Ma T X, Xu Y W, Jiang D Y
Department of Plastic Surgery, Henan Provincial People's Hospital, Zhengzhou 450000, China.
Emergency Department, the Second Hospital of Shandong University, Jinan 250000, China.
Zhonghua Shao Shang Za Zhi. 2020 Mar 20;36(3):234-243. doi: 10.3760/cma.j.cn501120-20190510-00232.
To explore the effects and mechanism of interleukin-17 (IL-17)-modified mouse bone marrow mesenchymal stem cells (BMSCs) on the allogeneic skin transplantation in mice. (1) The femur, tibia, and humerus were isolated from five BALB/c mice (all female, aged 4 to 8 weeks, the same gender and age below) after sacrifice. BMSCs were isolated, purified, and cultured by whole bone marrow density gradient centrifugation combined with adherent separation method. The third passage of cells was used for morphological observation and identification of adipogenic and osteogenic differentiation. The fourth passage of cells was used for identification of the expression of stem cell surface markers. The third to sixth passages of BMSCs were pretreated with mouse recombinant IL-17 at a final mass concentration of 50 ng/mL for 5 days, and then were harvested for morphological observation. After being labeled with carbocyanine fluorescent dye (CM-Dil), IL-17-pretreated BMSCs and IL-17-unpretreated BMSCs were obtained for morphological observation and the labeling rates were calculated. (2) Forty-five C57BL/6J mice were divided into phosphate buffer solution (PBS) control group (=13), BMSCs alone group (=16), and BMSCs+ IL-17 group (=16) according to the random number table. One day before the skin transplantation of mice, 0.1 mL BMSCs (5×10(6) cells/mL) without CM-Dil labeling were injected to the 13 mice in BMSCs alone group through the tail vein, and 0.1 mL BMSCs (5×10(6) cells/mL) labeled with CM-Dil were injected to the other 3 mice in BMSCs alone group through the tail vein. IL-17-pretreated BMSCs (5×10(6) cells/mL) without CM-Dil labeling in the volume of 0.1 mL were injected to the 13 mice in BMSCs+ IL-17 group through the tail vein, and 0.1 mL IL-17-pretreated BMSCs (5×10(6) cells/mL) labeled with CM-Dil were injected to the other 3 mice in BMSCs+ IL-17 group through the tail vein. PBS in the volume of 0.1 mL was injected to the 13 mice in PBS control group through the tail vein. Forty-five BALB/c mice were used as donors, and forty-five treated C57BL/6J mice in the 3 groups were used as recipients to establish a back-to-back full-thickness skin transplantation model. On the 2nd day after transplantation, the same number of corresponding cells and the equal amount of PBS were injected to the recipient mice of each group again. On the 7th day after transplantation, three mice injected with CM-Dil-labeled BMSCs in BMSCs alone group and three mice injected with CM-Dil-labeled IL-17-pretreated BMSCs in BMSCs+ IL-17 group were sacrificed by cervical dislocation to track the CM-Dil-labeled BMSCs by fluorescence microscope, which was counted. After the dressing removal on the 6th day post transplantation, 7 mice were selected respectively from 13 mice in BMSCs alone group injected with BMSCs without CM-Dil-labeling, 13 mice in BMSCs+ IL-17 group injected with IL-17-pretreated BMSCs without CM-Dil-labeling, and 13 mice in PBS control group, respectively, to record the skin graft survival time. On the 8th day post transplantation, three of the remaining six mice in the three groups were taken for general observation of the grafted skin, serum levels of interferon-γ, IL-10, and transforming growth factor β (TGF-β) by enzyme-linked immunosorbent assay method, the percentage of CD4(+) CD25(+) forkhead/winged helix transcription factor p3 (Foxp3)(+) regulatory T cells (Tregs) in spleen by flow cytometer, and the histopathological observation of the grafted skin by hematoxylin eosin staining. The rest three mice in each group were also taken for histopathological observation as above on the 14th day post transplantation. Data were statistically analysed with independent sample test, one-way analysis of variance, and least significant difference test. (1) There were no significant differences in the morphology and size between IL-17-pretreated BMSCs and IL-17-unpretreated BMSCs on culture day 5. (2) After CM-Dil labeling, BMSCs and IL-17-pretreated BMSCs grew well, and the labeling rate was almost 100%. (3) On the 7th day post transplantation, there were 6.2±2.6 CM-Dil-labeled BMSCs per 100 fold visual field in the skin and adjacent subcutaneous tissue of mice in BMSCs alone group, which were significantly fewer than the 15.0±5.3 CM-Dil-labeled IL-17-pretreated BMSCs per 100 fold visual field in BMSCs+ IL-17 group (=-2.962, <0.05). (4) The skin graft survival time of mice in BMSCs alone group and BMSCs+ IL-17 group was (13.3±1.2) and (17.0±1.5) days respectively, significantly longer than (8.7±0.8) days in PBS control group (<0.01), and the skin graft survival time of mice in BMSCs+ IL-17 group was significantly longer than that in BMSCs alone group (<0.01). (5) On the 8th day post transplantation, most of the skin grafts of mice in PBS control group was black, scabby, and necrotic. Most of the skin grafts of mice in BMSCs alone group survived well, while all the skin grafts of mice in BMSCs+ IL-17 group survived well. (6) On the 8th day post transplantation, compared with those of PBS control group, the serum levels of IL-10 and TGF-β of mice in BMSCs alone group and BMSCs+ IL-17 group were significantly higher (<0.01), and the serum level of interferon-γ was significantly lower (<0.01). Compared with those of BMSCs alone group, the serum levels of IL-10 and TGF-β of mice in BMSCs+ IL-17 group were significantly higher (<0.01), and the serum level of interferon-γ was significantly lower (<0.01). (7) On the 8th day post transplantation, the percentages of CD4(+) CD25(+) Foxp3(+) Treg in spleen of mice in BMSCs alone group and BMSCs+ IL-17 group were significantly higher than the percentage of PBS control group (<0.01), and the percentage of CD4(+) CD25(+) Foxp3(+) Treg in spleen of mice in BMSCs+ IL-17 group was significantly higher than that of BMSCs alone group (<0.01). (8) On the 8th day post transplantation, infiltration of a large number of inflammatory cells and necrosis of epidermis and dermis were found in the skin grafts of mice in PBS control group; focal infiltration of inflammatory cells and slight epidermal degeneration were found in the skin grafts of mice in BMSCs alone group; the skin appendages of the skin grafts of mice in BMSCs+ IL-17 group survived well with angiogenesis. On the 14th day post transplantation, the skin grafts of mice in BMSCs alone group showed extensive infiltration of inflammatory cells, severe epidermal degeneration and focal necrosis; the skin grafts of mice in BMSCs+ IL-17 group showed focal infiltration of inflammatory cells and slight epidermal degeneration; the skin grafts of mice in PBS control group were completely necrotic. IL-17 can reduce the immune rejection in allogeneic skin grafting and prolong the survival time of mouse skin grafts by improving mice BMSCs' capabilities to induce immune tolerance and enhancing the homing ability of BMSCs.
探讨白细胞介素-17(IL-17)修饰的小鼠骨髓间充质干细胞(BMSCs)对小鼠同种异体皮肤移植的影响及机制。(1)处死后从5只BALB/c小鼠(均为雌性,4至8周龄,下同)分离股骨、胫骨和肱骨。采用全骨髓密度梯度离心结合贴壁分离法分离、纯化和培养BMSCs。取第3代细胞进行形态学观察及成脂和成骨分化鉴定。取第4代细胞鉴定干细胞表面标志物的表达。将BMSCs第3至6代用终质量浓度为50 ng/mL的小鼠重组IL-17预处理5天,然后收获进行形态学观察。用羰花青荧光染料(CM-Dil)标记后,获取IL-17预处理的BMSCs和未预处理的BMSCs进行形态学观察并计算标记率。(2)将45只C57BL/6J小鼠按随机数字表分为磷酸盐缓冲液(PBS)对照组(n = 13)、单纯BMSCs组(n = 16)和BMSCs + IL-17组(n = 16)。在小鼠皮肤移植前1天,将0.1 mL未用CM-Dil标记的BMSCs(5×10⁶个细胞/mL)经尾静脉注射到单纯BMSCs组的13只小鼠中,将0.1 mL用CM-Dil标记的BMSCs(5×10⁶个细胞/mL)经尾静脉注射到单纯BMSCs组的另外3只小鼠中。将0.1 mL未用CM-Dil标记的IL-17预处理的BMSCs(5×10⁶个细胞/mL)经尾静脉注射到BMSCs + IL-17组的13只小鼠中,将0.1 mL用CM-Dil标记的IL-17预处理的BMSCs(5×10⁶个细胞/mL)经尾静脉注射到BMSCs + IL-17组的另外3只小鼠中。将0.1 mL PBS经尾静脉注射到PBS对照组的13只小鼠中。取45只BALB/c小鼠作为供体,3组中45只处理后的C57BL/6J小鼠作为受体,建立背靠背全层皮肤移植模型。移植后第2天,再次向每组受体小鼠注射相同数量的相应细胞和等量的PBS。移植后第7天,处死单纯BMSCs组中3只注射了CM-Dil标记的BMSCs的小鼠和BMSCs + IL-17组中3只注射了CM-Dil标记的IL-17预处理的BMSCs的小鼠,通过荧光显微镜追踪CM-Dil标记的BMSCs并计数。移植后第6天换药时,分别从单纯BMSCs组中13只注射未用CM-Dil标记的BMSCs的小鼠、BMSCs + IL-17组中13只注射未用CM-Dil标记的IL-17预处理的BMSCs的小鼠以及PBS对照组的13只小鼠中各选取7只记录皮肤移植存活时间。移植后第8天,每组剩余6只小鼠中的3只用于对移植皮肤进行大体观察,采用酶联免疫吸附测定法检测血清干扰素-γ、IL-10和转化生长因子β(TGF-β)水平,用流式细胞仪检测脾脏中CD4⁺CD25⁺叉头/翼状螺旋转录因子p3(Foxp3)⁺调节性T细胞(Tregs)的百分比,并用苏木精伊红染色对移植皮肤进行组织病理学观察。每组其余3只小鼠在移植后第14天也进行上述组织病理学观察。数据采用独立样本t检验、单因素方差分析和最小显著差检验进行统计学分析。(1)培养第5天时,IL-17预处理的BMSCs与未预处理者在形态和大小上无显著差异。(2)CM-Dil标记后,BMSCs和IL-17预处理的BMSCs生长良好,标记率近100%。(3)移植后第7天,单纯BMSCs组小鼠皮肤及相邻皮下组织每100倍视野中有6.2±2.6个CM-Dil标记的BMSCs,明显少于BMSCs + IL-17组的15.0±5.3个/100倍视野(t = -2.962,P < 0.05)。(4)单纯BMSCs组和BMSCs + IL-17组小鼠皮肤移植存活时间分别为(13.3±1.2)天和(17.0±1.5)天,明显长于PBS对照组的(8.7±0.8)天(P < 0.01),且BMSCs + IL-17组小鼠皮肤移植存活时间明显长于单纯BMSCs组(P < 0.01)。(5)移植后第8天,PBS对照组小鼠的大多数移植皮肤变黑结痂坏死。单纯BMSCs组小鼠的大多数移植皮肤存活良好,而BMSCs + IL-17组小鼠的所有移植皮肤均存活良好。(6)移植后第8天,与PBS对照组相比,单纯BMSCs组和BMSCs + IL-17组小鼠血清IL-10和TGF-β水平明显升高(P < 0.01),血清干扰素-γ水平明显降低(P < 0.01)。与单纯BMSCs组相比,BMSCs + IL-17组小鼠血清IL-10和TGF-β水平明显升高(P < 0.01),血清干扰素-γ水平明显降低(P < 0.01)。(7)移植后第8天,单纯BMSCs组和BMSCs + IL-17组小鼠脾脏中CD4⁺CD25⁺Foxp3⁺Tregs的百分比明显高于PBS对照组(P < 0.01),且BMSCs + IL-17组小鼠脾脏中CD4⁺CD25⁺Foxp3⁺Tregs的百分比明显高于单纯BMSCs组(P < 0.01)。(8)移植后第8天,PBS对照组小鼠移植皮肤中发现大量炎性细胞浸润及表皮和真皮坏死;单纯BMSCs组小鼠移植皮肤中有局灶性炎性细胞浸润及轻度表皮退变;BMSCs + IL-17组小鼠移植皮肤的皮肤附属器存活良好且有血管生成。移植后第14天,单纯BMSCs组小鼠移植皮肤有广泛炎性细胞浸润、严重表皮退变和局灶性坏死;BMSCs + IL-17组小鼠移植皮肤有局灶性炎性细胞浸润及轻度表皮退变;PBS对照组小鼠移植皮肤完全坏死。IL-17可通过提高小鼠BMSCs诱导免疫耐受的能力和增强BMSCs的归巢能力,减轻同种异体皮肤移植中的免疫排斥反应,延长小鼠皮肤移植存活时间。
