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Endosc Int Open 2015; 03(06): E665-E671
DOI: 10.1055/s-0034-1393077
Original article
© Georg Thieme Verlag KG Stuttgart · New York

Differences in miRNA expression profiles between GIST and leiomyoma in human samples acquired by submucosal tunneling biopsy

Koji Fujita
1   Department of Gastroenterology and Neurology, Kagawa University School of Medicine, Kagawa, Japan
,
Hideki Kobara
1   Department of Gastroenterology and Neurology, Kagawa University School of Medicine, Kagawa, Japan
,
Hirohito Mori
1   Department of Gastroenterology and Neurology, Kagawa University School of Medicine, Kagawa, Japan
,
Shintaro Fujihara
1   Department of Gastroenterology and Neurology, Kagawa University School of Medicine, Kagawa, Japan
,
Taiga Chiyo
1   Department of Gastroenterology and Neurology, Kagawa University School of Medicine, Kagawa, Japan
,
Tae Matsunaga
1   Department of Gastroenterology and Neurology, Kagawa University School of Medicine, Kagawa, Japan
,
Noriko Nishiyama
1   Department of Gastroenterology and Neurology, Kagawa University School of Medicine, Kagawa, Japan
,
Maki Ayaki
1   Department of Gastroenterology and Neurology, Kagawa University School of Medicine, Kagawa, Japan
,
Tatsuo Yachida
1   Department of Gastroenterology and Neurology, Kagawa University School of Medicine, Kagawa, Japan
,
Asahiro Morishita
1   Department of Gastroenterology and Neurology, Kagawa University School of Medicine, Kagawa, Japan
,
Masao Fujiwara
2   Department of Gastroenterological Surgery, Kagawa University School of Medicine, Kagawa, Japan
,
Keiichi Okano
2   Department of Gastroenterological Surgery, Kagawa University School of Medicine, Kagawa, Japan
,
Yasuyuki Suzuki
2   Department of Gastroenterological Surgery, Kagawa University School of Medicine, Kagawa, Japan
,
Hisakazu Iwama
3   Life Science Research Center, Kagawa University School of Medicine, Kagawa, Japan
,
Tsutomu Masaki
1   Department of Gastroenterology and Neurology, Kagawa University School of Medicine, Kagawa, Japan
› Author Affiliations
Further Information

Corresponding author

T. Masaki
Department of Gastroenterology and Neurology
Kagawa University School of Medicine
Ikenobe 1750-1, Miki
Kagawa 761-0793
Japan   
Phone: 81-87-891-2156   
Fax: 81-87-891-2158   

Publication History

Publication Date:
23 September 2015 (online)

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Background and study aims: Small gastrointestinal stromal tumors (GISTs) rarely have malignant potential with poor prognosis. Using conventional imaging to differentiate between small GISTs and leiomyoma, which often have similar characteristics, is difficult but essential in daily practice. Although some studies have reported on the utility of serum c-kit as a biomarker for non-small GIST and specific miRNA, clinical aspects of such testing are controversial. The aim of this study was to identify differences between small GIST and leiomyoma through the investigation of miRNA expression patterns in human cases.

Patients and methods: MiRNA expression was examined in nine GIST (less than low risk, mean 18 mm in size) samples and seven leiomyoma samples acquired by a novel sampling method, submucosal tunneling biopsy (STB), which produces tumor specimens of submucosal tumor (SMT) without contamination of sufficient size to be examined under direct vision. Total RNA was extracted from these tissues and analyzed for miRNA expression patterns by microarray. Subsequently, real-time quantitative polymerase chain reaction (qPCR) were used to confirm specific miRNA overexpression, comparing GISTs with leiomyomas.

Results: Microarray analysis revealed upregulation of the miR-140 family up to 20 times higher in GISTs than in leiomyomas. Real-time qPCR revealed that the expression level of miR-140-5 p in GISTs was 27.86 times higher than in leiomyomas; miR-140-3 p was 12.24 times higher as well.

Conclusions: The STB method provided suitable SMT samples for miRNA analysis. MiR-140 family members may serve as specific biomarkers to distinguish GIST from leiomyoma.


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Introduction

Early detection of tumors is crucial in cases of gastrointestinal stromal tumor (GIST) because larger tumor diameters tend to result in worse prognoses [1]. It is also important to identify GISTs at a smaller size, because even small GISTs have malignant potential with poor prognosis [2]. Each case of GIST is now subjected to surgery if possible. Thus, differentiating between GISTs and other submucosal tumors (SMTs) is essential. Leiomyomas, which are benign mesenchymal tumors located mainly in the muscular propria of the gastrointestinal tract, are difficult to differentiate from GISTs because of similar features in origin, although electron microscopy with immunohistochemistry may reveal differences [3]. Moreover, it is difficult to distinguish GISTs from leiomyomas using imaging techniques in daily practice. Serum biomarkers for GIST have not yet been established, although GISTs express specific proteins in tissues, such as c-kit and CD34 [4]. Immunohistochemical analysis (i. e., c-kit staining for GIST) has furthered the accuracy of differential diagnosis of submucosal tumors [1]. Although 95 % of GIST tissues express c-kit protein, the other subset presents low or negative expression [5]. Most cases of c-kit-negative GIST arise in the stomach [6]. Therefore, c-kit protein is not perfect for diagnosis of GIST, especially cases of gastric GIST. Although detection of serum c-kit by flow cytometry was reported as useful for diagnosis of GIST measuring more than 2 cm in diameter, the method has limitations in that it cannot be used to detect GIST smaller than 2 cm in diameter and cut-off levels of c-kit are not optimized in this system [7]. Genetic mutations such as KIT and PDGFRA also are associated with GIST [1]. Approximately 10 % to 15 % of GIST, however, do not have mutations in either KIT or PDGFRA [6].

MiRNAs have been shown to serve as biomarkers of malignant and benign diseases [8]. MiRNAs are key molecules in post-transcriptional regulation of gene expression, and alteration of miRNA expression is related to aberrant gene expression. Tumorigenesis, tumor progression, fibrosis, and tumor immunity have been described in the context of disordered miRNA expression. Accordingly, miRNA expression was previously examined in various sarcoma cases including GIST [9] and uterine leiomyoma cases [10]. A comparison of miRNA expression profiles between GISTs and leiomyosarcomas also was performed in a gastroenterology context [11]. In addition, miRNAs with altered expression levels have been identified in patients with osteosarcoma [12]. However, miRNAs specific to small GISTs classified as low risk have not been identified. Because basic approaches comparing GIST and leiomyoma may provide clinically significant findings, we aimed to identify miRNAs as biomarkers of GIST by comparing low-risk GISTs and leiomyomas of the stomach in humans.


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Patients and methods

Study design

MiRNA expression was measured in nine GIST samples and seven leiomyoma samples, which were diagnosed histopathologically and acquired using a modified version of the submucosal tunneling biopsy (STB) technique [13]. STB provides the advantage of sufficient tumor specimen acquisition without contamination under direct vision. Total RNAs were extracted from these tissues and analyzed for the expression of 2,555 miRNAs by microarray, comparing GISTs with leiomyomas.


#

Ethics

This study was approved by the Clinical Ethics Committee of Kagawa University Hospital. All patients provided written informed consent to undergo STB and participate in the study. The use of STB was previously approved by the same ethics committee.


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Clinical and pathologic information

Clinical information about the patients included gender, clinical presentation, radiologic and endoscopic findings, laboratory findings, and the pathologic characteristics of the tumors ([Table 1]). Immunohistochemical analysis of tissue samples was performed for c-kit, SMA, and S-100 proteins. Mitotic counts per 50 high-power fields were estimated by expert pathologists. GISTs were classified according to the Fletcher [1] classification, including mitotic counts and maximum tumor size.

Table 1

Patient profile.

Serial number

Age

Gender

Tumor location

Layer

Maximum tumor size (mm)

Echogenicity on EUS

 1

76

Female

Stomach

MP

32

Hypo

 2

41

Male

Stomach

MP

15

Hypo

 3

72

Female

Stomach

MP

14

Hypo

 4

82

Female

Stomach

MP

13

Hypo

 5

73

Male

Rectum

MP

25

Hypo

 6

70

Male

Stomach

MP

15

Hypo

 7

48

Male

Stomach

MP

20

Hypo

 8

52

Male

Stomach

MP

7.5

Hypo

 9

67

Female

Stomach

MP

21

Hypo

10

54

Female

Stomach

MP

22

Hypo

11

53

Male

Stomach

MP

15

Hypo

12

66

Male

Stomach

MP

21

Hypo

13

63

Male

Stomach

MP

20

Hypo

14

69

Female

Esophagus

MP

30

Hypo

15

39

Female

Stomach

MP

10

Hypo

16

44

Male

Stomach

MP

10

Hypo

EUS: endoscopic ultrasonography; MP: muscularis propria;


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Submucosal tunneling biopsy

Tissue samples were obtained from patients using STB [13] [14]. This technique enables endoscopists to obtain core biopsy specimens of endoluminal subepithelial tumors under direct vision. We believe that specimens acquired with this technique are suitable for miRNA analysis because endoscopists can exclude other tissues, such as connective and adipose tissues and smooth muscle, under direct vision of the target tumors. This methodology consists of four procedures: 1) creation of the entry; 2) submucosal endoscopy with a mucosal flap (SEMF) [15]; 3) acquisition of core specimen; and 4) clip closure of the entry. These steps are shown in [Fig. 1] as a schema. In short, mucosal incision using a needle knife (KD-441Q; Olympus, Tokyo, Japan), based on the endoscopic submucosal dissection (ESD) technique, was performed to create a 10-mm opening flap, followed by two-point marking of the normal mucosa around the lesion with 10-mm margins. Second, a submucosal tunnel was created by submucosal dissection toward the tumor. After the tumor was identified and exposed under direct vision, a core specimen measuring 1 to 4 mm was acquired with biopsy forceps (Radial JawTM 4 Standard Capacity; Boston Scientific). Finally, the opening flap was sutured with hemoclips (HX-610 – 135; Olympus, Tokyo, Japan). All procedures were performed by an experienced endoscopist (H.K.; more than 200 gastric ESD cases were performed successfully).

Zoom Image
Fig. 1 Schematic protocol for submucosal tunneling biopsy. The protocol consists of four procedures: 1) creation of the entry; 2) submucosal endoscopy with a mucosal flap (SEMF), in which the tumor is identified via a submucosal tunnel; 3) core specimen (1 – 4 mm in size) acquisition using biopsy forceps; and 4) clip closure of the entry.

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MiRNA analysis by microarray

Total RNA was extracted from tumor tissues using the miRNeasy Mini Kit (Qiagen, Venlo, Netherland), as previously described [16]. RNA was labeled using a miRCURY Hy3 Power Labeling Kit (Exiqon, Vedbaek, Denmark) and hybridized on a human miRNA Oligo chip, version 20.0 (Toray, Tokyo). Scanning was conducted with the 3D-Gene Scanner 3000 (Toray). 3D-Gene extraction software (ver. 1.2, Toray) was used to read the raw intensity of the image. The raw data were analyzed with GeneSpringGX (ver. 10.0, Agilent Technologies, Santa Clara, CA) and quantile normalized. The microarray data obtained in this study are registered at the NCBI Gene Expression Omnibus (GEO) with the accession number GSE63453.

We calculated the fold changes in miRNA expression level between GIST and leiomyoma samples. Hierarchical clustering was accomplished using the farthest neighbor method. The uncentered Pearson's product-moment correlation coefficient was used as a metric. Statistical analysis was performed using unpaired t-tests. P values < 0.05 were recognized as significant.


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Real-time qPCR

Reverse transcription and real-time quantitative polymerase chain reaction (qPCR) were performed for miRNAs using the ΔΔCT method to confirm their increased expression in GISTs compared to leiomyomas, as shown in the microarray analysis. Taqman® microRNA Assays (Life technologies, Carlsbad, CA) were adapted to determine the expression level of miRNAs with U6 as an internal control (Assay ID: 001093 for U6; 001187 for miR-140 – 5p; 002234 for miR-140 – 3 p). MiRNAs were reverse transcribed using the Taqman® microRNA Reverse Transcription Kit (Life Technologies) according to the manufacturer’s protocol. In short, total RNA extracted using the miRNeasy Mini Kit (Qiagen) was diluted to 1.0 ng/μl. Reverse transcription was prepared in 15 μl reaction consisting of 5 μl of RNA, 3 μl of 5 x RT primer and 12 μl of reverse transcripition master mix. As a result, 0.33 ng/μl of cDNA was produced. The final PCR reaction, performed in a 20-μl-volume tube, consisted of 2 μl of cDNA (0.66 ng), 1 μl of 20 × qPCR assay, 7 μl of nuclease-free water and 10 μl of Taqman® Fast Advanced Master Mix according to the manufacturer’s protocol. The cDNA was amplified and quantified using StepOne PlusTM (Life technologies). MiRNA expression levels were standardized to U6.


#
#

Results

Clinical and pathologic features

The average maximum diameter of the nine GISTs was 18.05 mm, which was smaller than that of the seven leiomyomas (18.29 mm). Three of the patients with GIST presented tumors larger than 2.0 cm in diameter, and six of the nine patients presented smaller tumors. The STB method was performed successfully, providing large specimens for histopathologic assessment and total RNA extraction ([Table 2]). The 9 GISTs were assigned scores of 5 (very low risk) and 4 (low risk), according to the Fletcher classification ([Table 3]).

Table 2

Sampling data obtained by submucosal tunneling biopsy.

Serial number

Technical performance

Acquired specimen size (mm)

Clinical diagnosis
according to Fletcher
Classification

 1

Success

1.4 × 1.2

GIST, low

 2

Success

1.9 × 0.9

GIST, very low

 3

Success

2.6 × 1.4

GIST, very low

 4

Success

1.1 × 0.6

GIST, very low

 5

Success

2.1 × 1.1

GIST, low

 6

Success

2.2 × 2.1

GIST, very low

 7

Success

1.4 × 0.9

GIST, low

 8

Success

2.1 × 0.9

GIST, very low

 9

Success

4.5 × 3.5

GIST, low

10

Success

2.4 × 2.0

Leiomyoma

11

Success

2.4 × 1.5

Leiomyoma

12

Success

1.9 × 1.6

Leiomyoma

13

Success

Leiomyoma

14

Success

Leiomyoma

15

Success

4.0 × 2.5

Leiomyoma

16

Success

Leiomyoma

GIST, gastrointestinal stromal tumor

Table 3

Details of pathology.

Serial number

Pathologic diagnosis

Mitotic counts (/ 50 HPF)

Ki67
(M1B index)

c-kit

α-SMA

Fletcher
Classification

 1

GIST

< 2

< 3 %

+ 

GIST, low

 2

GIST

none < 2

1 %

 + 

GIST, very low

 3

GIST

none < 1

 < 2 %

 + 

GIST, very low

 4

GIST

none < 1

1 – 2 %

+ 

GIST, very low

 5

GIST

none < 1

5 %

+ 

GIST, low

 6

GIST

none < 1

none

+ 

GIST, very low

 7

GIST

none < 1

< 5 %

+ 

GIST, low

 8

GIST

< 5

1 – 2 %

+ 

GIST, very low

 9

GIST

< 5

< 5 %

+ 

GIST, low

10

Leiomyoma

none

none

+ 

Leiomyoma

11

Leiomyoma

none

none

+ 

Leiomyoma

12

Leiomyoma

none

< 1 %

+ 

Leiomyoma

13

Leiomyoma

none

< 1 %

+ 

Leiomyoma

14

Leiomyoma

+ 

Leiomyoma

15

Leiomyoma

+ 

Leiomyoma

16

Leiomyoma

+ 

Leiomyoma

GIST, gastrointestinal stromal tumor.


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MiRNA analysis

To investigate candidate miRNAs as biomarkers of GIST, we screened the miRNA expression levels in GIST and leiomyoma tissues. An unsupervised hierarchical clustering analysis revealed that miRNAs in GISTs clustered separately from those in leiomyomas ([Fig. 2]). We identified 39 miRNAs that were differently expressed among 2,555 miRNAs examined ([Table 4]). In particular, 13 miRNAs were upregulated and 26 were downregulated in GISTs compared to leiomyomas. Upregulation of the miR-140 family showed the largest fold change, approximately 20-fold higher in GISTs compared to leiomyomas.

Zoom Image
Fig. 2 Hierarchical clustering of miRNA expression profiles extracted from GIST and leiomyoma specimens acquired by submucosal tunneling biopsy. The samples are arranged in columns, and the miRNAs are arranged in rows. The tree on the left represents miRNA clustering. The tree above the heatmap shows sample clustering. The serial numbers of the samples are noted in the tree. Red squares around the serial numbers indicate the samples that were analyzed for miR-140-5 p and -3 p expression by real-time qPCR. Heatmaps show the relative expression intensity for each miRNA, in which the base-2 logarithm of the intensity is median-centered for each row. The color-coding is indicated as a horizontal bar at the left shoulder of the heatmap. 
Table 4

miRNA profiling of GIST compared to leiomyoma.

Name

Fold change (GIST/leiomyoma)

SD

P [*]

Chromosomal location

miR-140 – 5 p

20.08

15.82

0.0099

16

miR-140 – 3 p

16.82

11.39

0.0040

16

miR-181a-5 p

6.18

5.10

0.0256

1

miR-199a-5 p

3.45

2.52

0.0322

19

miR-3151 – 5 p

2.58

1.07

0.0044

8

miR-483 – 5 p

2.56

0.92

0.0029

11

miR-4436b-3 p

1.77

0.66

0.0273

2

miR-6756 – 5 p

1.71

0.63

0.0271

11

miR-3917

1.69

0.61

0.0228

1

miR-26b-3 p

1.67

0.70

0.0488

2

miR-4776 – 5 p

1.65

0.54

0.0188

2

miR-3175

1.57

0.47

0.0136

15

miR-6127

1.56

0.34

0.0241

1

miR-1909 – 3 p

0.69

0.22

0.0378

19

miR-4745 – 5 p

0.66

0.32

0.0288

19

miR-3195

0.64

0.10

0.0178

20

miR-718

0.62

0.22

0.0424

X

miR-4535

0.61

0.08

0.0032

22

miR-4467

0.58

0.25

0.0372

7

miR-5090

0.56

0.22

0.0500

7

miR-6746 – 3 p

0.55

0.34

0.0413

11

miR-4443

0.49

0.13

0.0432

3

miR-4687 – 5 p

0.43

0.11

0.0412

11

miR-3135b

0.43

0.21

0.0046

6

miR-5010 – 5 p

0.36

0.24

0.0203

17

miR-497 – 5 p

0.31

0.30

0.0074

17

miR-222 – 3 p

0.29

0.35

0.0364

X

miR-378f

0.25

0.17

0.0072

1

miR-28 – 3 p

0.23

0.25

0.0050

3

miR-422a

0.23

0.18

0.0206

15

miR-378 d

0.22

0.17

0.0093

4

miR-378c

0.22

0.17

0.0074

5

miR-378e

0.22

0.18

0.0090

5

miR-378 g

0.22

0.21

0.0110

1

miR-378i

0.21

0.16

0.0084

22

miR-378a-3 p

0.19

0.13

0.0102

5

miR-195 – 5 p

0.19

0.24

0.0024

17

miR-133a-3 p

0.04

0.03

0.0016

18

miR-133b

0.03

0.02

0.0001

6

GIST, gastrointestinal stromal tumor

* Unpaired t-tests



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Real-time qPCR

Reverse transcription and real-time qPCR were performed for miR-140 – 5 p and – 3 p, the two miRNAs that presented the most difference in their expression level between GIST and leiomyoma samples in the microarray analysis. The expression level of miR-140 – 5 p compared to U6 (ΔCT ± SD) was – 1.255 ± 1.891 for GISTs and 3.545 ± 1.114 for leiomyomas (P = 0.0008); thus, the relative expression level (2-ΔΔCT) was 27.86 times greater in GISTs compared to leiomyomas as shown in [Fig. 3]. In the case of miR-140 – 3 p, the ΔCT value was 5.167 ± 1.886 in GISTs and 8.780 ± 2. 337 in leiomyomas (P = 0.0304), revealing a 12.24 times greater. Samples numbered 3, 4, 6 – 10, 12, 14, 15, and 16 were analyzed by real-time qPCR for miR-140 family miRNAs; the other samples were not assessed because no total RNAs remained after microarray analysis.

Zoom Image
Fig. 3 Real-time qPCR for miR-140 – 5 p and – 3 p in GISTs compared to leiomyomas. a The relative expression level (2-ΔΔCT) of miR-140-5 p and -3 p was higher in GISTs than leiomyomas (27.86 times and 12.24 times, respectively). b The expression level of the miRNAs is shown as the average ΔCT ± SD. Six GIST and five leiomyoma samples were analyzed using real-time qPCR because no total RNA remained for other GIST or leiomyoma tissues after microarray analysis. *The P values were calculated using an unpaired t-test.

#
#

Discussion

The aim of the current study was to identify differences between small GISTs and leiomyoma through the investigation of miRNA expression patterns in human cases, because small GISTs and leiomyomas are difficult to differentially diagnose using contrast-enhanced CT scanning or endoscopic ultrasonography. Our main findings demonstrated that among 2,555 miRNAs, 13 miRNAs were upregulated and 26 miRNAs were downregulated in GISTs compared to leiomyomas. Among these, the miR-140 family was upregulated around 20 times greater in GISTs than in leiomyomas. Moreover, miRNAs extracted from tumor tissues differentially clustered between GISTs and leiomyomas. Real-time qPCR confirmed greater than a 10 – to 20-fold expression of the miR-140 family in GISTs compared to leiomyomas, in accordance with the microarray analysis.

Although EUS-guided fine needle aspiration (EUS-FNA), which has emerged as a standard method for sampling submucosal tumors, has the advantages of being rapid and convenient, its diagnostic yield is generally limited because of too little material for immunohistochemistry and technical issues [17] [18]. Accordingly, novel techniques with a greater diagnostic yield are needed to optimize tissue sampling. We have developed a novel sampling method, submucosal tunneling biopsy by using submucosal endoscopy, for gastric SMTs [13] [14]. The method that is applied to create a submucosal tunnel with a safety mucosal flap [15] enables us to obtain one core specimen for immunohistologic analysis, visualization of the tumor surface [19], identification of the layer of origin, and management of hemostasis under endoscopic vision. In addition, histologic analysis demonstrated that the acquired samples were pure specimens without contamination [20] and provided suitable SMT samples for miRNA analysis in the current study. The limitation of this method is that the potential for larger and deeper fibrotic changes of mucosa following the procedure. Fibrotic adhesion between layers of mucosa may make it difficult to perform secondary endoscopic resection of the tumor [21]. Submucsal endoscopy, an endoscopic submucosal tunneling method which is recognized worldwide for use in oral endoscopic myotomy (POEM) [22] in patients with achalasia, has opened up the new discipline of submucosal endoscopic surgery. Through what are best termed submucosal operations, we are exploring the full potential of the outstanding diagnostic and therapeutic interventions possible in the submucosal space [21]. Thirteen miRNAs among 2,555 examined, including miR-140 – 5 p and miR-140 – 3 p, were upregulated in GISTs compared to leiomyomas. The miR-140 family, which presented the largest change (approximately 20 times more highly expressed in GISTs compared to leiomyomas), is expressed in mesenchymal tissues such as articular cartilage in chondrogensis [23], human airway smooth muscle [24], and osteosarcoma [25]. MiR-140 has also been reported to regulate skeletal development. In two past studies that also reported upregulation of miR-140 family in GIST, 668 to 725 probes for miRNAs were used in microarray analysis without clear information about tumor diameter and validation of miR-140 – 5 p/3 p expression by real-time qPCR [9] [11]. Although the significance of miR-140 upregulation in GISTs remains unclear, this is the first report to identify an association between small GISTs with diameters ~ 20 mm and miR-140 that used reliable human samples and array analysis on up to 2,555 miRNAs.

MiRNA profiling revealed miRNAs that were differentially clustered between GISTs and leiomyomas, despite the histologic similarities between these tumors. Typically, GISTs cannot be distinguished from leiomyomas without immunohistochemical examination and electron microscopy analysis [3]. Although miR-140 – 3 p has been shown to be a poor serum biomarker in patients with osteosarcoma [12], the miR-140 family, which presented the largest change among the 39 miRNAs identified in this array analysis, should be evaluated as serum biomarkers of GIST. In addition, future studies should investigate how cartilage-specific miRNAs function in GIST and how these miRNAs contribute to the differentiation and proliferation of several mesenchymal tissues.

In conclusion, the expression profiles of the miR-140 family differed between GISTs and leiomyomas among the 2,555 miRNAs examined. MiR-140-5 p and -3 p may serve as specific biomarkers of small GISTs with diameters of approximately 20 mm for differential diagnosis of GISTs and leiomyomas.


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Competing interests: None

Acknowledgement

This study was supported by the UEGW2013 Top 5 abstract prize (H. Kobara).

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  • 14 Kobara H, Mori H, Fujihara S et al. Bloc biopsy by using submucosal endoscopy with a mucosal flap method for gastric subepithelial tumor tissue sampling (with video). Gastrointest Endosc 2013; 77: 141-145
    CrossrefPubMedGoogle Scholar
  • 15 Sumiyama K, Gostout CJ, Rajan E et al. Submucosal endoscopy with mucosal flap safety valve. Gastrointest Endosc 2007; 65: 688-694
    CrossrefPubMedGoogle Scholar
  • 16 Kato K, Gong J, Iwama H et al. The antidiabetic drug metformin inhibits gastric cancer cell proliferation in vitro and in vivo. Mol Cancer Ther 2012; 11: 549-560
    CrossrefPubMedGoogle Scholar
  • 17 Hoda KM, Rodriguez SA, Faigel DO. EUS-guided sampling of suspected GI stromal tumors. Gastrointest Endosc 2009; 69: 1218-1223
    CrossrefPubMedGoogle Scholar
  • 18 Sepe PS, Moparty B, Pitman MB et al. EUS-guided FNA for the diagnosis of GI stromal cell tumors: sensitivity and cytologic yield. Gastrointest Endosc 2009; 70: 254-261
    CrossrefPubMedGoogle Scholar
  • 19 Kobara H, Mori H, Fujihara S et al. Endoscopically visualized features of gastric submucosal tumors on submucosal endoscopy. Endoscopy 2014; 46: E660-E661
    Article in Thieme ConnectPubMedGoogle Scholar
  • 20 Kobara H, Mori H, Rafiq K et al. Analysis of the amount of tissue sample necessary for mitotic count and Ki-67 index in gastrointestinal stromal tumor sampling. Oncol Rep 2015; 33: 215-222
    PubMedGoogle Scholar
  • 21 Khashab MA, Pasricha PJ. Conquering the third space: challenges and opportunities for diagnostic and therapeutic endoscopy. Gastrointest Endosc 2013; 77: 146-148
    CrossrefPubMedGoogle Scholar
  • 22 Inoue H, Minami H, Kobayashi Y et al. Peroral endoscopic myotomy (POEM) for esophageal achalasia. Endoscopy 2010; 42: 265-271
    Article in Thieme ConnectPubMedGoogle Scholar
  • 23 Karlsen TA, Jakobsen RB, Mikkelsen TS et al. microRNA-140 targets RALA and regulates chondrogenic differentiation of human mesenchymal stem cells by translational enhancement of SOX9 and ACAN. Stem Cells Dev 2014; 23: 290-304
    CrossrefPubMedGoogle Scholar
  • 24 Jude JA, Dileepan M, Subramanian S et al. miR-140-3p regulation of TNF-α-induced CD38 expression in human airway smooth muscle cells. Am J Physiol Lung Cell Mol Physiol 2012; 303: L460-L468
    CrossrefPubMedGoogle Scholar
  • 25 Song B, Wang Y, Xi Y et al. Mechanism of chemoresistance mediated by miR-140 in human osteosarcoma and colon cancer cells. Oncogene 2009; 28: 4065-4074
    CrossrefPubMedGoogle Scholar

Corresponding author

T. Masaki
Department of Gastroenterology and Neurology
Kagawa University School of Medicine
Ikenobe 1750-1, Miki
Kagawa 761-0793
Japan   
Phone: 81-87-891-2156   
Fax: 81-87-891-2158   

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    Article in Thieme ConnectPubMedGoogle Scholar
  • 14 Kobara H, Mori H, Fujihara S et al. Bloc biopsy by using submucosal endoscopy with a mucosal flap method for gastric subepithelial tumor tissue sampling (with video). Gastrointest Endosc 2013; 77: 141-145
    CrossrefPubMedGoogle Scholar
  • 15 Sumiyama K, Gostout CJ, Rajan E et al. Submucosal endoscopy with mucosal flap safety valve. Gastrointest Endosc 2007; 65: 688-694
    CrossrefPubMedGoogle Scholar
  • 16 Kato K, Gong J, Iwama H et al. The antidiabetic drug metformin inhibits gastric cancer cell proliferation in vitro and in vivo. Mol Cancer Ther 2012; 11: 549-560
    CrossrefPubMedGoogle Scholar
  • 17 Hoda KM, Rodriguez SA, Faigel DO. EUS-guided sampling of suspected GI stromal tumors. Gastrointest Endosc 2009; 69: 1218-1223
    CrossrefPubMedGoogle Scholar
  • 18 Sepe PS, Moparty B, Pitman MB et al. EUS-guided FNA for the diagnosis of GI stromal cell tumors: sensitivity and cytologic yield. Gastrointest Endosc 2009; 70: 254-261
    CrossrefPubMedGoogle Scholar
  • 19 Kobara H, Mori H, Fujihara S et al. Endoscopically visualized features of gastric submucosal tumors on submucosal endoscopy. Endoscopy 2014; 46: E660-E661
    Article in Thieme ConnectPubMedGoogle Scholar
  • 20 Kobara H, Mori H, Rafiq K et al. Analysis of the amount of tissue sample necessary for mitotic count and Ki-67 index in gastrointestinal stromal tumor sampling. Oncol Rep 2015; 33: 215-222
    PubMedGoogle Scholar
  • 21 Khashab MA, Pasricha PJ. Conquering the third space: challenges and opportunities for diagnostic and therapeutic endoscopy. Gastrointest Endosc 2013; 77: 146-148
    CrossrefPubMedGoogle Scholar
  • 22 Inoue H, Minami H, Kobayashi Y et al. Peroral endoscopic myotomy (POEM) for esophageal achalasia. Endoscopy 2010; 42: 265-271
    Article in Thieme ConnectPubMedGoogle Scholar
  • 23 Karlsen TA, Jakobsen RB, Mikkelsen TS et al. microRNA-140 targets RALA and regulates chondrogenic differentiation of human mesenchymal stem cells by translational enhancement of SOX9 and ACAN. Stem Cells Dev 2014; 23: 290-304
    CrossrefPubMedGoogle Scholar
  • 24 Jude JA, Dileepan M, Subramanian S et al. miR-140-3p regulation of TNF-α-induced CD38 expression in human airway smooth muscle cells. Am J Physiol Lung Cell Mol Physiol 2012; 303: L460-L468
    CrossrefPubMedGoogle Scholar
  • 25 Song B, Wang Y, Xi Y et al. Mechanism of chemoresistance mediated by miR-140 in human osteosarcoma and colon cancer cells. Oncogene 2009; 28: 4065-4074
    CrossrefPubMedGoogle Scholar

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Zoom Image
Fig. 1 Schematic protocol for submucosal tunneling biopsy. The protocol consists of four procedures: 1) creation of the entry; 2) submucosal endoscopy with a mucosal flap (SEMF), in which the tumor is identified via a submucosal tunnel; 3) core specimen (1 – 4 mm in size) acquisition using biopsy forceps; and 4) clip closure of the entry.
Zoom Image
Fig. 2 Hierarchical clustering of miRNA expression profiles extracted from GIST and leiomyoma specimens acquired by submucosal tunneling biopsy. The samples are arranged in columns, and the miRNAs are arranged in rows. The tree on the left represents miRNA clustering. The tree above the heatmap shows sample clustering. The serial numbers of the samples are noted in the tree. Red squares around the serial numbers indicate the samples that were analyzed for miR-140-5 p and -3 p expression by real-time qPCR. Heatmaps show the relative expression intensity for each miRNA, in which the base-2 logarithm of the intensity is median-centered for each row. The color-coding is indicated as a horizontal bar at the left shoulder of the heatmap. 
Zoom Image
Fig. 3 Real-time qPCR for miR-140 – 5 p and – 3 p in GISTs compared to leiomyomas. a The relative expression level (2-ΔΔCT) of miR-140-5 p and -3 p was higher in GISTs than leiomyomas (27.86 times and 12.24 times, respectively). b The expression level of the miRNAs is shown as the average ΔCT ± SD. Six GIST and five leiomyoma samples were analyzed using real-time qPCR because no total RNA remained for other GIST or leiomyoma tissues after microarray analysis. *The P values were calculated using an unpaired t-test.