miRNAs are small non-coding RNAs transcribed from miRNA genes, which suppress the translation or result in the degradation of their target mRNAs by interacting with the 3′-untranslated region (UTR), open reading frame, or 5′-UTR of target mRNA. It has been reported that miRNAs play a vital role in the development of diseases, such as depression and cancer (15). The competitive endogenous RNA hypothesis explains the interaction between circRNA and miRNA. circRNA binds to miRNA through the miRNA response element, thus preventing miRNA-mRNA binding, and relieving the repressive effect of miRNA on target gene expression (16). For example, circ_PGPEP1 can reverse the oncogenic effect of miR-1297, and promote GC progression by binding miR-1297, which positively inhibits the expression of transcription factor E2F3 (17).

RBPs are a class of proteins that bind RNA to regulate processes such as splicing and translation. RBP binding sites on the surface of circRNA can specifically bind RBPs to form the RNA-protein complex, thereby blocking RBPs from binding to mRNAs for transcription and translation to inhibit the expression of specific genes. Cyclin-dependent kinases 2 (CDK2) is an important factor in cell cycle regulation, enabling the cell cycle to proceed in an orderly manner. circFOXO3 combines CDK2 and p21 proteins to form a ternary complex, leading to cell cycle disruption (18). In addition, circRNA can also interact with CCHC-type zinc finger nucleic acid binding protein (CNBP), nucleosome remodeling factor complex and other proteins to regulate life activities (19).

circRNAs are traditionally defined as ncRNAs, yet studies have demonstrated that some circRNAs are also capable of encoding proteins that play vital roles in numerous biological processes. For example, circular neuroligin RNA (circNlgn) encodes Nlgn173 in the heart, a protein isoform that causes proliferation of cardiac fibroblasts and reduced cardiomyocyte viability, and circNlgn expression is upregulated in congenital heart disease with cardiac overload (20). circMAPK1 encodes a polypeptide 109 amino acids in length that is localized in the cytoplasm and inhibits cancer cell proliferation, migration and invasion, thereby acting as a tumor suppressor (21). Owing to the lack of 5′ cap and 3′ poly(A) tail, circRNA initiates the translation process through the mediation of internal ribosome entry sites (IRES) or N-methyladensine (m6A) residues. IRES form secondary structures of RNA sequences, which recruit ribosomes and allow translation to be triggered (22). The m6A not only initiates and promotes the translation of circRNA, but also enhances the formation of translatable circRNA (23).

ElciRNAs localized in the nucleus, such as circEIF3J and circPAIP2, can bind to the U1 small nuclear ribonucleic proteins (snRNPs) to form the ElciRNA-U1 snRNP complex, which combines with RNA polymerase II and enhances the activity of enzymes, thus positively regulating gene transcription (24). CircRNAs can also compete with mRNAs for expression. Some genes can be transcribed, which later produce both mRNAs and circRNAs. When the spliceosome components are silenced, circRNA expression increases, while mRNA expression decreases, and the opposite occurs when the spliceosome components are activated (25).

Aberrant expression of circRNA in GC greatly contributes to carcinogenesis and development of GC. With the development of bioinformatics, researchers have identified a number of distinguishing circRNAs expressed in GC tissues, blood and gastric juice compared with normal samples. Luo et al (32) performed RNA-seq analysis of GC tissues and adjacent normal tissues, and identified 85 differentially expressed circRNAs, of which 52 were upregulated and 33 were downregulated in GC tissues. Wang et al (33) identified 145 circRNAs that were differentially expressed in cancerous and non-cancerous tissues, with 67 upregulated and 78 downregulated in GC tissues. Shen et al (34) distinguished 950 differentially expressed circRNAs by microarray, among which 347 were upregulated and 603 were downregulated in GC tissues. Chen et al (35) reported 180 differentially expressed circRNAs by RNA-seq, of which 82 were upregulated and 98 were downregulated in GC tissues, and ~80% of the circRNAs were from protein-coding genes. Shao et al (36) identified 308 differentially expressed circRNAs by microarray, of which 107 were upregulated and 201 were downregulated in GC tissues. Dang et al (37) screened the expression profiles of circRNAs in GC tissues using circRNA chip and found that 713 circRNAs were differentially expressed in GC tissues and normal tissues, of which 191 were upregulated and 522 were downregulated in GC tissues.

Differences in circRNA expression in GC tissues were often associated with sex, tumor diameter, degree of differentiation, T stage, distant metastasis, Tumor-Node-Metastasis (TNM) stage, lymph node metastasis, carcinoembryonic antigen and carbohydrate antigen 19-9 levels (38,39).

Numerous circRNAs have been found to be involved in GC cell proliferation, migration, invasion and apoptosis (Table SI) (1).

circRNA regulates the progression of gastric carcinogenesis mainly through its role as an miRNA sponge. As aforementioned, miRNA can repress target gene expression, and circRNA can deregulate this repressive effect. When miRNAs act on cancer genes, circRNAs can affect the relevant cancer pathways accordingly. If the miRNA target gene is a proto-oncogene, circRNA tends to promote the differentiation and proliferation of cancer cells, while if the miRNA target gene is an anti-oncogene, circRNA usually inhibits carcinogenesis. Numerous studies on the mechanism of the circRNA-miRNA-mRNA network in GC have appeared in the last 3 years (Table SI). For example, Zhang et al (40) found that knockdown of circular nuclear receptor interacting protein 1 (circNRIP1) inhibited the proliferation, migration and invasion of GC cells, and the study confirmed that circNRIP1 bound miR-149-5P, thus promoting the expression level of AKT1 and acting as a cancer promoter through the AKT1/mTOR pathway. The expression of circular RNA thrombospondin-1 (circTHBS1) was increased in GC and it was associated with a poor prognosis. Mechanistically, circTHBS1 sponged miR-204-5p to promote the expression of inhibin subunit βA (41). By contrast, Rong et al (42) showed that circPSMC3 expression was downregulated in GC tissues and plasma, and that circPSMC3 exerted tumor-suppressive effects by binding to miR-296-5p to regulate the expression of phosphatase and tensin homolog.

In addition to binding miRNAs, circRNAs can also bind directly to proteins to produce cancer-promoting or cancer-suppressing effects. For example, Yang et al (19) showed that circular RNA human antigen R (circ-HuR) can bind to CNBP, thus inhibiting CNBP binding to HuR promoter, downregulating HuR and ultimately exerting oncogenic effects. Zang et al (43) showed a tumor suppressor function of circEIF4G3 in GC through binding to δ-catenin protein to promote its tripartite motif containing 25-mediated ubiquitin degradation, and revealed its role as a promising prognostic biomarker and therapeutic target for GC.

Some circRNAs can also encode cancer-related proteins. As aforementioned, circMAPK1 can encode MAPK1-109aa, which inhibits the malignant biological behavior of cancer cells (21).

In addition, circRNA can act on promoters and regulate carcinogenesis by affecting gene expression. For instance, Ding et al (44) reported that circular RNA-downstream neighbor of SON (circ-DONSON) recruits the nucleosome remodeling factor complex to Sox4 promoter, initiates Sox4 transcription, and promotes proliferation, migration and invasion of GC cells. Jie et al (45) showed that circular RNA mitochondrial ribosomal protein S35 recruit histone acetyltransferase KAT7 to the promoters of FOXO1 and FOXO3a, and then activate FOXO1 and FOXO3a transcription, and inhibit the proliferation and invasion of GC cells.

Biomarker means ‘a biological molecule found in blood, other body fluids or tissues, which could be a marker of a normal or abnormal process, or of a condition or disease’, and it can distinguish diseased individuals from normal individuals (46). Biomarkers are relatively diverse chemically. Proteins, nucleic acids and glycans could all serve as biomarkers. As aforementioned, circRNA has higher stability than linear RNA, is conserved across species and is widely distributed in blood and various tissue fluids. These properties make circRNA a suitable choice for a biomarker. In patients with GC, researchers often sample plasma or GC tissue to detect circRNAs, and their role as diagnostic and prognostic markers is displayed in Table SII (1,47,48).

Existing studies have demonstrated the high value of some circRNAs in the diagnosis of GC. In GC tissues, circ_0066444, hsa_circ_0000467 and hsa_circRNA_102958 were upregulated and were used as diagnostic biomarkers (47). In GC plasma, circ_0004771 expression was detected to be upregulated, and it was expressed at different levels in patients with GC, patients with post-operative GC and patients with recurrence of GC, indicating that plasma circ_0004771 can be used as a biomarker for the diagnosis and dynamic monitoring of GC (48). In addition, a number of circRNAs with downregulated expression were also detected in GC tissues, including hsa_circ_0000181, hsa_circ_0001445, hsa_circ_0005758, hsa_circ_0005556, hsa_circ_0065149, hsa_circ_0067582, hsa_circ_0001811, circ_0049447, hsa_circ_0006470 and hsa_circ_0001874 (49). In plasma, hsa_circ_0006848 and hsa_circ_0001811 expression was found to be downregulated (50). The aforementioned studies confirmed the great potential of circRNAs as diagnostic biomarkers for GC.

circRNA has also shown great promise in the prognosis of GC. Tang et al (51) revealed that the expression of circ-KIAA1244 was lower in GC tissues than that in normal controls, and clinical analysis showed that its expression level was associated with TNM stage, lymph node metastasis and overall survival time of patients. circ-KIAA1244 can be considered a prognostic biomarker for GC, with an area under the curve value of 0.7481 (51). In addition, as aforementioned, some circRNAs, including hsa_circ_0001445, hsa_circ_0000467, hsa_circ_0005556, hsa_circ_0065149, circ_0004771, hsa_circ_0067582 and hsa_circ_0001874, are not only used as diagnostic biomarkers, but also have a suggested role in the prognosis of GC (48).

circRNA is involved in a variety of biological processes in cancer development, including cell proliferation, migration and invasion. The use of circRNA as a major target for GC therapy is receiving increasing attention.

Tumor suppressor circRNAs offer new options for the treatment of GC. As aforementioned, a number of circRNAs can inhibit tumors as miRNA sponges. Liu et al (52) synthesized circRNAs targeting miR-21 in vitro, and these sponges were able to prohibit cancer cell proliferation through relevant pathways, suggesting that synthetic circRNAs are a promising therapeutic strategy. Some drugs, such as lidocaine, can also increase the expression of tumor suppressor circRNAs; for example, upregulating circ_ANO5 in GC cells and regulating the circ_ANO5/miR-21-5p/leukemia inhibitory factor receptor axis to inhibit tumor growth (53). By contrast, cancer-promoting circRNAs are viable therapeutic targets. For circRNAs that promote the proliferation, spread and invasion of cancer cells, a therapeutic process can be achieved by inhibiting their expression. Piwecka et al (54) successfully knocked out Cdr1as from mice to achieve the relevant functional deletion, suggesting the feasibility of eliminating cancer-promoting circRNAs in patients with GC to attain cancer suppression. Cancer-promoting circRNAs were inhibited by drugs, such as gambogic acid, which downregulates circular RNA_arfGAP with SH3 domain, ankyrin repeat and PH domain 2 (circ_ASAP2) expression, isoproterenol, which reduces circular RNA plasmacytoma variant translocation 1 (circPVT1) expression in GC cells, and bupivacaine, which inhibits cancer progression by reducing circ_0000376 expression and exerts antitumor effects (55).

circAKT3 expression was higher in cisplatin-resistant GC tissues than in cisplatin-sensitive GC tissues, and circAKT3 promoted the resistance of GC cells to cisplatin by targeting the miR-198/PIK3R1 axis (56). Circular RNA cullin 2 (circCUL2) regulates cisplatin resistance by modulating autophagy activation via miR-142-3p/ROCK2 circCUL2 (57). circ_0110805 knockdown enhances the sensitivity of GC cells to cisplatin. Mechanistically, circ_0110805 acted as a sponge of miR-299-3p and its targeted endothelial protein disulfide isomerase (58). circ-DONSON expression is elevated in cisplatin-resistant GC tissues and cells, and it facilitates cisplatin resistance in GC cells by regulating the miR-802/BMI1 axis (59). circ_0026359 enhances cisplatin resistance in GC by targeting the miR-1200/POLD4 pathway (60). hsa_circ_0081143 inhibits miR-646 expression and activity, and leads to upregulation of CDK6 to promote cisplatin resistance in GC (61). Circular RNA multiple C2-domains with two transmembrane regions 2 (circMCTP2) sensitizes GC cells to cisplatin by upregulating myotubularin-related protein 3 through binding of miR-99a-5p. Upregulation of circMCTP2 may be a new strategy against cisplatin resistance in GC (62). In cisplatin-resistant GC cells, circPVT1 and heparin binding growth factor (HDGF) mRNA expression was upregulated. However, miR-152-3p expression was downregulated. circ-PVT1 regulates HDGF expression by targeting miR-152-3p, thereby regulating chemoresistance and malignancy in GC (63). circular RNA vesicle-associated membrane protein-associated protein A promotes chemoresistance and malignant progression of GC through the miR-125b-5p/STAT3 signaling pathway (64). circ_ASAP2 regulates drug sensitivity and functional behaviors of cisplatin-resistant GC cells by the miR-330-3p/NT5E/circ_ASAP2 axis (65). circ-PVT1 promotes cisplatin resistance by regulating autophagy, invasion and apoptosis in GC cells through the miR-30a-5p/YAP1 axis (66). circ-PVT1 expression is upregulated in paclitaxel-resistant GC tissues and cells, and it promotes paclitaxel resistance in GC cells by binding miR-124-3p to regulate ZEB1 expression, suggesting a potential therapeutic strategy for GC (67). circ_0032821 contributes to oxaliplatin (OXA) resistance of GC cells by regulating SOX9 via miR-515-5p, while hsa_circ_0000144 enhances OXA resistance by sponging miR-502-5P and upregulating ADAM9 (68). circNRIP1 can bind miR-138-5p to enhance 5-fluorouracil (5-FU) resistance in GC cells, providing a new target of action to overcome hypoxia-induced 5-FU resistance (69). circular RNA carboxypeptidase M has a crucial role in 5-FU resistance by targeting protein kinase AMP-activated catalytic subunit alpha 2 (70). Considering the effects of circRNAs on resistance to various antitumor drugs, combining drug therapy with target-acting circRNAs might play an unexpectedly large role in the treatment of GC.