Objective: To investigate the feasibility of in vitro inflammatory wound microenvironment simulated by using inflammatory wound tissue homogenate of mice. Methods: (1) Ten eight-week-old C57BL/6 male mice were collected and full-thickness skin tissue with diameter of 1.0 cm on both sides of the midline of the back was taken with a perforator to make the normal skin tissue homogenate supernatant. At 48 h after the full-thickness skin defect wound was established, the wound tissue within 2 mm from the wound edge was taken to make inflammatory wound tissue homogenate supernatant. Two kinds of tissue homogenate supernatant were taken to adjust the total protein concentration to 1 mg/mL, and the tumor necrosis factor α (TNF-α) content was detected by enzyme-linked immunosorbent assay. The number of sample was 6. (2) The primary passage of human umbilical cord mesenchymal stem cells (hUCMSCs) were collected and cultured to the 3rd passage with the normal exosomes being extracted from the hUCMSCs after cultured for 48 h. Another batch of hUCMSCs in the 3rd passage was collected and stimulated with inflammatory wound tissue homogenate supernatant of 30, 50, and 100 μg/mL total protein and normal skin tissue homogenate supernatant of 30, 50, and 100 μg/mL total protein, respectively. After cultured for 48 h, the exosomes stimulated with normal protein of 30, 50, and 100 μg/mL and exosomes stimulated with inflammatory protein of 30, 50, and 100 μg/mL were extracted. Normal exosomes, exosomes stimulated with 30 μg/mL normal protein, and exosomes stimulated with 30 μg/mL inflammatory protein were collected, the morphology was observed by transmission electron microscope, the particle size was detected by nanoparticle tracking analyzer, and the expressions of CD9 and CD63 were detected by Western blotting. (3) Twenty one-day-old C57BL/6 mice were taken to isolate the primary passage of fibroblasts (Fbs) and the 3rd passage of Fbs, whose morphology was observed under the inverted phase contrast microscope. The Fbs of 3rd passage were collected to observe the expression of vimentin by cell crawling method combined with immunofluorescence method at culture hour (CH) 2. (4) The Fbs of 3rd passage were divided into control group, normal exosome group, 30, 50, 100 μg/mL normal protein stimulating exosome group, and 30, 50, 100 μg/mL inflammatory protein stimulating exosome group according to the random number table, with 4 wells in each group. Cells in control group received no treatment, and cells in the other 7 groups were respectively added with normal exosomes, exosomes stimulated with normal protein of 30, 50, and 100 μg/mL, and exosomes stimulated with inflammatory protein of 30, 50, and 100 μg/mL prepared in experiment (2). The final mass concentration of exosomes was adjusted to 10 μg/mL. The cell viability was detected by cell count kit 8 at CH 48. (5) Two batches of Fbs in the 3rd passage were divided and treated as those in experiment (4), with 4 wells in each group, and the final mass concentration of exosomes was adjusted to 1 and 10 μg/mL, respectively. The cell mobility was detected by cell scratch test at CH 6, 12, and 24. (6) Two batches of the Fbs of 3rd passage were collected, divided, and treated as those in experiment (4) except with no control group, with 3 wells in each group, and the final mass concentration of exosomes was respectively adjusted to 1 and 10 μg/mL. The mRNA expression levels of transforming growth factor β(1) (TGF-β(1)), TGF-β(3), and α smooth muscle actin (α-SMA) were detected by real-time fluorescent quantitative reverse transcription polymerase chain reaction at CH 48. Data were statistically analyzed with analysis of variance for repeated measurement, one-way analysis of variance, and Bonferroni method. Results: (1) The content of TNF-α in inflammatory wound tissue homogenate supernatant of mice was (116±3) pg/mL, significantly higher than (97±5) pg/mL in normal skin tissue homogenate supernatant at post injury hour 48 (t=3.306, P<0.05). (2) Normal exosomes, exosomes stimulated with 30 μg/mL normal protein, and exosomes stimulated with 30 μg/mL inflammatory protein of hUCMSCs showed the typical saucer-like shape. The particle sizes of the three exosomes of hUCMSCs were 30-150 nm, which were all within the normal particle size range of exosome. Three exosomes of hUCMSCs positively expressed CD9 and CD63. (3) The primary passage of cells were clearly defined and showed protruding spindle shape, irregular polygon shape, or slender strip shape. The morphology of the 3rd and the primary passage of cells is similar. At CH 2, vimentin in cells was positively expressed, and the cells were identified as Fbs. (4) At CH 48, the cell viability was (137.4±2.8)% in 30 μg/mL inflammatory protein stimulating exosome group, obviously higher than 100%, (107.5±2.4)%, (113.3±3.2)%, (104.0±2.0)%, and (101.9±1.5)% in control group, normal exosome group, 30 μg/mL normal protein stimulating exosome group, and 50 and 100 μg/mL inflammatory protein stimulating exosome groups, respectively (P<0.01), and cell viability in 30 μg/mL normal protein stimulating exosome group was obviously higher than that in control group, normal exosome group, and 50 and 100 μg/mL normal protein stimulating exosome groups [(103.4±2.2)% and (102.5±1.4)%], respectively (P<0.01). (5) At CH 6, 12, and 24, the mobility rate of cells in 30 μg/mL inflammatory protein stimulating exosome group was significantly higher than that in control group, normal exosome group, 30 μg/mL normal protein stimulating exosome group, and 50 and 100 μg/mL inflammatory protein stimulating exosome groups, respectively, when the final mass concentrations of exosome was 1 μg/mL (P<0.05) . At CH 12, the mobility rate of cells in 30 μg/mL normal protein stimulating exosome group was obviously higher than that in control group, normal exosome group, and 50 and 100 μg/mL normal protein stimulating exosome groups, respectively, when the final mass concentration of exosome was 1 μg/mL (P<0.05). At CH 6, the mobility rate of cells in 30 μg/mL inflammatory protein stimulating exosome group was significantly higher than that in control group and normal exosome group (P<0.05), and the mobility rate of cells in 30 μg/mL normal protein stimulating exosome group was significantly higher than that in 50 and 100 μg/mL normal protein stimulating exosome groups, respectively, when the final mass concentration of exosome was 10 μg/mL (P<0.05). At CH 12 and 24, the mobility rate of cells in 30 μg/mL inflammatory protein stimulating exosome group was significantly higher than that in control group, normal exosome group, and 50 and 100 μg/mL inflammatory protein stimulating exosome groups (P<0.05), and the mobility rate of cells in 30 μg/mL normal protein stimulating exosome group was significantly higher than that in control group, normal exosome group, and 50 and 100 μg/mL normal protein stimulating exosome groups, respectively, when the final mass concentration of exosome was 10 μg/mL (P<0.05). (6) There were no statistically significant differences in mRNA expression levels of TGF-β(1), TGF-β(3), and α-SMA of cells among the 7 groups at CH 48 when the final mass concentration of exosome was 1 μg/mL (F=1.123, 1.537, 1.653, P>0.05). There were no statistically significant differences in mRNA expression levels of TGF-β(1) and α-SMA of cells among the 7 groups at CH 48 when the final mass concentration of exosome was 10 μg/mL (F=1.487, 1.308, P>0.05), and mRNA expression level of TGF-β(3) of cells in 50 μg/mL inflammatory protein stimulating exosome group at CH 48 was significantly higher than that in normal exosome group, 50 μg/mL normal protein stimulating exosome group, and 30 and 100 μg/mL inflammatory protein stimulating exosome groups when the final mass concentration of exosome was 10 μg/mL (P<0.05). Conclusions: The pretreatment with inflammatory wound tissue homogenate supernatant of mice has no significant effect on the total protein of hUCMSCs exosomes. The hUCMSCs exosomes stimulated by low concentration inflammatory wound tissue homogenate supernatant can significantly promote the proliferation and migration ability of Fbs. The content of inflammatory mediators in the wound tissue homogenate supernatant during the inflammatory phase is extremely low, which may be the reason that the anti-inflammation and tissue repair paracrine effects of mesenchymal stem cell cannot be effectively started.
目的: 探讨小鼠炎症创面组织匀浆体外模拟创面炎症微环境的可行性。 方法: (1)取10只8周龄C57BL/6雄性小鼠,在背部中线两侧用打孔器各取直径1.0 cm的圆形全层皮肤组织,制作正常皮肤组织匀浆上清液。形成全层皮肤缺损创面48 h后,取距创缘2 mm内创面组织,制作炎症创面组织匀浆上清液。取2种组织匀浆上清液,调整总蛋白质量浓度为1 mg/mL,酶联免疫吸附测定法检测肿瘤坏死因子α(TNF-α)含量,样本数为6。(2)取原代人脐带间充质干细胞(hUCMSC)并培养至第3代,培养48 h后提取正常外泌体。另外取第3代hUCMSC,分别加入总蛋白质量浓度为30、50、100 μg/mL正常皮肤组织匀浆上清液和炎症创面组织匀浆上清液,培养48 h后,提取30、50、100 μg/mL正常蛋白刺激外泌体和30、50、100 μg/mL炎症蛋白刺激外泌体。取正常外泌体、30 μg/mL正常蛋白刺激外泌体和30 μg/mL炎症蛋白刺激外泌体,透射电子显微镜下观察外泌体形态,纳米颗粒跟踪分析仪检测外泌体粒径,蛋白质印迹法检测CD9和CD63表达。(3)取1 d龄C57BL/6小鼠乳鼠20只,分离培养原代成纤维细胞(Fb)和第3代Fb,倒置相差显微镜下观察细胞形态。取第3代Fb,培养2 h,利用细胞爬片法结合免疫荧光法观察波形蛋白的表达。(4)取第3代Fb,按随机数字表法分为对照组,正常外泌体组,30、50、100 μg/mL正常蛋白刺激外泌体组及30、50、100 μg/mL炎症蛋白刺激外泌体组,每组4孔。对照组不进行任何处理,其余7组依次加入实验(2)中制备的正常外泌体,30、50、100 μg/mL正常蛋白刺激外泌体和30、50、100 μg/mL炎症蛋白刺激外泌体,并调整外泌体终质量浓度为10 μg/mL。培养48 h,采用细胞计数试剂盒8法检测8组细胞活力。(5)取2个批次第3代Fb,同实验(4)进行分组及处理,每组4孔,并分别调整外泌体终质量浓度为1、10 μg/mL,采用细胞划痕试验检测培养6、12、24 h细胞迁移率。(6)取2个批次第3代Fb,同实验(4)进行分组及处理,但不设置对照组,每组3孔,并调整外泌体终质量浓度为1、10 μg/mL,实时荧光定量反转录PCR法检测培养48 h转化生长因子β(1)(TGF-β(1))、TGF-β(3)、α平滑肌肌动蛋白(α-SMA)的mRNA表达。对数据行重复测量方差分析、单因素方差分析及Bonferroni法。 结果: (1)伤后48 h,小鼠炎症创面组织匀浆上清液中TNF-α含量为(116±3)pg/mL,显著高于正常皮肤组织匀浆上清液的(97±5)pg/mL,t=3.306,P<0.05。(2)hUCMSC正常外泌体、30 μg/mL正常蛋白刺激外泌体、30 μg/mL炎症蛋白刺激外泌体均呈典型茶托样;3种hUCMSC外泌体粒径为30~150 nm,均在外泌体正常粒径范围内;3种hUCMSC外泌体CD9和CD63均呈阳性表达。(3)原代细胞轮廓清晰,呈突起的纺锤形、不规则多角形或细长条状;第3代细胞形态与原代细胞相近。培养2 h,细胞中波形蛋白呈阳性表达,细胞鉴定为Fb。(4)培养48 h,30 μg/mL炎症蛋白刺激外泌体组细胞活力为(137.4±2.8)%,明显高于对照组的100%、正常外泌体组的(107.5±2.4)%、30 μg/mL正常蛋白刺激外泌体组的(113.3±3.2)%及50、100 μg/mL炎症蛋白刺激外泌体组的(104.0±2.0)%、(101.9±1.5)%,P<0.01, 30 μg/mL正常蛋白刺激外泌体组细胞活力明显高于对照组、正常外泌体组及50、100 μg/mL正常蛋白刺激外泌体组[(103.4±2.2)%、(102.5±1.4)%],P<0.01。(5)外泌体终质量浓度为1 μg/mL时,培养6、12、24 h,30 μg/mL炎症蛋白刺激外泌体组细胞迁移率明显高于对照组、正常外泌体组、30 μg/mL正常蛋白刺激外泌体组及50、100 μg/mL炎症蛋白刺激外泌体组(P<0.05);培养12 h,30 μg/mL正常蛋白刺激外泌体组细胞迁移率明显高于对照组、正常外泌体组以及50、100 μg/mL正常蛋白刺激外泌体组(P<0.05)。外泌体终质量浓度10 μg/mL时,培养6 h,30 μg/mL炎症蛋白刺激外泌体组细胞迁移率明显高于对照组、正常外泌体组(P<0.05);30 μg/mL正常蛋白刺激外泌体组细胞迁移率明显高于50、100 μg/mL正常蛋白刺激外泌体组(P<0.05)。培养12、24 h,30 μg/mL炎症蛋白刺激外泌体组细胞迁移率明显高于对照组、正常外泌体组及50、100 μg/mL炎症蛋白刺激外泌体组(P<0.05);30 μg/mL正常蛋白刺激外泌体组细胞迁移率明显高于对照组、正常外泌体组及50、100 μg/mL正常蛋白刺激外泌体组(P<0.05)。(6)外泌体终质量浓度1 μg/mL时,7组细胞培养48 h TGF-β(1)、TGF-β(3)、α-SMA mRNA表达量组间总体比较,差异无统计学意义(F=1.123、1.537、1.653,P>0.05)。外泌体终质量浓度为10 μg/mL时,培养48 h,7组细胞TGF-β(1)、α-SMA mRNA表达量组间总体比较,差异无统计学意义(F=1.487、1.308,P>0.05)。50 μg/mL炎症蛋白刺激外泌体组细胞培养48 h TGF-β(3) mRNA表达量明显高于正常外泌体组、50 μg/mL正常蛋白刺激外泌体组及30、100 μg/mL炎症蛋白刺激外泌体组(P<0.05)。 结论: 小鼠炎症创面组织匀浆上清液预处理对hUCMSC外泌体的总蛋白含量无影响,低浓度炎症创面组织匀浆上清液刺激所得的hUCMSC外泌体能够上调Fb的增殖和迁移能力,但炎症创面组织匀浆上清液中的炎症介质含量过低,不足以有效启动间充质干细胞抗炎及组织修复旁分泌效应。.
Keywords: Exosomes; Fibroblasts; Human umbilical cord mesenchymal stem cells; Inflammation; Microenvironment; Tissue homogenate.