Inhibition of KDM4C/c‐Myc/LDHA signalling axis suppresses prostate cancer metastasis via interference of glycolytic metabolism
Ching‐Yu Lin, Bi‐Juan Wang, Yu‐Ke Fu, Chieh Huo, Ya‐Pei Wang, Bo‐Chih Chen, Wei‐Yi Liu, Jen‐Chih Tseng, Shih Shen Jiang, Zong‐Lin Sie, Kelvin K. Tsai, Chiou‐Hwa Yuh, Wen‐Ching Wang, Hsing‐Jien Kung, Chih‐Pin Chuu
Abstract
Dear Editor, we discovered that knockout of KDM4C can effectively suppress prostate cancer (PCa) cells’ migration and invasion. We identified that targeting KDM4C/c-Myc/LDHA signalling can be an effective prevention for metastatic PCa. Epigenetics change is an important feature in cancer metabolism reprograming and metabolism rewiring can enhance cancer progression. Histone lysine demethylase 4C (KDM4C), which can remove the dimethyl/trimethyl group from H3K9 or H3K36, is an androgen receptor (AR) co-regulator. KDM4C is elevated in castration-resistant prostate cancer (CRPC)1 and elevation of KDM4C stimulates the proliferation of PCa cells.2 However, how KDM4C regulates PCa metastasis or cancer metabolism is unclear. We examined the KDM4C gene level in online gene datasets Gene Expression Omnibus (GEO) profile GDS 2547 (HG-U95C) (Figure 1A), The Cancer Genome Atlas (TCGA) Prostate Adenocarcinoma (PRAD) (Supplemental Figure S1), Chandran PCa dataset (Figure 1B), Grasso PCa dataset (Figure 1C) and LaTulippe PCa dataset (Figure 1D). Expression level of KDM4C gene was increased in metastatic prostate cancer (PCa). To study how KDM4C promotes PCa metastasis, CRISPR/Cas9 single-guide RNA (sgRNA) was constructed in C4-2B PCa cells (Supplemental Figure S2), which impaired KDM4C's demethylation ability (Supplemental Figure S3). Knockout of KDM4C suppressed C4-2B cells’ ability to migrate and to invade (Figure 1E). Knockdown of KDM4C with siRNA also repressed the migration and invasion of LNCaP cells (Figure 1F). Treatment with SD70, a potent and selective inhibitor for KDM4C, repressed the migration and invasion of both C4-2B and LNCaP (Figure 1G–J) cells. KDM4C knockout decreased metastatic distance of C4-2B PCa tumours in zebrafish xenotransplantation model (Figure 1K–M). Oppositely, overexpression of KDM4C promoted the migration of DU-145 cells (Supplemental Figure S4). To explore how KDM4C regulates PCa metastasis, gene microarray (Clariom S HT06, human gene microarray) was used to compare the gene profile in control C4-2B (sgControl) cells versus KDM4C knockout C4-2B cells (sgKDM4C). There were 441 genes being upregulated and 345 genes being downregulated (GEO number: GSE178727). Gene Set Enrichment Analysis (GSEA) analysis indicated that MYC target is the pathway most affected by KDM4C knockout (Figure 2A and B. Supplemental Figures S5 and S6). The suppression of MYC target genes by KDM4C knockout was confirmed by qRT-PCR (Supplemental Figure S7). Micro-Western Array was applied to analyse the changes of proteins involved in c-Myc signalling, epithelial-mesenchymal transition (EMT), glycolysis, TCA and oxidative phosphorylation (OXPHOS), cancer stemness and other metabolic proteins under influence of KDM4C knockout in C4-2B cells (Supplemental Figure S8) or KDM4C knockdown in LNCaP cells (Supplemental Figure S9). Silencing of KDM4C repressed c-Myc as well as proteins regulating EMT and metabolism (Figure 2C–F). Gene expression level of KDM4C and MYC were positively correlated in Chandran Prostate dataset (r = 0.595) and Grasso Prostate dataset (r = 0.477) (Supplemental Figure 10A and B). Chromatin-immunoprecipitation (Ch-IP) assay indicated that KDM4C directly interacted with MYC promoter region as knockout of KDM4C decreased 54% of the MYC promoter activity (Figure 3A) and repressed the MYC gene expression level (Figure 3B). We further constructed the upstream region of nucleotide 1–1160 of the MYC promoter region for luciferase reporter gene assay. Overexpression of KDM4C increased the transcription of MYC gene for approximately 23% (Figure 3C), while treatment with SD70 inhibitor decreased MYC gene transcription (Figure 3D). Ectopic expression of c-Myc rescued the cell migration in sgKDM4C C4-2B cells to level comparable to the sgControl (Figure 3E and F). Seahorse metabolism platform was performed to examine effects of KDM4C knockout on mitochondrial functions. KDM4C knockout suppressed OCR (oxygen consumption rate) and ECAR (extracellular acidification rate) of mitochondria (Figure 3G and H) as well as suppressed production of ATP, glycolysis, basal respiration and maximum respiration rate (Figure 3I and J) in PCa cells. These observations suggested that sgKDM4C cells were under stress and becoming quiescent. Indeed, the proliferation rate of sgKDM4C cells was lower than that of sgControl cells (Supplemental Figure S11). As activated c-Myc is known to induce the expression of several glycolytic enzymes,3 we examined the consequences of KDM4C knockout on expression of metabolic genes and proteins . Knockout of KDM4C suppressed gene and protein expression of GAPDH, hexokinase 2 (HK2), lactate dehydrogenase (LDH), LDHA, LDHB, phosphofructokinase-1 (PFK1), Transaldolase 1 (TALDO1), Aconitase 1 (ACO1), Malate Dehydrogenase 1 (MDH1), pyruvate dehydrogenase E1 component subunit α (PDHA), PDH, pyruvate kinase M2 (PKM2), GLS and phosphogluconate dehydrogenase (PGD) but increased genes expression of γ-glutamyltransferase 1 (GGT1) and glucose-6-phosphate dehydrogenase (G6PD) (Figure 4A and B). These genes and proteins are involved in regulation of glucose transporter and glycolysis, TCA cycle, lipid synthesis, metabolism of glutamine and pentose phosphate pathway. Knockout of KDM4C also reduced protein and gene expression of epithelial-mesenchymal transition (EMT) regulatory proteins (Figure 4B and C). LDHA is a direct target of c-Myc.4 LDHA converts pyruvate, which is derived from glycolysis of glucose, to lactate with simultaneous inter-conversion of NADH and NAD+.5 Activation of c-Myc increases the transport of glucose, its catabolism to trioses and pyruvate and production of lactate via induction of LDHA.5 Overexpression of LDHA in sgKDM4C C4-2B cells restored the cell migration to level comparable to sgControl (Figure 4D and E), while knockdown of LDHA repressed migration of sgKDM4C cells (Figure 4F–G). Knockout of KDM4C reduced the secretion of lactate (Figure 4H) and increased the accumulation of pyruvate (Figure 4I) in sgKDM4C cells. Increase of secreted lactate will acidify the microenvironment nearby and assist cancer metastasis. Inevitably, lactate can be an inducer of cancer invasion and metastasis.6 PKM2 is an important enzyme in glycolysis. PKM2 has been reported to promote metastasis of PCa cells.7 Liquid chromatography-mass spectrometry was applied to examine the difference in profile of metabolites inside the sgControl vs. sgKDM4C C4-2B cells (Supplemental Figure S12). LC MS/MS and qRT-PCR (Figure 4A) demonstrated that knockout of KDM4C decreased the enzymes and metabolites involved in glycolytic metabolism (Figure 4J). Our observations revealed that inhibition of KDM4C/c-Myc/LDHA signalling suppresses PCa metastasis via suppression of glycolytic metabolism in PCa cells and targeting KDM4C/c-Myc/LDHA signalling can be a potential therapy for advanced PCa. This study was supported by MOST 107-2811-B-400-525 and MOST 109-2320-B-400-004-MY3 from Ministry of Science and Technology (MOST), Taiwan. The authors declare no potential conflicts of interest. 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