The Single-Nucleotide Polymorphism of miR-27a <i>rs895819</i> and the Expression of miR-27a in <i>Helicobacter pylori</i>-Related Diseases and the Correlation with the Traditional Chinese Medicine Syndrome

Zhang, Ling; Huang, Meng-Xin; Li, Dan-Yan; Zhang, Yun-Zhan; Lan, Shao-Yang; Luo, Qi; Dai, Yun-Kai; Wu, Yun-Bo; Ye, Jin-Tong; Chen, Wei-Jing; Li, Ru-Liu; Hu, Ling

doi:https://doi.org/10.1155/2022/3086205

Evidence-Based Complementary and Alternative Medicine

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Abstract Introduction Methods and Materials Results Discussion Conclusion Data Availability Ethical Approval Consent Disclosure Conflicts of Interest Authors’ Contributions Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2022 | Article ID 3086205 | https://doi.org/10.1155/2022/3086205

The Single-Nucleotide Polymorphism of miR-27a rs895819 and the Expression of miR-27a in Helicobacter pylori-Related Diseases and the Correlation with the Traditional Chinese Medicine Syndrome

Ling Zhang,¹Meng-Xin Huang,¹Dan-Yan Li,¹Yun-Zhan Zhang,¹Shao-Yang Lan,²Qi Luo,²Yun-Kai Dai,¹Yun-Bo Wu,¹Jin-Tong Ye,¹Wei-Jing Chen,¹Ru-Liu Li,¹and Ling Hu¹

Academic Editor: George B. Lenon

Received10 Jun 2021

Revised11 Oct 2021

Accepted22 Feb 2022

Published15 Mar 2022

Abstract

Aims. The study aims to explore the effects of the single-nucleotide polymorphism of miR-27a and its expression in Helicobacter pylori (H. pylori)-related diseases and the relationship between gastric pathology and traditional Chinese medicine (TCM). Methods. Subjects were classified into six histopathological groups and five TCM syndrome groups. All specimens underwent H. pylori detection through rapid urease test and methylene blue staining. Histopathological characteristics were observed by hematoxylin-eosin. The expression of miR-27a and its genotype were, respectively, detected by Quantitative Real-Time PCR and direct sequencing. Results. H. pylori promoted the malignant evolution of gastric mucosa and were involved in the formation of TCM syndrome. In H. pylori-positive patients, the frequency of miR-27a CT genotype at the rs895819 locus and its expression in the gastric cancer group were higher than those in other pathological groups. TCM syndrome had a close relationship with histopathological changes, and patients with spleen-qi deficiency syndrome had a higher risk of gastric cancer than other syndromes, regardless of H. pylori infection. Conclusion. The C allele at miR-27a rs895819 locus may be an oncogene in gastric cancer. High levels of miR-27a could play an important role in gastric malignant evolution, especially cancerization. There is a certain connection between TCM syndrome and pathological changes of the gastric mucosa to some extent, where patients with SQD syndrome had a higher risk of GC.

1. Introduction

Gastric cancer (GC) is the fifth most common cancer and the third most common cause of cancer death worldwide, especially in Eastern Asian and Eastern European countries [1–4]. Helicobacter pylori (H. pylori), a type of Gram-negative bacteria, colonizes the epithelial cells of gastric mucosa and continuously releases toxins and induces inflammation. Chronic uncontrollable inflammation caused by H. pylori is the first step before carcinogenesis, which then develops into atrophy, intestinal metaplasia (IM), dysplasia, and eventually cancer [5–7]. The various lesions caused by H. pylori, covering the gastric mucosa from benign to malignant, are collectively referred to as H. pylori-related gastric disease (HPGD). The mechanism of HPGD is complicated and is related to the inflammation and immune response of gastric mucosa. In this process, the activation of related inflammatory pathways and the release of various inflammatory factors are the microscopic manifestations of gastric mucosal lesions.

MicroRNAs (miRNAs), a kind of small noncoding RNA, can modulate gene expression at the posttranscriptional level by either inhibiting messenger RNA (mRNA) translation or promoting mRNA degradation. miRNAs are highly related to many physiological and pathological processes, such as cancer, cardiovascular disease, digestive disorders, metabolic diseases, and neurodegeneration [8–11]. miR-27a, a member of the miRNA-27 family, plays a vital role in modulating polymorphisms, tumorigenesis, proliferation, apoptosis, invasion, migration, and angiogenesis [12]. Many studies have indicated that the overexpression of miR-27a can promote the proliferation and migration of tumor cells and enhance the drug resistance of GC [13–16]. Single-nucleotide polymorphism (SNP), a kind of DNA sequence polymorphism, refers to a variation of a single nucleotide in DNA, which is the most common type of human heritable variation, accounting for more than 90% of all known polymorphisms. SNP can reduce processing, lower levels, and disrupt the function of a mature miRNA by affecting RNA synthesis [17]. Arisawa et al. found that miR-27a polymorphism was associated with gastric mucosal atrophy [18]; Xu et al. revealed that miR-27a rs895819 was involved in increased atrophic gastritis risk, improved gastric cancer prognosis, and negative interaction with H. pylori [19].

TCM syndrome is a comprehensive response of the body to internal and external pathogenic factors at a certain stage in diseases. Our previous research found that there was a close connection between TCM syndrome and HPGD. The TCM syndromes are a macroscopic manifestation of the pathological changes in gastric mucosa, which can reflect the pathological process of the gastric mucosa to a certain extent and can play a warning role in the evolution of gastric cancer [20–22]. Our study detected the SNPs of miR-27a rs895819 and the miR-27a expression in different stages of HPGD to explore the microscopic differences of TCM syndromes and interpret the mechanism of pathological changes in gastric mucosa from multiple perspectives and thus can provide an early warning basis for the clinic.

2. Methods and Materials

2.1. Study Population

All subjects are from the Endoscopy Center and Gastrointestinal Surgery of the First Affiliated Hospital of Guangzhou University of Chinese Medicine from Oct 2016 to Oct 2017. The subjects were diagnosed with chronic gastritis (CG), peptic ulcer (PU), and GC. Four biopsy samples were obtained from the gastric antrum or mucosal lesions and used for rapid urease test, histopathology, miR-27a gene polymorphisms, and miR-27a detection. The research protocol was approved by the Ethics Committee of the First Affiliated Hospital of Guangzhou University of Chinese Medicine (ethical research permission code: No. [2015]009); all subjects signed informed consent.

2.2. H. pylori Detection and Criteria of Gastric Mucosal Histopathology

Criteria of H. pylori infection referenced to the Second Asia-Pacific Consensus Guidelines for Helicobacter pylori infection and Kyoto Global Consensus [23–25]. Rapid urease test (Guangzhou Beisiqi Reagent Co., Ltd., Guangdong, China) and methylene blue staining (Guangzhou Chemical Reagent Factory, Guangdong, China) were performed in all subjects, and either positive can be diagnosed as H. pylori-positive (Figure 1). Based on the distribution on the small curve on the surface epithelium, Hp infection can be divided into four grades [26]: (1) none: no Hp infection; (2) mild: occasionally or less the 1/3 length of the specimen; (3) moderate: continuously or accounting for 1/3–2/3 length of the specimen; (4) severe: diffusely or distributed over the entire length of the specimen. According to the updated Sydney System, consensus on chronic gastritis in China, and our research needs [22, 26, 27], specimens are classified into six groups (Figure 2): (1) normal group (NOR): normal histology or only mild inflammation; (2) inflammation group (INF): moderate-severe inflammation; (3) gastric atrophy group (GA): gastric gland atrophy without IM or dysplasia; (4) premalignant lesion group (PL): with IM or mild-moderate dysplasia; (5) severe dysplasia group (SD): severe dysplasia with gland atrophy and inflammation; (6) gastric cancer group (GC): different degrees of GC. In addition, we divided chronic inflammation, gastric atrophy, intestinal metaplasia, and dysplasia into four grades from no to severe, according to the updated Sydney System [26].

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2.3. Criteria of TCM Syndromes

According to the syndrome differentiation in modern research of TCM and WHO International Standard Terminology on Traditional Medicine in the Western Pacific Region [28, 29], TCM syndromes of subjects were differentiated as follows: (1) nonsyndrome (NON): the subjects have no uncomfortable symptoms or abnormal signs; (2) spleen-stomach dampness-heat (SSDH) syndrome: a pathological condition ascribed to the accumulation of damp-heat that impairs the functions of the spleen and stomach, the same as dampness-heat in the middle energizer; (3) syndrome of liver-stomach disharmony (LSD): a syndrome marked by irritability, epigastric distension and pain, anorexia, belching, nausea, vomiting, and string-like pulse; (4) syndrome of spleen-qi deficiency (SQD): a pathological change characterized by qi deficiency with impaired transporting and transforming function of the spleen; (5) syndrome of internal blockade of static blood (IBSB): a pathological product of blood stagnation, including extravasated blood and blood circulating sluggishly or blood congested in a viscus, all of which may turn into a pathogenic factor, the same as blood stasis or stagnant blood. The TCM syndromes were diagnosed by two physicians and were confirmed in the condition of two primary symptoms or one primary symptom with two secondary symptoms.

2.4. Genotyping of miR-27a rs895819

HiPure Tissue DNA Kits (Magen, D3121-02) were used to extract DNA from gastric mucosal tissue. PCR amplification was performed by PCR DSMIX (Dongsheng Biotech, Guangdong, China; 077). The primer sequences were as follows: forward primer: 5′-TGTGTTTCAGCTCAGTAGGCAC-3′; reverse primer: 5′-CTGTCACAAATCACATTGCC-3′. The PCR conditions were 94°C for 4 min; then 40 cycles of 94°C for 30 s, 60°C for 30 s, and 72°C for 30 s; finally, 72°C for 10 min and 10°C 30 s. The PCR products were separated by 1% agarose gel electrophoresis (Figure 3). Then, the direct sequencing of PCR products was performed with the dideoxy-chain method.

2.5. miRNA-27a Expression Detection

HiPure FFPE miRNA Kits (Magen, R4313-02) were used to extract total RNA from gastric mucosal specimens, and then cDNA was reverse-transcribed and synthesized by ReverTra Ace qPCR RT Kits (ToYoBo, 511000). The cDNA was amplified by quantitative fluorescence PCR, and Typrobe, ROX dye, and KAPA Probe Fast qPCR Master Mix were used (KAPA Biosystems, KK4702). The conditions were 95°C for 2 min; 40 cycles of 95°C for 5 s, 55°C for 5 s, and 70°C for 30 s. The primer sequence is consistent with the above miRNA-27a genotyping primer sequence. U6 is the internal reference gene, and the expression difference of miR-27a was analyzed by the 2^−ΔΔCp.

2.6. Statistical Analysis

SPSS 25.0 and Stata 15.0 software were used for statistical analysis. Categorical variables including gender, H. pylori infection rate, distribution of TCM syndrome, and genotype were summarized by proportions and were analyzed by the Chi-square test or Fisher’s exact probability test. Levels of miR-27a were assessed by the Kruskal–Wallis H test due to unconformity with normal distribution. The miaR-27a rs895819 genotype distribution was examined by the Hardy–Weinberg equilibrium. Multivariate logistic regression analysis was conducted to explore compound factors in the formation of gastric pathology and TCM syndrome. value less than 0.05 indicated that the difference was statistically significant.

3. Results

3.1. Characteristics of Subjects

In total, 213 participants (129 males and 84 females) were included in the study. The distribution of age, gender, Hp infection, and miR-27a genotype of gastric pathological group and TCM syndrome group are displayed in Tables 1 and 2. Through the Fisher exact probability test, a significant difference in age and H. pylori infection among histopathological groups and TCM syndrome group was found ( < 0.05). Specifically, the proportion of patients over 65 in the GC group was higher than that of the INF and PL group; the H. pylori infection rate of the PL and GC group was greater than that of the NOR and INF groups. In the TCM syndrome group, both the SSDH and LSD groups had higher H. pylori infection rate than that in the NON and SQD groups, while it was higher in the SQD group than the NON group. All P values were less than 0.05. Table 3 shows the distribution of age, gender, Hp infection, gastric pathology, and TCM syndrome in different genotypes. No statistical difference was found.

3.2. The Severity of H. pylori Infection

As indicated in Figure 4(a), in the histopathological groups, the H. pylori infection degree in the PL and SD groups was higher than that in the NOR ( ≤ 0.001, = 0.002) and INF groups ( ≤ 0.001, = 0.007); the H. pylori infection in the PL group was more severe than that in the GC group ( = 0.008). Regarding the TCM syndrome groups (Figure 4(b)), SSDH, LSD, and IBSB groups had a higher H. pylori infection degree than the NON group ( = 0.003, 0.002, 0.016).

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3.3. Relationship between Gastric Histopathology/TCM Syndrome

Figure 5 illustrates the correlation between gastric histopathology and TCM syndrome. The distribution of gastric histopathology in NON, SSDH, LSD, and SQD syndrome groups was significantly different ( < 0.05). On the whole (Figure 5(a)), the ratio of the NOR group in the NON syndrome group was higher than that of the LSD syndrome group (27.3% vs. 4.3%), while the proportion of the INF group was far beyond the SSDH and SQD syndrome group (72.7% vs. 22.3%; 72.7% vs. 18.8%). Besides, PL was more common in LSD syndrome than in SQD syndrome (51.4% vs. 15.6%), and GC was more likely to occur in SQD syndrome than in SSDH and SD syndrome (56.3% vs. 22.3%; 56.3% vs. 15.6%). To further analyze the effect of H. pylori infection, we divided all subjects into H. pylori-positive and H. pylori-negative groups. In H. pylori-positive patients (Figure 5(b)), the proportion of GC in the SQD syndrome was much higher than that in the SSDH and LSD syndrome (58.3% vs. 25.6%; 58.3% vs. 8.6%), and GC in SSDH syndrome was more common than LSD syndrome (25.6% vs. 7.9%). Besides, the ratio of PL in SQD syndrome was lower than that of the LSD syndrome (16.7% vs. 55.6%). In H. pylori-negative subjects (Figure 5(c)), we also found the proportion of GC in SQD syndrome was remarkably higher than that in the SSDH syndrome (50.0% vs. 6.3%). All values were less than 0.05.

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3.4. The miR-27a rs895819 Locus SNPs in Gastric Histopathology/TCM Syndrome

The frequency of TT, CT, and CC genotypes of miR-27a rs895819 was 54.9% (117/213), 36.6% (78/213), and 8.5% (18/213), and the alleles did not deviate from the Hardy–Weinberg genetic equilibrium law. Figure 6 reveals the distribution of TT, CT, and CC genotypes and C/T allele frequency in different pathological groups and TCM syndrome groups. No statistical difference was observed in the histopathological group, neither in the whole subjects nor the H. pylori-negative subjects (Figures 6(a) and 6(c)). However, in H. pylori-positive patients (Figure 6(b)), the distribution of genotype in INF group and GC group was significantly different, with the higher frequency of CT genotype in GC group compared to INF group (53.7% vs. 21.1%). The frequency of genotypes in TCM syndrome groups showed no statistical difference, regardless of H. pylori infection (Figures 6(e)–6(f)). However, among H. pylori-negative patients, the frequency of CT genotype in the SQD group tended to increase compared with other syndrome groups.

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3.5. The Effect of miR-27a rs895819 Genotype on Its Expression

To explore the effect of rs895819 genotype on miR-27a expression, we analyzed the levels of miR-27a in different genotypes in both the histopathological group and the TCM syndrome group (Table 4). Altogether, the expression of miR-27a in different genotypes showed no significant difference ( > 0.05). However, patients with CT genotype tended to express more miR-27a than those with TT/CC genotype. There was no statistical difference in miR-27a expression in different genotypes between each of the pathological groups and TCM syndrome groups as well ( > 0.05).

3.6. miR-27a Expression in Histopathological Group/TCM Syndrome Group

The levels of miR-27a in each histopathological group and TCM syndrome group are displayed in Figure 7. In all subjects (Figure 7(a)), miR-27a expression in the GC group was dramatically higher than that in the PL group ( = 0.043). For H. pylori-positive patients (Figure 7(b)), the GC group also had higher levels of miR-27a than the PL group ( = 0.004), and there was no significant difference in miR-27a expression for H. pylori-negative patients (Figure 7(c)). These results suggested that the occurrence of GC was associated with the high expression of miR-27a. Whether infected with H. pylori or not, the levels of miR-27a in the TCM syndrome group showed no statistical difference (Figures 7(d)–7(f)). Nevertheless, miR-27a expression in the SQD group tended to increase compared to other groups in H. pylori-positive patients.

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3.7. The Correlation of miR-27a Level and Its Genotype with H. pylori Infection and Gastric Histopathology

Figure 8 reveals the relationship between miR-27a levels and the severity of gastric histopathology and H. pylori infection. The levels of miR-27a have no relationship with the severity of H. pylori infection and the grade of chronic gastric inflammation, gastric atrophy, and intestinal metaplasia. However, patients without gastric dysplasia expressed higher levels of miR-27a compared to those with moderate and severe dysplasia ( < 0.05). In addition, Spearman’s analysis showed that the degree of H. pylori infection had a negative correlation with the levels of miR-27a (Table 5). Figure 9 presents the relation between the miR-27a genotype and the severity of H. pylori infection and the grade of gastric histopathology. The results showed no statistical difference and Spearman’s analysis (Table 5) showed no correlation between them ( > 0.05).

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3.8. Multivariate Logistic Regression Analysis

To further evaluate the effect of compounding factors such as age, gender, H. pylori, and genotype, we performed a multivariate logistic regression analysis on gastric histopathology and TCM syndrome. Table 6 describes the outcome of the multinomial logistic regression between covariables and gastric histopathology using the NOR group as the reference. Compared with the NOR group, the female gender decreased the risk of GC (OR = 0.23), and H. pylori dramatically increased the risk of PL (OR = 26.85) and GC (OR = 10.16). Besides, the CT genotype was correlated with a high risk of GC (OR = 5.03). Table 7 shows the results of multinomial logistic regression between covariables and TCM syndrome using the NON group as the reference. Compared with the NON group, H. pylori infection significantly elevated the risk of SSDH (OR = 9.69), LSD (OR = 20.98), and SQD group (OR = 5.33). In addition, ages above 65 reduced the risk of LSD (OR = 0.09), while ages between 45 and 55 decreased the risk of SQD (OR = 0.1). After adjusting for age, gender, and H. pylori, no significant relation was found between TCM syndrome and miR-27a rs895819 SNPs.

4. Discussion

This study revealed that age, gender, levels of miR-27a, and its SNPs were closely related to HPGD, and H. pylori played a crucial role in the development of HPGD. H. pylori colonize the surface of the gastric mucosa by secretion of urease and then release virulence factors such as OpiA, CagA, and VacA, which cause damage to gastric mucosa persistently [30]. Our study showed that the infection rate of H. pylori and the severity of infection gradually elevated with the malignant evolution of gastric mucosal. Furthermore, the multivariate logistic regression analysis showed that H. pylori infection could dramatically increase the risk of PL and GC (OR = 26.85, 10.16), which indicated that H. pylori played a major role in HPGD. At the same time, plenty of studies showed that the eradication of H. pylori might decrease the risk of gastric atrophy, intestinal metaplasia, dysplasia, and carcinoma [31–33].

Around 41.35–72.3% of Chinese adults were infected with H. pylori [34], whereas only a part of them developed into the disease, which may be related to multiple factors such as the virulence of H. pylori, the host immune response, lifestyle, and the environmental factors [35, 36]. Our study found that patients in the GC group were older than those in the INF group, and as age increased, the probability of malignant transformation of gastric mucosa also increased, which may be due to the lower ability of immune response and self-repair and the higher infection rate and severity of H. pylori. de Vries et al. discovered that the risk of GA in patients over 40 was twice that of those under 40 [36]. A study also showed that older age was one of the risk factors in GC [4]. Moreover, gender can also influence the occurrence of the disease. According to the global survey, the proportion of males in GC was twice as much as that of females [2]. In this study, we found that the female gender had a lower risk of GC than the male gender (OR = 0.23), which was probably related to the unhealthy lifestyle in males, such as drinking and smoking, and these were considered risk factors of GC [4].

It has been found that miR-27a was closely correlated to GC. Zhang et al. demonstrated that miR-27 could induce epithelial-to-mesenchymal transition by activating the Wnt pathway and thus promoting gastric cancer cell metastasis [15]. Ding et al. discovered that miR-27a promoted the proliferation and metastasis of gastric tumor cells by suppressing PHLPP2 and activating the AKT/GSK3β pathway [13]. In this study, we detected the expression of miR-27a in each pathological group. No significant difference in miR-27a expression was found from NOR to SD group. However, when gastric mucosa became cancerous, the expression of miR-27a was dramatically increased regardless of H. pylori infection. Therefore, we speculated that the expression of miR-27a was tightly connected with the development of GC. Interestingly, our study also found that miR-27a expression has a negative correlation with the severity of H. pylori infection.

Furthermore, our study also analyzed the effect of miR-27a rs895819 polymorphism on HPGD. Although the distribution of TT/CT/CC genotype and the frequency of alleles showed no statistical difference among the histopathological groups in H. pylori-negative patients, the proportion of CC genotype and C allele tended to increase with the malignant evolution of gastric mucosa. In H. pylori-positive patients, the ratio of CT genotype in the GC group was significantly higher than that in the INF group. Also, the multivariate logistics regression analysis showed that the CT genotype dramatically increased the risk of GC (OR = 5.30). Therefore, we speculated that the C allele was an oncogene in GC, and patients with CT genotype have a high risk of malignant changes of the gastric mucosa.

To study the relation between miR-27a genotype and its expression, we also detected the expression of miR-27a in different genotypes. The level of miR-27a in the CT genotype tended to increase compared with TT/CC group, which is consistent with Xu et al.’ study [19]. Consequently, we speculate that the SNPs of rs895819 may affect miR-27a expression to some extent.

The syndrome is the core of TCM, and its formation is the result of the combination of multiple factors such as age, diet, living style, external evil (i.e., H. pylori), and body’s health condition. We explored the relationship between TCM syndrome and H. pylori infection, gastric histopathology, and miR-27a expression. We discovered that the TCM syndromes could reflect pathological changes to a certain extent. Among H. pylori-positive patients, the gastric mucosal of the NON group was normal or showed only mild inflammation. Patients with SSDH or LSD syndrome were likely to develop gastric atrophy or intestinal metaplasia, while GC was most common in the SQD group. Without H. pylori infection, most of the patients in the NON, SSDH, and LSD groups showed only inflammation, but the proportion of GC still took advantage in the SQD group. Meanwhile, the H. pylori infection rate and infection degree of the SSDH, LSD, SQD, and IBSB groups were much higher than those of the NON group. Therefore, we presume that TCM syndrome is an external manifestation of gastric mucosal lesions and H. pylori infection. The combination of TCM syndrome and H. pylori could help infer the histopathological changes of gastric mucosa clinically. At the molecular level, we found no statistical differences in the distribution of miR-27a genotypes and miR-27a expression in the TCM syndrome group. However, the proportion of CT genotype in the SQD group tended to increase among H. pylori-negative patients. The expression of miR-27a in the SQD group seemed to be higher than other syndrome groups among H. pylori-positive patients. It is reasonable to speculate that miR-27a and its SNPs play a role in the formation of SQD.

In this study, we found that whether infected with H. pylori or not, patients with SQD had a higher risk of GC than that of other syndromes, which suggested that patients with GC were likely to present as SQD. Many scholars have studied the gastric pathological changes in SQD. Liu et al. found that the gastric mucosal morphology and blood flow were changed, and the expression of multiple immune factors was reduced in SQD model rats [37]. Under the transmission electron microscope, Hu et al. discovered significant changes of ultrastructure in gastric mucosal epithelium cells in SQD patients, with the overexpression of MUC5A in crypt gland cells [21]. H. pylori can release various virulence factors to activate cell signaling pathways such as PI3-kinase/Akt, JAK/STAT and Ras, Raf, and ERK signaling pathways [38] and promote the expression of multiple carcinogenic factors such as miR-27a, eventually leading to cell cancerization. Cancer cells proliferate and spread and continue to damage the gastric mucosa and surrounding tissue. The early manifestations of GC are simply a series of dyspeptic symptoms such as abdominal distention and loss of appetite, which are consistent with the clinical symptoms of SQD. Clinical studies have shown that Jianpi-Yiqi medicine combined with chemotherapy can alleviate clinical symptoms, improve the quality of life, reduce adverse reactions, and enhance the immune function in GC patients [39]. Therefore, patients with H. pylori infection, clinically manifested as SQD syndrome, who have unhealthy lifestyles such as drinking and smoking, should have a gastroscope examination and early cancer screening.

Our study has several limitations. First, there were only a few subjects in the GA and SD groups in our study, affecting the conclusion. In addition, the patients included were all Chinese and from the same hospital. Hence, the external validity still needs to be studied on a large scale and in different races.

5. Conclusion

This study indicates that male gender, aging, and Hp infection are risk factors in the formation of gastric precancerous lesions and GC. The C allele at miR-27a rs895819 locus may be a susceptibility gene for GC. The high level of miR-27a expression may promote the occurrence of GC and SQD syndrome to a certain extent. There is a certain connection between TCM syndrome and pathological changes of the gastric mucosa, and patients with SQD syndrome are more likely to have gastric cancerization. The combination of H. pylori detection, TCM syndrome, the CT genotype at miR-27a rs895819 and its high expression may have a warning effect on gastric mucosal lesions [35].

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Ethical Approval

The research protocol was approved by the Ethics Committee of the First Affiliated Hospital of Guangzhou University of Chinese Medicine (ethical research permission code: No. [2015]009).

All subjects signed informed consent.

Disclosure

The funders had no role in the whole process of this research.

Conflicts of Interest

All the authors declare that there are no conflicts of interest regarding the publication of this article.

Authors’ Contributions

Ling Hu conceived and designed the study. Ling Zhang drafted the manuscript. Meng-xin Huang, Dan-yan Li, Yun-zhan Zhang, and Jin-tong Ye prepared the data. Ling Zhang, Yun-kai-Dai, and Yun-bo Wu analyzed the results. Qi Luo and Shao-yang Lan offered technical support and specimens’ collection. Wei-jing Chen, Ru-liu Li, and Ling Hu supervised the study. Ling Hu revised the manuscript. All authors approved the final manuscript as submitted.

Acknowledgments

All authors acknowledge the Guangzhou Huayin Medical Laboratory Center for technical assistance. This work was supported by the National Natural Science Foundation of China (Nos. 81774238, 81373563, and 30772689), construction of Chinese first-class discipline research of key project of Guangzhou University of Chinese Medicine ([2020] No. 62, [2019] No. 5, and [2018] No. 6), construction of Chinese first-class discipline of Guangzhou University of Chinese Medicine (2017, No. 70), construction of high-level university of Guangzhou University of Chinese Medicine (2016, No. 64), and innovation team to foster scientific research projects of Guangzhou University of Chinese Medicine (No. 2016KYTD07).

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