Abstract
Background
Lipid droplet formation is a prominent histological feature in clear cell renal cell carcinoma (ccRCC), but the significance and mechanisms underlying lipid droplet accumulation remain unclear.
Methods
Expression and clinical significance of MT1G in ccRCC were analyzed by using TCGA data, GEO data and scRNASeq data. MT1G overexpression or knockdown ccRCC cell lines were constructed and in situ ccRCC model, lung metastasis assay, metabolomics and lipid droplets staining were performed to explore the role of MT1G on lipid droplet accumulation in ccRCC.
Results
Initially, we observed low MT1G expression in ccRCC tissues, whereas high MT1G expression correlated with advanced disease stage and poorer prognosis. Elevated MT1G expression promoted ccRCC growth and metastasis both in vitro and in vivo. Mechanistically, MT1G significantly suppressed acylcarnitine levels and downstream tricarboxylic acid (TCA) cycle activity, resulting in increased fatty acid and lipid accumulation without affecting cholesterol metabolism. Notably, MT1G inhibited H3K14 trimethylation (H3K14me3) modification. Under these conditions, MT1G-mediated H3K14me3 was recruited to the CPT1B promoter through direct interaction with specific promoter regions, leading to reduced CPT1B transcription and translation.
Conclusions
Our study unveils a novel mechanism of lipid droplet accumulation in ccRCC, where MT1G inhibits CPT1B expression through modulation of H3K14 trimethylation, consequently enhancing lipid droplet accumulation and promoting ccRCC progression.
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Introduction
Clear cell renal cell carcinomas (ccRCCs) constitute approximately 75% of all cases of renal cell carcinoma (RCC) and are responsible for the majority of RCC-related deaths [1]. While surgical and ablative methods are effective treatments for early-stage ccRCC, a significant fraction of patients eventually develop metastases. This underscores the urgent need for early diagnostic markers, exploration of molecular mechanisms, and the identification of effective targets to enhance survival rates among kidney cancer patients. Historically, ccRCCs are characterized by malignant renal tubular epithelial cells with a clear cytoplasm, resulting from extensive lipid and glycogen accumulation [2]. Research in various cancer types has unveiled alterations in metabolic pathways governing tumor energy production and biosynthesis, termed “metabolic reprogramming”. Studies in ccRCC have been particularly enlightening, leading to the recognition of ccRCC as a metabolic disorder. In ccRCC, metabolic reprogramming typically encompasses changes in glucose and fatty acid metabolism, along with modifications to the tricarboxylic acid (TCA) cycle [3]. Lipid droplets, the primary intracellular lipid storage sites, serve as indicators of lipid deposition in cells. Research indicates that lipid droplet accumulation in ccRCC not only contributes to membrane biosynthesis but also exerts critical control over cancer proliferation and metastasis [4]. Therefore, targeting lipid deposition represents a promising therapeutic approach and an avenue for better comprehending the intricate mechanisms at play.
Recent evidence highlights the pivotal roles of Metallothioneins (MTs), small cysteine-rich proteins, in tumor initiation, progression, and drug resistance. Furthermore, specific MT isoforms’ varying expression levels offer diagnostic and therapeutic potential [5]. Among these isoforms, MT1G, a newly identified member of the MT1 family in humans, has been linked to ferroptosis in various cancers, including colorectal cancer, hepatocellular carcinoma (HCC), esophageal adenocarcinoma, prostate cancer, pancreatic adenocarcinoma, glioblastoma, and osteosarcoma [6,7,8,9,10,11,12]. However, the role of MT1G and its relationship with lipid accumulation in ccRCC remain unexplored. While histone modification is known to play a crucial role in tumorigenesis and malignant progression, its association with lipid metabolism in ccRCC has received scant attention. Importantly, the interplay between MT1G, histone modification, lipid metabolism, and their collective impact on ccRCC progression remains to be elucidated.
In our study, we observed a significant decrease in MT1G expression in ccRCC cells compared to adjacent normal renal cells, making it a promising diagnostic marker to distinguish renal cancer from normal tissue. Notably, high MT1G expression correlated with poorer prognosis in ccRCC patients. In vitro experiments revealed that MT1G promoted proliferation, migration, and resistance to sormentalafenib in ccRCC cells. In vivo, MT1G overexpression accelerated renal cancer tumor growth and metastasis. Mechanistically, MT1G was found to suppress the expression of CPT1B by inhibiting the binding of H3K14m3 to the CPT1B promoter, thereby impeding lipid droplet depletion and facilitating lipid droplet accumulation, ultimately driving ccRCC progression.
Materials and methods
A detailed description of the materials and methods used in this study is available in the online supplementary materials.
Results
MT1G expression as a sensitive marker for ccRCC tissue identification and its prognostic implications
Analysis of the TCGA database revealed that the MT1G gene exhibits reduced expression in ccRCC cancer (Fig. 1a). This finding was corroborated by data from the GES6344 and GSE781 databases, which also showed diminished MT1G expression in ccRCC cancer patients (Fig. 1b, c). To confirm this at the mRNA level, we collected cDNAs from both ccRCC cancer and normal adjacent tissues, performing qPCR assays that validated this observation (Fig. 1d). Moreover, the CPTAC database analysis indicated that MT1G’s protein level was lower in ccRCC cancer than in normal adjacent tissue (Fig. 1e). Immunofluorescence results further supported a decrease in MT1G protein expression in ccRCC cancer patients (Fig. 1f, Supplementary Fig. 1a). ATAC-seq data indicated reduced chromatin openness in ccRCC cancer tissues compared to normal tissues (Supplementary Fig. 1b). Notably, among these genes, MT1G emerged as a crucial player with diminished chromatin openness in ccRCC (Fig. 1g). The ROC curve demonstrated that MT1G mRNA expression in the aforementioned datasets (TCGA, GSE6344, GSE781, and cDNAs) exhibited high clinical diagnostic value (AUC = 0.911, 1.000, 0.884, 0.950) (Fig. 1h). Interestingly, we observed a positive correlation between high MT1G expression and the malignant progression stage of ccRCC cells (Fig. 1i), while it did not impede MT1G’s utility as a ccRCC tissue indicator. Prognostic analysis indicated that up-regulation of MT1G was linked to poor prognosis and lower disease-free survival rates for ccRCC patients (Fig. 1j and Supplementary Fig. 1c, d). T tests revealed that high MT1G expression was more prevalent in advanced ccRCC patients over 60 years old, as well as in patients with higher pathological grades (P < 0.05), higher clinical stages (III-IV stage) (P < 0.05), T3-4 depth (P < 0.05), and deceased patients (Supplementary Fig. 1e–k). Chi-square tests showed a significant positive association between high MT1G expression and patient age and histologic grade (P < 0.05) (Table 1). Single-cell sequencing data indicated that MT1G was primarily expressed in proximal tubule cells (Supplementary Fig. 1l, m, n), which are the presumptive origin of ccRCC cells [13]. We further analyzed the expression of MT1G in renal clear cell carcinoma tubular epithelial cellswith different malignant progression stages in GSE224630 single cell data, and found that the expression of MT1G in tubular epithelial cells increased with increasing malignant stage (Fig. 1k).These findings suggest that MT1G may play a tumor-promoting role during ccRCC progression.
MT1G promotes ccRCC tumor cell growth and metastasis in vitro and in vivo
To investigate the role of MT1G in ccRCC cancer development, we conducted cell function experiments using ccRCC 786-O and A498 cell lines. Lentiviruses carrying MT1G overexpression and knockdown constructs were successfully introduced into these cells, resulting in altered MT1G expression levels, both at the mRNA and protein levels (Supplementary Fig. 2a, b). Cell proliferation assays revealed that MT1G overexpression promoted the proliferation of 786-O and A498 cells compared to control cells (Supplementary Fig. 3a, b), whereas MT1G knockdown suppressed cell viability in both ccRCC cell lines (Supplementary Fig. 3c, d). Flow cytometry analysis demonstrated that MT1G overexpression reduced the number of cells in the G1 phase while increasing those in the S phase for 786-O cells (Supplementary Fig. 3e). In A498 cells, MT1G overexpression decreased the number of G1 phase cells and increased those in the G2/M phase (Supplementary Fig. 3f). Conversely, MT1G knockdown led to opposite effects in both cell lines (Supplementary Fig. 3g, h). These alterations in cell cycle progression correlated with changes in the expression of cyclin kinases CDK 2, CDK 4, CDK 6, CyclinD1, and the cell cycle inhibitory gene P21 (Supplementary Fig. 2c). Apoptosis assays using flow cytometry showed that MT1G had no significant effect on apoptosis in 786-O and A498 cells (Supplementary Fig. 2d, e). Sorafenib resistance experiments demonstrated that MT1G overexpression significantly reduced the sensitivity of ccRCC cells to sorafenib, while MT1G knockdown enhanced sensitivity (Supplementary Fig. 3i-j). Moreover, qPCR and western blot assays revealed that sorafenib could concentration-dependently induce the expression of MT1G at both the mRNA and protein levels (Supplementary Fig. 3k, l). In cell migration assay using transwell chambers, MT1G overexpression promoted the migration of ccRCC cells relative to control cells, while MT1G knockdown reversed this effect (Supplementary Fig. 3m–p). Additionally, high MT1G expression led to alterations in migration-associated marker proteins, including the inhibition of E-cadherin and increased expression of N-cadherin and Vimentin, both at the mRNA (Supplementary Fig. 2f, g) and protein levels (Supplementary Fig. 3q).
To assess whether MT1G promotes ccRCC cell growth in vivo, we subcutaneously injected ccRCC 786-O cells into four-week-old male nude mice. After 26 days, mice were euthanized and tumor tissues were removed and weighed. During these 26 days, the tumor volumes were measured and immunohistochemistry (IHC) analysis of tumor tissues using MT1G, Ki67, E-cadherin, and N-cadherin antibodies were performed. Above results revealed that MT1G overexpression increased the subcutaneous tumorigenic capacity of ccRCC 786-O cells compared to the control group, resulting in more tumors (Fig. 2a), increased tumor weight (Fig. 2b), and larger tumor volumes (Fig. 2c). Hematoxylin-eosin (HE) staining and IHC results showed that MT1G overexpression correlated with increased expression of Ki67, N-cadherin, and Vimentin, as well as decreased E-cadherin expression in xenograft tumor cells (Supplementary Fig. 4a). Equal weight of subcutaneous tumor from MT1G-overexpressing cells and control cells carrying a luciferase/GFP reporter gene were injected into right kidney of NVSG mice, and the effect of MT1G expression on the growth of renal orthotopic tumor was analyzed by live imaging, and these results showed that MT1G overexpression promoted the renal clear cell carcinoma growth in situ (Fig. 2d). Kidney GFP signals and kidney weight in OEMT1G orthotopic clear cell renal carcinoma mice were much more than OENC group mice (Fig. 2e, f). Analysis of survival ratio showed that renal tumors mice in situ with MT1G overexpression died more than control OENC group (Fig. 2g). Moreover, a detectable liver metastatic nodules was found in orthotopic renal carcinoma model mice with MT1G overexpression, whereas it was not be found in control group (Supplementary Fig. 4b). Furthermore, we injected MT1G-overexpressing cells and control cells carrying a luciferase/GFP reporter gene into the tail veins of severely immunodeficient NVSG mice. After six weeks, we observed liver and lung metastases using live imaging. MT1G-overexpressing 786-O cells developed more detectable liver and lung metastases than the control group (Fig. 2h, i; Supplementary Fig. 4c). Additionally, we conducted tail vein metastasis experiments in four-week-old male nude mice to confirm the role of MT1G in promoting lung and liver metastasis. Although nude mice are only deficient in T lymphocytes, resulting in a low metastasis rate compared to NVSG mice, IVIS imaging revealed that MT1G also promoted the formation of liver and lung metastatic nodules compared to the respective control groups (Supplementary Fig. 4d). Survival curve analysis of tail vein transfer model mice showed that 786-O cells expressing high MT1G significantly inhibited viability compared with control group mice (Fig. 2j).
MT1G modulates fatty acid metabolism by downregulating fatty acyl carnitine expression in ccRCC cells
To elucidate the potential mechanisms underlying MT1G’s role in human ccRCC progression, we conducted GSEA to explore signaling pathways from the KEGG database in samples with high and low MT1G expression. Our analysis of KEGG terms revealed a significant association between MT1G expression and fatty acid metabolism (Normalized Enrichment Score [NES] = –2.41, p = 0.00, q = 0.00) (Table 2). Moreover, GSEA data indicated that genes related to fatty acid metabolism were predominantly enriched in the low MT1G expression group (Supplementary Fig. 5a). Notably, analysis of the UCLAN database demonstrated a correlation between MT1G expression in ccRCC tissue and the obesity level of ccRCC patients (Supplementary Fig. 5b). Differential gene enrichment analysis of transcriptomic data following MT1G knockdown revealed significant impacts on genes associated with metabolic pathways, including the sterol signaling pathway, cholesterol metabolism, fatty acid metabolism, glucose and lipid metabolism, among others (Supplementary Fig. 5c). ATAC-seq results also showed that MT1G significantly influenced differential open genes enriched in metabolic pathways, such as the sphingolipid signaling pathway and glucose and lipid metabolism (Supplementary Fig. 5d).
To explore metabolic alterations influenced by MT1G expression, we conducted non-targeted metabolomics analysis in 786-O cells, followed by LC-MS analysis of cell lysates. We identified 62 up-regulated and 75 down-regulated metabolites affected by MT1G overexpression (P < 0.05) (Supplementary Fig. 5e). The variable weight values (VIP) were used to assess the influence and explanatory power of each metabolite’s expression pattern on group classification discrimination (VIP > 1, P < 0.05). Among the top three metabolites with the highest VIP scores, isovalerylcarnitine (VIP = 13.22, log 2(OEMT1G/OENC)= –0.46, P = 0.005), PE-NME2(15:0/20:2(11Z,14Z)) (VIP = 12.69, log 2(OEMT1G/OENC) = 2.483, P = 0.046), and PC(P-18:1(11Z)/18:1(9Z)-O(12,13)) (VIP = 10.147, log2(OEMT1G/OENC) = 2.785, P = 0.005) stood out (Supplementary Fig. 5f). Notably, isovalerylcarnitine, isobutyrylcarnitine, butyrylcarnitine, and oxoglutaric acid were significantly decreased, while glycerophosphocholine, PC(P-18:1(11Z)/18:1(9Z)-O(12,13)), and PE-NMe2(15:0/20:2(11Z,14Z)) were upregulated in the MT1G-higher expression group among the top 20 VIP score metabolites (Supplementary Fig. 5f). Further analysis of differential metabolites using KEGG pathways revealed that upregulated metabolites were associated with the regulation of lipolysis in adipocytes and the sphingolipid signaling pathway, among others, while downregulated metabolites were enriched in the TCA cycle (Fig. 3a, b). We classified remarkably differential metabolites related to glycolysis, lipid and fatty acid metabolism, cholesterol metabolism, and the TCA cycle pathway (Fig. 3c). Our results demonstrated that MT1G downregulated the TCA cycle and glycolysis processes, as well as fatty acyl carnitines, while upregulating lipid-related metabolites (Fig. 3c). Notably, targeted cholesterol metabolomics analysis showed that MT1G had no effect on cholesterol metabolism (Fig. 3c). Pearson correlation analysis revealed strong negative correlations among differential metabolites. Notably, glycerophospholipid metabolites (PC(P-18:1(11Z)/18:1(9Z)-O(12,13)), PE-NME2(15:0/20:2(11Z,14Z)), glycerophosphocholine) and carnitine metabolites (isobutyryl-L-carnitine, butyrylcarnitine, and isovalerylcarnitine) exhibited significant negative correlations (P < 0.05, correlation > 0.95) (Supplementary Fig. 5g, h). Carnitine and acylcarnitines, such as isobutyrylcarnitine, isovalerylcarnitine, and butyrylcarnitine, were identified as biomarkers related to fatty acid metabolism [14]. These findings suggest that MT1G inhibits the TCA cycle and glycolysis processes while suppressing fatty acid metabolism and upregulating lipid levels.
MT1G upregulates lipid metabolites and induces lipid droplet accumulation in ccRCC cells thereby accelerating ccRCC development
To investigate the impact of MT1G on fatty acid metabolism, we conducted targeted lipidomics, which revealed alterations in 308 lipid molecules, with 136 being up-regulated and 16 down-regulated following MT1G overexpression (Supplementary Fig. 6a). A pie plot illustrating the proportion of identified metabolite classes across all samples demonstrated that the majority of lipids detected in renal cancer cells were phosphatidylcholines (PC), free fatty acids (FFA), and lysophosphatidylcholines (LPC) (Supplementary Fig. 6b). A stacked bar chart displaying the relative abundance of each metabolite class in different groups showed that MT1G significantly modified the lipid composition ratios, particularly those of fatty acids (Fig. 4a). Further statistical analysis identified ten types of lipids and fatty acids that were significantly up-regulated following MT1G overexpression (Fig. 4b). We ranked the top 50 significantly differential metabolites based on the fold difference, and results indicated that the fatty acid with the most substantial fold change after MT1G overexpression was FFA (18:4), while the lipid with the most pronounced difference was diacylglycerol (DAG) (14:1/22:4) (Fig. 4c). Pathway enrichment analysis, using pathway-associated metabolite sets from the Small Molecule Pathway Database (SMPDB), revealed that MT1G influenced metabolites primarily enriched in long and medium-chain fatty acid beta-oxidation and fatty metabolism, consistent with our earlier findings (Supplementary Fig. 6c). We performed ORO staining to investigate whether lipid droplets accumulated in renal cancer cells due to MT1G expression. ORO staining revealed a significant increase in lipid droplet intensity, including both the ORO staining area and the number of lipid droplets per cell, in MT1G-overexpressing 786-O and A498 cells compared to the control groups (Fig. 4d, e). Furthermore, cells with high MT1G expression exhibited significantly inhibited lipid utilization, as evidenced by increased lipid droplets compared to controls when treated with 200 or 400 μmol oleic acid (Fig. 4d, e).The impact of MT1G knockdown on lipid droplet accumulation and the growth of ccRCC were also performed, the resultsdemonstrate that MT1G knockdown significantly reduces lipid droplet accumulation in ccRCC cells when treated with 200 μmol oleic acid (Supplementary Fig. 6d, e). Moreover, our subcutaneous tumor experiment in immunodeficiency mice revealed that MT1G knockdown markedly inhibits ccRCC growth, with a noticeable decrease in the number of lipid droplets in tumors formed by MT1G knockdown cells compared to the control group (Supplementary Fig. 6f–h). These findings collectively suggest that MT1G promotes lipid accumulation in ccRCC cells thereby accelerating ccRCC development.
MT1G suppresses fatty acid β-oxidation by inhibiting CPT1B, promoting lipid droplet accumulation
Mitochondrial fatty acid β-oxidation is the major pathway for the catabolism of fatty acids, the transfer of fatty acids into the mitochondria for fatty acid oxidation (FAO) need carnitine acetyltransferases which can catalyze the reversible transfer of acyl groups between coenzyme A (CoA) and carnitine, converting acyl-CoA esters into acyl-carnitine esters and vice versa [4]. This exchange step between CoA and carnitine was essential as the mitochondrial inner membrane was impermeable to long-chain CoA fatty acids [15]. The carnitine palmitoyltransferase system is responsible for delivering the long-chain fatty acid from cytoplasm into mitochondria for oxidation, where carnitine palmitoyltransferase I (CPTI) catalyzes the rate-limiting step of fatty acid oxidation (FAO), resulting in intracellular lipid accumulation. The CPT1 family of proteins contains 3 isoforms: CPT1A, CPT1B and CPT1C [16, 17]. Non-targeted metabolomics and lipid-targeted metabolomics combined analysis showed that long-chain fatty acids increased, while downstream acylcarnitines and COA decreased, and the TCA cycle decreased after MT1G overexpression (Fig. 5a). Therefore, we hypothesized that MT1G may inhibit the expression of CPTs, thus inhibiting the metabolism of fatty acids, leading to the accumulation of lipid droplets. The relative mRNA levels of CPT1B and CPT1C were significantly lower in MT1G over-expressing ccRCC cells (Fig. 5b), whereas the CPT1A mRNA levels remained unchanged (Fig. 5b). Correlation analysis showed MT1G also has a negative correlation with CPT1B (R = −0.095, P < 0.05) but bot CPT1C (R = −0.018, P = 0.69) in TCGA KIRC dataset (Fig. 5c). In addition, CPT1B were also decreased at protein levels without CPT1A and CPT1C protein levels trend changing (Fig. 5d). Polychromatic immunofluorescence experiments further demonstrated a negative relationship between MT1G and CPT1B at the protein level in different grades of ccRCC patient tissues. As MT1G levels increased, CPT1B levels progressively decreased in different grades of ccRCC cancer patients, accompanied by lipid droplet accumulation (Fig. 5e, Supplementary Fig. 7a). 786-O cells were lentivirally infected with GFP/MT1G constructs, with GFP-positive cells confirming successful infection. MT1G overexpression in these cells led to a notable decrease in CPT1B expression (Fig. 5f). Furthermore, transfection of pcdna3.0-MT1G suppressed CPT1B expression, while si-RNA-mediated MT1G knockdown inhibited CPT1B expression as observed in polyolor immunofluorescence experiments (Supplementary Fig. 7b).To confirm that MT1G inhibited lipid droplet accumulation through CPT1B, we designed three pairs of CPT1B siRNAs and transfected them into shMT1G cells. The results showed that MT1G knockdown led to CPT1B activation, and CPT1B knockdown effectively reversed this phenomenon (Fig. 6a, b; Supplementary Fig. 8a). Cell proliferation assay showed that low MT1G expression significantly inhibited cell proliferation. However, re-lowering the CPT1B gene, in addition to MT1G knockdown, by transfecting three different siRNAs targeting CPT1B effectively restored the proliferation-inhibitory effect of MT1G knockdown. Among these, siCPT1B-1 fully complemented the proliferation-inhibitory effect of MT1G knockdown (Fig. 6c). Cell migration assay demonstrated that CPT1B also reversed the weakened migration caused by MT1G knockdown (Fig. 6d). ORO staining experiments confirmed that the increased lipid depletion observed after MT1G knockdown was significantly restored after CPT1B knockdown in both oleic acid-treated and untreated groups (Fig. 6e). These results suggest that MT1G induces intracellular lipid accumulation by suppressing CPT1B in ccRCC cells, thereby promoting ccRCC progression.
MT1G suppresses CPT1B expression via H3K14 trimethylation modification
Active genes typically possess an open chromatin structure at their promoters, facilitating access to the transcription machinery [18]. The ATAC-seq technique, which detects chromatin accessibility, has been increasingly employed to elucidate gene expression regulation mechanisms [19]. To assess the impact of MT1G on chromatin accessibility, we employed ATAC-seq following MT1G knockdown. IGV browser views revealed a significant increase in chromatin accessibility within the –1000 to +1 bp region of the CPT1B promoter in the MT1G knockdown (shMT1G) group compared to the control group (shNC) (Fig. 6f). To investigate changes in histone modification status resulting from MT1G knockdown or overexpression, we examined six key histone modifications via western blotting. Our results indicated that MT1G overexpression reduced the levels of H3K14ac, H3K14me3, and H3K27ac, while MT1G knockdown increased their levels, with no impact on H3K36me3, H3K36ac, or H3K27me3 (Fig. 6g). To determine whether MT1G influenced the binding of specific proteins (H3K14ac, H3K14me3, and H3K27ac) to the CPT1B promoter region, we employed the chromatin immunoprecipitation qPCR method. We designed four primer pairs targeting different intervals of the CPT1B promoter (–999 to +1 bp regions) (Fig. 6f). Our results indicated that MT1G inhibited the chromatin accessibility of CPT1B by primarily suppressing H3K14me3 binding at sequences 1 and 2, located approximately –968 to -456 bp upstream of the CPT1B promoter (Fig. 6g, h). Due to CPT1B expression maybe controlled by transcription factors, so we utilized a transcription factor prediction website to analyze potential transcription factors binding to the CPT1B promoter region which regulated by MT1G. Our analysis identified three transcription factorsSP1, IRF1, and ICSBP may bind to this region (Supplementary Fig. 8b). To assess the impact of MT1G on the regulation of these transcription factors on the CPT1B promoter, we knocked down these three transcription factors in MT1G-deficient cell lines and evaluated the activity of the CPT1B promoter. Interestingly, we observed that while MT1G knockdown enhanced the promoter activity of CPT1B, knockdown of the three transcription factors did not alter the regulatory effect of MT1G knockdown on the CPT1B promoter (Supplementary Fig. 8c). These results suggest that MT1G regulated CPT1B expressionindependently of transcription factors, potentially through affecting the binding of H3K14me3 to the CPT1B promoter region, subsequently repressing CPT1B expression.
Discussion
Metabolic reprogramming is pivotal in maintaining cellular homeostasis, with cancer cells often displaying dysregulation in key metabolic pathways, including glucose and fatty acid metabolism [20]. ccRCC, a subtype of RCC, is characterized by the presence of large intracellular lipid droplets [21]. Recent studies have highlighted the significance of aberrant β-oxidation processes in ccRCC, contributing to its tumorigenesis and progression, often indicating poorer prognosis for patients [22, 23]. However, the precise mechanisms underpinning altered lipid metabolism in ccRCC remained elusive until recently. In our study, we have identified MT1G promotion of disease progression in ccRCC patients, despite its low expression in ccRCC. Notably, MT1G enhances lipid accumulation in ccRCC cells through epigenetic repression of CPT1B expression. Knockdown of CPT1B counteracts the inhibitory effects on cell proliferation, migration, and lipid droplet reduction induced by MT1G knockdown. MT1G accomplishes this by inhibiting the binding of H3K14me3 to the CPT1B promoter region. Thus, our study unveils the novel MT1G/H3K14me3/CPT1B signaling axis, which drives lipid accumulation in ccRCC, promoting ccRCC tumor growth and metastasis.
In this study, we have established MT1G as an oncogenic factor in ccRCC. MT1G expression significantly correlates with advanced cancer stage and grade, both at the protein and mRNA levels. Moreover, high MT1G expression predicts poor prognosis in ccRCC patients, as supported by data from GEO and TCGA datasets. In vitro experiments demonstrated that MT1G promoted ccRCC cell proliferation and migration, consistent with Wu Zhang’s findings of MT1G’s role in negatively regulating ferroptosis in ccRCC [23]. In vivo, our subcutaneous neoplasia experiments in NVSG and nude mice consistently showed that MT1G overexpression enhanced kidney tumor growth. Furthermore, we observed that elevated MT1G expression accelerated ccRCC growth in situ. Tail vein lung metastasis assays in both NVSG and nude mice unveiled that high MT1G expression promoted lung and liver metastases, underscoring MT1G’s pro-tumorigenic role in ccRCC. Patients with ccRCC often face a grim prognosis due to chemoresistance and metastatic spread. Sorafenib, an established chemotherapeutic drug for kidney cancer, is hindered by the development of drug resistance, significantly impacting patient outcomes [24]. While MT1G has been reported to promote sorafenib resistance in HCC cells [10], its role in renal cancer remained unexplored. Our study establishes that MT1G inhibits sorafenib sensitivity in ccRCC cells. In summary, MT1G emerges as a promising target for future clinical applications, particularly in patients resistant to sorafenib treatment.
Lipid droplet formation is a defining histological feature in ccRCC but the underlying mechanisms and importance of this biological behavior have remained enigmatic [25]. Suppression of FFA oxidation has been shown to contribute to lipid storage, which is a necessary tumor adaptation. The lipid droplets contain different lipid species (fatty acids (FFAs), triglycerides and cholesterol esters) and non-lipid component (glycogen) [26]. Targeted cholesterol metabolomics revealed the expression of cholesterol was not altered in MT1G high expression cells relative to the control group, suggesting that MT1G promoted lipid droplet accumulation independent of cholesterol. Clinical studies and mechanistic investigations into the roles of different enzymes in FA metabolism pathways have revealed new metabolic vulnerabilities that hold promise for clinical effect [4]. Enzymes involved in the intrinsic FFA metabolism pathway include FFA synthase, acetyl-CoA carboxylase, ATP citrate lyase, stearoyl-CoA desaturase 1, carnitine palmitoyltransferase 1 A and the perilipin family, and each might be potential therapeutic targets in ccRCC owing to the link between lipid deposition and ccRCC risk [3, 27]. In our study, we found for the first time that MT1G can be significantly inhibited the expression of carnitine palmitoyltransferase 1 B (CPT1B), therefore, molecular of MT1G may act as targeted agents to target carnitine palmitoyltransferase. FFA metabolism could potentially be targeted for therapeutic intervention in ccRCC as small-molecule inhibitors targeting the pathway have shown promising results in preclinical models. Storage of excess FFAs is necessary for maintaining endoplasmic reticulum (ER) integrity, and suppressing lipid reactive oxygen species to prevent lipotoxicity [4]. Targeted lipidomics analysis showed that 27.79% of lipids in renal cancer cells were fatty acids, and MT1G overexpression cell lines significantly promoted the total amount of fatty acids. In addition, half of the top 50 metabolites with the highest meaningful fold change and P values affected by MT1G high expression were fatty acids. This result suggested that MT1G most likely increased the integrity of the ER and reduced lipotoxicity and thus promoted renal cancer cell growth by promoting increased fatty acids. Elevated lipid storage levels might also benefit ccRCC tumors, as elevated phosphatidylcholine can maintain cell membrane fluidity, which enhances metastatic capability [28], as has been found in other malignancies such as lung carcinoma and glioma. Thus we can explain our results that the augment of phosphatidylcholine after MT1G overexpressing may be why MT1G promoted ccRCC cells invasion and migration in vitro and metastasis in vivo. Metabolomics data show that MT1G high expression lead to glycolysis key metabolites beta-frutose-2,6 bisphosphate upregulation, lactate downregulation. It has been reported that the gluconeogenic enzyme fructose-1, 6-bisphosphatase 1 (FBP1) was uniformly depleted in ccRCC tumors [29]. Whereas the beta-frutose-2,6 bisphosphate was catalyzed by FBP1 to the downstream beta-frutose-1,6 bisphosphate [30], thus explaining why frutose-2,6 bisphosphate was elevated and lactate decreased. The above results suggest that MT1G inhibited the glycolytic phenomenon and promoted the progression of ccRCC. Even though it was not consisted with the “Warburg effect” that cancer cells take large amounts of sugar and produce lactic acid in the presence of hyperglycolysis [31], we concluded that by contrast, the coincident accumulation of glycogen granules in ccRCC was currently thought to be indispensable for tumorigenesis [32], suggesting that both the lipid component and non-lipid component glycogen granules in lipid dropts promotes ccRCC progression. The carnitine palmitoyltransferase system is responsible for delivering the long-chain FFAs from cytoplasm into mitochondria for oxidation, where carnitine palmitoyltransferase I (CPTI) catalyzes the rate-limiting step of FAO [33, 34]. Concurrently, MT1G mediated carnitine palmitoyltransferase 1B (CPT1B) suppression prevents FAO and results in accumulation of cytoplasmic lipids.
In eukaryotes, DNA is compactly organized in nucleosomes (chromatin), where it is intricately associated with histone proteins. These histone modifications play a crucial role in regulating DNA transcription [35]. Recent large-scale sequencing analyses have unveiled significant alterations in histone modifications, underscoring the pivotal role of epigenetic changes in ccRCC [29]. Specific combinations of histone modifications serve as characteristic signatures of gene activity [36,37,38]. For instance, the presence of histone H3 lysine 36 trimethylation (H3K36me3) and histone H3 lysine 14 trimethylation (H3K14me3) on the gene body is a universal hallmark of active genes [39]. Conversely, developmentally silenced genes often exhibit enrichment in promoter-bound histone H3 lysine 27 trimethylation (H3K27me3) [40] and histone H3 lysine 14 acetylation (H3K14ac) [41, 42]. Certain histone modifications, such as H3K36ac [43] and H3K27ac, are known to promote oncogenic processes in tumors [44, 45]. Our study reveals that MT1G exerts regulatory control over histone modifications. Specifically, MT1G suppresses the expression of H3K14ac, H3K14me3, and H3K27ac, with the high expression of MT1G primarily influencing the interaction of the CPT1B promoter region with H3K14ac and H3K14me3. Chromatin immunoprecipitation followed by quantitative PCR (ChIP-qPCR) results demonstrate that elevated MT1G expression enhanced the binding of H3K14ac to the CPT1B promoter while inhibiting the binding of H3K14me3 to the CPT1B promoter region spanning from -968 to -456 bp. Notably, the DNA in the CPT1B promoter region is considerably less associated with H3K14ac compared to H3K14me3 [46, 47]. This leads us to posit that MT1G primarily hampers CPT1B transcription and translation by impeding the binding of H3K14me3 to the core promoter region of CPT1B.
In summary, our study provides groundbreaking insights into the regulatory role of MT1G in lipid metabolism accumulation. By inhibiting FAO, MT1G promotes the progression of renal cancer. Crucially, MT1G achieves this by suppressing CPT1B gene expression through the regulation of histone modifications. Given the significance of histone modifications in ccRCC development and the success of small molecule histone regulatory agents as therapeutic drugs, MT1G holds promise as a potential targeted drug for renal clear cell cancer.
Data availability
The Original/source data of ATAC-sequencing (accession number: HRA005634) are deposited in the Genome Sequence Archive (GSA, https://ngdc.cncb.ac.cn/gsa/).
References
Li Y, Lih TM, Dhanasekaran SM, Mannan R, Chen L, Cieslik M, et al. Histopathologic and proteogenomic heterogeneity reveals features of clear cell renal cell carcinoma aggressiveness. Cancer Cell. 2023;41:139–63.e17.
Oberling C, Riviere M, Haguenau F. Ultrastructure of the clear cells in renal carcinomas and its importance for the demonstration of their renal origin. Nature. 1960;186:402–3.
Wettersten HI, Aboud OA, Lara PN Jr., Weiss RH. Metabolic reprogramming in clear cell renal cell carcinoma. Nat Rev Nephrol. 2017;13:410–9.
Tan SK, Hougen HY, Merchan JR, Gonzalgo ML, Welford SM. Fatty acid metabolism reprogramming in ccRCC: mechanisms and potential targets. Nat Rev Urol. 2023;20:48–60.
Si M, Lang J. The roles of metallothioneins in carcinogenesis. J Hematol Oncol. 2018;11:107.
Meng J, Du H, Lu J, Wang H. Construction and validation of a predictive nomogram for ferroptosis-related genes in osteosarcoma. J Cancer Res Clin Oncol. 2023;149:14227–39.
Chen W, Lei C, Wang Y, Guo D, Zhang S, Wang X, et al. Prognostic prediction model for glioblastoma: a ferroptosis-related gene prediction model and independent external validation. J Clin Med. 2023;12:1341.
Shi Y, Wang Y, Dong H, Niu K, Zhang W, Feng K, et al. Crosstalk of ferroptosis regulators and tumor immunity in pancreatic adenocarcinoma: novel perspective to mRNA vaccines and personalized immunotherapy. Apoptosis. 2023;28:1423–35.
Zhu L, Yang F, Wang L, Dong L, Huang Z, Wang G, et al. Identification the ferroptosis-related gene signature in patients with esophageal adenocarcinoma. Cancer Cell Int. 2021;21:124.
Sun X, Niu X, Chen R, He W, Chen D, Kang R, et al. Metallothionein-1G facilitates sorafenib resistance through inhibition of ferroptosis. Hepatology. 2016;64:488–500.
Liu Z, Ye Q, Wu L, Gao F, Xie H, Zhou L, et al. Metallothionein 1 family profiling identifies MT1X as a tumor suppressor involved in the progression and metastastatic capacity of hepatocellular carcinoma. Mol Carcinog. 2018;57:1435–44.
Peng B, Peng J, Kang F, Zhang W, Peng E, He Q. Ferroptosis-related gene MT1G as a novel biomarker correlated with prognosis and immune infiltration in colorectal cancer. Front Cell Dev Biol. 2022;10:881447.
Cohen HT, McGovern FJ. Renal-cell carcinoma. N Engl J Med. 2005;353:2477–90.
Lasheras-Otero I, Feliu I, Maillo A, Moreno H, Redondo-Munoz M, Aldaz P, et al. The regulators of peroxisomal acyl-carnitine shuttle CROT and CRAT promote metastasis in melanoma. J Invest Dermatol. 2023;143:305–16.e5.
Pinkosky SL, Scott JW, Desjardins EM, Smith BK, Day EA, Ford RJ, et al. Long-chain fatty acyl-CoA esters regulate metabolism via allosteric control of AMPK beta1 isoforms. Nat Metab. 2020;2:873–81.
Schlaepfer IR, Joshi M. CPT1A-mediated fat oxidation, mechanisms, and therapeutic potential. Endocrinology. 2020;161:bqz046.
Qu Q, Zeng F, Liu X, Wang QJ, Deng F. Fatty acid oxidation and carnitine palmitoyltransferase I: emerging therapeutic targets in cancer. Cell Death Dis. 2016;7:e2226.
Dawson MA, Kouzarides T. Cancer epigenetics: from mechanism to therapy. Cell. 2012;150:12–27.
Mimitou EP, Lareau CA, Chen KY, Zorzetto-Fernandes AL, Hao Y, Takeshima Y, et al. Scalable, multimodal profiling of chromatin accessibility, gene expression and protein levels in single cells. Nat Biotechnol. 2021;39:1246–58.
Xia L, Oyang L, Lin J, Tan S, Han Y, Wu N, et al. The cancer metabolic reprogramming and immune response. Mol Cancer. 2021;20:28.
Xiao W, Xiong Z, Xiong W, Yuan C, Xiao H, Ruan H, et al. Melatonin/PGC1A/UCP1 promotes tumor slimming and represses tumor progression by initiating autophagy and lipid browning. J Pineal Res. 2019;67:e12607.
Chen X, Li J, Kang R, Klionsky DJ, Tang D. Ferroptosis: machinery and regulation. Autophagy. 2021;17:2054–81.
Zhang W, Luo M, Xiong B, Liu X. Upregulation of Metallothionein 1 G (MT1G) Negatively Regulates Ferroptosis in Clear Cell Renal Cell Carcinoma by Reducing Glutathione Consumption. J Oncol. 2022;2022:4000617.
Nielsen OH, Grimm D, Wehland M, Bauer J, Magnusson NE. Anti-angiogenic drugs in the treatment of metastatic renal cell carcinoma: advances in clinical application. Curr Vasc Pharmacol. 2015;13:381–91.
Du W, Zhang L, Brett-Morris A, Aguila B, Kerner J, Hoppel CL, et al. HIF drives lipid deposition and cancer in ccRCC via repression of fatty acid metabolism. Nat Commun. 2017;8:1769.
Shen D, Gao Y, Huang Q, Xuan Y, Yao Y, Gu L, et al. E2F1 promotes proliferation and metastasis of clear cell renal cell carcinoma via activation of SREBP1-dependent fatty acid biosynthesis. Cancer Lett. 2021;514:48–62.
Wang J, Chang H, Su M, Qiao Y, Sun H, Zhao Y, et al. Identification of HGD and GSTZ1 as biomarkers involved metabolic reprogramming in kidney renal clear cell carcinoma. Int J Mol Sci. 2022;23:4583.
Saito RF, Andrade LNS, Bustos SO, Chammas R. Phosphatidylcholine-derived lipid mediators: the crosstalk between cancer cells and immune cells. Front Immunol. 2022;13:768606.
Li B, Qiu B, Lee DS, Walton ZE, Ochocki JD, Mathew LK, et al. Fructose-1,6-bisphosphatase opposes renal carcinoma progression. Nature. 2014;513:251–5.
Bartrons R, Simon-Molas H, Rodriguez-Garcia A, Castano E, Navarro-Sabate A, Manzano A, et al. Fructose 2,6-bisphosphate in cancer cell metabolism. Front Oncol. 2018;8:331.
Vaupel P, Multhoff G. Revisiting the Warburg effect: historical dogma versus current understanding. J Physiol. 2021;599:1745–57.
Xie H, Song J, Godfrey J, Riscal R, Skuli N, Nissim I, et al. Glycogen metabolism is dispensable for tumour progression in clear cell renal cell carcinoma. Nat Metab. 2021;3:327–36.
Vantaku V, Dong J, Ambati CR, Perera D, Donepudi SR, Amara CS, et al. Multi-omics integration analysis robustly predicts high-grade patient survival and identifies CPT1B effect on fatty acid metabolism in bladder cancer. Clin Cancer Res. 2019;25:3689–701.
Angelini A, Saha PK, Jain A, Jung SY, Mynatt RL, Pi X, et al. PHDs/CPT1B/VDAC1 axis regulates long-chain fatty acid oxidation in cardiomyocytes. Cell Rep. 2021;37:109767.
Armeev GA, Kniazeva AS, Komarova GA, Kirpichnikov MP, Shaytan AK. Histone dynamics mediate DNA unwrapping and sliding in nucleosomes. Nat Commun. 2021;12:2387.
An X, Lan XH, Feng ZZ, Li XH, Su QS. Histone modification: Biomarkers and potential therapies in colorectal cancer. Ann Hum Genet. 2023;87:274–84.
Montalbano S, Raboni S, Sidoli S, Mozzarelli A, Bettati S, Buschini A. Post-translational modifications of histone variants in the absence and presence of a methionine-depleting enzyme in normal and cancer cells. Cancers (Basel). 2023;15:527.
Lazo PA. Targeting histone epigenetic modifications and DNA damage responses in synthetic lethality strategies in cancer? Cancers (Basel). 2022;14:4050.
He J, Xu T, Zhao F, Guo J, Hu Q. SETD2-H3K36ME3: an important bridge between the environment and tumors. Front Genet. 2023;14:1204463.
Verma A, Singh A, Singh MP, Nengroo MA, Saini KK, Satrusal SR, et al. EZH2-H3K27me3 mediated KRT14 upregulation promotes TNBC peritoneal metastasis. Nat Commun. 2022;13:7344.
Peña-Hernández R, Aprigliano R, Carina Frommel S, Pietrzak K, Steiger S, Roganowicz M, et al. BAZ2A-mediated repression via H3K14ac-marked enhancers promotes prostate cancer stem cells. EMBO Rep. 2021;22:e53014.
Li N, Li Y, Lv J, Zheng X, Wen H, Shen H, et al. ZMYND8 reads the dual histone mark H3K4me1-H3K14ac to antagonize the expression of metastasis-linked genes. Mol Cell. 2016;63:470–84.
Lu X, Xin DE, Du JK, Zou QC, Wu Q, Zhang YS, et al. Loss of LOXL2 promotes uterine hypertrophy and tumor progression by enhancing H3K36ac-dependent gene expression. Cancer Res. 2022;82:4400–13.
He W, Li Q, Li X. Acetyl-CoA regulates lipid metabolism and histone acetylation modification in cancer. Biochim Biophys Acta Rev Cancer. 2023;1878:188837.
Hnisz D, Abraham BJ, Lee TI, Lau A, Saint-André V, Sigova AA, et al. Super-enhancers in the control of cell identity and disease. Cell. 2013;155:934–47.
Hu S, Song A, Peng L, Tang N, Qiao Z, Wang Z, et al. H3K4me2/3 modulate the stability of RNA polymerase II pausing. Cell Res. 2023;33:403–6.
Karmodiya K, Krebs AR, Oulad-Abdelghani M, Kimura H, Tora L. H3K9 and H3K14 acetylation co-occur at many gene regulatory elements, while H3K14ac marks a subset of inactive inducible promoters in mouse embryonic stem cells. BMC Genomics. 2012;13:424.
Acknowledgements
This study was supported by grants from the National Natural Science Foundation of China (No. 82102798,82173371,82273447,82273069,82372679), Project funded by China Postdoctoral Science Foundation (2022M721339), Tai Shan Young Scholar Foundation of Shandong Province (No. tsqn201909192), Shandong Provincial Natural Science Foundation (ZR2021QH021, ZR202112020099), Youth Innovation Science and Technology Support Plan of Shandong Province’s colleges and universities (2021KJ017), the Project of Medicine Health and Technology Development Plan of Shandong Province (NO. 202103030586), Project of Shandong Province Higher Educational Youth Innovation Science and Technology Program (2022KJ106).
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SW and BZ have contributed substantially to the conception and design of the study, acquisition of data, or analysis and interpretation of data; SW and BY H drafting of the manuscript or revising it for important content; SW and KX W performed the in vitro and in vivo assay. XXY, XZP, FFK, RZ, DXT and QLB reviewed the manuscript and provided critical support during the design of the experiments. DY and SQZ provided all renal tumor specimens and theoretical support for renal cancer disease.Finally, final approval of the version submitted for publication by BY H and ZB. All authors discussed the findings, and also approved the final manuscript.
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Human clinical samples were collected with informed consent from the patients. The collection and study of human clinical samples were performed in accordance with the approved guidelines of the Ethics and Scientific Committees of the Affiliated Hospital of Jining Medical University (No. 2021-09-C016). All methods in the study was performed in accordance with the relevant guidelines and regulations in the Declaration of Helsinki.
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Wang, S., Wang, K., Yue, D. et al. MT1G induces lipid droplet accumulation through modulation of H3K14 trimethylation accelerating clear cell renal cell carcinoma progression. Br J Cancer (2024). https://doi.org/10.1038/s41416-024-02747-y
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DOI: https://doi.org/10.1038/s41416-024-02747-y
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