This article is mentioned in:

Introduction

Functional dyspepsia (FD) is a clinical syndrome originated from the stomach and duodenum which displays no structural abnormalities through superior gastrointestinal endoscopy (1). The prevalence of FD in Asia is 8–23%, and it normally occurs in young people; influenced by dietary factor, social culture and psychological factors, the main clinical symptoms include postprandial fullness, epigastric pain, epigastric burning, nausea, vomiting and eructation (2). FD is a common gastrointestinal disorder that seriously affects the quality of life and socio-economic costs. The pathogenesis of FD is uncertain, which is closely related to gastrectasis hypersensitivity, impairments in the regulation of food intake, delayed gastric emptying and neuropsychological factors (3,4).

MicroRNAs (miRNAs), a small non-coding RNA molecule, play a crucial role in cell proliferation, apoptosis and differentiation as a transcriptional regulator of gene expression (5). The association between miRNAs and cancer is increasingly studied; the abnormal expression of miRNAs is correlated to the occurrence and development of gastrointestinal carcinoma (6,7). The analysis of miRNA chip indicates that the expression of miR-29c in gastric carcinoma tissue is obviously downregulated, and it is related to the progression of gastric cancer (8). Recent studies have shown that miRNA-510 and miRNA-29a are involved in the pathophysiology of irritable bowel syndrome (IBS) (9–11); miRNA is not only closely associated with gastrointestinal cancer, but also plays an important role in functional gastrointestinal disorders such as IBS and FD (12–14). To investigate the role of miRNA-19a in functional dyspepsia, we established models of functional dyspepsia in rats and compared the changes in miRNA-19a and studied the possible mechanisms.

Materials and methods

Animals

Sprague-Dawley (SD) rats (8-week-old male) of clean grade, weighing 205±16.5 g, were purchased from Nanjing Junke Biological Engineering Co., Ltd., and fed in different cages. All rats were free to eat and drink in the environment of 22±1°C at room temperature and 65–70% in relative humidity. The study was approved by the Ethics Committee of The Central Hospital of Enshi Autonomous Prefecture (Enshi, China). All authors read and approved the final manuscript.

Materials and reagents

TRIzol, reverse-transcription kit and real-time fluorescence quantitative polymerase chain reaction (qRT-PCR) kit (Promega Corp., Madison, WI, USA), miRNA-19a, U6 specific primers (Shanghai Sangon Biological Engineering Co., Ltd., Shanghai, China), miRNA-19a sequence mimics (miRNA-19a mimic) and miRNA-19a unrelated sequence mimics (scramble mimic) (Shanghai Sangon Biological Engineering Co., Ltd.), In vivo-jetPEI® (Polyplus Transfection, Illkirch, France), rat motilin (MTL), vasoactive intestinal peptide (VIP) (Wuhan Huamei Biological Engineering Co., Ltd., Wuhan, China), real-time fluorescent quantitative PCR 7500 system (Applied Biosystems, Foster City, CA, USA).

Establishment of functional dyspepsia rat model

Fifty rats were randomly divided into normal group, model group, miRNA-19a mimic group, miRNA-19a inhibitor group, miRNA-19a scramble (negative control) group using a random number table, 10 rats in each group. Rat models of functional dyspepsia in the other groups were established by proper clipping tail stimulation except the normal group (12). During the modeling period, the feeding and drinking of the experimental animals were not restricted, and the activity, weight and food intake of the rats were observed.

qRT-PCR

The total RNA of tissue was extracted by TRIzol and used as a template to be reverse transcribed into cDNA. Subsequently, PCR amplification was conducted in accordance with the steps in the qRT-PCR kit, with U6 as internal reference, for 40 cycles. The relative expression level of miRNA was expressed by 2−∆∆Cq. The primers of miRNA-19a were as follows: forward, 5′-CCGGTGTGCAAATCTATGCAA-3′ and reverse, 5′-CAGTGCAGGGTCCGAGGTAT-3′.

Gastric emptying rate and intestinal propulsive ratio

After rats were treated by fasting, not fluid deprivation, for 24 h, intragastric administration with semisolid paste was given. After 30 min, rats were sacrificed, followed by anatomy and measurement of total length of small intestine (pylorus - ileocecus). The distance from the pylorus to the leading edge of the ink served as the propelling distance of the ink in the intestine. Intestinal propulsive ratio = propelling length of the ink/total length of small intestine ×100%. Total gastric mass was weighed, and gastric body was cut open along with greater curvature, followed by washing away gastric content. The net gastric mass was weighed after drying. Gastric emptying rate = [1 - (total gastric mass - net gastric mass)/mass of intragastric administration) ×100% (13).

Serum MTL and VIP

The abdominal aortic blood was extracted and naturally coagulated, followed by centrifugation at 2,450 × g for 15 min at 4°C and collection of serum. The serum MTL and VIP were determined according to the instructions in the enzyme-linked immunosorbent assay (ELISA) kit.

Intraperitoneal injection with miRNA-19a mimic and miRNA-19a inhibitor

According to the instructions, In vivo-jetPEI and miRNA-19a mimic, miRNA-19a inhibitor or miRNA-19a scramble were mixed at a certain proportion and injected into the abdominal cavity of the rats, once every four days. The aseptic operation needs special attention, and other operations were the same as those in the model group. The functional dyspepsia rat model was established by clipping tail stimulation.

Statistical analysis

SPSS 17.0 software (SPSS, Inc., Chicago, IL, USA) was used for statistical analysis. Measurement data are expressed as mean ± SD. Student's t-test was adopted for independent samples. The analysis of variance was utilized for multivariate data. P<0.05 was considered to indicate a statistically significant difference.

Results

Comparisons of gastric emptying rate, intestinal propulsive ratio, MTL and VIP between model and normal group

The gastric emptying rate and intestinal propulsive ratio between normal and model group were calculated, further suggesting that gastric emptying rate and intestinal propulsive ratio in model group were significantly lower than those in normal group (P<0.05). MTL and VIP in rats were calculated by ELISA, which displayed that MTL in model group was remarkably decreased, and VIP was increased (P<0.05), indicating that the rat model of functional dyspepsia was successfully established (Table I).

Table I. Comparison of gastrointestinal motility between model group and normal group.

Table I.

Comparison of gastrointestinal motility between model group and normal group.

Group	No	Gastric emptying rate (%)	Intestinal propulsive ratio (%)	MTL (pg/ml)	VIP (pg/ml)
Normal group	10	77.56±4.87	65.34±4.62	432.4±69.2	324.8±51.2
Model group	10	59.18±5.85a	46.83±6.92a	316.8±73.4a	425.6±58.3a
P-value		<0.001	0.003	0.015	0.012

a P<0.05.

Comparison of difference of miRNA-19a expression between model and normal group

The contents of miRNA-19a in rat gastric tissue of model and normal group were detected by qRT-PCR, which displayed that the relative content of miRNA-19a in gastric tissue of model group was 6.13±0.89, which was 4.56±0.65 in normal tissue, suggesting that miRNA-19a was highly expressed in rats with functional dyspepsia (Fig. 1).

Figure 1. Comparison of difference of miRNA-19a expression between model and normal group. The contents of miRNA-19a in rat gastric tissue of model and normal group are detected by qRT-PCR, which displayed that the relative content of miRNA-19a in gastric tissue of model group is 6.13±0.89, which is 4.56±0.65 in normal tissue, suggesting that miRNA-19a is highly expressed in rats with functional dyspepsia, *P<0.05.

Changes of miRNA-19a after intraperitoneal injection with miRNA-19a mimic, miRNA-19a inhibitor

During the establishment of the rat model of functional dyspepsia, the expression of miRNA-19a was 8.52±1.04 in rats intraperitoneally injected with miRNA-19a mimic, 3.02±0.99 in those injected with miRNA-19a inhibitor, 4.62±0.76 in miRNA-19a scramble group, indicating that the expression of miRNA-19a in rats intraperitoneally injected with miRNA-19a mimic was obviously higher than that in the negative control group, and miRNA-19a inhibitor could remarkably decrease it in the gastric tissue (P<0.05) (Fig. 2).

Figure 2. Changes of miRNA-19a after intraperitoneal injection with miRNA-19a mimic, miRNA-19a inhibitor. After rats are intraperitoneally injected with miRNA-19a mimic, miRNA-19a inhibitor and negative control miRNA-19a scramble in rat model of functional dyspepsia, the expression of miRNA-19a was detected, indicating that the expression of miRNA-19a in rats of miRNA-19a mimic group is obviously increased, which significantly decreased in miRNA-19a inhibitor group, *P<0.05.

Effect of intraperitoneal injection with miRNA-19a mimic and miRNA-19a inhibitor on gastric motility

During the establishment the rat model of functional dyspepsia, the changes of gastric emptying rate, intestinal propulsive ratio, MTL and VIP in serum of rats intraperitoneally injected with miRNA-19a mimic and miRNA-19a inhibitor were further studied, indicating that gastric emptying rate, intestinal propulsive ratio and MTL in serum after injection with miRNA-19a mimic were increased (P<0.05). After injection with miRNA-19a inhibitor, it was found that gastric emptying rate, intestinal propulsive ratio and MTL in serum were significantly increased in model group, and VIP was decreased (P<0.05) (Table II).

Table II. Effect of intraperitoneal injection with miRNA-19a mimic and miRNA-19a inhibitor on gastric motility.

Table II.

Effect of intraperitoneal injection with miRNA-19a mimic and miRNA-19a inhibitor on gastric motility.

Group	No.	Gastric emptying rate (%)	Intestinal propulsive ratio (%)	MTL (pg/ml)	VIP (pg/ml)
miR-19a scramble	10	55.25±5.28	45.88±7.69	308.45±50.34	420.45±59.34
miR-19a mimic	10	41.98±7.24a	32.78±8.24a	214.34±69.23a	500.23±68.38a
miR-19a inhibitor	10	78.62±6.35a	68.45±7.93a	452.63±72.24a	306.27±72.93a
P-value		<0.001	0.009	0.002	0.008

a P<0.05.

Discussion

miRNA-19a is an important member of the miRNA-17-92 cluster. miR-17-92 gene is an oncogene, expressed in a variety of tumors, but its mechanism is unclear. The low miRNA-19a expression in serum can be used as a new indicator of poor prognosis in multiple myeloma (MM), but it is more sensitive to high expression of miRNA-19a relative to bortezomib that can reverse the prognosis of MM patients with low expression of miRNA-19a, thus improving survival time (14). miRNA-19a is highly expressed in bladder cancer (15), liver cancer (16), lung cancer (17), colon cancer (18) and other multiple tumors, which acts as an oncogene, and it is closely related to tumor invasion, metastasis, invasion and drug resistance. A study shows that miRNA-19a is highly expressed in the tissue of gastric cancer, and the high expression of miRNA-19a can induce the epithelial mesenchymal transition through phosphatidylinositol-3-kinase (PI3K)/serine/threonine kinase (Akt) pathway, promoting cell proliferation, migration and invasion, thus playing a role in carcinogenesis; the prognosis of patients with high miRNA-19a expression is poor (19). In gastric cancer cells, high expression levels of miRNA-19a can lead to the enhancement of cell proliferation and migration via activating nuclear factor κ-B (NF-κB) (20). The abnormal expression of miRNA is closely related with the occurrence and development of tumors; moreover, the dysregulation of miRNA expression can lead to a variety of diseases. miRNA is not only closely associated with gastrointestinal cancer, but also plays an important role in IBS, FD and other functional gastrointestinal diseases. This study aimed to investigate the effect of miRNA-19a on functional dyspepsia in rats.

The rat functional dyspepsia model was established by clipping tail stimulation, and the detection revealed that gastric emptying rate and intestinal propulsive ratio in rats of model group were significantly lower than those in normal group. MTL, as a gastrointestinal hormone, promotes gastric emptying and stimulates gastrointestinal motility through inducing the gastric three-phase of the migrating complex. In the digestive system, MTL can increase appetite and inhibit nausea and plays different roles in a variety of digestive disorders. In patients with functional dyspepsia, gastric emptying function is reduced, and gastric electrical rhythm is disordered, which are related to the decrease of plasma MTL content; gastroparesis or slow gastric emptying can be treated by MTL receptor agonist (21). VIP is not only a gastrointestinal hormone but also a neuropeptide. It is widely distributed in various body systems and closely related to and widely applied in the study of gastrointestinal diseases. The comparison of detection of MTL and VIP between model and normal group displayed that MTL was significantly lower in model group than that in normal group, and VIP was higher in model group than that in normal group (P<0.05). Thus, the model was established successfully.

miRNA-19a is closely related to functional dyspepsia and involved in the regulation of gastric motility in rats with functional dyspepsia. The contents of miRNA-19a in model and normal group were detected by qRT-PCR, which showed that miRNA-19a expression in model group was higher than that in normal group (P<0.05), indicating that miRNA-19a participates in the regulation of rat functional dyspepsia. To further determine the role of miRNA-19a, the intraperitoneal injection with miRNA-19a mimic was adopted, suggesting that gastric emptying rate, intestinal propulsive ratio and serum MTL in model group were significantly decreased, and VIP was increased (P<0.05); the high expression of miRNA-19a could decrease gastric motility in rats, resulting in elevating the harm of the disease. In contrast, after intraperitoneal injection with miRNA-19a inhibitor, gastric emptying rate, intestinal propulsive ratio and serum MTL were further increased in model group, and VIP was decreased (P<0.05). The gastric function can be ameliorated through reducing the expression of miRNA-19a.

This study indicated that miRNA-19a is highly expressed in the functional dyspepsia and can inhibit gastrointestinal motility. The gastrointestinal motility can be improved by reducing the expression of miRNA-19a.

Acknowledgements

Not applicable.

Funding

No funding was received.

Availability of data and materials

The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.

Authors' contributions

YD wrote the manuscript. YD and XZ established functional dyspepsia rat. YD and XX conducted PCR. YO and JH were responsible for gastric emptying rate and intestinal propulsive ratio. All authors read and approved the final manuscript.

Ethics approval and consent to participate

The study was approved by the Ethics Committee of The Central Hospital of Enshi Autonomous Prefecture (Enshi, China).

Consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

References