氨基酮戊酸光动力疗法治疗前后SKH-1小鼠皮肤鳞状细胞癌组织中免疫细胞亚群变化

doi:10.35541/cjd.20210192

中华皮肤科杂志 ›› 2021, Vol. 54 ›› Issue (11): 978-983.doi: 10.35541/cjd.20210192

氨基酮戊酸光动力疗法治疗前后SKH-1小鼠皮肤鳞状细胞癌组织中免疫细胞亚群变化

郑哲¹ 张国龙^2，3 王佩茹^2，3 吉杰^2，3 王秀丽^1，2，3

¹扬州大学医学院 225001；²上海市皮肤病医院 200443；³同济大学医学院光医学研究所，上海 200443

收稿日期:2021-03-07 修回日期:2021-05-26 发布日期:2021-11-01
通讯作者: 王秀丽 E-mail:wangxiuli_1400023@tongji.edu.cn
基金资助:
国家自然科学基金（81872212、81602396、81872512）；上海市浦江人才计划资助项目（17PJ1408500）；上海市静安区首批领军人才计划项目

Changes in immune cell subsets in cutaneous squamous cell carcinoma tissues from SKH-1 mouse models after aminolevulinic acid-based photodynamic therapy

Zheng Zhe¹, Zhang Guolong^2,3, Wang Peiru^2,3, Ji Jie^2,3, Wang Xiuli^1,2,3

¹Clinical College of Yangzhou University, Yangzhou 225001, Jiangsu, China; ²Shanghai Skin Disease Hospital, Shanghai 200443, China; ³Institute of Photomedicine, Tongji University School of Medicine, Shanghai 200443, China

Received:2021-03-07 Revised:2021-05-26 Published:2021-11-01
Contact: Wang Xiuli E-mail:wangxiuli_1400023@tongji.edu.cn
Supported by:
National Natural Science Foundation of China （81872212, 81602396, 81872512）; Shanghai Pujiang Program （17PJ1408500）; Jing An District Leadership Talent Program

摘要/Abstract

摘要： 【摘要】目的研究氨基酮戊酸光动力疗法（ALA-PDT）对小鼠皮肤鳞状细胞癌（cSCC）的免疫效应。方法建立紫外线诱导的SKH-1无毛小鼠cSCC模型，进行ALA-PDT治疗，在治疗前及治疗后1、3、6、12、24 h和3 d、7 d各取5 mm3大小皮肤组织，采用免疫组化及流式细胞仪检测不同时间点小鼠肿瘤组织免疫细胞浸润情况，包括中性粒细胞、巨噬细胞、T细胞、B细胞、自然杀伤细胞和树突细胞。采用SPSS16.0软件进行两样本均数t检验。结果与治疗前相比，小鼠cSCC肿瘤局部中性粒细胞和巨噬细胞数量及比例在ALA-PDT治疗后1 h增高最明显［免疫组化结果（每400倍视野细胞数量）：61.22 ± 6.65比22.56 ± 4.13，59.67 ± 4.30比21.89 ± 3.26，均P＜0.05；流式细胞仪结果：（35.64 ± 15.33）%比（5.46 ± 2.44）%，（12.15 ± 4.86）%比（1.98 ± 1.49）%，均P＜0.05］。同时，免疫组化和流式细胞仪检测均显示肿瘤局部T细胞、B细胞、自然杀伤细胞及树突细胞在治疗后6 h表达显著增高（均P＜0.05）。达峰后，肿瘤组织中上述细胞数量和比例下降，但仍高于治疗前，并持续至本研究终点（治疗后第7天）。结论 ALA-PDT通过招募免疫细胞发挥抗肿瘤作用，其中以中性粒细胞和巨噬细胞最为明显。

关键词: 光化学疗法, 癌, 鳞状细胞, 免疫, 细胞, 氨基酮戊酸光动力法

Abstract: 【Abstract】 Objective To investigate immune effects of aminolevulinic acid-based photodynamic therapy （ALA-PDT） on mouse models of cutaneous squamous cell carcinoma （cSCC）. Methods Ultraviolet-induced SKH-1 hairless mouse models of cSCC were established, and 40 tumor- bearing mice were randomly and equally divided into several groups: control group receiving no treatment, and 7 treatment groups treated with ALA-PDT for 1, 3, 6, 12 and 24 hours, as well as 3 and 7 days respectively. After treatment, these mice were sacrificed at different time points, and skin tissues measuring 5 mm3 in size were resected. Immunohistochemical study and flow cytometry were performed to detect local infiltration of immune cells in cSCC tissues at different time points, including neutrophils, macrophages, T cells, B cells, natural killer cells and dendritic cells. Statistical analysis was done by the two-sample t test using SPSS 16.0 software. Results The number and proportion of local neutrophils and macrophages showed the most significant increase in mouse cSCC tumors 1 hour after ALA-PDT compared with those before treatment （immunohistochemical results ［number of cells per 400 × field］: 61.22 ± 6.65 vs. 22.56 ± 4.13, 59.67 ± 4.30 vs. 21.89 ± 3.26, respectively, both P < 0.05; flow cytometry results: 35.64% ± 15.33% vs. 5.46% ± 2.44%, 12.15% ± 4.86% vs. 1.98% ± 1.49%, respectively, both P < 0.05）. Both immunohistochemical study and flow cytometry showed that the expression of T cells, B cells, natural killer cells and dendritic cells significantly increased in cSCC tissues 6 hours after treatment （all P < 0.05）. After reaching the peak, the number and proportion of the above-mentioned cells decreased in cSCC tissues, but were still higher than those before treatment, and the increase continued until the end of this study, that is, day 7 after treatment. Conclusion ALA-PDT may exert anti-tumor effects by recruiting immune cells, especially neutrophils and macrophages.

Key words: Photochemotherapy, Carcinoma, squamous cell, Immunity, cellular, Aminolevulinic acid photodynamic therapy

郑哲张国龙, 王佩茹, 吉杰, 王秀丽, . 氨基酮戊酸光动力疗法治疗前后SKH-1小鼠皮肤鳞状细胞癌组织中免疫细胞亚群变化[J]. 中华皮肤科杂志, 2021,54(11):978-983. doi:10.35541/cjd.20210192

Zheng Zhe, Zhang Guolong, Wang Peiru, Ji Jie, Wang Xiuli, . Changes in immune cell subsets in cutaneous squamous cell carcinoma tissues from SKH-1 mouse models after aminolevulinic acid-based photodynamic therapy[J]. Chinese Journal of Dermatology, 2021, 54(11): 978-983.doi:10.35541/cjd.20210192

参考文献 23

［1］	Kim J, Kozlow JH, Mittal B, et al. Guidelines of care for the management of cutaneous squamous cell carcinoma［J］. J Am Acad Dermatol, 2018,78（3）:560⁃578. doi: 10.1016/j.jaad.2017. 10.007.
［2］	Calzavara⁃Pinton PG, Venturini M, Sala R, et al. Methylaminolaevulinate⁃based photodynamic therapy of Bowen′s disease and squamous cell carcinoma［J］. Br J Dermatol, 2008,159（1）:137⁃144. doi: 10.1111/j.1365⁃2133.2008.08593.x.
［3］	Cohen DK, Lee PK. Photodynamic therapy for non⁃melanoma skin cancers［J］. Cancers （Basel）, 2016,8（10）:90. doi: 10.3390/cancers8100090.
［4］	徐世正, 王秀丽, 张春荣. δ⁃氨基酮戊酸光动力疗法治疗皮肤基底细胞癌和鳞状细胞癌［J］. 中华皮肤科杂志, 1999,32（3）: 185⁃186. doi: 10.3760/j.issn:0412⁃4030.1999.03.023.
［5］	Peng Q, Nesland JM. Effects of photodynamic therapy on tumor stroma［J］. Ultrastruct Pathol, 2004,28（5⁃6）:333⁃340. doi: 10. 1080/01913120490515586.
［6］	Nelson JS, Liaw LH, Berns MW. Tumor destruction in photodynamic therapy［J］. Photochem Photobiol, 1987,46（5）:829⁃835. doi: 10.1111/j.1751⁃1097.1987.tb04855.x.
［7］	Hryhorenko EA, Oseroff AR, Morgan J, et al. Antigen specific and nonspecific modulation of the immune response by aminolevulinic acid based photodynamic therapy［J］. Immunopharmacology, 1998,40（3）:231⁃240. doi: 10.1016/s0162⁃3109（98）00047⁃2.
［8］	邱海霞, 刘凡光, 顾瑛. 肿瘤光动力学疗法免疫机制的研究进展［J］. 中国激光医学杂志, 2005,14（5）:326⁃330. doi: 10.3969/j.issn.1003⁃9430.2005.05.014.
［9］	Castano AP, Mroz P, Hamblin MR. Photodynamic therapy and anti⁃tumour immunity［J］. Nat Rev Cancer, 2006,6（7）:535⁃545. doi: 10.1038/nrc1894.
［10］	吕婷, 王秀丽, 周文江, 等. 紫外线所致皮肤鳞状细胞癌小鼠模型的建立［J］. 中华皮肤科杂志, 2011,44（3）:174⁃177. doi: 10.3760/cma.j.issn.0412⁃4030.2011.03.008.
［11］	Wang B, Shi L, Zhang YF, et al. Gain with no pain? Pain management in dermatological photodynamic therapy［J］. Br J Dermatol, 2017,177（3）:656⁃665. doi: 10.1111/bjd.15344.
［12］	Korbelik M, Cecic I. Contribution of myeloid and lymphoid host cells to the curative outcome of mouse sarcoma treatment by photodynamic therapy［J］. Cancer Lett, 1999,137（1）:91⁃98. doi: 10.1016/s0304⁃3835（98）00349⁃8.
［13］	李晶晶, 吕婷, 王宏伟, 等. 氨基酮戊酸光动力疗法治疗SKH⁃1小鼠皮肤鳞状细胞癌作用机制研究［J］. 中华皮肤科杂志, 2014,47（3）:181⁃185. doi: 10.3760/cma.j.issn.0412⁃4030.2014. 03.007.
［14］	Krosl G, Korbelik M, Dougherty GJ. Induction of immune cell infiltration into murine SCCVII tumour by photofrin⁃based photodynamic therapy［J］. Br J Cancer, 1995,71（3）:549⁃555. doi: 10.1038/bjc.1995.108.
［15］	商占仙, 路丽明. 中性粒细胞在肿瘤发生、发展中的研究进展［J］. 现代免疫学, 2018,38（6）:488⁃492,518.
［16］	Davis RW 4th, Snyder E, Miller J, et al. Luminol chemiluminescence reports photodynamic therapy⁃generated neutrophil activity in vivo and serves as a biomarker of therapeutic efficacy［J］. Photochem Photobiol, 2019,95（1）:430⁃438. doi: 10.1111/php.13040.
［17］	Kim J, Bae JS. Tumor⁃associated macrophages and neutrophils in tumor microenvironment［J］. Mediators Inflamm, 2016,2016:6058147. doi: 10.1155/2016/6058147.
［18］	Korbelik M. Induction of tumor immunity by photodynamic therapy［J］. J Clin Laser Med Surg, 1996,14（5）:329⁃334. doi: 10.1089/clm.1996.14.329.
［19］	Hendrzak⁃Henion JA, Knisely TL, Cincotta L, et al. Role of the immune system in mediating the antitumor effect of benzophenothiazine photodynamic therapy［J］. Photochem Photobiol, 1999,69（5）:575⁃581.
［20］	Jiang H, Granville DJ, North JR, et al. Selective action of the photosensitizer QLT0074 on activated human T lymphocytes［J］. Photochem Photobiol, 2002,76（2）:224⁃231. doi: 10.1562/0031⁃8655（2002）076<0224:saotpq>2.0.co;2.
［21］	Kushibiki T, Tajiri T, Tomioka Y, et al. Photodynamic therapy induces interleukin secretion from dendritic cells［J］. Int J Clin Exp Med, 2010,3（2）:110⁃114.
［22］	Park MJ, Bae JH, Chung JS, et al. Induction of NKG2D ligands and increased sensitivity of tumor cells to NK cell⁃mediated cytotoxicity by hematoporphyrin⁃based photodynamic therapy［J］. Immunol Invest, 2011,40（4）:367⁃382. doi: 10.3109/0882 0139.2010.551435.
［23］	Yeung HY, Lo PC, Ng DK, et al. Anti⁃tumor immunity of BAM⁃SiPc⁃mediated vascular photodynamic therapy in a BALB/c mouse model［J］. Cell Mol Immunol, 2017,14（2）:223⁃234. doi: 10.1038/cmi.2015.84.

[1]	张宁, 李舒, 李敬. 免疫检查点抑制剂和靶向药物辅助治疗可切除黑素瘤疗效的网状Meta分析[J]. 中华皮肤科杂志, 2022, 0(4): 20200767-e20200767.
[2]	黄雅馨, 何渊民, 黄书莉, 熊霞, 邓永琼. 血清几丁质酶3样蛋白1水平在寻常型天疱疮中的临床意义研究[J]. 中华皮肤科杂志, 2022, 0(2): 20210155-e20210155.
[3]	王佳绮, 王平, 李刘雨, 樊奇敏, 朱蒙燕, 王燕清, 周鸿宇, 沈宏, 许爱娥. 皮肤色素减退性淋巴增殖性疾病41例临床病理分析[J]. 中华皮肤科杂志, 2022, 55(2): 110-115.
[4]	阎诗, 周小英, 罗晓燕, 任发亮, 江为, 牛琳琳, 王华, 白晓明. Spink5基因条件性敲除小鼠模型的构建及表型分析[J]. 中华皮肤科杂志, 2022, 55(2): 95-101.
[5]	于聪, 周城, 张建中. 硬皮病样皮肤移植物抗宿主病24例临床特征分析[J]. 中华皮肤科杂志, 2022, 55(2): 123-128.
[6]	葛新红, 焦亚宁, 葛明昊, 马迎东, 石越, 王禹, 刘玲玲. 沉默信息调节因子1、3和缺氧诱导因子1α在皮肤鳞状细胞癌组织和细胞中的表达[J]. 中华皮肤科杂志, 2022, 55(2): 116-122.
[7]	林羽洁, 刘凤洁, 高玉梅, 刘向君, 许卜方, 李映依, 赖盼, 陈卓婧, 孙婧茹, 涂平, 汪旸. 溶血磷脂酸受体6在蕈样肉芽肿向大细胞转变中的意义及其对皮肤T细胞淋巴瘤细胞增殖和凋亡的影响[J]. 中华皮肤科杂志, 2022, 55(2): 102-109.
[8]	王慧, 刘董, 田芳, 魏志平. 表皮生长因子受体shRNA联合西罗莫司对Colo-16细胞体外增殖、凋亡的研究[J]. 中华皮肤科杂志, 2022, 55(2): 135-141.
[9]	闫娜, 杨丽娟, 赵婵, 刘燕, 曾维惠, 耿松梅, 谭宣丰. 皮下组织蒂隧道插入皮瓣在鼻翼缺损修复中的应用[J]. 中华皮肤科杂志, 2022, 55(2): 161-163.
[10]	包诗杰, 程杨, 晏莹, 范昉, 高婷婷, 冯小兰, 郑亮, 雷卫, 黄琴斯, 张伟明, 周小勇. 人免疫球蛋白和重组人Ⅱ型肿瘤坏死因子受体-抗体融合蛋白治疗中毒性表皮坏死松解症的对比研究[J]. 中华皮肤科杂志, 2022, 55(2): 153-156.
[11]	赵文玲, 杨语嫣, 李丽, 晋红中. 大疱性类天疱疮合并其他免疫性疾病研究进展[J]. 中华皮肤科杂志, 2022, 55(2): 177-181.
[12]	赵莹王娟娟季江苏文星魏钰倩冷红丁瑜洁施辛. 白细胞介素17A介导银屑病及心血管合并症的研究进展[J]. 中华皮肤科杂志, 2022, 55(1): 76-79.
[13]	杨瑞孔庆涛许洁张晨桑红. 复发性念珠菌颈部淋巴结炎1例易感基因筛查及免疫学研究[J]. 中华皮肤科杂志, 2022, 55(1): 50-54.
[14]	王文明贾倩楠方凯曾跃平. 血管内大B细胞淋巴瘤4例临床病理分析[J]. 中华皮肤科杂志, 2022, 55(1): 27-30.
[15]	张莹甘璐李思琪李颜宋昊邵雪宝张韡徐秀莲姜祎群曾学思陈浩孙建方. 伴大细胞转化的蕈样肉芽肿24例临床病理及免疫表型分析[J]. 中华皮肤科杂志, 2022, 55(1): 20-26.

氨基酮戊酸光动力疗法治疗前后SKH-1小鼠皮肤鳞状细胞癌组织中免疫细胞亚群变化

Changes in immune cell subsets in cutaneous squamous cell carcinoma tissues from SKH-1 mouse models after aminolevulinic acid-based photodynamic therapy

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献 23

相关文章 15

Metrics

本文评价

推荐阅读 10