乙胺嘧啶对巨噬细胞叶酸水平及免疫功能的影响

doi:10.12140/j.issn.1000-7423.2021.02.014

摘要/Abstract

摘要：

目的探讨抗弓形虫药物乙胺嘧啶对巨噬细胞叶酸水平和免疫功能的影响。方法将小鼠巨噬细胞RAW264.7（1 × 10 ⁴个/孔）接种于96孔板中,用0（对照组）、0.01、0.05、0.10、0.50、1.00、5.00、10.00、50.00、100.00、500.00和1 000.00 μmol/L的乙胺嘧啶分别处理24 h后,CCK8检测细胞活性抑制率。将RAW264.7细胞（5 × 10 ⁵个/孔）接种于6孔板中,弓形虫RH株速殖子感染后3 h,用0（对照组）、0.10、1.00、10.00和100.00 μmol/L的乙胺嘧啶分别处理24 h,实时荧光定量PCR（qRT-PCR）检测弓形虫速殖子的二氢叶酸还原酶的表达。TRIzol试剂提取RAW264.7细胞的总RNA,qRT-PCR检测巨噬细胞二氢叶酸还原酶和炎症因子基因的表达,Western blotting检测巨噬细胞DHFR的蛋白表达,全自动化学发光免疫分析仪检测胞内活性叶酸水平。用BLAST对速殖子DHFR蛋白和小鼠巨噬细胞DHFR蛋白的氨基酸序列进行同源比对。用无叶酸培养基预处理RAW264.7细胞48 h,随后用100 μmol/L的乙胺嘧啶处理24 h,qRT-PCR检测无叶酸条件下巨噬细胞炎症因子基因的表达。两组之间比较采用t检验,多重比较采用单因素方差分析。结果 CCK8检测结果显示,乙胺嘧啶的细胞活性抑制率具有剂量依赖效应,在0.01~0.10 μmol/L时可促进巨噬细胞的轻度增殖,浓度高于0.10 μmol/L时显示有抑制细胞增殖作用。qRT-PCR检测结果显示,0.10、1.00、10.00和100.00 μmol/L组弓形虫二氢叶酸还原酶mRNA相对转录水平分别为1.190 ± 0.054、1.460 ± 0.206、0.468 ± 0.077和0.399 ± 0.073,1 μmol/L组高于对照组,10.00和100.00 μmol/L组均低于对照组（P < 0.01）;而巨噬细胞二氢叶酸还原酶mRNA相对转录水平分别为0.789 ± 0.505、1.820 ± 0.119、2.120 ± 0.140和2.080 ± 0.189,其中1.00、10.00和100.00 μmol/L组均高于对照组（P < 0.05或0.01）。Western blotting分析结果显示,100.00 μmol/L组巨噬细胞DHFR蛋白表达显著高于对照组。BLAST同源比对显示,速殖子DHFR蛋白和小鼠巨噬细胞DHFR蛋白的同源性仅为37.0%。化学发光免疫分析结果显示,100.00 μmol/L组巨噬细胞的胞内活性叶酸水平为（10.600 ± 2.930）nmol/L,高于对照组（P < 0.01）。100 μmol/L乙胺嘧啶处理后,巨噬细胞炎症相关指标TNF-α、iNOS、Arg-1和IL-1β的mRNA相对转录水平分别为2.230 ± 0.100、11.800 ± 1.350、3.610 ± 0.256和7.810 ± 0.987,均高于对照组（P < 0.05或0.01）。乙胺嘧啶处理后,无叶酸培养组RAW264.7细胞TNF-α、iNOS、Arg-1和IL-1β的mRNA相对转录水平分别为2.460 ± 0.026、1.330 ± 0.091、0.974 ± 0.141和0.997 ± 0.018,iNOS、Arg-1和IL-1β低于含叶酸正常组（P < 0.05或0.01）,TNF-α高于含叶酸正常组（P < 0.01）。结论乙胺嘧啶可以通过促进小鼠巨噬细胞二氢叶酸还原酶的表达,升高胞内活性叶酸水平,从而诱导巨噬细胞炎症因子基因表达。

关键词: 乙胺嘧啶, 巨噬细胞, 叶酸, 二氢叶酸还原酶

Abstract:

Objective To explore the effects of pyrimethamine, an anti-Toxoplasma gondii drug, on folate level and immune function of macrophages. Methods RAW264.7 cells were seeded in 96-well plates (1 × 10⁴ cells/well) and treated with 0 (control), 0.01, 0.05, 0.10, 0.50, 1.00, 5.00, 10.00, 50.00, 100.00, 500.00 and 1 000.00 μmol/L pyrimethamine for 24 h, respectively, followed by CCK8 assay. RAW264.7 cells were seeded in 6-well plates (5 × 10⁵ cells/well), and infected with T. gondii tachyzoites for 3 h, followed by treatement with 0.10, 1.00, 10.00 and 100.00 μmol/L pyrimethamine for 24 h, respectively. The expression of dihydrofolate reductase (DHFR) in T. gondii tachyzoites was detected by qRT-PCR. Total RNA of RAW264.7 cells was extracted by TRIzol reagent. The expression of DHFR and inflammatory genes in macrophages was detected by qRT-PCR, the protein abundance of DHFR was detected by Western blotting and intracellular folate levels were detected by Automated Chemiluminescence Systems. The amino acid sequences of DHFR from T. gondii tachyzoites and from RAW264.7 cells were compared by BLAST. RAW264.7 cells were cultured in folate-free medium for 48 h, and then treated with 100 μmol/L pyrimethamine for 24 h to detect the expression of inflammatory genes by qRT-PCR. The comparison between two groups was performed by t-test, and multiple comparison was performed by one-way ANOVA. Results CCK8 detection showed that the inhibition rate of pyrimethamine on cell activity was in a dose-dependent manner, which could induce slight proliferation of macrophages at 0.01-0.10 μmol/L, while inhibited cell proliferation at the concentration higher than 0.10 μmol/L. qRT-PCR showed that the mRNA expression of DHFR in T. gondii tachyzoites in the 0.10, 1.00, 10.00 and 100.00 μmol/L groups were 1.190 ± 0.054, 1.460 ± 0.206, 0.468 ± 0.077 and 0.399 ± 0.073 respectively, showing mRNA expression in the 1.00 μmol/L group being higher than that in the control group, and the level in the 10.00 and 100.00 μmol/L groups lower than that in the control group (P < 0.01). Meanwhile, the mRNA expression of DHFR in the RAW264.7 cells were 0.789 ± 0.505, 1.820 ± 0.119, 2.120 ± 0.140 and 2.080 ± 0.189 respectively, higher in the 1.00, 10.00 and 100.00 μmol/L groups than those in the control group (P < 0.05 or 0.01). Western blotting results showed that the protein abundance of DHFR in macrophages in the 100.00 μmol/L group was significantly higher than that in the control group. BLAST results showed that the homology between tachyzoite DHFR and mouse macrophage DHFR was only 37.0%. Using Automated Chemiluminescence Systems, we found that the intracellular folate level of macrophages in the 100.00 μmol/L group was (10.600 ± 2.930) nmol/L, which was much higher than that in the control group (P < 0.01). After treatment with 100 μmol/L pyrimethamine, the mRNA expression of TNF-α, iNOS, Arg-1 and IL-1β were 2.230 ± 0.100, 11.800 ± 1.350, 3.610 ± 0.256 and 7.810 ± 0.987 respectively, which were all higher than those in the control group (P < 0.05 or 0.01). After treatment with 100 μmol/L pyrimethamine, the mRNA levels of TNF-α, iNOS, Arg-1 and IL-1β in the folate-free culture group were 2.460 ± 0.026, 1.330 ± 0.091, 0.974 ± 0.141 and 0.997 ± 0.018 respectively. The mRNA levels of iNOS, Arg-1 and IL-1β in the folate-free group were much lower than those in the normal folate group (P < 0.05 or 0.01), while the opposite was found for TNF-α (P < 0.01). Conclusion Pyrimethamine could increase the intracellular folate level of macrophages by promoting the expression of DHFR in mice, which further induces the inflammatory gene expression of macrophages.

Key words: Pyrimethamine, Macrophage, Folate, Dihydrofolate reductase

中图分类号:

R531.8

秦敏, 邵天业, 赵成思, 缪婷婷, 张戎, 邱竞帆, 王勇. 乙胺嘧啶对巨噬细胞叶酸水平及免疫功能的影响[J]. 中国寄生虫学与寄生虫病杂志, 2021, 39(2): 210-217.

QIN Min, SHAO Tian-ye, ZHAO Cheng-si, MIAO Ting-ting, ZHANG Rong, QIU Jing-fan, WANG Yong. Effects of pyrimethamine on folate level and immune function of macrophages[J]. Chinese Journal of Parasitology and Parasitic Diseases, 2021, 39(2): 210-217.

图/表 5

表1

图1

图2

图3

图4

参考文献 32

[1]	Zhou P, Chen ZG, Li HL, et al. Toxoplasma gondii infection in humans in China[J]. Parasit Vectors, 2011,4:165-173.
[2]	Wang ZZ, Xu R, Hong Y, et al. Fusion expression and identification of B cell epitopes of Toxoplasma gondii surface antigens (SAG) 1 and 2[J]. Chin J Parasitol Parasit Dis, 2017,35(6):575-579. (in Chinese)
[2]	( 王钊哲, 许瑞, 洪炀, 等. 刚地弓形虫表面抗原1、2 B细胞表位基因的融合表达和鉴定[J]. 中国寄生虫学与寄生虫病杂志, 2017,35(6):575-579.)
[3]	Lewis JM, Clifford S, Nsutebu E. Toxoplasmosis in immunosuppressed patients[J]. Rheumatology, 2015,54(11):1939-1940.
[4]	Xie ZX, Jiang J, Wang WH, et al. Construction of the RSepitope-HPV16L1 fusion protein using the dominant epitope of ROP2-SAG1 antigen from Toxoplasma gondii and late structural protein 1 of HPV type 16 and its expression in eukaryotic cells[J]. Chin J Parasitol Parasit Dis, 2018,36(3):266-271. (in Chinese)
[4]	( 谢自新, 姜洁, 汪文寰, 等. 弓形虫复合抗原ROP2-SAG1优势表位与人乳头瘤病毒16型晚期结构蛋白L1融合体的构建及其在真核细胞中的表达[J]. 中国寄生虫学与寄生虫病杂志, 2018,36(3):266-271.)
[5]	Ma YL, Lyu FL. The role of type Ⅰ interferon in protozoan infections[J]. Chin J Parasitol Parasit Dis, 2018,36(4):399-404. (in Chinese)
[5]	( 马远林, 吕芳丽. Ⅰ型干扰素在原虫感染中的作用[J]. 中国寄生虫学与寄生虫病杂志, 2018,36(4):399-404.)
[6]	Montazeri M, Sharif M, Sarvi S, et al. A systematic review of in vitro and in vivo activities of anti-Toxoplasma drugs and compounds (2006—2016)[J]. Front Microbiol, 2017,8:25-55.
[7]	Meneceur P, Bouldouyre MA, Aubert D, et al. In vitro susceptibility of various genotypic strains of Toxoplasma gondii to pyrimethamine, sulfadiazine, and atovaquone[J]. Antimicrob Agents Chemother, 2008,52(4):1269-1277.
[8]	Martins-Duarte éS, de Souza W, Vommaro RC. Toxoplasma gondii: the effect of fluconazole combined with sulfadiazine and pyrimethamine against acute toxoplasmosis in murine model[J]. Exp Parasitol, 2013,133(3):294-299.
[9]	Borkowski PK, Brydak-Godowska J, Basiak W, et al. Adverse reactions in antifolate-treated toxoplasmic retinochoroiditis[J]. Adv Exp Med Biol, 2018,1108:37-48.
[10]	Ben-Harari RR, Goodwin E, Casoy J. Adverse event profile of pyrimethamine-based therapy in toxoplasmosis: a systematic review[J]. Drugs R D, 2017,17(4):523-544.
[11]	Khan Assir MZ, Ahmad HI, Akram J, et al. An outbreak of pyrimethamine toxicity in patients with ischaemic heart disease in Pakistan[J]. Basic Clin Pharmacol Toxicol, 2014,115(3):291-296.
[12]	Maggini S, Wintergerst ES, Beveridge S, et al. Selected vitamins and trace elements support immune function by strengthening epithelial barriers and cellular and humoral immune responses[J]. Br J Nutr, 2007,98(Suppl 1):S29-S35.
[13]	Troen AM, Mitchell B, Sorensen B, et al. Unmetabolized folic acid in plasma is associated with reduced natural killer cell cytotoxicity among postmenopausal women[J]. J Nutr, 2006,136(1):189-194.
[14]	Protiva P, Mason JB, Liu ZH, et al. Altered folate availability modifies the molecular environment of the human colorectum: implications for colorectal carcinogenesis[J]. Cancer Prev Res(Phila Pa), 2011,4(4):530-543.
[15]	Meadows DN, Bahous RH, Best AF, et al. High dietary folate in mice alters immune response and reduces survival after malarial infection[J]. PLoS One, 2015,10(11):e0143738.
[16]	Klee GG. Cobalamin and folate evaluation: measurement of methylmalonic acid and homocysteine vs vitamin B(12) and folate[J]. Clin Chem, 2000,46(8 pt 2):1277-1283.
[17]	Kolb AF, Petrie L, Mayer CD, et al. Folate deficiency promotes differentiation of vascular smooth muscle cells without affecting the methylation status of regulated genes[J]. Biochem J, 2019,476(19):2769-2795.
[18]	Ling YM, Shaw MH, Ayala C, et al. Vacuolar and plasma membrane stripping and autophagic elimination of Toxoplasma gondii in primed effector macrophages[J]. J Exp Med, 2006,203(9):2063-2071.
[19]	Du KG, Zhuo XH, Lu SH. Research advances on the innate immunity mechanisms against Toxoplasma gondii[J]. Chin J Parasitol Parasit Dis, 2020,38(6):764-770. (in Chinese)
[19]	( 杜凯歌, 卓洵辉, 陆绍红. 抗弓形虫固有免疫机制研究进展[J]. 中国寄生虫学与寄生虫病杂志, 2020,38(6):764-770.)
[20]	Ying W, Cheruku PS, Bazer FW, et al. Investigation of macrophage polarization using bone marrow derived macrophages[J]. J Vis Exp, 2013(76):50323.
[21]	Zhang AM, Shen Q, Li M, et al. Comparative studies of macrophage-biased responses in mice to infection with Toxoplasma gondii ToxoDB #9 strains of different virulence isolated from China[J]. Parasit Vectors, 2013,6(1):308-319.
[22]	Xu ZP, Zuo GP, Jin JL. Macrophage heterogeneity and its research progress in inflammation regulation[J]. Chin J Cell Mol Immunol, 2015,31(12):1711-1714. (in Chinese)
[22]	( 徐志鹏, 左国平, 靳建亮. 巨噬细胞异质性及其在炎症调控中的研究进展[J]. 细胞与分子免疫学杂志, 2015,31(12):1711-1714.)
[23]	Lipka B, Milewska-Bobula B, Filipek M. Monitoring of plasma concentration of pyrimethamine (PYR) in infants with congenital Toxoplasma gondii infection: own observations[J]. Wiad Parazytol, 2011,57(2):87-92.
[24]	Reiter-Owona I, Hlobil H, Enders M, et al. Sulfadiazine plasma concentrations in women with pregnancy-acquired compared to ocular toxoplasmosis under pyrimethamine and sulfadiazine therapy: a case-control study[J]. Eur J Med Res, 2020,25(1):59-67.
[25]	Wu XP. Study on pharmacokinetics and residues of pyrimethamine in eel[D]. Wuhan: Huazhong Agricultural University, 2008: 1-27. (in Chinese)
[25]	( 吴小平. 乙胺嘧啶在鳗鲡体内的药物动力学和残留研究[D]. 武汉: 华中农业大学, 2008: 1-27.)
[26]	Jainkittivong A, Arenholt-Bindslev D, Jepsen A, et al. Effect of folic acid on human oral epithelium in vitro[J]. J Dent Assoc Thai, 1989,39(4):121-127.
[27]	Boot MJ, Steegers-Theunissen RP, Poelmann RE, et al. Folic acid and homocysteine affect neural crest and neuroepithelial cell outgrowth and differentiation in vitro[J]. Dev Dyn, 2003,227(2):301-308.
[28]	Luo SH, Zhang XM, Yu M, et al. Folic acid acts through DNA methyltransferases to induce the differentiation of neural stem cells into neurons[J]. Cell Biochem Biophys, 2013,66(3):559-566.
[29]	de Leeuw VC, van Nieuwland M, Bokkers BGH, et al. Culture conditions affect chemical-induced developmental toxicity in vitro: the case of folic acid, methionine and methotrexate in the neural embryonic stem cell test[J]. Altern Lab Anim, 2020,48(4):173-183.
[30]	Hwang SY, Kang YJ, Sung B, et al. Folic acid promotes the myogenic differentiation of C2C12 murine myoblasts through the Akt signaling pathway[J]. Int J Mol Med, 2015,36(4):1073-1080.
[31]	Kong DL, Zhou CL, Guo HF, et al. Praziquantel targets M1 macrophages and ameliorates splenomegaly in chronic schistosomiasis[J]. Antimicrob Agents Chemother, 2018,62(1):e00005-e00017.
[32]	Wang W, Zhao CS, Miao TT, et al. Praziquantel inhibits splenic macrophage proliferation and inflammatory reaction in mice infected with Schistosoma japonicum[J]. Chin J Parasitol Parasit Dis, 2020,38(3):263-270. (in Chinese)
[32]	( 王伟, 赵成思, 缪婷婷, 等. 吡喹酮治疗对日本血吸虫感染小鼠脾巨噬细胞增殖和炎症反应的抑制作用[J]. 中国寄生虫学与寄生虫病杂志, 2020,38(3):263-270.)

基因名称 Gene name	引物序列（5′→3′） Primer sequence (5′→3′)
Mus-GAPDH	F: AGGTCGGTGTGAACGGATTTG
	R: TGTAGACCATGTAGTTGAGGTCA
Mus-DHFR	F: CGCTCAGGAACGAGTTCAAGT
	R: TGCCAATTCCGGTTGTTCAATA
Mus-TNF-α	F: CTGTAGCCCACGTCGTAGC
	R: TTGAGATCCATGCCGTTG
Mus-iNOS	F: GGAGCGAGTTGTGGATTGTC
	R: GTGAGGGCTTGGCTGAGTGAG
Mus-Arg-1	F: CAGAAGAATGGAAGAGTCAG
	R: CAGATATGCAGGGAGTCACC
Mus-IL-1β	F: GCAACTGTTCCTGAACTCAACT
	R: ATCTTTTGGGGTCCGTCAACT
Mus-IL-10	F: GACCAGCTGGACAACATACTGCTAA
	R: GATAAGGCTTGGCAACCCAAGTAA
Mus-TGF-β	F: GCAACAATTCCTGGCGTTACC
	R: CGAAAGCCCTGTATTCCGTCT
RH-DHFR	F: GGCATCGGCATCAACAAC
	R: TCAGGCGACTGGCTTCTT