Glucose metabolism is a fundamental physiological process essential for sustaining life, comprising both catabolism and anabolism. In catabolism, glycolysis converts glucose into pyruvate within the cytoplasm. Under anaerobic conditions, pyruvate is reduced to lactate, whereas under aerobic conditions, it enters the mitochondria and converts to acetyl-CoA to fuel the TCA cycle—the common pathway for complete substrate oxidation and substantial ATP generation (61). Regarding anabolism, glycogenesis polymerizes glucose to store energy via enzymatic reactions (62), while glycogenolysis functions in reverse to rapidly release glucose for blood glucose homeostasis (63). Additionally, gluconeogenesis synthesizes glucose from non-carbohydrate precursors to ensure energy supply during specific physiological states (64). These interconnected pathways are precisely regulated through mechanisms such as allosteric modulation, covalent modification, and hormonal control of key enzymes. This coordination adapts glucose metabolism to the organism’s varying energy and metabolic demands, ensuring normal physiological function.

Reprogramming of glucose metabolism is a hallmark of lung cancer. Lung cancer cells exhibit the “Warburg effect”, prioritizing glycolysis even in the presence of oxygen (65). Enhanced glycolytic flux enables rapid glucose uptake and its conversion to lactate, accompanied by limited ATP production (66). Beyond fueling rapid tumor proliferation, this process supplies abundant metabolic intermediates for biosynthesis. For instance, the pentose phosphate pathway derives ribose for nucleic acid synthesis, while glycolytic intermediates serve as precursors for amino acid and fatty acid synthesis (67). In the context of non-small cell lung cancer (NSCLC), Wang et al. (68) demonstrated via immunohistochemistry that protein tyrosine phosphatase receptor type H (PTPRH) upregulates glycolysis-related proteins (GLUT1, HK2, PKM2, and LDHA), thereby promoting tumor proliferation, migration, and invasion. Lung adenocarcinoma (LUAD), a common subtype of NSCLC, has been shown to be influenced by potassium channel activity. Lin et al. (69)reported that the acid-sensitive potassium channel 1 (KCNK3) suppresses cancer cell proliferation and glucose metabolism by activating the AMPK-TXNIP pathway in LUAD cells. Furthermore, Wang et al. (70) revealed that knocking down SLC2A1 expression in LUAD cells significantly impairs glucose transport, consumption, and lactate secretion, highlighting its pivotal role in glycolysis. Collectively, these findings suggest that targeting shared regulatory nodes linking glucose metabolism to lung cancer pathology—particularly in NSCLC and LUAD—may offer a promising strategy for modulating glucose metabolism and improving therapeutic outcomes.

Lipid metabolism encompasses the digestion, absorption, synthesis, and breakdown of lipids—including fats, phospholipids, sphingolipids, and cholesteryl esters—in living organisms (71). Triglycerides are primarily synthesized in the liver via the monoacylglycerol and diacylglycerol pathways using products derived from glucose metabolism. Fatty acid synthesis occurs in the cytoplasm, starting from acetyl-CoA as the substrate (72). In catabolic pathways, triglyceride mobilization is catalyzed by hormone-sensitive lipase, while fatty acids are oxidized through β-oxidation and other pathways to generate energy. Unsaturated fatty acids undergo specific oxidative processes, and under certain conditions, the liver produces ketone bodies to supply extrahepatic tissues (73). These pathways work in concert to maintain lipid homeostasis, and dysregulation at any step may lead to various health disorders.

In addition to glucose reprogramming, lung cancer cells undergo profound changes in lipid metabolism to support membrane biogenesis, signaling, and energy storage (74). This is achieved by upregulating fatty acid uptake transporters and activating de novo synthesis pathways (75). Furthermore, tumor cells flexibly adjust lipid enzyme activity and metabolic flux to facilitate growth and dissemination. For instance, Xu et al. (76)demonstrated that miR-365-3p suppresses CPT1A expression by targeting its 3′-untranslated region in lung cancer cells, leading to increased lipid droplet accumulation, reduced ATP production, and decreased fatty acid oxidation, ultimately regulating cell proliferation and migration. Similarly, Wang et al. (77)identified CCAAT enhancer-binding protein δ (C/EBPδ) as a key lipid regulator. By recruiting nuclear receptor coactivator 3 (NCOA3), C/EBPδ transcriptionally activates Slug (a classic EMT transcription factor), which induces the expression of oxidized low-density lipoprotein (oxLDL) receptor-1 (Lox1) and enhances oxLDL uptake to promote metastasis. Additionally, using multi-omics approaches and lung epithelial-specific Cpt1a-knockout mouse models, Ma et al. (78)confirmed that CPT1A, the rate-limiting enzyme of FAO, collaborates with L-carnitine derived from tumor-associated macrophages to drive ferroptosis resistance and CD8⁺T cell inactivation in lung cancer. Therefore, elucidating the mechanisms linking lipid metabolism to lung cancer may provide a theoretical basis for developing innovative therapeutic strategies targeting key lipid metabolic regulators.

Amino acid metabolism is a critical physiological process encompassing both anabolism and catabolism. In terms of anabolism, non-essential amino acids are synthesized endogenously via pathways such as transamination and reductive amination, whereas essential amino acids must be acquired through dietary intake. During catabolism, amino acids initially undergo deamination to yield ammonia and corresponding α-keto acids. Ammonia is primarily converted into urea in the liver via the urea cycle (ornithine cycle) and excreted to maintain nitrogen balance. Meanwhile, the resulting α-keto acids serve as substrates for gluconeogenesis, ketogenesis, or OXPHOS supplying energy and biosynthetic raw materials (79). Collectively, this precisely regulated system is essential for sustaining vital life activities, regulating physiological functions and systemic homeostasis.

Amino acid metabolism also plays a pivotal role in lung cancer progression, with tumor cells exhibiting an increased demand for specific amino acids. Using high-performance liquid chromatography-mass spectrometry (HPLC-MS), Sun et al. (80)analyzed 23 amino acids in bronchoalveolar lavage fluid from lung cancer patients. Their results, validated through partial least squares-discriminant analysis (PLS-DA), Shapiro-Wilk tests, and Bonferroni correction, revealed significantly elevated serine levels in the lung cancer group. Serine serves not only as a nitrogen source for multiple biosynthetic pathways but also enters the TCA cycle to support energy production (81). Lung cancer cells enhance serine uptake by upregulating serine transporter expression. Concurrently, key enzymes involved in serine metabolism undergo adaptive changes, enabling efficient utilization of serine in support of tumor metabolic reprogramming (82).

Furthermore, glutamine plays a central role in the metabolic reprogramming of lung cancer cells. As the most abundant free amino acid in cells, glutamine serves not only as a critical substrate for protein and nucleotide synthesis but also as a key regulator of intracellular redox homeostasis (83, 84). Huang et al. (85)demonstrated that glutamine blockade using 6-diazo-5-oxo-L-norleucine (JHU083) significantly potentiates the efficacy of an EGFR peptide vaccine (EVax) in controlling EGFR-driven lung cancer. This blockade enhances immunoprevention by promoting the infiltration of anti-tumor CD8+T cells and Th1 cells while reducing immunosuppressive cell populations. Additionally, Liu et al. (86)revealed that cancer-associated fibroblast (CAF)-specific long non-coding RNA LINC01614, packaged in CAF-derived exosomes, directly interacts with ANXA2 and p65 to promote NF-κB activation. This leads to upregulation of the glutamine transporters SLC38A2 and SLC7A5, enhances glutamine uptake in cancer cells, and ultimately contributes to an unfavorable prognosis in LUAD.

In summary, amino acid metabolism plays a crucial role in lung cancer progression. Further elucidation of the regulatory mechanisms linking additional amino metabolic pathways to lung cancer may open up novel and effective therapeutic avenues for precision treatment of this malignancy.

In lung cancer cells, circRNAs such as CircZNF707 and CircHIPK3 play a crucial role in regulating the expression of key metabolic enzymes. Mostly by altering the expression levels and activity of metabolic enzymes such as PFKM and HK2, they can meet the energy and material demands for rapid proliferation, invasion, and metastasis of lung cancer cells (91). But how exactly do circRNAs exert their regulatory functions in lung cancer cells? Further studies have revealed that circRNAs can participate in the regulation of key metabolic enzyme expression through multiple mechanisms. On one hand, circRNAs can act as molecular sponges to adsorb microRNAs (miRNAs), thereby alleviating the inhibitory effect of miRNAs on the mRNA of key metabolic enzymes and promoting their expression. For example, CircZNF707 competitively binds to miR-668-3p, upregulates PFKM expression, promotes glycolysis, and enhances the proliferation, migration, and invasion of non-small cell lung cancer cells (48); Researchers such as Gu et al. found that CircHIPK3, by adsorbing miR-381-3p, relieves the negative regulation of HK2 by miR-381-3p, upregulates HK2 expression, modulates glycolytic metabolism, and promotes lung cancer cell proliferation and migration (92); Similarly, CircSHKBP1 upregulates PKM2 expression by sponging miR-1294, mediating glycolysis and promoting the growth and metastasis of non-small cell lung cancer cells (93); Likewise, CircEHD2 adsorbs miR-3186-3p, upregulates HK2 expression, and facilitates glycolysis and the proliferation of non-small cell lung cancer cells (94); Moreover, Circ_UBE2C captures miR-107, alleviating its inhibition of HK2 and upregulating HK2 expression, thereby promoting glycolysis and lung cancer cell proliferation (95); It is noteworthy that some circRNAs exhibit more complex regulatory hierarchies. For instance, CircSLC25A16 can activate LDHA and promote its transcription through the miR-488-3p/HIF1α/LDHA signaling axis, enhancing glycolysis while significantly promoting the spread of non-small cell lung cancer (96); Meanwhile, Circ0000518 upregulates SLC1A5 expression by modulating the miR-330-3p/SLC1A5 axis, regulating glutamine metabolism and promoting the progression of non-small cell lung cancer (97). On the other hand, as a special class of non-coding RNAs, circRNAs can interact with specific proteins to regulate the expression of key metabolic enzymes. For example, CircP4HB binds to PKM2 and subsequently upregulates its expression by enhancing tetramer formation, promoting tumor progression in lung adenocarcinoma (98); Researchers such as Li et al. found that CircACC1 binds to the β and γ subunits of AMPK, stabilizing AMPK and enhancing its activity, promoting fatty acid β-oxidation and glucose metabolism while inhibiting lipid synthesis, thereby regulating metabolic reprogramming in lung cancer cells (99). Additionally, circRNAs can directly influence transcription and translation processes to regulate the expression of key metabolic enzymes. For instance, CircRARS positively regulates LDHA activity and expression at the transcriptional level, promoting glycolysis and the proliferation of non-small cell lung cancer cells (100). In summary, in lung cancer tissues, these circRNAs directly or indirectly regulate the expression of key metabolic enzymes through various molecular mechanisms, promoting metabolism such as glycolysis, which serves as the primary nutrient source for the proliferation and spread of lung cancer cells.(as shown in Figure 3 and Table 1).

In addition to influencing the metabolic processes of lung cancer cells by regulating the expression of key metabolic enzymes, circRNAs can also mediate metabolism-related signaling pathways such as PI3K, MAPK, and Wnt/β-catenin to modulate various metabolic processes in lung cancer cells, thereby regulating metabolic reprogramming in lung cancer. The PI3K pathway plays a crucial role in the proliferation, apoptosis, invasion, metastasis, and immune regulation of lung cancer cells, making it one of the key signaling pathways involved in the development and targeted therapy of lung cancer (101). Researchers have found that CircVAPA can activate the PI3K/AKT signaling pathway by regulating the miR-377-3p/IGF1R axis and the miR-494-3p/IGF1R axis, thereby modulating small cell lung cancer (102). For instance, Circ_0000376 inhibits the activity of the PI3K/PKB signaling pathway by downregulating the levels of phosphorylated PI3K and PKB, thereby suppressing the progression of non-small cell lung cancer (103). Circ-PLCD1, on the other hand, can adsorb miR-375 and miR-1179 and increase PTEN expression, thereby inhibiting the PI3K/AKT signaling pathway and acting as a tumor suppressor in non-small cell lung cancer (104). Additionally, miR-760 overexpression attenuates the regulatory effects of Circ_0008594 on the functions of H23 and H460 cells as well as the PI3K/AKT pathway. Therefore, Circ_0008594 promotes the development of non-small cell lung cancer by regulating the miR-760-mediated PI3K/AKT pathway (105).

The MAPK signaling pathway connects extracellular signals to cellular functions such as development, proliferation, differentiation, migration, and apoptosis. Abnormalities in the MAPK pathway can lead to cancer development (106). Circ0001313, Circ-ZKSCAN1, and others can mediate the MAPK signaling pathway to regulate the proliferation and development of lung cancer. For example, Circ0001313 competitively binds with miR-452, upregulates HMGB3 levels, and attenuates the ERK/MAPK signaling pathway, thereby inhibiting the proliferation and invasion of non-small cell lung cancer cells (107). Meanwhile, some scholars have found that Circ-ZKSCAN1, by adsorbing miR-330-5p, upregulates FAM83A expression, thereby inhibiting the MAPK signaling transduction pathway and further promoting the progression of non-small cell lung cancer (108).

Aberrations in the Wnt/β-catenin signaling pathway are not only a critical factor in the development and progression of lung cancer but also regulate cancer stem cell properties, invasion, and metastasis (109). Certain circRNAs can also mediate the Wnt/β-catenin signaling pathway and other metabolism-related pathways to regulate lung cancer progression. For instance, CircFBXW7 can be translated into a short peptide, circFBXW7-185aa, which, after epigenetic modification, interacts with β-catenin, leading to its ubiquitination and degradation. This process mediates the Wnt/β-catenin signaling pathway and modulates the progression of lung adenocarcinoma (110). Furthermore, circRNAs such as CircERI3 and CircACC1 can participate in regulating other signaling pathways, including mitochondrial metabolism and glucose metabolism, thereby providing necessary nutrients and energy support for the growth and migration of lung cancer cells. Specifically, CircERI3 interacts with DDB1, modulates its ubiquitination process, and enhances its stability, thereby promoting peroxisome proliferation, influencing mitochondrial function and metabolism, and ultimately driving lung cancer proliferation (111). Circ_0047921 mediates the miR-1287-5p/LARP1 signaling pathway, enhances glucose metabolism, and significantly promotes the proliferation, migration, and invasion of lung cancer cells (112). Additionally, researchers such as Li et al. found that CircACC1 directly binds to AMPK subunits, stabilizing and enhancing AMPK activity, which coordinates fatty acid β-oxidation and glucose metabolism while promoting lung cancer proliferation (99). It is noteworthy that some circRNAs can mediate multiple metabolic pathways simultaneously, rather than just one. For example, Circ-ZKSCAN1 not only promotes non-small cell lung cancer proliferation by adsorbing miR-330-5p and mediating the MAPK signaling pathway but also facilitates lung adenocarcinoma proliferation by regulating the miR-185-5p/TAGLN2 axis (108, 113).(as shown in Figure 3 and Table 2).

The tumor microenvironment (TME) comprises cellular components such as fibroblasts, endothelial cells, and immune cells, as well as non-cellular components including the extracellular matrix (ECM) and cytokines (114). During the development and progression of lung cancer, significant changes occur in the TME of lung cancer tissues, including alterations in cellular components, remodeling of the ECM, changes in cytokines, and metabolic reprogramming, which collectively provide the driving force for the proliferation and migration of lung cancer cells (115). CircRNAs contribute substantially to the remodeling of the TME, thereby creating favorable conditions for the growth, invasion, and metastasis of lung cancer cells (116). For instance, CircNOX4 upregulates fibroblast activation protein (FAP) via the miR-329-5p/FAP axis, increasing the expression of cancer-associated fibroblasts (CAFs). This enhances the glycolytic capacity and lactate secretion of CAFs, providing energy and synthetic precursors for tumor cells, thereby promoting angiogenesis, inflammatory responses, and metastasis, ultimately influencing the growth and metastasis of NSCLC (117). Extracellular vesicle-carried CircMYBL1 can modulate CD44 expression in human pulmonary microvascular endothelial cells (HPMECs), promoting adhesion between cancer cells and endothelial cells and facilitating pulmonary metastasis of adenoid cystic carcinoma (118). Moreover, circRNAs can modulate the functions of key immune cells, such as T cells and macrophages, either directly or through exosome-mediated mechanisms, thereby fostering an immunosuppressive TME in lung cancer. On one hand, circRNAs suppress T cell activity and infiltration. For instance, Wei et al. (119) demonstrated that circFNDC3B binds to transcription factor II-I (TFII-I) to downregulate the chemokines CXCL10 and CXCL11, consequently restricting CD8+T cell infiltration in NSCLC tissues. Similarly, circUSP7 induces CD8+T cell dysfunction via the miR-934/SHP2 axis, leading to resistance against anti-PD-1 therapy (120). On the other hand, circRNAs are pivotal in regulating macrophage polarization. Studies have shown that circATP9A and exosomal circPLEKHM1 (under hypoxic conditions) can facilitate macrophage polarization toward the pro-tumorigenic M2 phenotype via extracellular vesicle-mediated delivery, thereby driving lung cancer progression and metastasis (121, 122). CircRNAs can also facilitate the invasion and metastasis of lung cancer cells by breaking through ECM constraints via regulation of ECM remodeling. For example, under hypoxic conditions, Circ_0007386 enhances its circularization through YAP1-EIF4A3 interaction, subsequently affecting ECM remodeling via the miR-383-5p/CIRBP axis (123). Meanwhile, CircRNAs play a significant role in modulating cytokines. CircNOX4, through the miR-329-5p/FAP axis, upregulates FAP and promotes the secretion of cytokines such as IL-6 and CCL2, thereby fostering a pro-metastatic inflammatory microenvironment and further promoting the growth and metastasis of NSCLC (117). Additionally, some CircRNAs can alter the tumor metabolic microenvironment of lung cancer by regulating metabolism. For instance, Circ_0008928 promotes glycolytic metabolism through the miR-488/HK2 axis, remodeling the glucose metabolic microenvironment and facilitating the growth and migration of NSCLC cells (124). Furthermore, researchers such as Xue et al. found that Circ-LDLRAD3 promotes glutamine transport and metabolism by regulating the miR-137/SLC1A5 axis, reshaping the amino acid metabolic microenvironment in lung cancer. This not only provides nitrogen sources and energy for lung cancer cells but also participates in amino acid synthesis, supporting the biosynthetic and energy metabolism required for lung cancer cell proliferation, thereby promoting lung cancer progression (125). In summary, CircRNAs remodel the tumor microenvironment through diverse pathways, involving both cellular and non-cellular components, creating favorable conditions for the proliferation and metastasis of lung cancer cells.(as shown in Figure 3 and Table 3).

Epigenetic modifications, including DNA methylation, histone modifications, and non-coding RNA-mediated gene regulation, represent a reversible and heritable mode of influencing gene expression (126). In the metabolic reprogramming of lung cancer, the regulation of epigenetic modifications by circRNAs is of great significance, as they exert regulatory roles at multiple levels such as DNA methylation, histone modifications, chromatin remodeling, and RNA modifications. Lung cancer tissues exhibit significantly abnormal histone acetylation, with promoter hypermethylation commonly observed in early stages leading to the inactivation of tumor suppressor genes, while promoter hypomethylation or loss of methylation is more frequent in advanced stages (127). Some circRNAs can regulate metabolism through epigenetic modifications such as DNA methylation, histone modifications, and chromatin remodeling, thereby promoting the proliferation and invasion of lung cancer cells (127). For instance, CircTFF1 upregulates DNMT3A via the miR-29c-3p/DNMT3A axis, promoting BCL6B promoter methylation and suppressing its transcription. As BCL6B is a transcriptional repressor, its downregulation alleviates the transcriptional repression of various metabolism-related genes, thereby remodeling the metabolic network of lung cancer cells and providing energy and nutrients for their proliferation, migration, and invasion (128). In NSCLC, upregulation of Circ_0077837 reduces PTEN expression and increases PTEN gene methylation, thereby inhibiting apoptosis in lung cancer cells (129). CircRNAs can also regulate lung cancer metabolism through RNA modifications. For example, CircERI3 undergoes increased nuclear export via 5-methyladenosine modification, enhancing DDB1 stability and promoting PGC-1α transcription, thereby altering mitochondrial energy metabolism and facilitating lung cancer development (111). Similarly, CircNOTCH1 regulates the NOTCH1 pathway by modulating m6A methylation, indirectly influencing glycolysis and promoting NSCLC cell growth (130). Additionally, CircVMP1 mediates the miR-524-5p/METTL3 axis by regulating m6A modification, promoting the progression of NSCLC (131). Beyond DNA methylation and RNA modifications, circRNAs in lung cancer tissues also regulate histone modifications and chromatin remodeling. For example, CircNDUFB2 inhibits NSCLC progression by enhancing the ubiquitination and degradation of IGF2BP (132). Meanwhile, CircEPB41L2 can bind to the RRM1 domain of PTBP1 and the E3 ubiquitin ligase TRIP12, promoting polyubiquitination and degradation of PTBP1, thereby inhibiting glucose uptake and lactate production, and subsequently suppressing NSCLC progression and metastasis (133). Conversely, CircDCUN1D4 forms a CircDCUN1D4/HuR/TXNIP RNA-protein ternary complex, stabilizing TXNIP expression, which inhibits glucose uptake and glycolysis, as well as the metastasis of lung cancer cells (134). The regulation of epigenetic modifications by circRNAs in lung cancer tissues constitutes a complex and precise network involving DNA methylation, histone modifications, and other mechanisms. This network not only influences the metabolism of lung cancer cells but also remodels the tumor microenvironment, promoting their proliferation and invasion.(as shown in Figure 3).