Expressions of iron transport related proteins in the spinal cord of amyotrophic lateral sclerosis transgenic mice

doi:10.16098/j.issn.0529-1356.2021.02.001

Abstract

Abstract:

Objective To investigate the relationship between the expressions of iron transport related proteins and the dysregulation of iron homeostasis in the spinal cord of amyotrophic lateral sclerosis(ALS) transgenic mice. Methods The hSOD1G93A transgenic mice (ALS mice) and littermate wild-type mice (WT mice) were selected to separate the spinal cord at day 70, day 95, and day 122 after birth, 9 mice per time point and per group. Western blotting was used to detect the expressions of iron transporter divalent metal transporter-1 (DMT1), ferroportin 1 (FPN1) and regulatory protein iron regulatory protein 1(IRP1) in the spinal cord. Double immunofluorescence labeling was used to detect the co-localization of cells in the ventral horn of lumbar spinal cord. Results Western blotting results showed that compared with WT mice the expressions of DMT1 protein were down-regulated with the disease progression from day 70 to day 122 (P<0.05, P<0.01); FPN1 protein was transiently up-regulated at day 70 (P<0.05), and decline expressions were observed at day 95 and day 122 (P<0.01); IRP1 was down-regulated at day 95 and day 122 (P<0.01). Double immunofluorescence labeling revealed that at day 70, DMT1 co-expressed mainly with β-tubulin Ⅲ both in WT and ALS mice lumbar spinal cord. Compared with the WT group, the DMT1 immunoreactivity in the neurons of the ventral horn lumbar spinal cord of ALS mice was elevated at day 95, while the FPN1 fluorescence intensity was weak. With the disease progression, the co-localization expression of DMT1, FPN1 with reactive glial cells increased. With the disease progresses, the expression of IRP1 decreased. Conclusion With the progression of ALS, iron influx increases and iron outflux decreases in neurons at the early-symptomatic stage of ALS, the activity of iron transport in reactive glial cells is enhanced, which participates in local iron homeostasis imbalance and progressive loss of motor neurons in ventral horn of spinal cord. Decreased expression of IRP1 partly participates in the regulation of local iron metabolism.

Key words: Amyotrophic lateral sclerosis, Iron homeostasis, Divalent metal transporter-1, Ferroportin 1, Iron regulatory protein, Western blotting, Mouse

CLC Number:

R744.8

ZHANG Ya-wen GAO Ying SUN Han-cong ZHANG Hao-yun WANG Feng-bin. Expressions of iron transport related proteins in the spinal cord of amyotrophic lateral sclerosis transgenic mice[J]. Acta Anatomica Sinica, 2021, 52(2): 161-167.

References

［1］ Zarei S, Carr K, Reiley L, et al. A comprehensive review of amyotrophic lateral sclerosis ［J］. Surg Neurol Int, 2015,6:171.

［2］ Kaur SJ, McKeown SR, Rashid S. Mutant SOD1 mediated pathogenesis of amyotrophic lateral sclerosis ［J］. Gene, 2016,577(2):109-118.

［3］ Shaw PJ. Molecular and cellular pathways of neurodegeneration in motor neurone disease ［J］. J Neurol Neurosurg Psychiatry, 2005,76(8):1046-1057.

［4］ D’Amico E, Factor-Litvak P, Santella RM, et al. Clinical perspective on oxidative stress in sporadic amyotrophic lateral sclerosis［J］. Free Radic Biol Med, 2013,65(113):509-527.

［5］ Hadzhieva M, Kirches E, Wilisch-Neumann A, et al. Dysregulation of iron protein expression in the G93A model of amyotrophic lateral sclerosis［J］. Neuroscience, 2013,230(30):94-101.

［6］ Crichton RR, Dexter DT, Ward RJ. Brain iron metabolism and its perturbation in neurological diseases ［J］. J Neural Transm (Vienna), 2011, 118(3):301-314.

［7］ Jeong SY, Rathore KI, Schulz K, et al. Dysregulation of iron homeostasis in the CNS contributes to disease progression in a mouse model of amyotrophic lateral sclerosis ［J］. J Neurosci,2009,29(3):610-619.

［8］ Kell DB. Towards a unifying, systems biology understanding of large-scale cellular death and destruction caused by poorly liganded iron: Parkinson’s, Huntington’s, Alzheimer’s, prions, bactericides, chemical toxicology and others as examples ［J］. Arch Toxicol, 2010,84(11):825-889.

［9］ Ikeda K, Hirayama T, Takazawa T, et al. Relationships between disease progression and serum levels of lipid, urate, creatinine and ferritin in japanese patients with amyotrophic lateral sclerosis: a cross-sectional study［J］. Intern Med, 2012,51(12):1501-1508.

［10］ Wang T, Xu SF, Fan YG, et al. Iron pathophysiology in Alzheimer’s diseases ［J］. Adv Exp Med Biol, 2019,1173(1):67-104.

［11］ Belaidi AA, Bush AI. Iron neurochemistry in Alzheimer‘s disease and Parkinson’s disease: targets for therapeutics ［J］. J Neurochem, 2016,139(94):179-197.

［12］ Jiang H, Wang J, Rogers J, et al. Brain iron metabolism dysfunction in Parkinson’s disease ［J］. Mol Neurobiol, 2017,54(4):3078-3101.

［13］ Ingrassia R, Garavaglia B, Memo M. DMT1 expression and iron levels at the crossroads between aging and neurodegeneration ［J］. Front Neurosci, 2019,13():575.

［14］ Fu LJ, Duan XL, Yu P, et al. The Expression and effects of hepcidin in mouse brain and its modulating effects on ferroportin 1 and divalent metal transporter 1［J］. Acta Anatomica Sinica, 2007, 38(3):265-270.(in Chinese)

付丽娟, 段相林, 于鹏, 等. 铁调素在小鼠脑内的表达及其对膜铁转运蛋白1和二价金属离子转运体1表达的影响［J］. 解剖学报, 2007,38(3): 265-270.

［15］ Wang L, Liu X, You LH, et al. Hepcidin and iron regulatory proteins coordinately regulate ferroportin 1 expression in the brain of mice［J］. J Cell Physiol, 2019, 234(5):7600-7607.

［16］ Pantopoulos K, Hentze MW. Activation of iron regulatory protein-1 by oxidative stress in vitro ［J］. Proc Natl Acad Sci USA, 1998,95(18):10559-10563.

［17］ Zhou FH, Guan YJ, Chen YC, et al. miRNA-9 expression is upregulated in the spinal cord of G93A-SOD1 transgenic mice［J］. Int J Clin Exp Pathol, 2013,6(9):1826-1838.

［18］ Pu LD, Zhang YW, Wang Q, et al. Expression of DDX3 and casein kinase 1ε in the hippocampus of the amyotrophic lateral sclerosis transgenic mice［J］.Acta Anatomica Sinica, 2017, 48(4):375-380.(in Chinese)

蒲蕾东,张雅雯,王箐,等. DDX3和酪蛋白激酶1ε在肌萎缩侧索硬化症转基因鼠海马中的表达［J］. 解剖学报, 2017,48(4):375-380.

［19］ Nakamura T, Naguro I, Ichijo H. Iron homeostasis and iron-regulated ROS in cell death, senescence and human diseases［J］. Biochim Biophys Acta Gen Subj, 2019,1863(9):1398-1409.

［20］ Urrutia P, Aguirre P, Esparza A, et al. Inflammation alters the expression of DMT1, FPN1 and hepcidin, and it causes iron accumulation in central nervous system cells［J］. J Neurochem, 2013, 126(114):541-549.

［21］ Lee JK, Shin JH, Gwag BJ, et al. Iron accumulation promotes TACE-mediated TNF-α secretion and neurodegeneration in a mouse model of ALS［J］. Neurobiol Dis, 2015,80(7):63-69.

［22］ Jeong SY, Rathore KI, Schulz K, et al. Dysregulation of iron homeostasis in the CNS contributes to disease progression in a mouse model of amyotrophic lateral sclerosis［J］. J Neurosci, 2009,29(3): 610-619.

［23］ Healy S, McMahon JM, FitzGerald U. Modelling iron mismanagement in neurodegenerative disease in vitro: paradigms, pitfalls, possibilities & practical considerations［J］. Prog Neurobiol,2017,158(4):1-14.

［24］ Zhang HY, Wang ND, Song N, et al. 6-Hydroxydopamine promotes iron traffic in primary cultured astrocytes ［J］. Biometals, 2013,26(5):705-714.

［25］ Bishop GM, Dang TN, Dringen R, et al. Accumulation of non-transferrin-bound iron by neurons, astrocytes, and microglia ［J］. Neurotox Res, 2011,19(3):443-451.

［26］ Winn NC, Volk KM, Hasty AH. Regulation of tissue iron homeostasis: the macrophage “ferrostat”［J］. JCI Insight, 2020,5(2): e132964.

［27］ Cui JT, Guo XL, Li QJ, et al. Hepcidin-to-ferritin ratio is decreased in astrocytes with extracellular alpha-synuclein and iron exposure ［J］. Front Cell Neurosci, 2020, 14:47.

[1]	HONG Xiao-min LI San-qiang CUI Qin-yi ZHENG Run-yue YANG Meng-li LUO Ren-li LI Qian-hui. Nuclear factor-κB signaling pathway and gender differences in alcoholic liver fibrosis [J]. Acta Anatomica Sinica, 2024, 55(1): 55-61.
[2]	WEI Xi-xi LI Chao-hong ZHAO Chen-lu TANG Jia-ping LIU Yu-zhen. Characterization of group Ⅰ metabotropic glutamate receptors in rat superior cervical ganglion and their changes following chronic intermittent hypoxia [J]. Acta Anatomica Sinica, 2024, 55(1): 3-9.
[3]	YUAN Lei YANG Zhi-wei YANG Hui LIU Zheng-hai HE Jie WAN Wei. Panax notoginseng saponin relieving the inflammatory pain caused by complete Freund’s adjuvant by inhibiting the activation of astrocytes in mice [J]. Acta Anatomica Sinica, 2024, 55(1): 25-31.
[4]	MA Ting-ting CHEN Jian-hong LIU Ai-cui LI Hai-ning. Role of inhibiting lncRNA TUG1 to down-regulate nucleotide binding oligomerization domain like receptor protein 1 inflammasome in delaying the progression of Alzheimer’s disease [J]. Acta Anatomica Sinica, 2024, 55(1): 32-42.
[5]	ZOU Cheng-gong FENG Hao CHEN Bing TANG Hui SHAO Chuan SUN Mou YANG Rong HE Jia-quan . Research on the dynamic changes of neurological dysfunction and cognitive function impairment in traumatic brain injury [J]. Acta Anatomica Sinica, 2024, 55(1): 43-48.
[6]	LÜ Hai-yan SHEN Xi-ya ZHAO Fu-sheng ZHU Mei . Effects of tricholoma matsutake polysaccharides on 1-methy-4-pehnyl-pyridine ion-induced PC12 cell damage [J]. Acta Anatomica Sinica, 2024, 55(1): 49-54.
[7]	ZHENG Li-ping LIU Xia DU Xiao-hua WU Ya-juan LIU Shan-shan . Expression and distribution of brain-derived neurotrophic factor in different cerebrum regions of yak and cattle [J]. Acta Anatomica Sinica, 2024, 55(1): 10-16.
[8]	HAO Yong-ming GUO Lei ZHOU Cheng-hui PEI Han-jun LI Li ZHAO Zhe . Establishment of a rat model of myocardial hypertrophy by a modified abdominal aortic coarctation method [J]. Acta Anatomica Sinica, 2024, 55(1): 120-124.
[9]	XU Ya-ping YU Yue-xin CHEN Jin-fu WANG Ke-ke GUO Zhikun . Structural distribution and mechanism of elastic fibers and collagen fibers in ventricular interstitium of aged rats [J]. Acta Anatomica Sinica, 2023, 54(6): 716-721.
[10]	WANG Wen-juan DING Yu-tong SU Hao REN Jie SUN Yan-rong WANG Han-fei LU Jia-li ZHANG Lin-qian BAI Yu QIN Li-hua. Changes of Nogo-A expression in hippocampus and striatum of rats under low estrogen condition [J]. Acta Anatomica Sinica, 2023, 54(6): 620-627.
[11]	ZHANG Qin YANG Jun-xia JIANG Qing-song. Effect of fosinopril on angiotensin converting enzyme 2 and vascular endothelial growth factor in diabetic retinopathy mice [J]. Acta Anatomica Sinica, 2023, 54(6): 628-634.
[12]	LIANG Pan-pan YU Ai-mei DU Jing KOU Wen-hui WANG Huan-huan SONG Ai-xia. Inhibitory effect of sodium ferulate on inflammatory response in migraine rats based on c-Jun N-terminal kinase/p38 mitogen-activated protein kinase signaling pathway [J]. Acta Anatomica Sinica, 2023, 54(6): 652-659.
[13]	XU Ying LIU Bin ZHENG Xing HE Zong-zhao. Role and mechanism of complement C3a receptor in the cognitive impairment of septic rats induced by cecal ligation and perforation [J]. Acta Anatomica Sinica, 2023, 54(6): 668-675.
[14]	LIU Zhe-chuan LI Kun MA Shuai-nan MENG Jia-qi WANG Yan-qin. Effects of liraglutide on inflammation and mitochondrial fusion/division in Parkinson’s disease model of mice induced by paraquat [J]. Acta Anatomica Sinica, 2023, 54(6): 676-681.
[15]	WU Jun-bo YANG Jie XIAO Feng LI Jin-liang . Effect of microRNA-138 regulation of Wnt pathway on the biological behavior of human glioma cells in vitro [J]. Acta Anatomica Sinica, 2023, 54(6): 682-688.