Calcium oxalate crystals stimulate expression of high mobility group box-1 protein in human macrophages

doi:10.3969/j.issn.2095-4344.2015.11.014

Abstract

Abstract:

BACKGROUND: There are a large amount of infiltrated monocytes and macrophages around the renal interstitial crystals in a kidney model, indicating that macrophages may be involved in the process of crystal deposition in the kidney. As macrophages are important human innate immune cells, a large number of infiltrated monocytes and macrophages in the kidney will produce some inflammatory injuries and damage renal tubular epithelial cells, which ultimately lead to the formation of stones.

OBJECTIVE: To study the expression of after high mobility group box-1 protein (HMGB1) in macrophages stimulated by calcium oxalate monohydrate crystals.

METHODS: Western blot assay was used to detect total protein and HMGB1 levels in the cytoplasm of macrophages under 100 mg/L calcium oxalate monohydrate stimulation for 0, 6, 12, 24, 36 hours. Meanwhile, real-time quantitative PCR was adopted to determine the mRNA expression of HMGB1. Tumor necrosis factor α and interleukin-6 levels in the cultured cell supernatant at 0, 1, 2 and 4 hours after calcium oxalate monohydrate stimulation were measured using ELISA.

RESULTS AND CONCLUSION: Under the calcium oxalate monohydrate stimulation, the level of HMGB1 in the cytoplasm of macrophages was lower within 0-6 hours, but gradually increased within 12-36 hours; the level of HMGB1 in the total protein of macrophages was not high within 0-6 hours, began to increase at 12 hours, and then kept at a higher level within 24-36 hours. RT-PCR results showed that under the calcium oxalate monohydrate stimulation, the mRNA level of HMGB1 in the cultured cells had no changes within 0-12 hours, but significantly increased within 18-24 hours. ELISA results showed that the levels of tumor necrosis factor α and interleukin-6 in the cultured cell supernatant subject to calcium oxalate monohydrate were increased at 2 hours and peaked at 4 hours. These findings indicate that calcium oxalate monohydrate can increase the HMGB1 expression in macrophages at mRNA and protein levels, and also induce the increase in tumor necrosis factor α and interleukin-6 expression in macrophages. Moreover, the expression of HMGB1 is later than the release of tumor necrosis factor α and interleukin-6.

中国组织工程研究杂志出版内容重点：组织构建；骨细胞；软骨细胞；细胞培养；成纤维细胞；血管内皮细胞；骨质疏松；组织工程

全文链接：

Key words: High Mobility Group Proteins, Calcium Oxalate, Macrophages

CLC Number:

R318

Huang Peng, Deng Yao-liang, Li Cheng-yang, Tao Zhi-wei, Wang Xiang, Feng You-cai, Wu Bo . Calcium oxalate crystals stimulate expression of high mobility group box-1 protein in human macrophages [J]. Chinese Journal of Tissue Engineering Research, 2015, 19(11): 1712-1716.

Figures/Tables 1

References

[1] De Water R, Noordermeer C, Houtsmuller AB, et al．The role of macrophages in nephrolithiasis in rats:An analysis of the renal interstitium. Am J Kidney Dis.2000;36:615-625．
[2] Khan SR. Crystal-induced inflammation of the kidney：results from human studies，animal models,and tissue culture studies. Clin Exp Nephrol.2004;8(2):75-88．
[3] Li J,Kokkola R,Tabibzadeh S,et al.Structural basis for the proinflam matory cytokine activity of high mobility group box1. Mol Med.2003;9(1-2):37-45.
[4] Lotze MT,Tracey KJ.High-mobility group box 1 protein (HMGB1): nuclear weapon in the immune arsenal.Nature Rev Immunol.2005;5(4):331-342.
[5] Sapojnikova N，Maman J，Myers FA，et al. Biochemical observation of the rapid mobility of nuclear HMGB1. Biochim Biophys Acta.2005;1729(1):57-63.
[6] Li W, Sama A E, Wang H. Role of HMGB1 in cardiovascular dis-eases. Curr Opin Pharmacol.2006;6(2):130-135.
[7] Mantell LL, Parris W R, Ullea L. Hmgb-1 as a therapeutic target for infectious and inflammatory disorders. Shock. 2006; 25(1):4-11．
[8] Chen X，Li W，Wang H．More tea for septic patients-Green tea may reduce endotoxin-induced release of high mobility group box l and other pro-inflammatory cytokines. Med Hypotheses. 2006;66(3):660-663．
[9] de Water R, Leenen PJ, Noordermeer C,et al.Cytokine production induced by binding and processing of calcium oxalate crystals in cultured macrophage.Am J Kidney Dis. 2001;38(2):331-338.
[10] Wang HC, Bloom O, Zhang MH, et al. HMG-1as a late mediator of endotoxin lethality in mice. Science.1999;285(5425):248-251．
[11] Fiuza C,Bustin M,Talwar S,et al. Inflammatory promoting activity of HMGBI on human microvascular endothelial ceHs. Blood.2003;101(7):2652-2660．
[12] Paehot A, Monneret G, Voifin N, bet al. Longitudinal study of cytokine and immune transcription factor mRNA expression in septic shock. Clinical Immunology.2005;114(1):61-69．
[13] Harris HE, Andersson U. The nuclear protein HMGBI as a proinflammatory mediator. Eur J Immunol.2004;34(6): 1503-1512．
[14] 奉有才,邓耀良,陶芝伟,等.吴博高迁移率族蛋白B1对磷酸钙诱导巨噬细胞释放炎症因子的协同作用[J].中国组织工程研究, 2014,18(33):5317-5322.

[1]	Chen Ziyang, Pu Rui, Deng Shuang, Yuan Lingyan. Regulatory effect of exosomes on exercise-mediated insulin resistance diseases [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(25): 4089-4094.
[2]	Chen Yang, Huang Denggao, Gao Yuanhui, Wang Shunlan, Cao Hui, Zheng Linlin, He Haowei, Luo Siqin, Xiao Jingchuan, Zhang Yingai, Zhang Shufang. Low-intensity pulsed ultrasound promotes the proliferation and adhesion of human adipose-derived mesenchymal stem cells [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(25): 3949-3955.
[3]	Yang Junhui, Luo Jinli, Yuan Xiaoping. Effects of human growth hormone on proliferation and osteogenic differentiation of human periodontal ligament stem cells [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(25): 3956-3961.
[4]	Sun Jianwei, Yang Xinming, Zhang Ying. Effect of montelukast combined with bone marrow mesenchymal stem cell transplantation on spinal cord injury in rat models [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(25): 3962-3969.
[5]	Gao Shan, Huang Dongjing, Hong Haiman, Jia Jingqiao, Meng Fei. Comparison on the curative effect of human placenta-derived mesenchymal stem cells and induced islet-like cells in gestational diabetes mellitus rats [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(25): 3981-3987.
[6]	Hao Xiaona, Zhang Yingjie, Li Yuyun, Xu Tao. Bone marrow mesenchymal stem cells overexpressing prolyl oligopeptidase on the repair of liver fibrosis in rat models [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(25): 3988-3993.
[7]	Liu Jianyou, Jia Zhongwei, Niu Jiawei, Cao Xinjie, Zhang Dong, Wei Jie. A new method for measuring the anteversion angle of the femoral neck by constructing the three-dimensional digital model of the femur [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(24): 3779-3783.
[8]	Meng Lingjie, Qian Hui, Sheng Xiaolei, Lu Jianfeng, Huang Jianping, Qi Liangang, Liu Zongbao. Application of three-dimensional printing technology combined with bone cement in minimally invasive treatment of the collapsed Sanders III type of calcaneal fractures [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(24): 3784-3789.
[9]	Qian Xuankun, Huang Hefei, Wu Chengcong, Liu Keting, Ou Hua, Zhang Jinpeng, Ren Jing, Wan Jianshan. Computer-assisted navigation combined with minimally invasive transforaminal lumbar interbody fusion for lumbar spondylolisthesis [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(24): 3790-3795.
[10]	Hu Jing, Xiang Yang, Ye Chuan, Han Ziji. Three-dimensional printing assisted screw placement and freehand pedicle screw fixation in the treatment of thoracolumbar fractures: 1-year follow-up [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(24): 3804-3809.
[11]	Shu Qihang, Liao Yijia, Xue Jingbo, Yan Yiguo, Wang Cheng. Three-dimensional finite element analysis of a new three-dimensional printed porous fusion cage for cervical vertebra [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(24): 3810-3815.
[12]	Wang Yihan, Li Yang, Zhang Ling, Zhang Rui, Xu Ruida, Han Xiaofeng, Cheng Guangqi, Wang Weil. Application of three-dimensional visualization technology for digital orthopedics in the reduction and fixation of intertrochanteric fracture [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(24): 3816-3820.
[13]	Sun Maji, Wang Qiuan, Zhang Xingchen, Guo Chong, Yuan Feng, Guo Kaijin. Development and biomechanical analysis of a new anterior cervical pedicle screw fixation system [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(24): 3821-3825.
[14]	Lin Wang, Wang Yingying, Guo Weizhong, Yuan Cuihua, Xu Shenggui, Zhang Shenshen, Lin Chengshou. Adopting expanded lateral approach to enhance the mechanical stability and knee function for treating posterolateral column fracture of tibial plateau [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(24): 3826-3827.
[15]	Zhu Yun, Chen Yu, Qiu Hao, Liu Dun, Jin Guorong, Chen Shimou, Weng Zheng. Finite element analysis for treatment of osteoporotic femoral fracture with far cortical locking screw [J]. Chinese Journal of Tissue Engineering Research, 2021, 25(24): 3832-3837.