Serum and Plasma Copy Number Detection Using Real-time PCR

Summary

This manuscript describes the copy number variation analysis performed in serum or plasma DNA using real-time PCR approach. This method is suitable for the prediction of drug resistance in castration resistant prostate cancer patients, but it could be informative also for other diseases.

Abstract

Serum and plasma cell free DNA (cfDNA) has been shown as an informative, non-invasive source of biomarkers for cancer diagnosis, prognosis, monitoring, and prediction of treatment resistance. Starting from the hypothesis that androgen receptor (AR) gene copy number (CN) gain is a frequent event in metastatic castration resistance prostate cancer (mCRPC), we propose to analyze this event in cfDNA as a potential predictive biomarker.

We evaluated AR CN in cfDNA using 2 different real-time PCR assays and 2 reference genes (RNaseP and AGO1). DNA amount of 60 ng was used for each assay combination. AR CN gain was confirmed using Digital PCR as a more accurate method. CN variation analysis has already been demonstrated to be informative for the prediction of treatment resistance in the setting of mCRPC, but it could be useful also for other purposes in different patient settings. CN analysis on cfDNA has several advantages: it is non-invasive, rapid and easy to perform, and it starts from a small volume of serum or plasma material.

Introduction

Circulating cell free DNA (cfDNA) in blood has been demonstrated to be an optimal source of biomarkers for cancer diagnosis, prognosis, monitoring, and prediction of treatment resistance^1,2. Many studies have shown a good concordance between DNA alterations (mutations, copy number variations, epigenetic modifications) in tissues and those found in corresponding plasma samples¹, confirming that circulating tumor DNA (ctDNA) is informative for primary and metastatic tumor tissue alterations³. The possibility of studying ctDNA thus allows for the reconstruction of genomic rearrangements and copy number variations (CNVs) at specific oncogenes⁴, identifying potentially metastatic clonal and subclonal cells. CtDNA has been shown to be clinically useful especially for cancer treatment monitoring as it harbors specific mutations and CNVs, related to specific targeted therapies^5,6. It also overcomes the need for tissue biopsies and allows results to be obtained at different times during a specific cancer treatment in a non-invasive manner.

With regard to prostate cancer, a significant correlation between circulating cell-free androgen receptor (AR) CNVs and treatment response to abiraterone and enzalutamide has been shown, indicating AR gene copy number (CN) in cfDNA may be a promising biomarker capable of predicting treatment resistance^7,8,9,10,11. CNVs of specific genes in ctDNA can be evaluated using different approaches with different sensitivity, cost, and rapidity (e.g. real-time, Digital PCR, and Next Generation Sequencing).

Here we describe a simple and fast approach, based on duplex assays in real-time PCR technology, for evaluating AR CN in cfDNA from serum and plasma samples^7,8. We considered two different PCR assays designed on two different genomic regions within intron 5 of AR (Xq12) and two other genes, as internal standard reference genes known to have a normal copy number status in prostate cancer (RNaseP, located on 14q11; AGO1, located on 1p34). We selected two reference genes, rather than one, to increase the precision and sensitivity of the results. A DNA amount of 60 ng was amplified for each assay combination (combined assay for AR-assay_1+RNaseP and for AR-assay_2+AGO1). Three serum or plasma DNA samples from healthy males were pooled and used as a calibrator. We considered cutoffs of >1.5 for AR gain and <0.5 for deletion. One of the main advantages of this method is that it is flexible and that other genes can also be evaluated, changing the standard internal reference genes, on the basis of tumor type and characteristics.

Protocol

The protocol consists of the isolation of DNA from serum or plasma samples to perform real-time PCR for copy number analysis. DNA extraction, DNA quantity control (spectrophotometer) and real-time PCR for specific targets were performed. In Figure 1, a summary of the procedures and time line are reported.

The protocol follows the guidelines of IRST Human Research Ethics Committee.

1. Serum Collection and Processing

1. Collect approximately 5 mL whole blood in a serum tube without anticoagulant to obtain serum. Maintain blood tubes at 4 °C until processing.
2. Centrifuge tubes at 1,000 x g for 15 min at 4 °C.
3. Carefully transfer serum into 2 mL tubes.
4. Discard the collecting tube and immediately freeze the supernatant at -80 °C until use.

2. Plasma Collection and Processing

1. Collect approximately 10 mL whole blood in a plasma tube with EDTA to obtain plasma. Fill the tube completely and then invert it 8 times. Maintain blood tubes at 4 °C until processing.
2. Centrifuge the tube at 1,800 x g for 15 min at room temperature with no brake setting on the centrifuge.
3. Carefully transfer the upper part of the plasma into 2 mL tubes. Repeat the transfer, leaving at least 1 mL of the supernatant above the white cell layer.
   NOTE: Transferring the upper part of the supernatant reduces the risk of contamination by cells or cell debris.
4. Discard the collecting tube and immediately freeze the supernatant at -80 °C until use.

3. DNA Isolation from Serum or Plasma

NOTE: Isolation of DNA from serum or plasma should be performed using the commercial protocol modified in the following steps.

1. Thaw one aliquot (containing from 0.5 to 2 mL) of serum or plasma at room temperature.
2. Vortex and mix the sample and transfer 0.5 mL of serum or plasma into a clear 1.5 mL tube. Freeze the rest of material at -80 °C.
3. Add 50 µL of proteinase k (20 mg/mL) directly to the sample.
4. Add 0.5 mL of lysis buffer to the sample and mix well by pipetting.
5. Close the tubes and incubate samples at 56 °C for 15 min in the heat block.
6. Add the indicated amount of 100% ethanol at wash buffer 1 and 2, as indicated by the manufacturer's instructions.
7. Bring the samples back to room temperature and add 0.5 mL of absolute ethanol and mix well by pipetting.
8. Add 650 µL of the mixture obtained in step 3.7 to the separation column and centrifuge at 6,000 x g for 1 min.
9. Discard the tube containing the flow through and place the column on a new clean collection tube. Repeat steps 3.8 and 3.9 one more time.
10. Add 500 µL of wash buffer 1, without wetting the rim of the column and centrifuge at 6,000 x g for 1 min.
11. Discard the tube containing the flow through and replace it with a new clean collection tube.
12. Add 500 µL of wash buffer 2, without wetting the rim of the column and centrifuge at full speed (20,000 x g) for 3 min.
13. Discard the tube containing the flow through and replace it with a new clean collection tube.
14. Centrifuge at full speed (20,000 x g) for 3 min to remove any residual washing buffer.
15. Place the column into a clean 1.5 mL tube. Add 150 µL of elution buffer and wait 7 min to ensure that buffer wets the column.
16. Centrifuge at 8,000 x g for 1 min.
17. Pipette the elute from step 3.16 again into the same column and centrifuge at full speed (20,000 x g) for 1 min to ensure maximum recovery of DNA.

4. DNA Quantification and Dilution

1. Perform quantification of DNA using a spectrophotometer. Use 2 µL of sample on a bench-top spectrophotometer per the manufacturer's instructions.
   NOTE: If the DNA quantity is not sufficient to proceed with real-time PCR (at least 120 ng), perform a new DNA isolation process.
2. Dilute DNA from serum or plasma to 2.5 ng/µL in a final volume sufficient for all real-time PCR (about 50 µL).

5. Real-time PCR

1. Thaw copy number assays, reference gene assay, DNA diluted samples, and calibrators pooled in ice. Equilibrate at room temperature the master mix that is stored at 4 °C.
2. Prepare a mix of 1 µL of target assay, 1 µL of reference gene assay, and 10 µL of master mix for 3 replicates of each sample and calibrators pooled. Prepare the mix including a negative control (water) and 2 extra samples.
3. In a 96 well plate, aliquot 12 µL of the mix into each well. Do not pipette or spin tubes.
4. Add 8 µL (concentration of 2.5 ng/µL) of each DNA sample and calibrators pooled into each well. Do not pipette or spin tubes. Change the tip for each well.
   NOTE: 30 DNA samples can be processed for each Real-time experiment using the 96-well plate: 30 x 3 samples + 1 x 3 calibrators pooled + negative control = 94.
5. Briefly spin down the plate at 1,000 x g.
6. Run the plate using the following protocol: hold stage at 95 °C for 10 min, 40 cycles at 95 °C for 15 s, and 60 °C for 1 min.

6. Data Analysis and Interpretation

1. In the section "option", below the amplification plot results, set the Ct threshold at 0.2 for the first target gene analyzed. Repeat the set for each target or reference genes. To Export the real-time PCR file in .txt extension, press "Export" into toolbar. Flag only "results" in the select data to export → choose as file type the extension .txt → press "start export" → close the export tool.
2. Open the analysis software and import the file .txt (toolbar → import).
3. Select the file name to analyze and select the analysis setting by toolbar (play symbol).
4. Specify the calibrator sample and the known number of copies of the target (e.g., 1 copy for AR gene). Press "apply."
5. For each sample, omit one well with different delta Ct (ΔCt) in comparison with other wells.
6. Reanalyze the experiment (press play symbol).
7. Evaluate the results by the copy number bar plot or the table.
   NOTE: The results table contains numerous parameters like confidence, Z-score, and replicates analyzed that could be useful for results interpretation.

Results

Total cfDNA concentration was quantifiable by spectrophotometry for all samples analyzed, showing a median of 6.12 ng/µL (range: 2.00 - 23.71 ng/µL) for serum samples and a median of 3.21 ng/µL (range: 2.31 - 8.49 ng/µL) for plasma samples. We analyzed a total of 115 samples by real-time PCR experiments.

Test sensitivity was assessed using mixed serum DNA from patients with high or low gain for AR, a...

Discussion

AR CN analysis in serum and plasma sample represents a new, non-invasive approach for the stratification of castration resistant prostate cancer (CRPC) patients. It has been recently demonstrated that the AR CN is able to predict outcomes in CRPC patients treated with abiraterone and enzalutamide, before and after chemotherapy^7,8,9,10.

The main adva...

Materials

Name	Company	Catalog Number	Comments
BD Vacutainer Serum Tubes	Becton Dickinson	367814	whole blood tube for serum
BD Vacutainer EDTA Tubes	Becton Dickinson	366643	whole blood tube for plasma
Ethanol absolute	VWR		the user could use also other companies
TaqMan Copy Number assay	Thermo Fisher Scientific	4400291	Pre-designed and validated assays with FAM-dye. We used the followig assay: AR_assay1: hs04107225 adn AR_assay2: hs04511283
TaqMan Copy Number assay (modified)	Thermo Fisher Scientific	4467084	Pre-designed assay modified with VIC-dye: AGO1: Hs02320401_cn
TaqMan Copy Number Reference Assay, human, RNase P	Thermo Fisher Scientific	4403326
TaqMan Universal PCR Master Mix	Thermo Fisher Scientific	4326708	Master mix for Real Time PCR
QIAamp DNA Mini Kit (50)	Qiagen	51304	DNA extraction kit
MicroAmp 96-Well Plates	Thermo Fisher Scientific	N8010560	plates for realt time PCR
NanoDrop 1000 Spectrophotometer	Thermo Fisher Scientific	-	the user could use also other spectrophotometric methods to quantify DNA
7500 Fast Real-Time PCR System	Applied Biosystem	-	the user could use also other real time instrument
CopyCaller Software	Applied Biosystem	-	Software for copy number analysis