Background
Ovarian cancer is the fifth-leading cause of cancer deaths in women [
1]. With a lack of early obvious symptoms, women are frequently diagnosed with advanced stage disease. Approximately 60% of women are diagnosed at stage 3 or higher where the 5-year survival rate is below 30% [
2]. In contrast, only 15% of cases are diagnosed at stage 1, when the tumor is localized to the primary site and patients have a 5-year survival rate of about 92%. In addition, patients with metastatic ovarian cancer frequently experience high recurrence rates within 16–22 months after conventional platinum-based combination chemotherapy. Identification of novel, specific and sensitive biomarkers for screening, monitoring or prediction may improve clinical outcomes and survival.
Screening tests currently used for ovarian cancer detection include pelvic examination, transvaginal ultrasound, and cancer antigen 125 (CA125). If an adnexal mass is detected by physical examination and/or ultrasound, surgery is ultimately needed for the confirmed ovarian cancer diagnosis and staging. CA125 is more routinely used as a marker for disease recurrence and treatment response [
3]. It has been shown to be elevated in 80% of epithelial ovarian carcinomas, but its increase in other conditions such as endometrial, pancreatic and breast cancer and certain benign conditions have limited its use as an early screening marker [
4,
5]. In addition, annual screening with both CA125 and transvaginal ultrasound has not reduced ovarian cancer mortality compared with usual care [
6]. Further research is necessary to discover and identify biomarkers that would be effective in early ovarian cancer screening.
Recently, extracellular vesicles (EVs) have been analyzed for their potential as ovarian cancer disease biomarkers [
7]. EVs comprise of exosomes (30–100 nm) and microvesicles (100–1000 nm) which are either actively released from cells by fusion of multivesicular bodies to plasma membrane or formed by direct budding of the cell membrane into the extracellular space, respectively. Exosomes and microvesicles contain proteins, lipids and nucleic acids such as mRNA and miRNA from their cell of origin. The increasing evidence of their roles in cell-to-cell communication [
8,
9], their high abundance in plasma (10
12 per mL), and highly stable nature, are several of the reasons for the increased interest to identify EV-based biomarkers. In ovarian cancer, EVs have been explored in ascites and urine for miRNA and protein surface markers [
10,
11]. Because of the demonstrated roles of EVs in communication and tumor progression, we initiated a study to examine the expression of EV mRNA and miRNA in ovarian cancer ascites and compared the expression with an ideal but difficult to obtain control source, peritoneal fluids from females inflicted with benign gynecologic diseases. These studies indicate that malignant ascites EVs package quantifiable mRNA and miRNA that can potentially provide insights into diagnostic biomarkers and therapeutic targets.
Methods
Study design
The experimental design is separated into two parts: 1) preliminary characterization of clinical samples and 2) evaluations of the biomarkers in cultured cell line. For the characterization of clinical samples, four main studies were performed: 1) size and concentration of EVs, 2) preliminary qPCR screening of mRNA biomarkers identified through previous literature, 3) pilot RNA-sequencing of EV mRNA, and 4) RT-qPCR validation of mRNA and screening of miRNA. The mRNA biomarkers identified through the RNA-seq qPCR validation were evaluated in several appropriate cell lines.
Biofluid collection
Ascites from advanced stage ovarian cancer patients were collected from the peritoneal cavity using Yankauer suction connected to a drainage bag, or bulb suction from volumes smaller than 500 mL. Bulb suction was also used to collect small volumes (1–5 mL) of peritoneal fluids from patients with non-malignant conditions. Samples were collected at the Brigham and Women’s hospital under informed consent and Internal Review Board approval. Fluids were transferred into 50 cm3 tubes and centrifuged at 2000 x g for 15 min at 4 °C to remove cell debris. The supernatant was then stored at − 80 °C until further use.
Cell culture
Immortalized human fallopian tube secretory epithelial cell line (FTSEC) was kindly provided by Dr. Ronny Drapkin [
12]. Ovarian surface epithelial (OSE7, HOSE1–15) and high-grade serous ovarian cancer (SKOV3, OVCA3) cell lines have been previously described [
13]. FTSEC cells were cultured in DMEM/Ham’s F-12 1:1 (Cellgro, Mediatech, Inc. Manassas, VA) supplemented with 2% Ultroser G serum substitute (Pall Corp., Port Washington, NY). Ovarian epithelial cell lines were cultured in a mixture of medium 199 and MCDB105 medium (1:1) (Sigma, St. Louis, MO) supplemented with 10% fetal bovine serum (FBS, Invitrogen, Carlsbad, CA).
Standard media was replaced with exosome-free fetal bovine serum (System Biosciences, SBI, Palo Alto, CA) containing media 24 h prior to conditioned media collection. Cell counts were determined at the time of conditioned media collection and ranged from 2 to 9 × 105 cells/mL. Conditioned media were transferred to 50 cm3 tubes and centrifuged at 2000×g for 15 min at 4 °C to remove cells and cell debris. The supernatant was then stored at − 80 °C until further use.
Differential ultracentrifugation and EV characterization
Ascites and peritoneal fluid samples were initially centrifuged at 2000 x g for 10 min to remove large debris. The supernatant was collected and further centrifuged at 10,000 x g for 30 min. EVs in the supernatant were then collected by ultracentrifugation at 100,000 x g for 1 h, washed with PBS, then collected again at 100,000 x g for 1 h in a Ti90 rotor. EV pellet was resuspended in PBS and stored at − 80 °C until further use. Nanoparticle tracking analysis of the EVs was conducted by Nanosight LM10 (Particle Characterization Laboratories, Inc., Novato, CA). Samples were diluted from 1:5 to 1:50 and applied to ELISA assay for EpCAM detection (Thermo Scientific, Frederick, MD) at 450 nm.
Scanning electron microscopy (SEM)
Ascites samples were pre-centrifuged at 3000 x g for 15 min at 4 °C before applying to the ExoComplete filterplate (Hitachi Chemical Diagnostics, Inc., (HCD), Mountain View, CA). EVs were captured on the filter membrane after centrifugation at 2000 x g for 5 min. Filters were fixed with 4% paraformaldehyde, and blocked with casein before incubation with 1:200 anti-human CD63 (Clone H5C6, BioLegend, Dedham, MA) for 1 h with gentle shaking. Samples were washed 3 times with casein PBS followed by incubation with 1:40 goat anti-mouse IgG gold colloid 9.0–11.0 nm (Sigma-Aldrich, St. Louis, MO) for 2 h. EVs were washed 3 times with casein PBS and PBS. Samples were fixed again with 4% paraformaldehyde for 5 min. Samples were washed once with PBS and 2 times with distilled water before incubation with 100 μL Silver Enhancement solution (BBI Solutions) for 10 min. Filters were washed with distilled water and air-dried overnight before analysis with SEM using Hitachi S-4800.
Next generation RNA sequencing
Ascites (n = 2) and peritoneal fluid (n = 3) samples were centrifuged at 2000 x g for 10 min at 4 °C after thawing as described above. The ExoComplete filterplate (HCD) captured EVs from 400 μL of centrifuged ascites and peritoneal fluid supernatant. Total RNA from EVs attached to the filter membrane was isolated using miRNeasy kit (Qiagen, Valencia, CA). Total RNA was monitored for quality control using the Agilent Bioanalyzer Nano RNA chip and Nanodrop absorbance ratios for 260/280 nm and 260/230 nm. Library construction was performed according to the Illumina TruSeq mRNA stranded protocol. The input quantity for total RNA was within the recommended range and mRNAs and noncoding RNAs with poly(A) tails was enriched using oligo dT magnetic beads. The enriched poly(A)+ RNA was chemically fragmented. First strand synthesis used random primers and reverse transcriptase to make cDNA. After second strand synthesis, the ds cDNA was cleaned using AMPure XP beads, cDNA was end repaired and then the 3′ ends were adenylated. Illumina barcoded adapters were ligated on the ends and the adapter ligated fragments were enriched by nine cycles of PCR. The resulting libraries were validated by qPCR and sized by Agilent Bioanalyzer DNA high sensitivity chip. Concentrations for the libraries were normalized and then multiplexed together. Multiplexed libraries were sequenced using paired end 100 cycles chemistry for the HiSeq 2500. The version of HiSeq control software was HCS 2.2.58 with real time analysis software, RTA 1.18.64. FASTQ files were input into Maverix Biomics platform mRNA-seq for differential expression in eukaryotes version 2.5. Additionally, Ingenuity Pathway Analysis (IPA) (Qiagen) was employed to identify biological pathway modulation.
Ascites (
n = 8), peritoneal fluid (
n = 10), and cell culture conditioned media (2 mL) were processed by first thawing for 10 min at 37 °C and then placed on ice. For preliminary qPCR screening of mRNA in clinical samples, ascites (
n = 8) and peritoneal fluid (
n = 2) were used. Thawed samples were centrifuged at 2000 x g for 10 min at 4 °C. Three hundred fifty μL of supernatant was applied to ExoComplete filterplate (HCD) and centrifuged. For cell culture conditioned media, samples were centrifuged as above and supernatants were applied to EV collection tubes (HCD). EVs were then captured onto the filter membrane after repeated centrifugation. From this step, procedures for mRNA analysis for ascites, peritoneal fluid, and cell culture conditioned media are identical. Exocomplete lysis buffer is applied to the EVs captured on the filter and incubated at 37 °C for 10 min. Centrifugation of the filterplate or filter tips from the collection tube was performed at 2000 x g for 5 min at 4 °C to transfer lysate to the mRNA Capture Plate for hybridization of mRNA to the oligo(dT)-covalently linked wells. After wash steps, on-plate random-primed cDNA synthesis using MMLV was performed at 37 °C for 2 h. For qPCR analysis, 2 μL of cDNA was used with Sso Advanced SYBR mix (Bio-Rad, Hercules, CA) and gene-specific primers (Additional file
1). Real-time PCR was performed on a ViiA7 (Thermo Fisher Scientific, Inc., Waltham, MA) instrument using the following profile: initial denaturation at 95 °C for 10 min, 40 cycles of 95 °C for 30 s and 65 °C for 1 min, melting curve analysis. Ct values greater than 36 were set to 36 cycles for data analysis. Real-time PCR data was processed by Data Assist v3.01 (Thermo Fisher Scientific, Inc.) and analyzed by Excel.
Ascites (n = 8) and peritoneal fluid (n = 10) were thawed for 10 min at 37 °C and then placed on ice. Four hundred μL ascites and peritoneal fluid were centrifuged at 2000 x g for 10 min at 4 °C. Supernatant was applied to ExoComplete filterplate and centrifuged at 2000 x g for 5 min at 4 °C. Lysis buffer from miRNeasy (Qiagen), was applied to the wells in the filterplate. Total RNA was isolated per manufacturer’s protocol. Synthesis of cDNA was performed using miScript RT kit (Qiagen). The cDNA was diluted 1:4 and 1 μL was used with the miScript PCR assay (Qiagen) for qPCR screening. For miRNA analysis, Excel and DataAssist v3.01 was used with the following parameters: cut-off value of Ct = 36, SNORD61 selected as endogenous reference RNA.
Statistical analysis
The statistical analysis was performed using Microsoft Excel software. The statistical significance of the differences was determined by applying the Student’s t-test.
Discussion
Extracellular vesicles (EVs), including exosomes and microvesicles, are small membranous particles released from all cells and found in many biofluids. These vesicles are thought to provide a mode of cellular communication and deliver their cargo of protein, DNA and RNA, to target cells [
10,
11]. As a result, EVs have been a novel source of biomarkers in a wide range of diseases. In this study, we analyzed EV mRNA and miRNA from ovarian cancer ascites and benign peritoneal fluids to determine if they can provide biological insight into metastasis and be a potential source of novel diagnostic biomarkers.
The average size and concentrations of EVs isolated from ovarian cancer ascites and peritoneal fluids were < 120 nm and at least 10
10 particles/mL and are within range of EVs isolated from other biofluids such as plasma and urine. The variability in particle concentration observed between samples is consistent with what has been observed in previous literature [
11]. In addition, EpCAM has been proposed as a marker for ovarian cancer-derived exosomes [
11], but only 1 out of 3 of the ovarian cancer and peritoneal fluid EV samples were positive for EpCAM. This may be reflective of the typically low presence of adenocarcinoma cells (< 0.1%) within ovarian cancer ascites and the presence of endometrial epithelial cells in peritoneal fluids [
19,
20]. The ovarian cancer ascites EV sample did not demonstrate a higher EpCAM concentration compared to the peritoneal fluid EV sample.
The ovarian cancer ascites and peritoneal fluid EVs were analyzed for differential mRNA expression. The mRNAs in this study were selected based on a combination of next generation sequencing (NGS) results and previous literature. The EV characterization and RNA sequencing were pilot analyses of the EVs and identification of new targets. IPA results confirmed RNA-seq is a methodology which may identify relevant biomarkers for diagnosis. The qPCR validation of the RNA-seq results employed more samples to confirm the gene expression pattern. Based on these qPCR analyses, the mRNAs confirmed to be decreased in ovarian cancer ascites compared to peritoneal fluid EVs included
LAMA4, CA11, and
MEDAG. EVs from a high grade serous ovarian adenocarcinoma cell line OVCA3 also contained less abundance of
CA11 compared to controls from immortalized epithelial fallopian and ovarian cells. Recently, fallopian tube secretory epithelial cells have been proposed to be the precursor tissue for high grade serous ovarian cancer, and immortalized human fallopian tube secretory epithelial cells are being used for studying early-stage development of high grade serous ovarian cancer [
21]. Based on the publicly available genotype-tissue expression (GTEx) database,
CA11 mRNA has high baseline expression in brain and medium expression in tissues such as ovary. Although no previous studies were found to link
CA11 with gynecological cancers, this mRNA was down-regulated in human gastric cancer [
22]. CA11 is a member of carbonic anhydrase family known to participate in biological processes such as formation of aqueous humor, CSF and saliva. Similar to
CA11, MEDAG was in lower abundance in ovarian cancer ascites EVs.
MEDAG expression, however, was either at the limit of detection or undetectable in the fallopian and ovarian cell lines used in this study suggesting low baseline expression of
MEDAG in these tissues. The GTEx database confirms this observation and shows MEDAG expressed at higher levels in visceral adipose and arterial tissues.
MEDAG is a gene involved in processes that promote adipocyte differentiation, lipid accumulation, and glucose uptake in mature adipocytes. Because ovarian cancer cells bind preferentially to omental fat and use human omental adipocytes as an energy source, the decrease observed in ovarian cancer ascites
MEDAG EV mRNA may reflect changes in the ascites microenvironment [
23]. A previous study using microarray has also shown a lower
MEDAG and
LAMA4 expression in ovarian cancer compared to normal epithelial cells [
24].
LAMA4 is a member of the major family of non-collagenous constituents of basement membranes. The decrease in
LAMA4 observed in malignant ascites EV and OVCA3 EV, in contrast to the increase in SKOV3 EV, are interesting and warrants further experimental studies to evaluate the relationship. Ascites EVs could be providing cell-to-cell communication through unique molecular profiles promoting cancer cell survival within the ascites milieu.
In contrast to
LAMA4, CA11, and
MEDAG, the 2 mRNAs,
SPINT2 and
NANOG, were found to be increased in ovarian cancer ascites compared to peritoneal fluid EVs.
SPINT2 was also in higher abundance in OVCA3 and SKOV3 EVs compared to controls. Interestingly, although SPINT2 is a putative suppressor, we demonstrate an increase in cancer ascites [
25]. Müller-Pillasch et al. also reports that
SPINT2 expression was elevated in pancreatic cancer [
26]. NANOG, on the other hand, is a DNA binding homeobox transcription factor involved in embryonic stem cell proliferation, renewal and pluripotency.
NANOG is increased in expression from normal tissue, benign, borderline, and malignant tumors of ovarian serous cystadenocarcinomas and protein is found selectively associated with high-grade ovarian serous carcinoma [
27,
28].
NANOG mRNA was found to be significantly increased in OVCA3 EVs compared to OSE7 control. Based on previous studies relating to these mRNA,
CA11 and
MEDAG may be involved in maintaining malignant ascites microenvironment, while
LAMA4, NANOG and
SPINT2 activities could regulate ovarian cancer progression and metastasis.
There were six miRNA biomarkers
, let7b, miR205, miR23b, miR29a, miR30d, and
miR720, significantly down-regulated in ovarian cancer ascites EVs compared to peritoneal fluids. These miRNAs have previously been shown to be involved in ovarian cancer progression, invasion or metastasis. The
let-7 family regulates downstream gene targets involved in self-renewal of mesenchymal stem cells derived from human embryonic stem cells
. Let-7b is often dysregulated in ovarian cancer and is associated with poor prognosis [
29]. Recently,
miR205 was shown to be elevated in ovarian cancer tissue and associated with tumor growth and metastasis in ovarian cancer [
30]. In pre-surgical plasma
, miR720 was elevated in women who had short overall survival (< 2 years) when compared to women with long overall survival (> 4 years) after their diagnosis [
31]. In contrast,
miR23b expression is lower in epithelial ovarian carcinoma and borderline tumors than in normal ovarian tissues and benign tumors consistent with the lower abundance observed in ovarian cancer ascites in this study.
MiR23b was shown to target cyclin G1 and suppress ovarian cancer tumorigenesis and progression [
14].
MiR29a was also shown to have tumor suppressive effects and may contribute to cisplatin resistance of ovarian cancer cells [
32,
33].
MiR30d also functions as a suppressor of ovarian cancer progression notably by decreasing Snail expression and blocking TGF-b1-induced EMT process [
34].
Malignant ascites presents in approximately 30% of women with ovarian cancer and is frequently tapped to relieve symptoms. This fluid is composed of lymphocytes, epithelial cells, and EVs, and provides clues into ascites formation and metastatic progression. Functional analysis of each specific mRNA and miRNA will be needed to determine the biological significance of their differential expression in ovarian cancer.