酸性微环境下大蒜素增强大鼠自然杀伤细胞的功能活性

Objective To investigate the role of allicin on rat nature killer (NK) cell activity in vitro under acidic microenvironment, and its possible mechanism. Methods CD3- NKR-P1+ NK cells isolated from the rat spleen were cultured in the complete RPMI 1640 medium ( pH 5. 6, pH 6. 5, or pH 7. 2 respectively), and treated with allicin at final concentration of 30 mg/L. Enzyme linked immunosorbent assay (ELISA) was used to determine supernatant interferon (IFN)-γ levels. The percentage of NK cells proliferation and apopotosis was analyzed by flow cytometry. NK cell cytotoxicity toward YAC-1 tumor cells was detected by LDH release assay. Results Proliferation and cytotoxicity of NK cells were significantly suppressed by acidic microenvironment in vitro. Under the cultured condition of acidic pH below 7. 2, allicin seemed to promote NK cells proliferation, which reached to highest level of 33% at pH 5. 6 cultured for 16 h. Correspondingly, at pH of 5. 6, allicin induced a marked increase of IFN-γ concentration in the supernatant from (50. 07 ± 0. 38) (cultured for 4 h) to (64. 59 ± 0. 09) ng/L ( cultured for 16 h). The cytotoxicity of NK cells toward YAC-1 tumor cells was also found strongest under the condition of pH 5. 6 cultured for 16 h. Conclusion Allicin favored to enhance the cytotoxicity of NK cells under the acidic cultured condition, which might be related to the increase of IFN-γ production.     

酸性微环境下大蒜素增强大鼠自然杀伤细胞的功能活性

目的 观察体外酸性培养环境下大蒜素对自然杀伤(NK)细胞功能活性的影响,并探讨其机制.方法 以pH 5.6、pH 6.5和pH 7.2的完全RPMI 1640培养基对大鼠脾脏CD3-NKR-P1+NK细胞进行悬浮培养,并给予30 mg/L浓度的大蒜素进行处理.酶联免疫吸附试验(ELISA)检测细胞培养液中干扰素(IFN)-γ的分泌水平,流式细胞仪检测NK细胞的增殖和凋亡率,乳酸脱氢酶法检测NK细胞的功能活性.结果 酸性培养环境下大鼠脾脏NK细胞的增殖能力明显下降,NK细胞功能活性明显受阻.在pH 7.2、pH 6.5和pH 5.6三种不同的培养条件下,大蒜素对NK细胞增殖率的影响表现为随培养环境的pH降低反而升高,以pH 5.6、培养16 h时达最高33.3%.与之相对应,NK细胞分泌的IFN-γ达(64.59±0.09)ng/L,较培养4 h时升高28%,且对小鼠淋巴瘤Yac-1细胞的杀伤活性也达到最高水平.结论 大蒜素可通过提高NK细胞IFN-γ分泌水平明显改善酸性培养环境下NK细胞的功能活性.

Abstract：

Objective To investigate the role of allicin on rat nature killer (NK) cell activity in vitro under acidic microenvironment, and its possible mechanism. Methods CD3- NKR-P1+ NK cells isolated from the rat spleen were cultured in the complete RPMI 1640 medium ( pH 5. 6, pH 6. 5, or pH 7. 2 respectively), and treated with allicin at final concentration of 30 mg/L. Enzyme linked immunosorbent assay (ELISA) was used to determine supernatant interferon (IFN)-γ levels. The percentage of NK cells proliferation and apopotosis was analyzed by flow cytometry. NK cell cytotoxicity toward YAC-1 tumor cells was detected by LDH release assay. Results Proliferation and cytotoxicity of NK cells were significantly suppressed by acidic microenvironment in vitro. Under the cultured condition of acidic pH below 7. 2, allicin seemed to promote NK cells proliferation, which reached to highest level of 33% at pH 5. 6 cultured for 16 h. Correspondingly, at pH of 5. 6, allicin induced a marked increase of IFN-γ concentration in the supernatant from (50. 07 ± 0. 38) (cultured for 4 h) to (64. 59 ± 0. 09) ng/L ( cultured for 16 h). The cytotoxicity of NK cells toward YAC-1 tumor cells was also found strongest under the condition of pH 5. 6 cultured for 16 h. Conclusion Allicin favored to enhance the cytotoxicity of NK cells under the acidic cultured condition, which might be related to the increase of IFN-γ production.     

不同浓度七氟醚对人肺腺癌A549细胞Survivin蛋白表达的影响

Objective To investigate the effects of different concentrations of sevoflurane on Survivin expression in human adenocarcinoma cell line A549. Methods A549 cells were obtained from Shanghai Cell Biology Medical Research Institute, Chinese Academy of Sciences and inoculated in 96 well culture plate. After being cultured for 24 h, the cells were randomly divided into 4 groups: Ⅰ , Ⅱ , Ⅲ and Ⅳ groups exposed to 95 % O2 -5 %CO2,1.7%, 3.4% and 5.1% sevoflurane respectively. A549 cells were exposed to sevoflurane for 2, 4 and 6 h respectively and then cultured for another 48 h in Ⅱ , Ⅲ and Ⅳ groups. Proliferation of A549 cells were measured by methyl thiazolyl tetrazolium (MTT) assay, and apoptosis was detected with flow cytometer at 48 h after 2, 4 and 6 h sevoflurane exposure. The expression of Survivin in A549 cells was determined by Western blot analysis at 48h after 4 h sevoflurane exposure. Results The rate of proliferation inhibition and percentage of apoptotic cells were significantly higher while the expression of Survivin was significantly lower in a concentration-dependent manner in Ⅱ , Ⅲ and Ⅳ groups as compared with group Ⅰ . Conclusion Sevoflurane can inhibit proliferation and induce apoptosis of A549 cells by inhibition of Survivin expression.     

不同浓度七氟醚对人肺腺癌A549细胞Survivin蛋白表达的影响

Objective To investigate the effects of different concentrations of sevoflurane on Survivin expression in human adenocarcinoma cell line A549. Methods A549 cells were obtained from Shanghai Cell Biology Medical Research Institute, Chinese Academy of Sciences and inoculated in 96 well culture plate. After being cultured for 24 h, the cells were randomly divided into 4 groups: Ⅰ , Ⅱ , Ⅲ and Ⅳ groups exposed to 95 % O2 -5 %CO2,1.7%, 3.4% and 5.1% sevoflurane respectively. A549 cells were exposed to sevoflurane for 2, 4 and 6 h respectively and then cultured for another 48 h in Ⅱ , Ⅲ and Ⅳ groups. Proliferation of A549 cells were measured by methyl thiazolyl tetrazolium (MTT) assay, and apoptosis was detected with flow cytometer at 48 h after 2, 4 and 6 h sevoflurane exposure. The expression of Survivin in A549 cells was determined by Western blot analysis at 48h after 4 h sevoflurane exposure. Results The rate of proliferation inhibition and percentage of apoptotic cells were significantly higher while the expression of Survivin was significantly lower in a concentration-dependent manner in Ⅱ , Ⅲ and Ⅳ groups as compared with group Ⅰ . Conclusion Sevoflurane can inhibit proliferation and induce apoptosis of A549 cells by inhibition of Survivin expression.     

缺氧微环境对胰腺癌细胞发生上皮向间叶转化的诱导作用

Objective To investigate whether hypoxic environment can promote the metastasis of pancreatic cancer cells by inducing epithelial to mesenchymal transition (EMT). Methods The Panc-1 cells were cultured in hypoxia environment. After cultured for indicated periods, the in vitro invasive ability of Pane-1 cells was compared with normoxia group using Transwell invasion assay. The epithelial marker E-cadherin and the mesenchymal marker vimentin were assayed by Western blot. The expression of Snail, a strong activator of EMT, was detected by real-time PCR. The HIF-1 α encoding cDNA was transiently trans-fected into the Pane-1 cells, and the E-cadherin and vimentin were analyzed. Results The number of cells invading to the lower side of the membrane under hypoxia was ( 121±5 ), whereas only ( 84±3 ) in no-morxia group ( P < 0.05 ). The relative expression of E-cadherin in normoxia, hyoxia groups at 12,24,48 hwas (0.59±0.04 vs 54.00±0.05,0.45±0.10,0.36±0.03 ), and that of vimentin was (0.36±0.05, 0.41±0.04,0.48±0.06,0.58±0.05 ) ( P < 0.05 ). The relative expression of Snail mRNA was in-creased in hypoxia environment, and the difference was significant after 72 h ( P < 0.05 ). Before and after HIF-1α cDNA was transfected into the Panc-1 cells, the relative expression of E-cadherin was 0.63± 0.05, and 0.47±0.07, and that of vimentin was 0.47±0.07, and 0.32±0.04 respectively ( P < 0.05 ). Conclusion Hypoxia microenvironment can activate HIF-1α and Snail to trigger EMT of pancreatic cancer cells.     

缺氧微环境对胰腺癌细胞发生上皮向间叶转化的诱导作用

Objective To investigate whether hypoxic environment can promote the metastasis of pancreatic cancer cells by inducing epithelial to mesenchymal transition (EMT). Methods The Panc-1 cells were cultured in hypoxia environment. After cultured for indicated periods, the in vitro invasive ability of Pane-1 cells was compared with normoxia group using Transwell invasion assay. The epithelial marker E-cadherin and the mesenchymal marker vimentin were assayed by Western blot. The expression of Snail, a strong activator of EMT, was detected by real-time PCR. The HIF-1 α encoding cDNA was transiently trans-fected into the Pane-1 cells, and the E-cadherin and vimentin were analyzed. Results The number of cells invading to the lower side of the membrane under hypoxia was ( 121±5 ), whereas only ( 84±3 ) in no-morxia group ( P < 0.05 ). The relative expression of E-cadherin in normoxia, hyoxia groups at 12,24,48 hwas (0.59±0.04 vs 54.00±0.05,0.45±0.10,0.36±0.03 ), and that of vimentin was (0.36±0.05, 0.41±0.04,0.48±0.06,0.58±0.05 ) ( P < 0.05 ). The relative expression of Snail mRNA was in-creased in hypoxia environment, and the difference was significant after 72 h ( P < 0.05 ). Before and after HIF-1α cDNA was transfected into the Panc-1 cells, the relative expression of E-cadherin was 0.63± 0.05, and 0.47±0.07, and that of vimentin was 0.47±0.07, and 0.32±0.04 respectively ( P < 0.05 ). Conclusion Hypoxia microenvironment can activate HIF-1α and Snail to trigger EMT of pancreatic cancer cells.     

缺氧微环境对胰腺癌细胞发生上皮向间叶转化的诱导作用

Objective To investigate whether hypoxic environment can promote the metastasis of pancreatic cancer cells by inducing epithelial to mesenchymal transition (EMT). Methods The Panc-1 cells were cultured in hypoxia environment. After cultured for indicated periods, the in vitro invasive ability of Pane-1 cells was compared with normoxia group using Transwell invasion assay. The epithelial marker E-cadherin and the mesenchymal marker vimentin were assayed by Western blot. The expression of Snail, a strong activator of EMT, was detected by real-time PCR. The HIF-1 α encoding cDNA was transiently trans-fected into the Pane-1 cells, and the E-cadherin and vimentin were analyzed. Results The number of cells invading to the lower side of the membrane under hypoxia was ( 121±5 ), whereas only ( 84±3 ) in no-morxia group ( P < 0.05 ). The relative expression of E-cadherin in normoxia, hyoxia groups at 12,24,48 hwas (0.59±0.04 vs 54.00±0.05,0.45±0.10,0.36±0.03 ), and that of vimentin was (0.36±0.05, 0.41±0.04,0.48±0.06,0.58±0.05 ) ( P < 0.05 ). The relative expression of Snail mRNA was in-creased in hypoxia environment, and the difference was significant after 72 h ( P < 0.05 ). Before and after HIF-1α cDNA was transfected into the Panc-1 cells, the relative expression of E-cadherin was 0.63± 0.05, and 0.47±0.07, and that of vimentin was 0.47±0.07, and 0.32±0.04 respectively ( P < 0.05 ). Conclusion Hypoxia microenvironment can activate HIF-1α and Snail to trigger EMT of pancreatic cancer cells.     

缺氧微环境对胰腺癌细胞发生上皮向间叶转化的诱导作用

Objective To investigate whether hypoxic environment can promote the metastasis of pancreatic cancer cells by inducing epithelial to mesenchymal transition (EMT). Methods The Panc-1 cells were cultured in hypoxia environment. After cultured for indicated periods, the in vitro invasive ability of Pane-1 cells was compared with normoxia group using Transwell invasion assay. The epithelial marker E-cadherin and the mesenchymal marker vimentin were assayed by Western blot. The expression of Snail, a strong activator of EMT, was detected by real-time PCR. The HIF-1 α encoding cDNA was transiently trans-fected into the Pane-1 cells, and the E-cadherin and vimentin were analyzed. Results The number of cells invading to the lower side of the membrane under hypoxia was ( 121±5 ), whereas only ( 84±3 ) in no-morxia group ( P < 0.05 ). The relative expression of E-cadherin in normoxia, hyoxia groups at 12,24,48 hwas (0.59±0.04 vs 54.00±0.05,0.45±0.10,0.36±0.03 ), and that of vimentin was (0.36±0.05, 0.41±0.04,0.48±0.06,0.58±0.05 ) ( P < 0.05 ). The relative expression of Snail mRNA was in-creased in hypoxia environment, and the difference was significant after 72 h ( P < 0.05 ). Before and after HIF-1α cDNA was transfected into the Panc-1 cells, the relative expression of E-cadherin was 0.63± 0.05, and 0.47±0.07, and that of vimentin was 0.47±0.07, and 0.32±0.04 respectively ( P < 0.05 ). Conclusion Hypoxia microenvironment can activate HIF-1α and Snail to trigger EMT of pancreatic cancer cells.     

缺氧微环境对胰腺癌细胞发生上皮向间叶转化的诱导作用

Objective To investigate whether hypoxic environment can promote the metastasis of pancreatic cancer cells by inducing epithelial to mesenchymal transition (EMT). Methods The Panc-1 cells were cultured in hypoxia environment. After cultured for indicated periods, the in vitro invasive ability of Pane-1 cells was compared with normoxia group using Transwell invasion assay. The epithelial marker E-cadherin and the mesenchymal marker vimentin were assayed by Western blot. The expression of Snail, a strong activator of EMT, was detected by real-time PCR. The HIF-1 α encoding cDNA was transiently trans-fected into the Pane-1 cells, and the E-cadherin and vimentin were analyzed. Results The number of cells invading to the lower side of the membrane under hypoxia was ( 121±5 ), whereas only ( 84±3 ) in no-morxia group ( P < 0.05 ). The relative expression of E-cadherin in normoxia, hyoxia groups at 12,24,48 hwas (0.59±0.04 vs 54.00±0.05,0.45±0.10,0.36±0.03 ), and that of vimentin was (0.36±0.05, 0.41±0.04,0.48±0.06,0.58±0.05 ) ( P < 0.05 ). The relative expression of Snail mRNA was in-creased in hypoxia environment, and the difference was significant after 72 h ( P < 0.05 ). Before and after HIF-1α cDNA was transfected into the Panc-1 cells, the relative expression of E-cadherin was 0.63± 0.05, and 0.47±0.07, and that of vimentin was 0.47±0.07, and 0.32±0.04 respectively ( P < 0.05 ). Conclusion Hypoxia microenvironment can activate HIF-1α and Snail to trigger EMT of pancreatic cancer cells.