepatocellular carcinomas associated with hepatitis B or C virus infections exhibit ARID1A mutations as well as other mutations in other chromatin regulators (~50%) that are not related to TP53 mutations [25-27]. In ovarian cancer, CCC has an epigenetic disposition with a methylation alteration subtype and ARID1A mutations, whereas SAC is characterized by TP53 mutations and thus a genetic disposition. ARID1A expression is positively correlated with the expression of ER in endometrial and breast cancer [28, 29]. Both ARID1A and ER alpha expression are lost and ER pathway genes are downregulated by hypermethylation in ovarian CCC [10]. BRG1, the main ATPase of the SWI/ SNF complex, regulates chromatin remodeling during steroid hormone signaling [30]. These trends suggest that loss of chromatin remodeling complex function, including ARID1A, initiates carcinogenesis with methylation- mediated suppression of ER signaling in the inflammatory carcinogenic environment. Further exploration of the role of the SWI/SNF complex and ARID1A may indicate an even more substantial impact on the biomolecular regulation of tumors with an epigenetic disposition phenotype.

The Warburg effect and an epigenetic disposition

In ovarian CCC, HNF1B is a fundamental molecular component of the biological characterization referred to as “ovarian CCC-likeness”. HNF1B expression is epigenetically regulated and its protein product is involved in glucose homeostasis. Mutations in HNF1B cause “RCAD syndrome” (Renal Cysts And Diabetes) and are associated with non-insulin-dependent (type 2) diabetes mellitus (NIDDM) of MODY5 (Mature-Onset Diabetes of the Young 5) as well as a syndrome of developmental renal anomalies [31]. Obesity induces impairment of glucose metabolism through silencing of HNF1B [32]. In ovarian CCC cells, HNF1B promotes the uptake of glucose through the glucose transporter-1 (GLUT1) protein and aerobic glycolysis, the “Warburg effect” [12]. The Warburg effect is a metabolic process in cancer that may contribute to cell survival under hypoxic conditions or in a stressful environment. Cancer cells utilize the Warburg effect to facilitate uptake and incorporation of nutrients into biomaterials (e.g., nucleotides, amino acids, and lipids) for production of a new cell [33]. Exploration of metabolic regulation specific for cancer cells is currently an area of intense research in order to identify and develop novel diagnostic tools and therapies. Recent reports support that the Warburg effect is influenced by the epigenetic regulation of genes related to glucose metabolism, such as GLUT1, PK (pyruvate kinase) and PKM (pyruvate kinase, muscle), in several malignancies including clear cell renal cell carcinoma, gastric cancer and colorectal cancer [34-36]. HNF1B plays a crucial role in defining an epigenetic disposition phenotype and the expression of HNF1B itself is regulated by DNA methylation. The Warburg effect may be epigenetically induced in cancers in the context of a stressful carcinogenic environment, leading to an epigenetic disposition phenotype.

Conclusions

Genetic and epigenetic dispositions are proposed to characterize high-grade serous and clear cell ovarian cancers, respectively. Ovarian high-grade serous adenocarcinoma exhibits a genetic disposition with high frequency TP53 mutations, essential for initiation of carcinogenesis, and chromosomal instability. ARID1A mutations often occur to initiate oncogenesis in cancers with an epigenetic disposition. An epigenetic disposition is frequent among ovarian CCC and is typified by a fundamental change in epigenetic regulation and subsequent gene expression affecting aggressive behavior leading to the development of cancer in the context of a stressful inflammatory environment. These characteristic methylation profiles may also affect cancer-specific glucose metabolism, commonly known as the Warburg effect. The concept of epigenetic and genetic dispositions is applicable for other organ malignancies, including gastric and colorectal cancers. Further exploration is needed to better understand these genetic and epigenetic disposition phenotypes across malignancies and how this can be used to further development of individualized and/ or targeted therapies.

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