痤疮丙酸杆菌生物膜诱导角质形成细胞发生炎症反应的分子机制研究

doi:10.35541/cjd.20230168

Abstract

Abstract: 【Abstract】 Objective To investigate molecular mechanisms underlying the inflammatory response induced by Cutibacterium acnes （C. acnes） biofilms in human primary keratinocytes. Methods A C. acnes biofilm model was established in vitro, and confocal fluorescence microscopy was performed to examine its three-dimensional structure. The cultured human primary keratinocytes were divided into 3 groups: a dimethyl sulfoxide （DMSO） control group （treated with 0.01% DMSO alone）, a C. acnes suspension group （co-incubated with C. acnes suspensions）, and a C. acnes biofilm group （co-incubated with C. acnes biofilms）. Real-time fluorescence-based quantitative PCR （RT-qPCR） was performed to determine the relative mRNA expression of interleukin （IL）-6, IL-8, and tumor necrosis factor （TNF）-α in the groups after 6-hour culture, enzyme-linked immunosorbent assay to detect the free protein levels of IL-6, IL-8, and TNF-α in the groups after 24-hour culture, and Western blot analysis to determine the protein expression of Toll-like receptor 2 （TLR2） in keratinocytes. In addition, some human primary keratinocytes were pretreated with key molecular blockers targeting the TLR2/mitogen-activated protein kinase （MAPK）/nuclear factor （NF）-κB signaling pathway （C29, ST2825, BAY11-7082, SB203580, U0126-EtOH）, and then co-incubated with C. acnes biofilms; the DMSO control group and the C. acnes biofilm group receiving no pretreatment were simultaneously set as negative and positive controls, respectively. The mRNA and free protein expression levels of IL-6, IL-8, and TNF-α were then detected in the above groups. One-way analysis of variance was used for comparisons among multiple groups, and the Bonferroni method was used for multiple comparisons. Results Confocal fluorescence microscopy demonstrated a three-dimensional C. acnes biofilm structure resembling a lawn, and the biofilm grew well. RT-qPCR and ELISA showed significant differences in the mRNA and free protein expression levels of IL-6, IL-8, and TNF-α among the C. acnes biofilm group, C. acnes suspension group and DMSO control group （mRNA: F = 89.70, 312.17, 46.09, respectively, all P < 0.001; free protein: F = 886.12, 634.25, 307.01, respectively, all P < 0.001）; in detail, the mRNA and free protein expression levels of IL-6, IL-8, and TNF-α were significantly higher in the C. acnes biofilm group than in the C. acnes suspension group and DMSO control group （all P < 0.001）; the C. acnes suspension group showed significantly increased expression levels of IL-6 mRNA and TNF-α free protein compared with the DMSO control group （P < 0.001, = 0.003, respectively）, while there were no significant differences in the expression of IL-6 free protein, TNF-α mRNA, or IL-8 mRNA and free protein between the 2 groups （all P > 0.05）. Western blot analysis showed that the TLR2 protein expression was significantly higher in the C. acnes suspension group and C. acnes biofilm group than in the DMSO control group. After the pretreatment with molecular blockers targeting the MAPK/NF-κB signaling pathway and co-incubation with C. acnes biofilms, the mRNA and free protein expression levels of IL-6, IL-8 and TNF-α were all significantly lower in the C29 group, ST2825 group, BAY11-7082 group, SB203580 group, U0126-EtOH group, as well as in the DMSO control group compared with the C. acnes biofilm group （all P < 0.05）. Conclusion The C. acnes biofilms exhibited a strong ability to induce inflammatory responses in human keratinocytes, possibly through the activation of the TLR2/MAPK/NF-κB signaling pathway.

Key words: Propionibacterium acnes, Biofilms, Keratinocytes, Toll-like receptor 2, Inflammatory reaction, MAPK/NF-κB signaling pathway

Pei Lu, Zheng Nana, Zeng Rong, Xie Yuanyuan, Xu Haoxiang, Duan Zhimin, Liu Yuzhen, Li Min, . Molecular mechanisms underlying the inflammatory response induced by Cutibacterium acnes biofilms in keratinocytes[J]. Chinese Journal of Dermatology, 2024, 57(4): 302-308.doi:10.35541/cjd.20230168

References ［21］

［1］	Okuda KI, Nagahori R, Yamada S, et al. The composition and structure of biofilms developed by Propionibacterium acnes isolated from cardiac pacemaker devices［J］. Front Microbiol, 2018,9:182. doi: 10.3389/fmicb.2018.00182.
［2］	Jahns AC, Alexeyev OA. Three dimensional distribution of Propionibacterium acnes biofilms in human skin［J］. Exp Dermatol, 2014,23（9）:687⁃689. doi: 10.1111/exd.12482.
［3］	Garcia D, Mayfield CK, Leong J, et al. Early adherence and biofilm formation of Cutibacterium acnes （formerly Propionibacterium acnes） on spinal implant materials［J］. Spine J, 2020,20（6）:981⁃987. doi: 10.1016/j.spinee.2020.01.001.
［4］	Firlej E, Kowalska W, Szymaszek K, et al. The role of skin immune system in acne［J］. J Clin Med, 2022,11（6）:1579. doi: 10.3390/jcm11061579.
［5］	Shaheen B, Gonzalez M. Acne sans P. acnes［J］. J Eur Acad Dermatol Venereol, 2013,27（1）:1⁃10. doi: 10.1111/j.1468⁃3083. 2012.04516.x.
［6］	Jiang Y, Tsoi LC, Billi AC, et al. Cytokinocytes: the diverse contribution of keratinocytes to immune responses in skin［J］. JCI Insight, 2020,5（20）:e142067. doi: 10.1172/jci.insight.142067.
［7］	Piipponen M, Li D, Landén NX. The immune functions of keratinocytes in skin wound healing［J］. Int J Mol Sci, 2020,21（22）:8790. doi: 10.3390/ijms21228790.
［8］	Colombo I, Sangiovanni E, Maggio R, et al. HaCaT cells as a reliable in vitro differentiation model to dissect the inflammatory/repair response of human keratinocytes［J］. Mediators Inflamm, 2017,2017:7435621. doi: 10.1155/2017/7435621.
［9］	刘宇甄, 曾荣, 郑娜娜, 等. 氨基酮戊酸孵育不同时间对光动力疗法抑制痤疮丙酸杆菌生物膜效应的影响［J］. 中华皮肤科杂志, 2022,55（3）:208⁃212. doi: 10.35541/cjd.20210575.
［10］	Jahns AC, Lundskog B, Ganceviciene R, et al. An increased incidence of Propionibacterium acnes biofilms in acne vulgaris: a case⁃control study［J］. Br J Dermatol, 2012,167（1）:50⁃58. doi: 10.1111/j.1365⁃2133.2012.10897.x.
［11］	Taff HT, Mitchell KF, Edward JA, et al. Mechanisms of Candida biofilm drug resistance［J］. Future Microbiol, 2013,8（10）:1325⁃1337. doi: 10.2217/fmb.13.101.
［12］	Van Acker H, Van Dijck P, Coenye T. Molecular mechanisms of antimicrobial tolerance and resistance in bacterial and fungal biofilms［J］. Trends Microbiol, 2014,22（6）:326⁃333. doi: 10.1016/j.tim.2014.02.001.
［13］	Graham GM, Farrar MD, Cruse⁃Sawyer JE, et al. Proin⁃flammatory cytokine production by human keratinocytes stimulated with Propionibacterium acnes and P. acnes GroEL［J］. Br J Dermatol, 2004,150（3）:421⁃428. doi: 10.1046/j.1365⁃2133.2004.05762.x.
［14］	Nagy I, Pivarcsi A, Koreck A, et al. Distinct strains of Propionibacterium acnes induce selective human beta⁃defensin⁃2 and interleukin⁃8 expression in human keratinocytes through toll⁃like receptors［J］. J Invest Dermatol, 2005,124（5）:931⁃938. doi: 10.1111/j.0022⁃202X.2005.23705.x.
［15］	Abd El All HS, Shoukry NS, El Maged RA, et al. Immunohistochemical expression of interleukin 8 in skin biopsies from patients with inflammatory acne vulgaris［J］. Diagn Pathol, 2007,2:4. doi: 10.1186/1746⁃1596⁃2⁃4.
［16］	Rocha MA, Costa CS, Bagatin E. Acne vulgaris: an inflammatory disease even before the onset of clinical lesions［J］. Inflamm Allergy Drug Targets, 2014,13（3）:162⁃167. doi: 10.2174/187152 8113666140606110024.
［17］	Ozkanli S, Karadag AS, Ozlu E, et al. A comparative study of MMP⁃1, MMP⁃2, and TNF⁃α expression in different acne vulgaris lesions［J］. Int J Dermatol, 2016,55（12）:1402⁃1407. doi: 10.1111/ijd.13275.
［18］	Flemming HC, Wingender J. The biofilm matrix［J］. Nat Rev Microbiol, 2010,8（9）:623⁃633. doi: 10.1038/nrmicro2415.
［19］	Gannesen AV, Zdorovenko EL, Botchkova EA, et al. Composition of the biofilm matrix of Cutibacterium acnes acneic strain RT5［J］. Front Microbiol, 2019,10:1284. doi: 10.3389/fmicb.2019. 01284.
［20］	Ma Y, Chen Q, Liu Y, et al. Effects of 5⁃aminolevulinic acid photodynamic therapy on TLRs in acne lesions and keratino⁃cytes co⁃cultured with P. acnes［J］. Photodiagnosis Photodyn Ther, 2016,15:172⁃181. doi: 10.1016/j.pdpdt.2016.07.002.
［21］	Kim J. Review of the innate immune response in acne vulgaris: activation of Toll⁃like receptor 2 in acne triggers inflammatory cytokine responses［J］. Dermatology, 2005,211（3）:193⁃198. doi: 10.1159/000087011.

[1]	Tang Zhiming, Jing Mengqing, Lu Lu, Shan Xiao, Zhang Cuixia, Zhang Xiaoyu, Meng Sa. Effect of Xidi Liangxue recipe on the proliferation and apoptosis of HaCaT cells through the lncRNA NEAT1/miR-485-5p/STAT3 regulatory network [J]. Chinese Journal of Dermatology, 2023, 56(7): 642-650.
[2]	Yang Yaqi, Jiang Xin, Chang Jinxiu, Tu Ying, Ma Yanyun, He Li, Gu Hua. Effect of blue light on the biological activity of human skin keratinocytes, fibroblasts and melanocytes: a preliminary study [J]. Chinese Journal of Dermatology, 2023, 56(12): 1115-1122.
[3]	Guo Qingqing, Qi Jiayue, Xie Fang, Li Chengxin, . Effects of fibroblast growth factor receptor 3 and human papillomavirus type 2 E2 protein on the differentiation of keratinocytes: a preliminary study [J]. Chinese Journal of Dermatology, 2023, 56(11): 1016-1022.
[4]	Zhou Meng, Zheng Nana, Zeng Rong, Xu Haoxiang, Duan Zhimin, Liu Yuzhen, Li Min, . Inhibitory effect of deoxyribonucleaseⅠ against Cutibacterium acnes biofilms [J]. Chinese Journal of Dermatology, 2023, 56(10): 920-924.
[5]	Zhou Xue, Yu Zengyang, Chen Youdong, Guo Chunyuan, Yu Qian, Hu Yifan, Yao Lingling, Shi Yuling, . Tumor necrosis factor α-mediated low expression of fatty acid desaturase 2 in psoriasis [J]. Chinese Journal of Dermatology, 2022, 55(9): 752-758.
[6]	Yao Lingling, Yu Zengyang, Guo Chunyuan, Zhou Jing, Cui Lian, Yu Qian, Yu Yingyuan, Zhou Xue, Cai Jiangluyi, Shi Yuling, . Changes in circadian gene cryptochrome 2 expression in mouse models of psoriasis and HaCaT cells and their underlying mechanisms [J]. Chinese Journal of Dermatology, 2022, 55(9): 759-766.
[7]	Bao Yingqiu, Zhang Yanjun, Li Bo, Gong Jing, Fu Yu, Xu Zhe. Gene therapy for recessive dystrophic epidermolysis bullosa [J]. Chinese Journal of Dermatology, 2022, 55(8): 739-743.
[8]	Xu Cui, He Yong, Wu Yilin, Lyu Qun, Li Liming, Jiang Mingjun. Establishment and identification of human immortalized keratinocytes stably expressing human papillomavirus type 16 E6/E7 gene [J]. Chinese Journal of Dermatology, 2022, 55(6): 501-507.
[9]	Liu Yuzhen, Zeng Rong, Zheng Nana, Duan Zhimin, Xu Haoxiang, Wu Qiuju, Lin Tong, Li Min. Effect of different incubation time of aminolevulinic acid on photodynamic inhibition of Propionibacterium acnes biofilms [J]. Chinese Journal of Dermatology, 2022, 55(3): 208-212.
[10]	Ge Xinhong, Jiao Yaning, Ge Minghao, Ma Yingdong, Shi Yue, Wang Yu, Liu Lingling. Expression of silent information regulator 1 and 3 and hypoxia-inducible factor 1α in cutaneous squamous cell carcinoma tissues and cells [J]. Chinese Journal of Dermatology, 2022, 55(2): 116-122.
[11]	Lin Luyang, Chen Zhengliang, Zhang Xibao. Major immune-related cells in psoriasis vulgaris lesions [J]. Chinese Journal of Dermatology, 2021, 54(9): 830-834.
[12]	Su Fang, Jin Liang, Li Hao, Ding Yingjie, Sun Xiaojie, Sun Xiaodong, Liu Wei, Xu Guijuan, Wang Qiang, Liu Yongbin. Mechanisms underlying microRNA-125a-mediated inhibition of proliferation of HaCaT cells by targeting the interleukin 23 receptor signaling pathway: a preliminary study [J]. Chinese Journal of Dermatology, 2021, 54(6): 499-503.
[13]	Chen Hongying, Chen Xu, Li Li, Gu Heng. Effect of resveratrol on apoptosis and cell cycle of human keratinocytes irradiated by ultraviolet B [J]. Chinese Journal of Dermatology, 2021, 54(5): 408-413.
[14]	Li Yueyue, Luo Dan. Roles and action mechanisms of skin microbiota in the occurrence of rosacea [J]. Chinese Journal of Dermatology, 2021, 54(12): 1122-1125.
[15]	Yang Xin, Lang Dexiu, Liao Yong, Li Haitao, Peng Zhuoying, Ao Junhong, Zhang Dequan, Yang Rongya, . Effect of microevolution on phenotypes and drug resistance of the Trichosporon asahii biofilm [J]. Chinese Journal of Dermatology, 2021, 54(1): 68-73.

Molecular mechanisms underlying the inflammatory response induced by Cutibacterium acnes biofilms in keratinocytes

PDF

Knowledge

Abstract

Cite this article

share this article

References ［21］

Related Articles 15

Metrics

Comments

Recommended 10