Objective: To explore the influence of pH value on tube formation of human dermal microvascular endothelial cells (HDMECs) and study its molecular mechanism, so as to provide theoretical basis for the study of promoting angiogenesis in the process of wound healing. Methods: The experimental study methods were applied. HDMECs of 4 or 5 passages in the logarithmic growth phase were collected for experiments. Culture mediums with pH values of 6.4, 6.6, 6.8, 7.0, 7.2, 7.4, 7.6, and 7.8 were prepared, and the cells were adaptively cultured (the same culture method below) for 24 h before further experiments being carried out. After another 36 h of culture, the relative fluorescence value of cytoplasmic pH value was measured by flow cytometry, and the correlation analysis between the relative fluorescence value of cytoplasmic pH value and the medium pH value was carried out. After another 1.5, 2.5, 3.5, 4.5, and 5.5 days of culture, the cell proliferation activity was detected with cell counting kit 8. OrisTM cell migration detection kit was used to detect the remaining area of cell migration at 0 (immediately), 24, and 48 h after removing the cell seeding stopper. Three-dimensional stromal gel cell tube formation experiment was carried out to detect the lumen diameter of tube formed by cells after another 48 h of culture. The protein expressions of phosphorylation sites 473 and 308 of protein kinase B (Akt) were detected by Western blotting after another 48 h of culture. The sample number was 3. Data were statistically analyzed with Pearson correlation analysis, one-way analysis of variance, analysis of variance for factorial design, analysis of variance for repeated measurement, and Bonferroni correction. Results: After another 36 h of culture, the relative fluorescence values of cytoplasmic pH value of cells cultured in pH 6.8-7.8 mediums were significantly higher than the level in pH 6.4 medium (P<0.05); compared with those in pH 6.6-7.0 mediums, the relative fluorescence values of cytoplasmic pH value of cells cultured in pH 7.4-7.8 mediums were significantly increased (P<0.05), and the relative fluorescence value of cytoplasmic pH value of cells cultured in pH 6.6 medium was significantly lower than that in pH 7.0 or 7.2 mediun (with P values all <0.05); the relative fluorescence values of cytoplasmic pH value of cells cultured in pH 7.6 and 7.8 mediums were significantly higher than those in pH 7.2 and 7.4 mediums (P<0.05). The relative fluorescence value of cytoplasmic pH value was significantly positively correlated with the medium pH value (r=0.99, P<0.05). The proliferation activity was similar among cells cultured in 8 mediums of different pH values for another 1.5 days (P>0.05). After another 2.5 days of culture, the proliferation activity of cells cultured in pH 6.4-6.8 mediums was significantly decreased compared with that in pH 7.6 medium (P<0.05). After another 3.5 days of culture, the proliferation activity of cells cultured in pH 7.0-7.8 mediums was significantly higher than that in pH 6.4-6.8 mediums (P<0.05); compared with that in pH 7.6 medium, the proliferation activity of cells cultured in pH 7.0-7.4 and 7.8 mediums was significantly decreased (P<0.05). After another 4.5 or 5.5 days of culture, the proliferation activity of cells cultured in pH 6.8-7.8 mediums was significantly higher than that in pH 6.4 medium (P<0.05); compared with that in pH 6.6 and 6.8 mediums, the proliferation activity of cells cultured in pH 7.0-7.8 mediums was significantly increased (P<0.05). After another 4.5 days of culture, the proliferation activity of cells cultured in pH 7.6 medium was significantly higher than that in pH 7.0 medium (P<0.05). After another 5.5 days of culture, the proliferation activity of cells cultured in pH 7.2-7.6 mediums was significantly increased compared with that in pH 7.0 medium (P<0.05); the proliferation activity of cells cultured in pH 7.2 and 7.4 mediums was significantly lower than that in pH 7.6 medium (with P values all <0.05) but significantly higher than that in pH 7.6 medium (with P values all <0.05). Immediately after removing the cell seeding stopper, the remaining migration areas were similar among cells cultured in 8 mediums of different pH values (P>0.05). At 24 h after removing the cell seeding stopper, the remaining migration areas of cells cultured in pH 6.6-7.8 mediums were significantly smaller than the area in pH 6.4 medium (P<0.05); compared with those in pH 6.6 and 6.8 mediums, the remaining migration areas of cells cultured in pH 7.0 to 7.6 mediums were significantly reduced (P<0.05). At 48 h after removing the cell seeding stopper, compared with those in pH 6.4 and 6.6 mediums, the remaining migration areas of cells cultured in pH 7.0-7.8 mediums were significantly reduced (P<0.05); the remaining migration areas of cells cultured in pH 7.2 and 7.4 mediums were significantly smaller than those in pH 6.8, 7.0, and 7.8 mediums (P<0.05) but significantly larger than the area in pH 7.6 medium (P<0.05); the remaining migration area of cells cultured in pH 7.6 medium was significantly smaller than that in pH 6.8 or 7.8 medium (with P values all <0.05). After another 48 h of culture, the lumen diameters of tubes formed by cells cultured in pH 7.0, 7.2, 7.4, 7.6, and 7.8 mediums were (5.0±0.5), (7.6±0.9), (8.5±0.7), (11.0±0.8), and (5.3±0.8) μm, respectively, which were significantly longer than (2.8±0.8) μm in pH 6.4 medium (P<0.05); the lumen diameters of tubes formed by cells cultured in pH 6.6 ((4.2±0.3) μm), 6.8 ((4.5±0.6) μm), 7.0, and 7.8 mediums were significantly shorter than the diameter in pH 7.6 medium (P<0.05). After another 48 h of culture, compared with those in pH 6.4 and 6.6 mediums, the protein expressions of Akt phosphorylation sites 473 and 308 of cells cultured in pH 6.8 to 7.8 mediums were significantly increased (P<0.05). Moreover, the protein expression of Akt phosphorylation site 308 of cells cultured in pH 6.6 medium was significantly higher than that in pH 6.4 medium (P<0.05); compared with the expression in pH 6.8 medium, the protein expressions of Akt phosphorylation site 473 of cells cultured in pH 7.0 and 7.4-7.8 mediums were significantly increased (P<0.05); compared with the expression in pH 7.6 medium, the protein expressions of Akt phosphorylation site 473 of cells cultured in pH 7.0-7.4 and 7.8 mediums were significantly decreased (P<0.05); compared with the expression in pH 7.8 medium, the protein expressions of Akt phosphorylation site 308 of cells cultured in pH 7.0 to 7.6 mediums were significantly increased (P<0.05). Conclusions: pH value can regulate the lumen diameter of HDMEC-formed capillaries, which is closely related to the activation of Akt. 7.2-7.6 is the appropriate pH value for constructing tissue engineered capillaries.
目的: 探讨pH值对人真皮微血管内皮细胞(HDMEC)成管的影响并研究其分子机制,为促进创面愈合过程中血管新生的研究提供理论依据。 方法: 采用实验研究方法。取第4、5代对数生长期HDMEC进行实验,制备pH值分别为6.4、6.6、6.8、7.0、7.2、7.4、7.6、7.8的培养液,用其适应性培养细胞(培养方式下同)24 h后进行后续实验。另培养36 h,采用流式细胞仪测定胞质pH值的相对荧光值并对胞质pH值的相对荧光值与培养液pH值进行相关分析。另培养1.5、2.5、3.5、4.5、5.5 d,采用细胞计数试剂盒8检测细胞增殖活性。采用OrisTM细胞迁移检测试剂盒检测去掉播种塞后0(即刻)、24、48 h细胞迁移剩余面积。进行三维基质胶细胞成管实验,检测另培养48 h细胞成管的管腔直径。另培养48 h,采用蛋白质印迹法检测细胞中蛋白激酶B(Akt)磷酸化位点473、308的蛋白表达。样本数均为3。对数据行Pearson相关性分析、单因素方差分析、析因设计方差分析、重复测量方差分析与Bonferroni校正。 结果: 另培养36 h,与pH值6.4培养液相比,pH值6.8~7.8培养液培养细胞胞质pH值的相对荧光值均显著升高(P<0.05);与pH值6.6~7.0培养液相比,pH值7.4~7.8培养液培养细胞胞质pH值的相对荧光值均显著升高(P<0.05),且pH值6.6培养液培养细胞胞质pH值的相对荧光值明显低于pH值7.0、7.2培养液(P值均<0.05);pH值7.6、7.8培养液培养细胞胞质pH值的相对荧光值均显著高于pH值7.2、7.4培养液(P<0.05)。胞质pH值的相对荧光值与培养液pH值呈显著正相关(r=0.99,P<0.05)。8种pH值培养液另培养1.5 d细胞增殖活性相近(P>0.05)。另培养2.5 d,与pH值7.6培养液相比,pH值6.4~6.8培养液培养细胞增殖活性均显著下降(P<0.05)。另培养3.5 d,与pH值6.4~6.8培养液相比,pH值7.0~7.8培养液培养细胞增殖活性均显著升高(P<0.05);与pH值7.6培养液相比,pH值7.0~7.4、7.8培养液培养细胞增殖活性均显著下降(P<0.05)。另培养4.5、5.5 d,与pH值6.4培养液相比,pH值6.8~7.8培养液培养细胞增殖活性均显著升高(P<0.05);与pH值6.6、6.8培养液相比,pH值7.0~7.8培养液培养细胞增殖活性均显著升高(P<0.05)。另培养4.5 d,pH值7.6培养液培养细胞增殖活性显著高于pH值7.0培养液(P<0.05)。另培养5.5 d,与pH值7.0培养液相比,pH值7.2~7.6培养液培养细胞增殖活性均显著升高(P<0.05);与pH值7.2、7.4培养液相比,pH值7.6培养液培养细胞增殖活性显著升高(P值均<0.05),pH值7.8培养液培养细胞增殖活性显著降低(P值均<0.05)。去掉播种塞后0 h,8种pH值培养液培养细胞迁移剩余面积相近(P>0.05)。去掉播种塞后24 h,与pH值6.4培养液相比,pH值6.6~7.8培养液培养细胞迁移剩余面积均显著缩小(P<0.05);与pH值6.6、6.8培养液相比,pH值7.0~7.6培养液培养细胞迁移剩余面积均显著缩小(P<0.05)。去掉播种塞后48 h,与pH值6.4、6.6培养液相比,pH值7.0~7.8培养液培养细胞迁移剩余面积均显著缩小(P<0.05);pH值7.2、7.4培养液培养细胞迁移剩余面积均显著小于pH值6.8、7.0、7.8培养液(P<0.05),均显著大于pH值7.6培养液(P<0.05);pH值7.6培养液培养细胞迁移剩余面积显著小于pH值6.8、7.8培养液(P值均<0.05)。另培养48 h,pH值7.0、7.2、7.4、7.6、7.8培养液培养细胞成管的管腔直径分别为(5.0±0.5)、(7.6±0.9)、(8.5±0.7)、(11.0±0.8)、(5.3±0.8)μm,均显著长于pH值6.4培养液的(2.8±0.8)μm(P<0.05);pH值6.6[(4.2±0.3)μm]、6.8[(4.5±0.6)μm]、7.0、7.8培养液培养细胞成管的管腔直径均显著短于pH值7.6培养液(P<0.05)。另培养48 h,与pH值6.4、6.6培养液相比,pH值6.8~7.8培养液培养细胞中Akt磷酸化位点473、308蛋白表达均明显升高(P<0.05),且pH值6.6培养液培养细胞中Akt磷酸化位点308蛋白表达明显高于pH值6.4培养液(P<0.05);与pH值6.8培养液相比,pH值7.0、7.4~7.8培养液培养细胞中Akt磷酸化位点473蛋白表达均明显升高(P<0.05);与pH值7.6培养液相比,pH值7.0~7.4、7.8培养液培养细胞中Akt磷酸化位点473蛋白表达均明显降低(P<0.05);与pH值7.8培养液相比,pH值7.0~7.6培养液培养细胞中Akt磷酸化位点308蛋白表达均明显升高(P<0.05)。 结论: pH值可调控HDMEC形成毛细血管的管腔直径,该调控作用与Akt的激活密切相关;7.2~7.6为构建组织工程毛细血管的适宜pH值。.