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Open Access 01-10-2018 | Original Paper

The effects of HAP and macrophage cells to the expression of inflammatory factors and apoptosis in HK-2 cells of vitro co-cultured system

Authors: Junchuan Yu, Yaoliang Deng, Zhiwei Tao, Weixia Liang, Xiaofeng Guan, Jihua Wu, Xin Ning, Yunlong Liu, Quan Liu, Ziqi He

Published in: Urolithiasis | Issue 5/2018

Abstract

This study developed an in vitro system by co-culturing HK-2 cells with different concentration of hydroxyapatite (HAP) and/or macrophage cells to simulate the internal environment of urolithiasis as far as possible, investigating the regulatory effects of macrophage cells on HAP-induced expression of relative inflammatory factors of HK-2 cells. The control group (H group) was only comprised of HK-2 cells. Experimental groups included co-culturing HK-2 cells and macrophage cells (H + M group), co-culturing HK-2 cells and HAP (H + A group), co-culturing macrophage cells and HAP (M + A group), and co-culturing HK-2 cells and macrophage cells with HAP (H + M + A group). In the H + A, M + A, and H + M + A group, we set the concentration of HAP as 5 μg/cm² (A1) and 10 μg/cm² (A2). After co-culturing for 2, 4, and 6 h, we detected the expression of CCL-2 in the liquid by ELISA. We tested the expression of LDH and ROS to evaluate the damage of HK-2 cells. We assessed the apoptosis of HK-2 cells using DAPI staining assay, flow cytometry, and the rate of BAX/BCL-2. Western Blotting detected OPN, Fetuin-A, BAX, and BCL-2 of HK-2 cells. The expression of CCL-2 in the medium of H + A1 and H + A2 group increased significantly compared with the control (P < 0.05); CCL-2 of M + A1 and M + A2 group was higher than the H + A1 and H + A2 group (P < 0.05). The expression of CCL-2 in H + M + A1 and H + M + A2 group was also higher than M + A1 and M + A2 group (P < 0.05). Compared with control, the expression of OPN, LDH release, the ratio of BAX/BCL-2, and the generation of ROS in HK-2 cells increased in a dose- and time-dependent manner. Compared with the control, the expression of Fetuin-A decreased in various degrees at different incubation periods. Especially when co-culturing for 6 h, Fetuin-A decreased most seriously in the H + M + A1 group. (1) The HAP can induce the HK-2 cells oxidative stress and inflammatory damage and apoptosis, when adding the macrophages to co-culture, macrophage cells can aggravate the damage and apoptosis of the HK-2 cells. (2) After the stimulation of HAP, the expression of OPN in HK-2 cells increased in a time- and dose-dependent manner; macrophage cells can aggravate the increase of OPN in HK-2 cells. (3) In the HAP and HK-2 cells co-cultured system, the low-level Fetuin-A of HK-2 cells may be related to the excessive consumption of Fetuin-A in the process of HAP-induced renal tubular epithelial cell excessive oxidative stress, inflammatory injury, and cell apoptosis. When adding macrophage cells to co-culture, Fetuin-A decreased even more seriously, it reminds us that macrophage cells can slightly regulate the expression of Fetuin-A in the HK-2 cells.

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Moe OW (2006) Kidney stones: pathophysiology and medical management. Lancet (London England) 367:333–344CrossRef

Antonelli JA, Maalouf NM, Pearle MS, Lotan Y (2014) Use of the National Health and Nutrition Examination Survey to calculate the impact of obesity and diabetes on cost and prevalence of urolithiasis in 2030. Eur Urol 66:724–729CrossRefPubMedPubMedCentral

El-Zoghby ZM, Lieske JC, Foley RN, Bergstralh EJ, Li X, Melton LJ 3rd, Krambeck AE, Rule AD (2012) Urolithiasis and the risk of ESRD Clin. J Am Soc Nephrol 7: 1409–1415CrossRef

Kohjimoto Y, Sasaki Y, Iguchi M, Matsumura N, Inagaki T, Hara I (2013) Association of metabolic syndrome traits and severity of kidney stones: results from a nationwide survey on urolithiasis in Japan. Am J Kidney Dis 61:923–929CrossRefPubMed

Dardamanis M (2013) Pathomechanisms of nephrolithiasis. Hippokratia 17:100–107PubMedPubMedCentral

Mandal T, Ward MD (2013) Determination of specific binding interactions at l-cystine crystal surfaces with chemical force microscopy. J Am Chem Soc 135:5525–5528CrossRefPubMed

Daudon M, Bazin D, Letavernier E (2015) Randall’s plaque as the origin of calcium oxalate kidney stones. Urolithiasis 43(Suppl 1):5–11CrossRefPubMed

Randall A (1937) The origin and growth of renal calculi. Ann Surg 105:1009–1027CrossRefPubMedPubMedCentral

Kim SC, Coe FL, Tinmouth WW, Kuo RL, Paterson RF, Parks JH, Munch LC, Evan AP, Lingeman JE (2005) Stone formation is proportional to papillary surface coverage by Randall’s plaque. J Urol 173:117–119 (discussion 119) CrossRefPubMed

10.

Verrier C, Bazin D, Huguet L, Stephan O, Gloter A, Verpont MC, Frochot V, Haymann JP, Brocheriou I, Traxer O, Daudon M, Letavernier E (2016) Topography, composition and structure of incipient Randall plaque at the nanoscale level. J Urol 196:1566–1574

11.

de Water R, Noordermeer C, van der Kwast TH, Nizze H, Boeve ER, Kok DJ, Schroder FH (1999) Calcium oxalate nephrolithiasis: effect of renal crystal deposition on the cellular composition of the renal interstitium. Am J Kidney Dis 33:761–771CrossRefPubMed

12.

Zuo L, Tozawa K, Okada A, Yasui T, Taguchi K, Ito Y, Hirose Y, Fujii Y, Niimi K, Hamamoto S, Ando R, Itoh Y, Zou J, Kohri K (2014) A paracrine mechanism involving renal tubular cells, adipocytes and macrophages promotes kidney stone formation in a simulated metabolic syndrome environment. J Urol 191:1906–1912CrossRefPubMed

13.

Khan SR (2013) Reactive oxygen species as the molecular modulators of calcium oxalate kidney stone formation: evidence from clinical and experimental investigations. J Urol 189:803–811CrossRefPubMed

14.

Okada A, Yasui T, Fujii Y, Niimi K, Hamamoto S, Hirose M, Kojima Y, Itoh Y, Tozawa K, Hayashi Y, Kohri K (2010) Renal macrophage migration and crystal phagocytosis via inflammatory-related gene expression during kidney stone formation and elimination in mice: detection by association analysis of stone-related gene expression and microstructural observation. J Bone Miner Res 25:2701–2711CrossRefPubMed

15.

Martinez FO, Gordon S (2014) The M1 and M2 paradigm of macrophage activation: time for reassessment. F1000prime Rep 6:13CrossRefPubMedPubMedCentral

16.

Anderson CF, Mosser DM (2002) A novel phenotype for an activated macrophage: the type 2 activated macrophage. J Leukoc Biol 72:101–106PubMed

17.

Gan QZ, Sun XY, Bhadja P, Yao XQ, Ouyang JM (2016) Reinjury risk of nano-calcium oxalate monohydrate and calcium oxalate dihydrate crystals on injured renal epithelial cells: aggravation of crystal adhesion and aggregation. Int J Nanomed 11:2839–2854

18.

Wang Y, Sun C, Li C, Deng Y, Zeng G, Tao Z, Wang X, Guan X, Zhao Y (2016) Urinary MCP-1HMGB1 increased in calcium nephrolithiasis patients and the influence of hypercalciuria on the production of the two cytokines. Urolithiasis 45:159–175

19.

Khan SR (2014) Reactive oxygen species, inflammation and calcium oxalate nephrolithiasis. Transl Androl Urol 3:256–276PubMedPubMedCentral

20.

Seto J, Busse B, Gupta HS, Schafer C, Krauss S, Dunlop JW, Masic A, Kerschnitzki M, Zaslansky P, Boesecke P, Catala-Lehnen P, Schinke T, Fratzl P, Jahnen-Dechent W (2012) Accelerated growth plate mineralization and foreshortened proximal limb bones in fetuin-A knockout mice. PloS One 7:e47338CrossRefPubMedPubMedCentral

21.

Stejskal D, Karpisek M, Vrtal R, Student V, Solichova P, Fiala R, Stejskal P (2008) Urine fetuin-A values in relation to the presence of urolithiasis. BJU Int 101:1151–1154CrossRefPubMed

22.

Aihara K, Byer KJ, Khan SR (2003) Calcium phosphate-induced renal epithelial injury and stone formation: involvement of reactive oxygen species. Kidney Int 64:1283–1291CrossRefPubMed

23.

Wang B, Zhang A, Zheng J, Gong J, Li S, Zeng Z, Gan W (2011) Bufalin inhibits platelet-derived growth factor-BB-induced mesangial cell proliferation through mediating cell cycle progression. Biol Pharm Bull 34:967–973CrossRefPubMed

24.

Lee KE, Kim EY, Kim CS, Choi JS, Bae EH, Ma SK, Kim KK, Lee JU, Kim SW (2013) Macrophage-stimulating protein attenuates gentamicin-induced inflammation and apoptosis in human renal proximal tubular epithelial cells. Biochem Biophys Res Commun 434:527–533CrossRefPubMed

25.

Bae EH, Cho S, Joo SY, Ma SK, Kim SH, Lee J, Kim SW (2011) 4-Hydroxy-2-hexenal-induced apoptosis in human renal proximal tubular epithelial cells. Nephrol Dial Transpl 26:3866–3873CrossRef

26.

Sugimoto MA, Ribeiro AL, Costa BR, Vago JP, Lima KM, Carneiro FS, Ortiz MM, Lima GL, Carmo AA, Rocha RM, Perez DA, Reis AC, Pinho V, Miles LA, Garcia CC, Teixeira MM, Sousa LP (2017) Plasmin and Plasminogen induce macrophage reprogramming and regulate key steps of inflammation resolution via Annexin A1. Blood 129:2896–2907

27.

Hardbower DM, Coburn LA, Asim M, Singh K, Sierra JC, Barry DP, Gobert AP, Piazuelo MB, Washington MK, Wilson KT (2017) EGFR-mediated macrophage activation promotes colitis-associated tumorigenesis. Oncogene 36:3807–3819

28.

Chung HJ (2014) The role of Randall plaques on kidney stone formation. Transl Androl Urol 3:251–254PubMedPubMedCentral

29.

Evan AP, Worcester EM, Williams JC Jr, Sommer AJ, Lingeman JE, Phillips CL, Coe FL (2015) Biopsy proven medullary sponge kidney: clinical findings, histopathology, and role of osteogenesis in stone and plaque formation. Anatom Rec (Hoboken, NJ: 2007) 298:865–877CrossRef

30.

Fujii Y, Okada A, Yasui T, Niimi K, Hamamoto S, Hirose M, Kubota Y, Tozawa K, Hayashi Y, Kohri K (2013) Effect of adiponectin on kidney crystal formation in metabolic syndrome model mice via inhibition of inflammation and apoptosis. PloS One 8:e61343CrossRefPubMedPubMedCentral

31.

Griffiths HR, Gao D, Pararasa C (2017) Redox regulation in metabolic programming and inflammation. Redox Biol 12:50–57CrossRefPubMedPubMedCentral

32.

de Water R, Noordermeer C, Houtsmuller AB, Nigg AL, Stijnen T, Schroder FH, Kok DJ (2000) Role of macrophages in nephrolithiasis in rats: an analysis of the renal interstitium. Am J Kidney Dis 36:615–625CrossRefPubMed

33.

Kanlaya R, Sintiprungrat K, Thongboonkerd V (2013) Secreted products of macrophages exposed to calcium oxalate crystals induce epithelial mesenchymal transition of renal tubular cells via RhoA-dependent TGF-beta1 pathway. Cell Biochem Biophys 67:1207–1215CrossRefPubMed

34.

Pyzer AR, Stroopinsky D, Rajabi H, Washington A, Tagde A, Coll M, Fung J, Bryant MP, Cole L, Palmer K, Somaiya P, Leaf RK, Nahas M, Apel A, Jain S, McMasters M, Mendez L, Levine J, Joyce R, Arnason J, Pandolfi PP, Kufe D, Rosenblatt J, Avigan D (2017) MUC1 mediated induction of myeloid-derived suppressor cells in patients with acute myeloid leukemia. Blood 129:1791–1801

35.

Ueda K, Beppu T (2017) Antibiotics in microbial coculture. J Antibiot 70:361–365CrossRef

36.

Kerneis S, Caliot E, Stubbe H, Bogdanova A, Kraehenbuhl J, Pringault E (2000) Molecular studies of the intestinal mucosal barrier physiopathology using cocultures of epithelial and immune cells: a technical update. Microbes Infect 2:1119–1124CrossRefPubMed

37.

Alex M, Sauganth Paul MV, Abhilash M, Mathews VV, Anilkumar TV, Nair RH (2014) Astaxanthin modulates osteopontin and transforming growth factor beta1 expression levels in a rat model of nephrolithiasis: a comparison with citrate administration. BJU Int 114:458–466PubMed

38.

Langdon A, Grohe B (2016) The osteopontin-controlled switching of calcium oxalate monohydrate morphologies in artificial urine provides insights into the formation of papillary kidney stones. Colloids Surf B Biointerfaces 146:296–306CrossRefPubMed

39.

Taguchi K, Hamamoto S, Okada A, Unno R, Kamisawa H, Naiki T, Ando R, Mizuno K, Kawai N, Tozawa K, Kohri K, Yasui T (2016) Genome-wide gene expression profiling of Randall’s plaques in calcium oxalate stone. JASN 28:333–347

40.

Thurgood LA, Sorensen ES, Ryall RL (2012) The effect of intracrystalline and surface-bound osteopontin on the degradation and dissolution of calcium oxalate dihydrate crystals in MDCKII cells. Urol Res 40:1–15CrossRefPubMed

41.

Hirose M, Tozawa K, Okada A, Hamamoto S, Higashibata Y, Gao B, Hayashi Y, Shimizu H, Kubota Y, Yasui T, Kohri K (2012) Role of osteopontin in early phase of renal crystal formation: immunohistochemical and microstructural comparisons with osteopontin knock-out mice. Urol Res 40:121–129CrossRefPubMed

42.

Scanu A, Luisetto R, Oliviero F, Gruaz L, Sfriso P, Burger D, Punzi L (2015) High-density lipoproteins inhibit urate crystal-induced inflammation in mice. Ann Rheum Dis 74:587–594CrossRefPubMed

43.

Dhanasekar C, Kalaiselvan S, Rasool M (2015) Morin, a bioflavonoid suppresses monosodium urate crystal-induced inflammatory immune response in RAW 264.7 macrophages through the inhibition of inflammatory mediators, intracellular ROS levels and NF-kappaB activation. PloS One 10:e0145093CrossRefPubMedPubMedCentral

44.

Peng Z, Chen W, Wang L, Ye Z, Gao S, Sun X, Guo Z (2015) Inhalation of hydrogen gas ameliorates glyoxylate-induced calcium oxalate deposition and renal oxidative stress in mice. Int J Clin Exp Pathol 8:2680–2689PubMedPubMedCentral

45.

Ichikawa J, Okada A, Taguchi K, Fujii Y, Zuo L, Niimi K, Hamamoto S, Kubota Y, Umemoto Y, Itoh Y, Yasui T, Kawai N, Tozawa K, Kohri K (2014) Increased crystal-cell interaction in vitro under co-culture of renal tubular cells and adipocytes by in vitro co-culture paracrine systems simulating metabolic syndrome. Urolithiasis 42:17–28CrossRefPubMed

46.

Khan SR (2011) Crystal/cell interaction and nephrolithiasis. Archivio italiano di urologia, andrologia: organo ufficiale [di] Societa italiana di ecografia urologica e nefrologica/Associazione ricerche in urologia 83:1–5

47.

Wang B, Wu B, Liu J, Yao W, Xia D, Li L, Chen Z, Ye Z, Yu X (2014) Analysis of altered microRNA expression profiles in proximal renal tubular cells in response to calcium oxalate monohydrate crystal adhesion: implications for kidney stone disease. PloS One 9:e101306CrossRefPubMedPubMedCentral

48.

Hu B, Wu HR, Ma ZY, Wu ZC, Lu YM, Shi GW (2014) Involvement of VKORC1 in the inhibition of calcium oxalate crystal formation in HK-2 cells. J Huazhong Univ Sci Technol Med Sci 34:376–381CrossRef

49.

Li CY, Deng YL, Sun BH (2009) Taurine protected kidney from oxidative injury through mitochondrial-linked pathway in a rat model of nephrolithiasi. Urol Res 37:211–220CrossRefPubMed

50.

Khan SR (2012) Is oxidative stress, a link between nephrolithiasis and obesity, hypertension, diabetes, chronic kidney disease, metabolic syndrome? Urol Res 40:95–112CrossRefPubMedPubMedCentral

51.

Evan AP, Unwin RJ, Williams JC Jr (2011) Renal stone disease: a commentary on the nature and significance of Randall’s plaque. Nephron Physiol 119:49–53CrossRef

52.

Wu YX, Li CY, Deng YL (2014) Patients with nephrolithiasis had lower fetuin-A protein level in urine and renal tissue. Urolithiasis 42:29–37CrossRefPubMed

53.

Kittikowit W, Waiwijit U, Boonla C, Ruangvejvorachai P, Pimratana C, Predanon C, Ratchanon S, Tosukhowong P (2014) Increased oxidative DNA damage seen in renal biopsies adjacent stones in patients with nephrolithiasis. Urolithiasis 42:387–394CrossRefPubMed

54.

Lang F, Abed M, Lang E, Foller M (2014) Oxidative stress and suicidal erythrocyte death. Antioxid Redox Signal 21:138–153CrossRefPubMed

55.

Wolk K, Sabat R (2016) Adipokines in psoriasis: an important link between skin inflammation and metabolic alterations Rev Endocr Metab Disord 17:305–317

56.

Ombrellino M, Wang H, Yang H, Zhang M, Vishnubhakat J, Frazier A, Scher LA, Friedman SG, Tracey KJ (2001) Fetuin, a negative acute phase protein, attenuates TNF synthesis and the innate inflammatory response to carrageenan. Shock (Augusta Ga) 15:181–185CrossRef

57.

Kahraman A, Sowa JP, Schlattjan M, Sydor S, Pronadl M, Wree A, Beilfuss A, Kilicarslan A, Altinbas A, Bechmann LP, Syn WK, Gerken G, Canbay A (2013) Fetuin-A mRNA expression is elevated in NASH compared with NAFL patients. Clin Sci (Lond) 125:391–400CrossRef

58.

Janda K, Krzanowski M, Gajda M, Dumnicka P, Jasek E, Fedak D, Pietrzycka A, Kuzniewski M, Litwin JA, Sulowicz W (2015) Vascular effects of advanced glycation end-products: content of immunohistochemically detected AGEs in radial artery samples as a predictor for arterial calcification and cardiovascular risk in asymptomatic patients with chronic kidney disease. Dis Mark 2015:153978

59.

Paloian NJ, Giachelli CM (2014) A current understanding of vascular calcification in CKD. Am J Physiol Renal Physiol 307:F891–F900CrossRefPubMedPubMedCentral

60.

Schinke T, Amendt C, Trindl A, Poschke O, Muller-Esterl W, Jahnen-Dechent W (1996) The serum protein alpha2-HS glycoprotein/fetuin inhibits apatite formation in vitro and in mineralizing calvaria cells. A possible role in mineralization and calcium homeostasis. J Biol Chem 271:20789–20796CrossRefPubMed

61.

Daveau M, Christian D, Julen N, Hiron M, Arnaud P, Lebreton JP (1988) The synthesis of human alpha-2-HS glycoprotein is down-regulated by cytokines in hepatoma HepG2 cells. FEBS Lett 241:191–194CrossRefPubMed

62.

Li W, Zhu S, Li J, Huang Y, Zhou R, Fan X, Yang H, Gong X, Eissa NT, Jahnen-Dechent W, Wang P, Tracey KJ, Sama AE, Wang H (2011) A hepatic protein, fetuin-A, occupies a protective role in lethal systemic inflammation. PloS One 6:e16945CrossRefPubMedPubMedCentral

63.

Aksoy H, Aksoy Y, Ozturk N, Aydin HR, Yildirim AK, Akcay F (2010) Fetuin-A gene polymorphism in patients with calcium oxalate stone disease. Urology 75:928–932CrossRefPubMed

Title: The effects of HAP and macrophage cells to the expression of inflammatory factors and apoptosis in HK-2 cells of vitro co-cultured system
Authors: Junchuan Yu
Yaoliang Deng
Zhiwei Tao
Weixia Liang
Xiaofeng Guan
Jihua Wu
Xin Ning
Yunlong Liu
Quan Liu
Ziqi He
Publication date: 01-10-2018
Publisher: Springer Berlin Heidelberg
Published in: Urolithiasis / Issue 5/2018
Print ISSN: 2194-7228
Electronic ISSN: 2194-7236
DOI: https://doi.org/10.1007/s00240-017-1032-8

Keynote webinar | Spotlight on sleep in brain health

Springer Medicine

The effects of HAP and macrophage cells to the expression of inflammatory factors and apoptosis in HK-2 cells of vitro co-cultured system

Abstract

Keynote webinar | Spotlight on sleep in brain health

Springer Medicine

Abstract

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