Objective: To explore the effects of decline of pH value on cardiomyocyte viability of rats, and to analyze the possible mechanism. Methods: Hearts of five newborn Sprague-Dawley rats were isolated, and then primary cardiomyocytes were cultured and used in the following experiments. (1) The primary cardiomyocytes were divided into pH 7.4+ 6 h, pH 7.0+ 6 h, pH 6.5+ 6 h, pH 6.0+ 6 h, pH 6.5+ 1 h, and pH 6.5+ 3 h groups according to the random number table, with 4 wells in each group. After being routinely cultured for 48 h (similarly hereinafter), cells in pH 7.4+ 6 h, pH 7.0+ 6 h, pH 6.5+ 6 h, and pH 6.0+ 6 h groups were cultured with pH 7.4, pH 7.0, pH 6.5, and pH 6.0 DMEM-F12 medium (similarly hereinafter), respectively, and then they were cultured for 6 h. Cells in pH 6.5+ 1 h and pH 6.5+ 3 h groups were cultured with pH 6.5 medium, and then they were cultured for 1 h and 3 h, respectively. Viability of cells was detected by methyl-thiazolyl-tetrazolium (MTT) method. (2) The primary cardiomyocytes were divided into pH 7.4, pH 6.5, and pH 6.5+ taxol groups according to the random number table, with 2 wells in each group. Cells in pH 7.4 group were cultured with pH 7.4 medium, while cells in pH 6.5 and pH 6.5+ taxol groups were cultured with pH 6.5 medium. Cells in pH 6.5+ taxol group were added with taxol of a final molarity of 0.2 μmol/L in addition, and then they were cultured for 6 h. Morphology and density of microtubule of cells was detected by immunofluorescence assay. (3) The primary cardiomyocytes were grouped and treated as in experiment (2), with 2 wells in each group. The expressions of polymerized microtubulin and free microtubulin were determined with Western blotting. (4) The primary cardiomyocytes were grouped and treated as in experiment (2), with 4 wells in each group. Viability of cells after treated with taxol was detected by MTT method. Data were processed with one-way analysis of variance and LSD-t test. Results: (1) The viability of cells in pH 7.4+ 6 h, pH 7.0+ 6 h, pH 6.5+ 6 h, pH 6.0+ 6 h, pH 6.5+ 1 h, and pH 6.5+ 3 h groups were 1.00±0.08, 0.90±0.08, 0.85±0.06, 0.83±0.04, 0.91±0.10, and 0.89±0.10, respectively. Compared with that in pH 7.4+ 6 h group, viability of cells in pH 7.0+ 6 h, pH 6.5+ 6 h, pH 6.0+ 6 h, pH 6.5+ 1 h, and pH 6.5+ 3 h groups were all decreased in different degrees (t=2.476, 4.002, 4.996, 2.168, 2.400, P<0.05). (2) Microtubules of cells in pH 7.4 group were radially distributed around the nucleus with clear tubular structure. Compared with that in pH 7.4 group, the skeleton of microtubules of cells in pH 6.5 group was obviously damaged, with broken structure of microtubule and reduced density. Compared with that in pH 6.5 group, the damage degree of microtubules of cells in pH 6.5+ taxol group was obviously alleviated, and the structure of microtubules basically returned to normal. (3) Compared with that in pH 7.4 group, the expression of free microtubulin of cells in pH 6.5 group was significantly increased (t=3.030, P<0.05), while the expression of polymerized microtubulin of cells was significantly decreased (t=8.604, P<0.05). Compared with that in pH 6.5 group, the expression of free microtubulin of cells in pH 6.5+ taxol group was significantly decreased (t=4.559, P<0.05), while the expression of polymerized microtubulin of cells was significantly increased (t=5.472, P<0.05). (4) Viability of cells in pH 7.4, pH 6.5, and pH 6.5+ taxol groups were 1.00±0.10, 0.83±0.04, and 0.93±0.10, respectively. Compared with that in pH 7.4 group, the viability of cells in pH 6.5 group was obviously declined (t=4.412, P<0.05). Compared with that in pH 6.5 group, the viability of cells in pH 6.5+ taxol group was obviously increased (t=2.461, P<0.05). Conclusions: The decline of pH value reduces the viability of cardiomyocytes of rats through destroying the skeleton of microtubule. Stabilizing microtubule skeleton can significantly reduce acidic treatment-induced damage and ameliorate cardiomyocyte viability.
目的: 探讨pH值降低对大鼠心肌细胞活力的影响并分析其可能机制。 方法: 取新生SD大鼠5只,分离心脏培养原代心肌细胞,进行以下实验。(1)取原代心肌细胞,按照随机数字表法分为pH值7.4+6 h组、pH值7.0+6 h组、pH值6.5+6 h组、pH值6.0+6 h组、pH值6.5+1 h组和pH值6.5+3 h组,每组4孔。pH值7.4+6 h组、pH值7.0+6 h组、pH值6.5+6 h组、pH值6.0+6 h组细胞常规培养48 h后(下同)分别更换pH值为7.4、7.0、6.5、6.0的DMEM-F12(下同)培养基,培养6 h;pH值6.5+1 h组、pH值6.5+3 h组细胞更换pH值为6.5的培养基,分别培养1、3 h。噻唑蓝法检测细胞活力。(2)取原代心肌细胞,按照随机数字表法分为pH值7.4组、pH值6.5组和pH值6.5+紫杉醇组,每组2孔。pH值7.4组细胞更换pH值为7.4培养基,pH值6.5组和pH值6.5+紫杉醇组细胞更换pH值为6.5培养基,pH值6.5+紫杉醇组细胞另加入终物质的量浓度为0.2 μmol/L紫杉醇,培养6 h。免疫荧光法检测细胞微管形态及密度。(3)取原代心肌细胞,同实验(2)分组处理,每组2孔,蛋白质印迹法检测细胞聚合态和游离态微管蛋白表达。(4)取原代心肌细胞,同实验(2)分组处理,每组4孔,噻唑蓝法检测紫杉醇处理后细胞活力。对数据行单因素方差分析、LSD-t检验。 结果: (1)pH值7.4+6 h组、pH值7.0+6 h组、pH值6.5+6 h组、pH值6.0+6 h组、pH值6.5+1 h组、pH值6.5+3 h组细胞活力分别为1.00±0.08、0.90±0.08、0.85±0.06、0.83±0.04、0.91±0.10、0.89±0.10。与pH值7.4+6 h组比较,pH值7.0+6 h组、pH值6.5+6 h组、pH值6.0+6 h组、pH值6.5+1 h组、pH值6.5+3 h组细胞活力均有不同程度下降(t=2.476、4.002、4.996、2.168、2.400,P<0.05)。(2)pH值7.4组细胞微管围绕细胞核呈放射状分布,管状结构清晰;与pH值7.4组比较,pH值6.5组细胞微管骨架破坏明显,表现为管状结构中断、破碎,微管密度降低;pH值6.5+紫杉醇组细胞微管破坏程度较pH值6.5组明显减轻,微管结构基本恢复正常。(3)与pH值7.4组比较,pH值6.5组细胞游离态微管蛋白表达量明显增加(t=3.030,P<0.05),聚合态微管蛋白表达量明显减少(t=8.604,P<0.05);与pH值6.5组比较,pH值6.5+紫杉醇组细胞游离态微管蛋白表达量明显减少(t=4.559,P<0.05),聚合态微管蛋白表达量明显增加(t=5.472,P<0.05)。(4)pH值7.4组、pH值6.5组、pH值6.5+紫杉醇组细胞活力分别为1.00±0.10、0.83±0.04、0.93±0.10。pH值6.5组细胞活力较pH值7.4组明显降低(t=4.412,P<0.05),pH值6.5+紫杉醇组细胞活力较pH值6.5组明显升高(t=2.461,P<0.05)。 结论: pH值降低通过破坏微管骨架引起大鼠心肌细胞活力下降,稳定微管骨架后可明显减轻酸性处理所致损害,改善心肌细胞活力。.
Keywords: Acidosis; Cell viability; Microtubules; Myocytes, cardiac.