Long noncoding RNAs: glycolysis regulators in gynaecologic cancers

The three most common gynaecologic cancers that seriously threaten female lives and health are ovarian cancer (OC), cervical cancer (CC), and endometrial cancer (EC). CC is associated with HPV infection [1]. One study found that from 1990 to 2019, the net drift in CC mortality was − 0.19% per year (95% CI, − 0.46% to 0.08%) in China [2]. These results were mainly due to improved medical standards, early detection, early treatment, and early diagnosis.

EC is associated with cumulative obesity, oestrogen-related exposure, and other reproductive factors [3]. Between 1990 and 2019, the estimated average percentage change in age-standardized mortality rates in EC was 0.85% (95% CI, 0.93 to 0.76) globally [4]. Compared to the traditional dualistic histopathologic classification, the new molecular classification based on genetic risk factors includes four prognostic categories: microsatellite instability hypermutation, tumours with low and high copy numbers, and POLE ultra-mutation [5]. A longer progression-free survival is correlated with the POLE ultra-mutation, which also has the best prognosis [6]. By using this new classification system, patients can receive more personalized care [7].

The factors that influence OC development are not clear. One study found that an imbalanced vaginal microbiome could increase a person's risk of developing OC [8]. However, advanced gynaecologic cancers continue to pose a serious threat to the lives and health of women worldwide. In particular, most cases of OC are diagnosed at an advanced stage, with 50–70% recurring within two years of initial treatment and a 5-year survival rate of less than 30% [9]. R0-targeted primary cytoreductive surgery and platinum-based combination chemotherapy remain the standard first-line treatments for primary OC. In the primary treatment of OC, poly (ADP-ribose) polymerase (PARP) inhibitors and antiangiogenic bevacizumab are increasingly being used as first-line maintenance therapies [10, 11]. According to research by Hanley, opportunistic salpingectomy can reduce OC risk [12], which leads to a primary prevention opportunity for the general population.

The link between aerobic glycolysis and cancer has existed for decades since the “Warburg effect” was proposed [13‐16]. Numerous studies have demonstrated that glycolysis is promoted in gynaecologic cancers [17‐19]. The pentose phosphate pathway (PPP), glycolytic enzymes, and glucose transporters (GLUTs) are essential components of glycolysis. Moreover, hypoxia-inducible factor-1α (HIF-1α) is a vital regulator [20, 21]. However, the mechanism of action of ideal drugs targeting the glycolytic pathway of gynaecologic cancers is still not clear; therefore, the in-depth study of their molecular mechanism is of great significance.

LncRNAs are a family of nonprotein-coding RNAs over 200 nt in length [22]. In the fields of chromatin dynamics, gene expression, development, differentiation, and protein stability, lncRNAs have been demonstrated to play a regulatory role [23, 24]. In recent years, lncRNAs have been reported to regulate the energy metabolism of tumours and thus affect the malignant behaviour of tumours, which also partially reveals the molecular mechanism of glycolysis reprogramming. This is true for oesophageal cancer [25], breast cancer [26], pancreatic cancer [27] and gynaecologic cancers [22, 28, 29]. LncRNAs can be considered potential indicators of prognosis, diagnosis, and therapeutic targets [30]. However, the in-depth relationship between lncRNAs and glycolysis remains unclear.

This review will provide a brief overview of the known functions of glycolysis and summarize how lncRNAs regulate glucose metabolism through the regulation of glucose transporters and glycolytic genes. Moreover, we emphasize the functional roles of several lncRNAs that have been found to promote glycolysis in gynaecologic cancers and suggest reasonable strategies for future research.

Under normal circumstances, mitochondrial oxidative phosphorylation (OXPHOS) is the main source of adenosine triphosphate (ATP). Notably, there is often more glycolysis in tumour cells, which can only produce two molecules of ATP, even under adequate oxygen conditions.

Studies have revealed that some glycolytic enzymes have tumoricidal effects in vitro and in vivo. When glycolytic inhibitors are used with chemotherapy, growth inhibition is considerably intensified. Unfortunately, considering the importance of glycolysis in normal cell glucose metabolism, there has been limited therapeutic success. Many studies have focused on glycolysis in gynaecologic cancers from the perspective of coding genes and proteins, but research progress has not been satisfactory. Through diverse molecular mechanisms, lncRNAs are currently thought to play key roles in tumour development [102, 103]. Upregulating glycolysis is one of the mechanisms of lncRNAs in cancer [104‐107]. For example, lncRNA AGPG regulates PFKFB3-mediated tumour glycolytic reprogramming in oesophageal squamous cell carcinoma (ESCC) [25]. HISLA enhances aerobic glycolysis and apoptosis resistance in breast cancer cells [108].

According to the origin of their expression, lncRNAs may be divided into six types: intergenic lncRNAs, intronic lncRNAs, enhancer RNA (eRNA), bidirectional lncRNAs, sense lncRNAs, and antisense lncRNAs [109‐111] (Fig. 1).

Functionally, five major mechanisms for widely varying classes of lncRNAs have emerged [112‐114] (Fig. 2): (1) Guide: lncRNAs may attach to other molecules to direct them to specific genomic locations where target gene expression is regulated. HOTAIR can cause chromatin-modifying enzymes such as polycomb repressive complex-2 (PRC2) to bind to target genes and control their expression [115]. Wang et al. found that lncRNA LINRIS promoted glycolysis via the LINRIS/IGF2BP2/MYC axis in colorectal cancer [116]. LncRNA CASC9 increased pancreatic cancer glycolysis and epithelial–mesenchymal transition (EMT) by binding to protein kinase B (AKT) to actively regulate HIF-1 signalling [117]. The lncRNA GLCC1/HSP90/c-Myc/LDHA axis promotes colorectal carcinogenesis and glucose metabolism [118]. SNHG6 enhances glycolysis via the SNHG6/hnRNPA1/PKM axis in colorectal cancer (CRC) [119]. LncSLCC1 can attach to AHR and actively control HK2 gene expression, inducing glycolysis activation and tumour development in CRC [120]. (2) Scaffold: lncRNAs can operate as scaffolds, allowing particular regulatory cofactors to join together to form a complex that activates target genes. The RBBP5 and GCN5 complexes were recruited to the PFKFB3 promoter using LINC00930 as a scaffold. It promoted glycolytic flux and cell cycle progression in nasopharyngeal cancer by increasing H3K4 trimethylation and H3K9 acetylation levels in the PFKFB3 promoter region, which epigenetically transactivates PFKFB3 [121]. (3) Decoy: lncRNAs can regulate gene expression by preventing transcriptional regulators from binding to their binding sites. (4) ceRNA: LncRNAs can act as sponges to titrate microRNAs (miRNAs) away from their mRNA targets, reducing target gene suppression. The overexpression of TUG1 promoted cell metastasis and glycolysis via the TUG1/miR-455-3p axis in hepatocellular carcinoma [122]. Through the miR-199a-5p/c-Myc axis, LINC01123 enhances non-small cell lung cancer proliferation and aerobic glycolysis [123]. In colorectal cancer, lncRNA MIR17HG promotes glycolysis by upregulating HK1 transcription by sponging miR-138-5p. By interacting with miR-222-3p and activating the HIPK2/ERK/c-myc pathway [124]. LINC00261 increases aerobic glycolysis. In pancreatic cancer, LINC00261 could also lower c-myc expression by sequestering IGF2BP1 [125]. (5) Signalling: LncRNAs control gene regulation by interacting directly with DNA or collaborating with signalling pathways or transcription factors. Wang et al. revealed that lncRNA HULC promoted glycolysis by directly binding to LDHA and PKM2 in liver cancer [126]. Liu et al. revealed that AGPG regulated PFKFB3 to reprogram glycolysis in oesophageal squamous cell carcinoma (ESCC) [25]. Through a hypoxia responsive element (HRE) motif, lnc-Dpf3 binds to HIF1a and suppresses its function [127]. LncRNA FEZF1-AS1 may bind to and stabilize PKM2, increasing aerobic glycolysis in CRC [128]. SNHG6 enhances glycolysis via the SNHG6/hnRNPA1/PKM axis in CRC cells [119].

As a result, lncRNA-mediated glucose metabolism might occur via four possible mechanisms: (1) altering glycolytic enzyme expression levels, (2) altering the expression levels and distribution of GLUTs, or (3) regulating glycolysis-related transcription factors or signalling pathways [129‐131]. These findings show that lncRNAs operate as upstream regulators of glucose metabolism and might be utilized to discover new therapeutic targets for cancer prevention.

For gynaecologic cancers with high drug resistance, proliferation, migration, invasion, metastasis, and EMT, it is crucial to investigate regulation of the glycolytic pathway. Cancer cell fate is strongly correlated with energy metabolism. A low pH cancer microenvironment may be maintained, and the energy required for cancer cell growth can be supported by glycolysis. Additionally, a significant amount of nucleic acid precursors can be created to facilitate cell proliferation. Unfortunately, considering the importance of glycolysis in normal cell glucose metabolism, there has been limited therapeutic success.

LncRNAs are novel players in cancer glycolysis, and studying metabolism-related lncRNAs might help researchers better understand the regulatory mechanisms governing gynaecologic cancers' biological processes. Despite the use of targeted medications such as PARP inhibitors, the treatment of gynaecologic tumours is still in its initial stages, owing to resistance to chemotherapy, which results in a considerable reduction in the survival rate of patients with OC. The lncRNA-based approach to glycolysis has various advantages. One of them is that, in contrast to targeting glycolytic enzymes, targeting a single lncRNA directly may have no effect on normal cells. Similarly, the expression of certain proteins that are considered non-targetable can be manipulated by targeting a specific lncRNA. Because many lncRNAs are very specific, they can remain stable in body fluids. Furthermore, the evaluation of lncRNA levels is extremely promising in diagnosis and prognosis.

However, the molecular mechanisms and roles of the great majority of lncRNAs remain unknown. There are still many challenges. First, the specific mechanism by which lncRNAs act on glycolysis in gynaecologic cancers is unclear. The mechanism of lncRNAs acting on downstream target genes is similar to that of ceRNAs. Guides, scaffolds, decoys, and signals are rare and still need to be explored. Many studies have found that m6A regulatory factors can regulate the expression of enzymes related to the glucose metabolism pathway, thus affecting glycolysis in tumours [196, 197]. Ferroptosis, immunosuppression and immune escape are also related to tumour cell metabolic reprogramming. These findings provide a reference for us to study the specific mechanism of lncRNAs acting on glycolysis in gynaecologic cancers. Second, the upstream mechanism of lncRNA is also not precise. Last, no specific lncRNA has been found in gynaecologic cancers. Many studies have examined particular markers of gynaecologic cancers [198, 199], but the effect is minimal. Typically, the target proteins changed in gynaecologic malignancies do not have mutations in their coding sequence. Because of the lack of DNA changes, direct sequencing of the DNA of these genes may result in erroneous molecular diagnosis. Indeed, lncRNA dysregulation occurs mostly at the post-transcriptional level, leaving the DNA untouched. As a result, the molecular diversity in various patients is greatly underestimated, potentially leading to ineffective therapy. Most lncRNAs that have been identified thus far influence just a small number of cell processes that are critical for cell replication and survival. These findings imply that effective methods of impairing their function may be promising treatment options for gynaecologic cancers as well. The disadvantage is that many targets are targeted at the same time, either directly or indirectly, amplifying the impact of the dysregulated lncRNA inside cancer cells. Because certain metabolic pathways are redundantly changed, concentrating on only one target protein may not be enough to treat gynaecologic cancers efficiently. Precision medicine in cancer is based on therapeutic pathways that are personalized to patients’ genetic and epigenetic characteristics. The diagnostic and predictive significance of lncRNAs can be improved by improving classification methods based on genetic and epigenetic events in gynaecologic cancers. This has been demonstrated in EC [198, 200].

There is currently no FDA-approved lncRNA-based therapeutic available. The specific characteristics will be a milestone for the diagnosis and treatment of gynaecologic cancers if we can obtain specific results.

Based on the current predictive ability of biomarkers, we need to explore more accurate and consistent biomarkers and other types of lncRNA screening methods in the future. LncRNAs play an essential role in drug resistance and prognosis in gynaecologic cancers by regulating glycolysis, so targeted treatment of lncRNAs presents a potential hope of a radical cure. In general, the link between lncRNAs and glycolysis is interesting and urge us to explore further, which will contribute to targeted therapy and new combination therapies and lead to long-term benefits for patients.