Introduction
Pancreatic ductal adenocarcinoma (PDA) is one of the most dismal types of cancer,
and novel methods for early detection are highly warranted [1]. The standard diagnostics for PDA include tumor tissue collection during endoscopy
and, in particular, the sensitivity and specificity values of endoscopic ultrasound-guided
fine needle aspiration/biopsy (EUS-FNA/B) are over 90 % [2]. However, tissue sampling sometimes results in inadequate examination due to insufficient
material. It is also challenging to fully uncover tumor heterogeneity using a small
piece of specimen. Another issue of the modalities is severe complications, reported
in up to 1 % – 2 % and 12.0 % of EUS-FNA/B and endoscopic retrograde cholangiopancreatography
(ERCP)-related procedures, respectively [3].
In patients with cancer, the presence of cell-free DNA (cfDNA) in the blood and its
potential utilities have been recognized, and their clinical relevance has attracted
widespread attention [4]. The primary limitation of such “liquid biopsy” is the modest availability of circulating
tumor-derived DNA. Given the extremely low tumor cellularity, detecting tumor-derived
DNAs in the blood of patients is challenging [5]. Here, we describe a case of early pancreatic cancer with successful detection of
mutant KRAS variants in the pancreatic juice collected through the Vater-papilla during
endoscopic cytology. The latest analytical tools for tumor genotyping are powerful
enough to identify the tumor-derived DNA, even from early lesions in the pancreatic
juice.
Case report
A 53-year-old woman was referred to our hospital due to a complaint of epigastric
and dorsal pain. Before the genetic study, written informed consent was obtained from
the patient for publication of the case. The laboratory data showed a slight elevation
of the pancreatic enzymes (110 U/L) and normal levels of carbohydrate antigen 19 – 9
(CA19 – 9) and IgG4. Images of the pancreas obtained using ultrasound, CT, and MRI
showed dilation of the main pancreatic duct (MPD; 6 mm) with no sign of the solid
tumor ([Fig. 1a]). EUS revealed an 8-mm hypoechoic area in the body of the pancreas connected to
the dilated MPD ([Fig. 1b]).
Fig. 1 Imaging diagnosis of the primary pancreatic tumor. a Magnetic resonance cholangiopancreatography (MRCP) demonstrates obstruction of the
main pancreatic duct (MPD; arrowhead) accompanied by distal dilatation. b CT shows dilation of the MPD with no sign of the solid tumor. c Hypoechoic area is visualized by endoscopic ultrasound in the body of the pancreas
(surrounded by arrowheads; 8 mm in diameter) connected to the dilated MPD (asterisk).
Note that there are no other detectable tumors or cystic lesions. MPD; main pancreatic
duct, SMV; superior mesenteric vein.
The patient was informed about the possible malignant tumor closing the portal vein;
however, she refused to undergo FNA/B testing for histological assessment. Instead,
a biopsy from the stricture of the MPD and pancreatic juice cytology were performed
to diagnose the tumor, resulting in no evidence of malignancy. Pancreaticoduodenectomy
was selected as the treatment option for this tumor, which was highly suspected to
be PDA.
Before the surgical intervention, we performed a genetic test in a droplet digital
PCR platform to capture mutant KRAS and GNAS using the pancreatic juice (500 µL).
The fresh pancreatic juice collected via the ERCP catheter was frozen immediately
after the procedure (within 10 min). In the purified DNA, two major variants, KRAS
G12V (13.3 %) and G12D (3.0 %), were detected ([Fig. 2]), whereas mutant GNAS was not detected (see the Supplementary Method for details).
We also used the pancreatic juice drained through the endoscopic nasopancreatic drainage
tube, a liquid left behind out of the organ for several hours; however, the yield
of DNA was much lower than the fresh sample and too heavily fragmented for assay.
Fig. 2 Droplet digital PCR confirming KRAS mutation in the pancreatic juice. KRAS (exon
2)-specific PCR fragments in cell-free DNA from the plasma and pancreatic juice are
analyzed by droplet digital PCR. Mutation in KRAS is selectively detected by mutant-specific
probe against mutant KRAS at codon 12/13 (upper panel). A larger p.G12V mutant frequency
is demonstrated in the pancreatic juice. Additionally, the presence of a smaller proportion
of p.G12D mutant alleles is also shown, whereas no signals for other KRAS variants
are detected (result using p.G12R-specific probe is shown). PJ, pancreatic juice;
FAM, 6-carboxyfluorescein; HEX, hexachloro-6-carboxyfluorescein.
In the resected specimen, focal fibrosis was found proximal to the MPD stricture,
and the size of the fibrotic area corresponded well with the hypoechoic lesion visualized
by EUS ([Fig. 3a]). Pathologically, well-differentiated adenocarcinoma was evident with no sign of
metastasis (stage IA; UICC 8th edition).
Fig. 3 Gross appearance of the resected pancreas and pathological mapping of the main tumor
and microscopic lesions. a The whole resected specimen is used to define the distribution of the lesions. The
primary ductal adenocarcinoma (PDA; red star) is surrounded by multiple low grade
(LGD; blue circles) and high grade dysplasias (HGD; red circles) as illustrated. Dashed
line indicates resection margin. b Macroscopic findings for the main tumor. c – g Microscopic lesions associated with the main tumor. The main PDA and closely located
HGD in the MPD harbor KRAS G12V (b). In the surrounding normal-looking pancreas, LGD and HGDs with KRAS G12V are identified
(c – e), whereas LGDs, one of which is accompanied by acinar-ductal metaplasia, are marked
by KRAS G12D (f, g). MPD; main pancreatic duct, BD; branch duct. Asterisk indicates MPD.
We next performed additional genetic analysis using a resected specimen; in the main
tumor
with dense desmoplasia, KRAS G12V mutation was demonstrated by targeted amplicon sequencing
([Fig. 3b, c] and [Supplementary Table 1]; see the Supplementary Methods for details). The series of lesions continuing to
the MPD possessed an identical type of KRAS mutation, suggesting a cancerization from
the primary PDA ([Fig. 3d, e]). Other abnormal ductal structures corresponding to acinar-to-ductal metaplasia
(ADM) to low grade pancreatic intraepithelial neoplasias were noted (PanINs; [Fig. 3f, g]). These lesions were micro-dissected and sequenced. Interestingly, some lesions
harbored KRAS G12D, a distinct type of variant from the main tumor, indicating an
independent development of additional precursor(s). All tumors had no other mutations
in the common PDA-related tumor suppressor genes, such as TP53, CDNK2A/p16, SMAD4,
or RNF43. Mutations in GNAS were also not evident in the tumors including abnormal
ductal structures in the normal looking pancreas.
Supplementary Table 1
Result of multiregion sequencing (targeted amplicon sequencing).
|
Main tumor (B)
|
HGD in MPD (B)
|
HGD (C)
|
LGD in MPD (D)
|
LGD (E)
|
LGD (F)
|
ADM (F)
|
LGD (G)
|
|
KRAS
|
G12V (10.3 %)[1]
|
G12V (11.5 %)[1]
|
G12V (19.2 %)[1]
|
G12V (1 %)[1]
|
G12V (2 %)[1]
|
G12D (5.2 %)[1]
|
G12D (2 %)[1]
|
G12D (1 %)[1]
|
|
TP53
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
CDKN2A
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
SMAD4
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
GNAS
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
RNF43
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
BRAF
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
PIK3CA
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
STK11
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
IDH1
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
CTNNB1
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
MAP2K4
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
TGFBR1
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
TGFBR2
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
ARID1A
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
SF3B1
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
RBM10
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
|
KDM6A
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
WT
|
LGD, low grade dysplasia; HGD, high grade dysplasia; ADM, acinar-to-ductal metaplasia;
WT, wild-type.
1 Values in parentheses indicate the multiregions shown in [Fig. 3].
Discussion
Reliable and feasible detection of early stage pancreatic cancer and premalignant
lesions, such as PanIN, will greatly aid in patient survival. However, obtaining trustworthy
evidence for the malignancy is not always easy, especially when a small lesion is
targeted. Recently, cell-free DNA in plasma has attracted attention as a diagnostic
tool for various types of cancer [4]. In human PDAs, mutations in KRAS are found in over 90 % of patients [1], and significant effort has been made to detect the driver gene in patient specimens,
such as pancreatic juice or plasma [5]. In the current report, KRAS genotyping of pancreatic juice indicated the presence
of “neoplasia” in the pancreas, although pancreatic duct biopsy and pancreatic juice
cytology did not provide morphological evidence of malignancy. Insufficient material
is a common reason for failure of cytology/biopsy, and diagnostic accuracy is hindered
by the invasiveness of tissue collection. In contrast, a genetic approach can detect
the tumor-associated alterations irrespective of the tumor size, providing very sensitive
diagnostics relative to conventional methods.
It should be noted that, in the current case, two types of KRAS variants were detected
in the pancreatic juice. Among the precursor lesions of invasive pancreatic cancer,
PanIN may progress to PDA sequentially from a monoclonal precursor, whereas intraductal
papillary mucinous neoplasms (IPMNs) are frequently accompanied by multi-centric clones
[6]. Interestingly, in our case, targeted amplicon sequencing of the resected specimen
demonstrated that the primary PDA and cancerization observed in the main duct were
marked by KRAS G12V, and other small areas composed of low grade PanIN (LG-PanIN)
associated with ADM on the caudal side of the tumor harbored KRAS G12D. Imaging studies
before the surgical intervention did not detect either IPMNs or other satellite lesions
to the hypoechoic area; however, genetic tests using pancreatic juice and resected
specimens provide evidence of multi-centric clones within the pancreas. Additionally,
the KRAS G12V mutation was found in other LG-PanINs located in branch ducts distant
from the primary PDA. Such lesions may also develop independently from the primary
PDA, and the “shared” mutation in KRAS may be incidental, although the possibility
of ductal spread (early dissemination via the pancreatic duct) cannot be entirely
excluded [7].
Detection of a KRAS mutation alone is not sufficient for a definitive diagnosis of
PDA, since it is the earliest genetic event during tumorigenesis and most precursor
lesions harbor the abnormality [8]. Additional mutations and aberrant protein expression of the tumor suppressor genes,
such as TP53 and SMAD 4, can accumulate [1], and significant time, perhaps over a decade, may be required for progression from
the emergence of the initiating mutation to the acquisition of malignant potential
[9]. On the other hand, a small subset of PDAs lack the typical stepwise mutations and
aberrant protein expressions [10]. Indeed, a smaller number of mutations in the major PDA-associated driver genes,
KRAS, CDKN2A, TP53, and SMAD4, is an independent predictor of better overall survival
[11]. Therefore, positive KRAS mutations with no other genetic abnormalities observed
by liquid biopsy indicate a wide range of conditions from an occurrence of the earliest
precursor to PDA with metastatic potential.
Endoscopy is an indispensable tool for the detection of small PDAs, and advanced options,
such as genetic and molecular tests, may further enhance diagnostic accuracy. Although
tissue collection by EUS-FNA/B is a standard procedure for providing histological
evidence of the tumor, the possibility of procedure-related dissemination has to be
borne in mind, specifically for candidates with a high probability of a cure [12]. A genetic test may compensate for the invasiveness with variable sensitivity and
specificity depending on the source of the samples (i. e. plasma, duodenal and pancreatic
juice, and other body fluids). It is necessary to integrate advanced imaging and feasible
molecular profiling for precise diagnosis of the tumor.
We report a case of an early stage PDA with genetic evidence of neoplasia (i. e. KRAS
mutation) in pancreatic juice before surgical intervention. Sequencing study of the
resected specimens indicated the utility of “liquid biopsy” for diagnosis when the
findings from pathological examination are not informative. Early detection of PDA
is still challenging, and more accurate and less invasive options that can uncover
both tumor grade and heterogeneity may bring out the full potential of endoscopic
diagnostics without hampering the possibility of a cure.
Supplementary methods
Pancreatic juice collection and cfDNA extraction
Pancreatic juice (< 1 mL) was used, immediately frozen (– 80 °C) after collection
via the transpapillary route using an ERCP catheter and drained through an endoscopic
nasopancreatic drainage tube. DNA was isolated using the QIAamp Circulating Nucleic
Acids Kit (Qiagen; Hilden, Germany) according to the manufacturer’s instructions.
The sample was quantified using the Qubit dsDNA HS Assay Kit (Thermo Fisher Scientific;
Waltham, Massachusetts, United States) and a Qubit2.0 fluorometer (Thermo Fisher Scientific).
Mutation detection by digital PCR
Mutant KRAS variants (codons 12 and 13) or mutant GNAS variants (codon 201) were analyzed
using a QX200 Droplet Digital PCR System (Bio-Rad; Hercules, California, United States)
as described previously [1]. Custom probes and primers were designed for eight major mutations in KRAS codons
12 and 13 or GNAS codon 201 [1]. The reaction mixture was prepared as described in [Supplementary Table 2]. Purified DNA was partitioned into ~22 000 droplets per sample by mixing with 70 µL
of Droplet Generation Oil in a QX200 droplet generator (Bio-Rad). Droplets were then
subjected to thermal cycling, as detailed in [Supplementary Table 3]. Samples were transferred to a QX200 droplet reader (Bio-Rad) for fluorescence measurement
of 6-fluorescein amidite and hexachlorofluorescein probes. Droplets were scored as
positive or negative based on their fluorescence intensity, which was determined by
the gating threshold defined using positive and negative controls. Finally, absolute
copy number input in the reaction and the ratio of mutated fragments were calculated
by QuantaSoft (ver 1.7; Bio-Rad) software based on the Poisson distribution.
Supplementary Table 2
Preparation of ddPCR reaction mixture.
|
Component
|
Final concentration
|
|
ddPCR Supermix for Probes (no dUTP)
|
1 ×
|
|
Template DNA[1]
|
–
|
|
Additional dNTP mixture
|
0.91 mM
|
|
Primers (forward and reverse primer)
|
0.45 µM each
|
|
Probes (input as a pair of WT and each mutant probe)
|
|
|
0.45 µM
|
|
|
0.77 µM
|
|
|
0.45 µM
|
|
|
0.45 µM
|
|
|
0.05 µM
|
|
|
0.68 µM
|
|
|
0.07 µM
|
|
|
0.68 µM
|
|
|
0.68 µM
|
|
|
0.45 µM
|
|
|
0.34 µM
|
|
|
0.45 µM
|
Total, 22 µL reaction volume.
1 1 – 4 µL of purified DNA were utilized.
Supplementary Table 3
ddPCR thermal cycling conditions.
|
Step
|
No. of cycles
|
Temperature, °C
|
Time, min
|
|
1
|
1
|
95
|
10
|
|
2
|
40
|
94
|
0.5
|
|
|
58 (KRAS)/60 (GNAS)
|
1
|
|
3
|
1
|
98
|
10
|
Mutation profiling of tumors and abnormal lesions
Each specimen was prepared as formalin-fixed paraffin embedded (FFPE) blocks and slides.
Genomic (g) DNA was then purified and isolated using the GeneRead DNA FFPE Kit (Qiagen;
Hilden, Germany) according to the manufacturer’s instructions, and finally eluted
with 30 µL of elution buffer.
Mutation profiles were determined by target amplicon sequencing using a next generation
sequencer as described previously [2]. A 20- to 60-ng portion of gDNA was amplified by PCR using an IPMN/PDA-related gene
panel which we designed, which consisted of 18 genes, and 220 amplicons (Ion AmpliSeq
Custom DNA Panel) ([Supplementary Table 4]). Sequencing was performed using an Ion Personal Genome Machine System and the Ion
PGM 200 Sequencing Kit (both from Thermo Fisher Scientific) according to the manufacturer’s
instructions. Sequence reads were demultiplexed, quality-filtered, and aligned to
the human reference genome (GRCh37) using Torrent Suite software (ver. 5.0.4; Thermo
Fisher Scientific). Variants were identified with the Variant Caller software (ver.
5.0.4.0; Thermo Fisher Scientific). To identify somatic mutations, independent genotyping
of each lesion and normal sample (duodenum) was subtracted; variants found in the
normal sample were excluded from the molecular profiling. The variant calling analysis
was operated using the somatic variant calling mode optimized to detect low-frequency
variants, which was set with the following parameters: minimum allele frequency of
0.02 and minimum coverage of 100. We also excluded putative false-negative variants
by evaluating the Phred-scaled variation call quality calculated by this plugin, and
by manually confirming the alignment with IGV software (version 2.3.59).
Supplementary Table 4
Targeted regions of the 18 genes explored by the AmpliSeq custom panel.
|
Gene
|
No. of amplicons
|
Total amplicon length, bp
|
|
KRAS
|
4
|
309
|
|
TP53
|
14
|
1317
|
|
CDKN2A
|
3
|
307
|
|
SMAD4
|
11
|
912
|
|
GNAS
|
2
|
170
|
|
RNF43
|
36
|
3349
|
|
BRAF
|
4
|
342
|
|
PIK3CA
|
4
|
311
|
|
STK11
|
6
|
553
|
|
IDH1
|
2
|
153
|
|
CTNNB1
|
2
|
152
|
|
MAP2K4
|
12
|
978
|
|
TGFBR1
|
21
|
1712
|
|
TGFBR2
|
12
|
1071
|
|
ARID1A
|
47
|
2934
|
|
SF3B1
|
8
|
628
|
|
RBM10
|
15
|
1371
|
|
KDM6A
|
17
|
1394
|
