线粒体转录因子A在肿瘤发生发展中作用的研究进展

doi:10.3969/j.issn.1004-616x.2023.06.015

[1] MARCHI S, PATERGNANI S, MISSIROLI S, et al. Mitochondrial and endoplasmic reticulum calcium homeostasis and cell death[J]. Cell Calcium, 2018, 69:62-72.
[2] EL-HATTAB A W, SCAGLIA F. Mitochondrial cytopathies[J]. Cell Calcium, 2016, 60(3):199-206.
[3] LARSSON N G, WANG J, WILHELMSSON H, et al. Mitochondrial transcription factor A is necessary for mtDNA maintenance and embryogenesis in mice[J]. Nat Genet, 1998, 18(3):231-236.
[4] 杨帆, 刘静, 袁冲, 等. 敲低线粒体转录因子A (TFAM)通过增强IL-6表达促进人前列腺癌细胞去势抵抗性增殖[J]. 细胞与分子免疫学杂志, 2021, 37(12):1111-1119.
[5] 吴丹, 何元方, 周幸春, 等. 敲低TFAM通过上调ROS/ADAM17促进可溶型MICA生成抑制NK细胞杀伤人肝癌细胞的作用[J]. 细胞与分子免疫学杂志, 2021, 37(3):257-264.
[6] KATSUKI T, NAKAYAMA Y, AKIYAMA M, et al. Prognostic significance of mitochondrial transcription factor A expression in patients with right- or left-sided colorectal cancer[J]. Anticancer Res, 2018, 38(1):569-575.
[7] 于洋, 郭文文. 线粒体转录因子A在肿瘤细胞中的作用[J]. 中国肿瘤, 2016, 25(1):58-62.
[8] NGO H B, KAISER J T, CHAN D C. The mitochondrial transcription and packaging factor Tfam imposes a U-turn on mitochondrial DNA[J]. Nat Struct Mol Biol, 2011, 18(11):1290-1296.
[9] CAMPBELL C T, KOLESAR J E, KAUFMAN B A. Mitochondrial transcription factor A regulates mitochondrial transcription initiation, DNA packaging, and genome copy number[J]. Biochim Biophys Acta, 2012, 1819(9/10):921-929.
[10] CLAY MONTIER L L, DENG J J, BAI Y D. Number matters:control of mammalian mitochondrial DNA copy number[J]. Yi Chuan Xue Bao, 2009, 36(3):125-131.
[11] IKEDA M, IDE T, FUJINO T, et al. Overexpression of TFAM or twinkle increases mtDNA copy number and facilitates cardioprotection associated with limited mitochondrial oxidative stress[J]. PLoS One, 2015, 10(3):e0119687.
[12] FRIEDMAN J R, NUNNARI J. Mitochondrial form and function[J]. Nature, 2014, 505(7483):335-343.
[13] MEI H, SUN S, BAI Y, et al. Reduced mtDNA copy number increases the sensitivity of tumor cells to chemotherapeutic drugs[J]. Cell Death Dis, 2015, 6(4):e1710.
[14] HAYASHI Y, YOSHIDA M, YAMATO M, et al. Reverse of age-dependent memory impairment and mitochondrial DNA damage in microglia by an overexpression of human mitochondrial transcription factor a in mice[J]. J Neurosci, 2008, 28(34):8624-8634.
[15] WANG X, MORAES C T. Increases in mitochondrial biogenesis impair carcinogenesis at multiple levels[J]. Mol Oncol, 2011, 5(5):399-409.
[16] LEE W R, NA H, LEE S W, et al. Transcriptomic analysis of mitochondrial TFAM depletion changing cell morphology and proliferation[J]. Sci Rep, 2017, 7(1):17841.
[17] 范荣辉, 徐子寒, 慕生枝, 等. MALAT1通过靶向miR-204调控TFAM表达对皮肤鳞状细胞癌增殖及凋亡的影响[J]. 兰州大学学报:医学版, 2022, 48(2):9-15.
[18] 肖顺崇, 罗汉传, 覃俊仕. miR-211通过靶向调控TFAM抑制人乳腺癌细胞系增殖[J]. 基础医学与临床, 2017, 37(11):1590-1595.
[19] 杨帆, 尚炳亮, 刘静, 等. 膀胱癌细胞TFAM下调介导mtDNA应激抑制NK细胞杀伤的作用机制[J]. 现代泌尿外科杂志, 2021, 26(12):1047-1054, 1081.
[20] 杨世荣, 黄启超, 何显力, 等. TFAM缺失介导的线粒体DNA应激促进炎症相关结直肠癌的作用机制研究[C]//中国抗癌协会肿瘤标志专业委员会. 2019年中国肿瘤标志物学术大会暨第十三届肿瘤标志物青年科学家论坛, 武汉, 2019.
[21] 唐番. COX-2调控TFAM表达的机制及其对肿瘤细胞辐射敏感性的影响[D]. 合肥:中国科学技术大学, 2019.
[22] JIANG X, WANG J. Down-regulation of TFAM increases the sensitivity of tumour cells to radiation via p53/TIGAR signalling pathway[J]. J Cell Mol Med, 2019, 23(7):4545-4558.
[23] TANG F, ZHANG R, WANG J. Cyclooxygenase-2-mediated up-regulation of mitochondrial transcription factor A mitigates the radio-sensitivity of cancer cells[J]. Int J Mol Sci, 2019, 20(5):1218.
[24] 姚佳, 周恩相, 徐峰, 等. microRNA-200a/TFAM通路调控紫杉醇对乳腺癌细胞的化疗敏感性[J]. 肿瘤药学, 2017, 7(5):528-533, 544.
[25] 陈曦, 王亚莉. miR-186-5p通过靶向TFAM增强乳腺癌细胞对5-Fu的化疗敏感性[J]. 广西医科大学学报, 2020, 37(11):1973-1979.
[26] FAN X L, ZHOU S C, ZHENG M, et al. miR-199a-3p enhances breast cancer cell sensitivity to cisplatin by downregulating TFAM (TFAM)[J]. Biomedecine Pharmacother, 2017, 88:507-514.
[27] GAO W, WU M H, WANG N, et al. Increased expression of mitochondrial transcription factor A and nuclear respiratory factor-1 predicts a poor clinical outcome of breast cancer[J]. Oncol Lett, 2018, 15(2):1449-1458.
[28] LIN C S, LEE H T, LEE S Y, et al. High mitochondrial DNA copy number and bioenergetic function are associated with tumor invasion of esophageal squamous cell carcinoma cell lines[J]. Int J Mol Sci, 2012, 13(9):11228-11246.
[29] VADROT N, GHANEM S, BRAUT F, et al. Mitochondrial DNA maintenance is regulated in human hepatoma cells by glycogen synthase kinase 3β and p53 in response to tumor necrosis factor Α[J]. PLoS One, 2012, 7(7):e40879.

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