High glucose consumption promoted invasion and migration in colorectal cancer through suppressing ferritinophagy <i>via</i> activating the RAGE/mTOR pathway_CHINESE JOURNAL OF BASES AND CLINICS IN GENERAL SURGERY

Authors：

XIONG Xiao , CHEN Hao , LI Yuanliang , TANG Yan , ZHANG Haogang ,  QIAO Pengfei

Department of General Surgery, The Second Affiliated Hospital of Harbin Medical University, Harbin 150001, P. R. China;

Corresponding author：

QIAO Pengfei, Email: lunwenqpf@126.com

Keywords：

colorectal cancer; high glucose consumption; ferritinophagy; receptor of advanced glycation end products; mechanistic target of rapamycin kinase

DOI：

10.7507/1007-9424.202405003

Video：

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Objective To explore the influence and mechanism of mechanistic target of rapamycin kinase (mTOR)/ receptor of advanced glycation end products (RAGE) pathway mediated-ferritinophagy on high glucose consumption promoting invasion and migration of colorectal cancer (CRC). Methods ① Patients and tissue samples. Clinical data and tissues were collected from CRC patients underwent surgery and completed the dietary questionnaire in the Second Affiliated Hospital of Harbin Medical University between October 2022 and October 2023. Real-time quantitative reverse transcription PCR (qRT-PCR) was used to analyzed the expression of nuclear receptor coactivator 4 (NCOA4) and ferritin in CRC and para-carcinoma tissues.② Cell culture and treatment. The HT29 and HCT116 cells were treated by RPMI1640 medium containing 0, 35, 70, 105, 140 mmol/L glucose, and cell counting kit-8 (CCK-8) and lactate dehydrogenase (LDH) activity analysis were performed to confirm 105 mmol/L glucose was the optimal concentration in the current study. Then the HT29 and HCT116 cells were randomly divided into: control group, glucose group; control group, glucose group, si-RAGE group, and glucose+si-RAGE group; control group, glucose group, rapamycin group, and glucose+rapamycin group. Untreated HT29 and HCT116 cells were considered as control group. The cells in glucose group were treated with 105 mmol/L glucose for 48 h. The CRC cells in si-RAGE group were transfected with si-RAGE for 6 h. The CRC cells in rapamycin group were treated with 10 nmol/L rapamycin for 48 h. The CRC cells in glucose+si-RAGE group were treated with 105 mmol/L glucose for 48 h combination transfected with si-RAGE for 6 h. The CRC cells in glucose+rapamycin group were treated with 105 mmol/L glucose for 48 h combination treated with 10 nmol/L rapamycin for 48 h. Then electron microscopy and western blot, wound healing assay and transwell assay were exhibited, respectively.③ Azoxymethane (AOM)-induced CRC rat model. The effects of glucose consumption on malignant behavior and ferritinophagy mediated by mTOR/RAGE pathway were evaluated in AOM-induced CRC rat models. A total of 16 rats were randomly divided into control group and glucose group, the colorectal tumor number was record and HE staining of colorectal tumor tissues was further performed. The expression of RAGE, mTOR, NCOA4, and ferritin in colorectal tissues of rats from each group was detected by qRT-PCR. Results ① More lymphatic node metastasis and TNM Ⅲ/Ⅳ stages was observed in CRC patients from high glucose consumption group (P=0.004, P=0.004). Moreover, we confirmed that NCOA4 expression was significantly decreased (P<0.001) while ferritin was significantly increased (P<0.001) in CRC tissues especially in the CRC tissues from patients with positive lymph nodes metastasis. Additionally, high glucose consumption of CRC patients was negatively correlated with ferritinophagy flux. ② High glucose treatment significantly decreased autophagosomes in HT29 and HCT116 cells while si-RAGE transfection increased autophagic vacuoles compared to the control group. When compared with the glucose group, autophagosomes were increased in the glucose+si-RAGE group. Moreover, compared to the control group, the expression of RAGE, p-mTOR, and ferritin was increased (P<0.001) while the expression of NCOA4 was decreased (P<0.001) in glucose group, but the expression of RAGE, p-mTOR and ferritin was decreased (P<0.001) while the expression of NCOA4 was increased (P<0.001) in si-RAGE group; when compared with the glucose group, the expression of RAGE, p-mTOR and ferritin was downregulated (P<0.001) while the expression of NCOA4 was upregulated (P<0.001) in HT29 and HCT116 cells from the glucose+siRAGE group. Compared to the control group, the HT29 and HCT116 cells in the glucose group performed enhanced wound scratch healing and migration, invasion viability (P<0.05); but the HT29 and HCT116 cells in the si-RAGE group performed impaired wound scratch healing and migration, invasion viability (P<0.05). When compared with the glucose group, the HT29 and HCT116 cells in the glucose+si-RAGE group performed impaired wound scratch healing and migration, invasion viability (P<0.05).③ Rapamycin treatment significantly inhibited the expression of RAGE, p-mTOR and ferritin (P<0.05) but induced the expression of NCOA4 (P<0.05) compared to the control group. When compared with the glucose group, the expression of RAGE, p-mTOR and ferritin was downregulated (P<0.05) while the expression of NCOA4 was upregulated (P<0.05) in HT29 and HCT116 cells from the glucose+rapamycin group. Additionally, compared to the control group, rapamycin treatment performed inhibited effect on wound scratch healing and migration, invasion viability in the HT29 and HCT116 cells (P<0.05); while the HT29 and HCT116 cells in the glucose+rapamycin group performed impaired wound scratch healing and migration, invasion viability (P<0.05) when compared with the glucose group.④ In the AOM induced CRC rat model, we found the more colorectal tumors, aggravated cellular pleomorphism and upregulate expression of RAGE, p-mTOR, ferritin (P<0.05) while downregulated expression of NCOA4 (P<0.05) in the control group than those of the glucose group. Conclusion High glucose consumption promote invasion and migration in CRC through suppressing ferritinophagy via activating the mTOR/RAGE pathway.

1.	黄理宾, 黄秋实, 杨烈. 全球及中国的结直肠癌流行病学特征及防治: 2022《全球癌症统计报告》解读. 中国普外基础与临床杂志, 2024, 31(5): 530-537.
2.	Liu B, Hu Y, Rai SK, et al. Low-carbohydrate diet macronutrient quality and weight change. JAMA Netw Open, 2023, 6(12): e2349552.
3.	Fuchs MA, Sato K, Niedzwiecki D, et al. Sugar-sweetened beverage intake and cancer recurrence and survival in CALGB 89803 (Alliance). PLoS One, 2014, 9(6): e99816.
4.	Grasgruber P, Hrazdira E, Sebera M, et al. Cancer incidence in Europe: an ecological analysis of nutritional and other environmental factors. Front Oncol, 2018, 8: 151.
5.	Goncalves MD, Lu C, Tutnauer J, et al. High-fructose corn syrup enhances intestinal tumor growth in mice. Science, 2019, 363(6433): 1345-1349.
6.	Liu X, Xie C, Wang Y, et al. Ferritinophagy and ferroptosis in cerebral ischemia reperfusion injury. Neurochem Res, 2024, 49(8): 1965-1979.
7.	Shi X, Zhang A, Lu J, et al. An overview of heavy chain ferritin in cancer. Front Biosci (Landmark Ed), 2023, 28(8): 182.
8.	Li S, Huang P, Lai F, et al. Mechanisms of ferritinophagy and ferroptosis in diseases. Mol Neurobiol, 2024, 61(3): 1605-1626.
9.	张小利. 高脂饮食促进结肠炎相关结肠癌发生发展的机制初探. 北京: 中国医学科学院北京协和医学院, 2020.
10.	李国强, 李彦川, 冯任南, 等. 基于网络的食物频率问卷信度和效度研究. 哈尔滨医科大学学报, 2014, 48(5): 376-380.
11.	祁少俊, 唐延金, 张正铎, 等. 补充多种微量元素对高糖饮食大鼠的保护作用. 山东大学学报(医学版), 2023, 61(7): 19-26.
12.	Singh LP, Yumnamcha T, Devi TS. Mitophagy, ferritinophagy and ferroptosis in retinal pigment epithelial cells under high glucose conditions: implications for diabetic retinopathy and age-related retinal diseases. JOJ Ophthalmol, 2021, 8(5): 77-85.
13.	Kim J, Kim Y, La J, et al. Supplementation with a high-glucose drink stimulates anti-tumor immune responses to glioblastoma via gut microbiota modulation. Cell Rep, 2023, 42(10): 113220.
14.	Wang M, Liu J, Yan L, et al. Burden of liver cancer attributable to high fasting plasma glucose: a global analysis based on the global burden of disease study 2019. J Nutr Health Aging, 2024, 28(6): 100261.
15.	Miles FL, Neuhouser ML, Zhang ZF. Concentrated sugars and incidence of prostate cancer in a prospective cohort. Br J Nutr, 2018, 120(6): 703-710.
16.	Dewdney B, Roberts A, Qiao L, et al. A sweet connection? Fructose’s role in hepatocellular carcinoma. Biomolecules, 2020, 10(4): 496.
17.	Bellelli R, Federico G, Matte’ A, et al. NCOA4 deficiency impairs systemic iron homeostasis. Cell Rep, 2016, 14(3): 411-421.
18.	Wang R, Liang Z, Xue X, et al. Microglial FoxO3a deficiency ameliorates ferroptosis-induced brain injury of intracerebral haemorrhage via regulating autophagy and heme oxygenase-1. J Cell Mol Med, 2024, 28(1): e18007.
19.	Liu YC, Gong YT, Sun QY, et al. Ferritinophagy induced ferroptosis in the management of cancer. Cell Oncol (Dordr), 2024, 47(1): 19-35.
20.	储昭银, 苏青. 碳水化合物与恶性肿瘤发生风险. 上海医学, 2021, 44(4): 286-292.
21.	Twarda-Clapa A, Olczak A, Białkowska AM, et al. Advanced glycation end-products (AGEs): formation, chemistry, classification, receptors, and diseases related to AGEs. Cells, 2022, 11(8): 1312.
22.	Yamamoto T, Shiburo R, Moriyama Y, et al. Protein components of maple syrup as a potential resource for the development of novel anti-colorectal cancer drugs. Oncol Rep, 2023, 50(4): 179.
23.	Pan S, Hu B, Sun J, et al. Identification of cross-talk pathways and ferroptosis-related genes in periodontitis and type 2 diabetes mellitus by bioinformatics analysis and experimental validation. Front Immunol, 2022, 13: 1015491.
24.	Song X, Zheng Y, Liu Y, et al. Production of recombinant human hybrid ferritin with heavy chain and light chain in escherichia coli and its characterization. Curr Pharm Biotechnol, 2023, 24(2): 341-349.
25.	He J, Li Z, Xia P, et al. Ferroptosis and ferritinophagy in diabetes complications. Mol Metab, 2022, 60: 101470.
26.	Bao L, Zhao C, Feng L, et al. Ferritinophagy is involved in Bisphenol A-induced ferroptosis of renal tubular epithelial cells through the activation of the AMPK-mTOR-ULK1 pathway. Food Chem Toxicol, 2022, 163: 112909.
27.	姚阳. 高糖通过激活AMPK/mTOR/ULK1通路诱导成骨细胞铁自噬进而促进铁死亡在2型糖尿病骨质疏松中的机制研究. 中国医科大学, 2022.
28.	Qin X, Zhang J, Wang B, et al. Ferritinophagy is involved in the zinc oxide nanoparticles-induced ferroptosis of vascular endothelial cells. Autophagy, 2021, 17(12): 4266-4285.

1. 黄理宾, 黄秋实, 杨烈. 全球及中国的结直肠癌流行病学特征及防治: 2022《全球癌症统计报告》解读. 中国普外基础与临床杂志, 2024, 31(5): 530-537.
2. Liu B, Hu Y, Rai SK, et al. Low-carbohydrate diet macronutrient quality and weight change. JAMA Netw Open, 2023, 6(12): e2349552.
3. Fuchs MA, Sato K, Niedzwiecki D, et al. Sugar-sweetened beverage intake and cancer recurrence and survival in CALGB 89803 (Alliance). PLoS One, 2014, 9(6): e99816.
4. Grasgruber P, Hrazdira E, Sebera M, et al. Cancer incidence in Europe: an ecological analysis of nutritional and other environmental factors. Front Oncol, 2018, 8: 151.
5. Goncalves MD, Lu C, Tutnauer J, et al. High-fructose corn syrup enhances intestinal tumor growth in mice. Science, 2019, 363(6433): 1345-1349.
6. Liu X, Xie C, Wang Y, et al. Ferritinophagy and ferroptosis in cerebral ischemia reperfusion injury. Neurochem Res, 2024, 49(8): 1965-1979.
7. Shi X, Zhang A, Lu J, et al. An overview of heavy chain ferritin in cancer. Front Biosci (Landmark Ed), 2023, 28(8): 182.
8. Li S, Huang P, Lai F, et al. Mechanisms of ferritinophagy and ferroptosis in diseases. Mol Neurobiol, 2024, 61(3): 1605-1626.
9. 张小利. 高脂饮食促进结肠炎相关结肠癌发生发展的机制初探. 北京: 中国医学科学院北京协和医学院, 2020.
10. 李国强, 李彦川, 冯任南, 等. 基于网络的食物频率问卷信度和效度研究. 哈尔滨医科大学学报, 2014, 48(5): 376-380.
11. 祁少俊, 唐延金, 张正铎, 等. 补充多种微量元素对高糖饮食大鼠的保护作用. 山东大学学报(医学版), 2023, 61(7): 19-26.
12. Singh LP, Yumnamcha T, Devi TS. Mitophagy, ferritinophagy and ferroptosis in retinal pigment epithelial cells under high glucose conditions: implications for diabetic retinopathy and age-related retinal diseases. JOJ Ophthalmol, 2021, 8(5): 77-85.
13. Kim J, Kim Y, La J, et al. Supplementation with a high-glucose drink stimulates anti-tumor immune responses to glioblastoma via gut microbiota modulation. Cell Rep, 2023, 42(10): 113220.
14. Wang M, Liu J, Yan L, et al. Burden of liver cancer attributable to high fasting plasma glucose: a global analysis based on the global burden of disease study 2019. J Nutr Health Aging, 2024, 28(6): 100261.
15. Miles FL, Neuhouser ML, Zhang ZF. Concentrated sugars and incidence of prostate cancer in a prospective cohort. Br J Nutr, 2018, 120(6): 703-710.
16. Dewdney B, Roberts A, Qiao L, et al. A sweet connection? Fructose’s role in hepatocellular carcinoma. Biomolecules, 2020, 10(4): 496.
17. Bellelli R, Federico G, Matte’ A, et al. NCOA4 deficiency impairs systemic iron homeostasis. Cell Rep, 2016, 14(3): 411-421.
18. Wang R, Liang Z, Xue X, et al. Microglial FoxO3a deficiency ameliorates ferroptosis-induced brain injury of intracerebral haemorrhage via regulating autophagy and heme oxygenase-1. J Cell Mol Med, 2024, 28(1): e18007.
19. Liu YC, Gong YT, Sun QY, et al. Ferritinophagy induced ferroptosis in the management of cancer. Cell Oncol (Dordr), 2024, 47(1): 19-35.
20. 储昭银, 苏青. 碳水化合物与恶性肿瘤发生风险. 上海医学, 2021, 44(4): 286-292.
21. Twarda-Clapa A, Olczak A, Białkowska AM, et al. Advanced glycation end-products (AGEs): formation, chemistry, classification, receptors, and diseases related to AGEs. Cells, 2022, 11(8): 1312.
22. Yamamoto T, Shiburo R, Moriyama Y, et al. Protein components of maple syrup as a potential resource for the development of novel anti-colorectal cancer drugs. Oncol Rep, 2023, 50(4): 179.
23. Pan S, Hu B, Sun J, et al. Identification of cross-talk pathways and ferroptosis-related genes in periodontitis and type 2 diabetes mellitus by bioinformatics analysis and experimental validation. Front Immunol, 2022, 13: 1015491.
24. Song X, Zheng Y, Liu Y, et al. Production of recombinant human hybrid ferritin with heavy chain and light chain in escherichia coli and its characterization. Curr Pharm Biotechnol, 2023, 24(2): 341-349.
25. He J, Li Z, Xia P, et al. Ferroptosis and ferritinophagy in diabetes complications. Mol Metab, 2022, 60: 101470.
26. Bao L, Zhao C, Feng L, et al. Ferritinophagy is involved in Bisphenol A-induced ferroptosis of renal tubular epithelial cells through the activation of the AMPK-mTOR-ULK1 pathway. Food Chem Toxicol, 2022, 163: 112909.
27. 姚阳. 高糖通过激活AMPK/mTOR/ULK1通路诱导成骨细胞铁自噬进而促进铁死亡在2型糖尿病骨质疏松中的机制研究. 中国医科大学, 2022.
28. Qin X, Zhang J, Wang B, et al. Ferritinophagy is involved in the zinc oxide nanoparticles-induced ferroptosis of vascular endothelial cells. Autophagy, 2021, 17(12): 4266-4285.

CHINESE JOURNAL OF BASES AND CLINICS IN GENERAL SURGERY

Latest ArticlesHigh glucose consumption promoted invasion and migration in colorectal cancer through suppressing ferritinophagy via activating the RAGE/mTOR pathway

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