Wei Z Y, Li H S, Zhou J Y, Han C, Dong H, Wu Y Z, He W F, Tian Y, Luo G X
State Key Laboratory of Trauma, Burns and Combined Injury, Institute of Burn Research, the First Affiliated Hospital of Army Medical University (the Third Military Medical University), Chongqing Key Laboratory for Disease Proteomics, Chongqing 400038, China.
Institute of Immunology, Army Medical University (the Third Military Medical University), Chongqing 400038, China.
Zhonghua Shao Shang Za Zhi. 2020 Mar 20;36(3):224-233. doi: 10.3760/cma.j.cn501120-20200109-00014.
To explore the transcriptional regulation mechanism of transforming growth factor β(1) (TGF-β(1)) on Meox1 and its effect on cell migration of adult human dermal fibroblasts (HDF-a). (1) HDF-a cells were cultured in RPMI 1640 complete medium (hereinafter referred to as routinely cultured). The cells were divided into TGF-β(1) stimulation group and blank control group. The cells in TGF-β(1) stimulation group were stimulated with 10 μL TGF-β(1) in the mass concentration of 1 mg/μL, while the cells in blank control group were stimulated with the equal volume of phosphate buffer solution. After 72 hours in culture, partial cells in both groups were collected for transcriptome sequencing. The genes with differential expression ratio greater than or equal to 2 and <0.01 between the two groups were selected to perform enrichment analysis and analysis of metabolic pathways of the Kyoto Gene and Genome Encyclopedia with, and the expression value of Meox1 per million transcripts (TPM) was recorded (=3). Partial cells from the two groups were used to detect the Meox1 mRNA expression by real-time fluorescent quantitative reverse transcription polymerase chain reaction (RT-PCR) (=3). (2) Cultured HDF-a cells in the logarithmic growth phase (the same growth phase of cells below) were divided into empty plasmid group, Smad2 overexpression (OE) group, Smad3 OE group, and Smad4 OE group, which were transfected respectively with 2 μg empty pcDNA3.1 plasmid and pcDNA3.1 plasmids separately carrying Smad2, Smad3, and Smad4 for 6 hours, and then were routinely cultured for 48 hours. The Meox1 mRNA expression in the transfected cells of each group was detected by real-time fluorescent quantitative RT-PCR (=3). (3) HDF-a cells were routinely cultured and grouped the same as in experiment (1). After 72 hours in culture, the enrichment of Smad2, Smad3, and Smad4 protein on the Meox1 promoter in the cells of each group was detected by chromatin immunoprecipitation-quantitative PCR (ChIP-qPCR) (=3). (4) HDF-a cells were routinely cultured and divided into negative interference group, small interference RNA (siRNA)-Smad2 group, siRNA-Smad3 group, siRNA-Smad4 group, empty plasmid group, Smad2 OE group, Smad3 OE group, and Smad4 OE group, which were transfected respectively with 50 μmol/L random siRNA, siRNA-Smad2, siRNA-Smad3, siRNA-Smad4, 2 μg empty pcDNA3.1 plasmid and pcDNA3.1 plasmids separately carrying Smad2, Smad3, and Smad4 for 6 hours and then routinely cultured for 48 hours. The enrichment of Smad2, Smad3, and Smad4 protein on the Meox1 promoter in the cells of corresponding group was detected by ChIP-qPCR (=3). (5) Two batches of HDF-a cells were cultured and divided into negative interference group, siRNA-Meox1 group, empty plasmid group, and Meox1 OE group, which were transfected respectively with 50 μmol/L random siRNA, siRNA-Meox1, 2 μg empty pcDNA3.1 plasmid and pcDNA3.1 plasmid carrying Meox1 for 6 hours and then routinely cultured for 24 hours. One batch of cells were subjected to scratch test with the scratch width being observed 24 hours after scratching and compared with the initial width for scratch wound healing; the other batch of cells were subjected to Transwell assay, in which the migrated cells were counted after being routinely cultured for 24 hours (=3). (6) From January 2018 to June 2019, 3 hypertrophic scar patients (2 males and 1 female, aged 35-56 years) were admitted to the First Affiliated Hospital of Army Medical University (the Third Military Medical University) 8-12 months after burns. The scar tissue and normal skin tissue along the scar margin resected during surgery were taken, and immunohistochemical staining was performed to observe the distribution of Meox1 protein expression. Data were statistically analyzed with one-way analysis of variance and independent sample test. (1) After 72 hours in culture, a total of 843 genes were obviously differentially expressed between the two groups, being related to tissue repair, cell migration, inflammatory cell chemotaxis induction process and potential signaling pathways such as tumor necrosis factor, interleukin 17, extracellular matrix receptor. The TPM value of Meox1 in the cells of blank control group was 45.9±1.9, which was significantly lower than 163.1±29.5 of TGF-β(1) stimulation group (=6.88, <0.01) with RNA-sequencing. After 72 hours in culture, the Meox1 mRNA expression levels in the cells of blank control group was 1.00±0.21, which was significantly lower than 11.00±3.61 of TGF-β(1) stimulation group (=4.79, <0.01). (2) After 48 hours in culture, the Meox1 mRNA expression levels in the cells of Smad2 OE group, Smad3 OE group, and Smad4 OE group were 198.70±11.02, 35.47±4.30, 20.27±2.50, respectively, which were significantly higher than 1.03±0.19 of empty plasmid group (=31.07, 13.80, 13.12, <0.01). (3) After 72 hours in culture, the enrichment of Smad2, Smad3, and Smad4 protein on the promoter of Meox1 in the cells of TGF-β(1) stimulation group was significantly higher than that of blank control group respectively (=12.99, 41.47, 29.10, <0.01). (4) After 48 hours in culture, the enrichment of Smad2 protein on the promoter of Meox1 in the cells of negative interference group was (0.200 000±0.030 000)%, significantly higher than (0.000 770±0.000 013)% of siRNA-Smad2 group (=11.67, <0.01); the enrichment of Smad2 protein on the promoter of Meox1 in the cells of empty plasmid group was (0.200 000±0.040 000)%, significantly lower than (0.700 000±0.090 000)% of Smad2 OE group (=8.85, <0.01). The enrichment of Smad3 protein on the promoter of Meox1 in the cells of negative interference group was (0.500 0±0.041 3)%, significantly higher than (0.006 0±0.001 3)% of siRNA-Smad3 group (=17.79, <0.01); the enrichment of Smad3 protein on the promoter of Meox1 in the cells of empty plasmid group was (0.470 0±0.080 0)%, which was significantly lower than (1.100 0±0.070 0)% of Smad3 OE group (=9.93, <0.01). The enrichment of Smad4 protein on the promoter of Meox1 in the cells of negative interference group was similar to that of siRNA-Smad4 group (=2.11, >0.05); the enrichment of Smad4 protein on the promoter of Meox1 in the cells of empty plasmid group was similar to that of Smad4 OE group (=0.60, >0.05). (5) Twenty-four hours after scratching, the scratch healing width of cells in siRNA-Meox1 group was narrower than that of negative interference group, while that of Meox1 OE group was wider than that of empty plasmid group. After 24 hours in culture, the number of migration cells in negative interference group was significantly higher than that in siRNA-Meox1 group (=9.12, <0.01), and that in empty plasmid group was significantly lower than that in Meox1 OE group (=8.99, <0.01). (6) The expression of Meox1 protein in the scar tissue was significantly higher than that in normal skin of patients with hypertrophic scars. TGF-β(1) transcriptionally regulates Meox1 expression via Smad2/3 in HDF-a cells, thus promoting cell migration.
探讨转化生长因子β(1)(TGF-β(1))对Meox1的转录调控机制及其对成人皮肤成纤维细胞(HDF-a)细胞迁移的影响。(1)将HDF-a细胞培养于RPMI 1640完全培养基中(以下简称常规培养)。将细胞分为TGF-β(1)刺激组和空白对照组。TGF-β(1)刺激组细胞用质量浓度为1mg/μL的10μL TGF-β(1)刺激,空白对照组细胞用等体积的磷酸盐缓冲液刺激。培养72小时后,收集两组部分细胞进行转录组测序。选取两组间差异表达倍数大于或等于2且P<0.01的基因进行京都基因与基因组百科全书富集分析和代谢途径分析,并记录Meox1每百万转录本(TPM)的表达值(n=3)。取两组部分细胞,采用实时荧光定量逆转录聚合酶链反应(RT-PCR)检测Meox1 mRNA表达(n=3)。(2)将处于对数生长期的HDF-a细胞(以下同细胞生长阶段)分为空质粒组、Smad2过表达(OE)组、Smad3 OE组和Smad4 OE组,分别用2μg空的pcDNA3.1质粒和分别携带Smad2、Smad3和Smad4的pcDNA3.1质粒转染6小时,然后常规培养48小时。采用实时荧光定量RT-PCR检测各组转染细胞中Meox1 mRNA表达(n=3)。(3)HDF-a细胞常规培养,分组同实验(1)。培养72小时后,采用染色质免疫沉淀-定量PCR(ChIP-qPCR)检测各组细胞中Smad2、Smad3和Smad4蛋白在Meox1启动子上的富集情况(n=3)。(4)HDF-a细胞常规培养,分为阴性干扰组,小干扰RNA(siRNA)-Smad2组、siRNA-Smad3组、siRNA-Smad4组、空质粒组、Smad2 OE组、Smad3 OE组和Smad4 OE组,分别用50μmol/L随机siRNA、siRNA-Smad2、siRNA-Smad3、siRNA-Smad4、2μg空的pcDNA3.1质粒和分别携带Smad2、Smad3和Smad4的pcDNA3.1质粒转染6小时,然后常规培养48小时。采用ChIP-qPCR检测相应组细胞中Smad2、Smad3和Smad4蛋白在Meox1启动子上的富集情况(n=3)。(5)培养两批HDF-a细胞,分为阴性干扰组、siRNA-Meox1组、空质粒组和Meox1 OE组,分别用50μmol/L随机siRNA、siRNA-Meox1、2μg空的pcDNA3.1质粒和携带Meox1的pcDNA3.1质粒转染6小时,然后常规培养24小时。一批细胞进行划痕试验,划痕后24小时观察划痕宽度,并与初始宽度比较计算划痕愈合率;另一批细胞进行Transwell试验,常规培养24小时后计数迁移细胞数(n=3)。(6)2018年1月至2019年6月,陆军军医大学第一附属医院(第三军医大学)收治3例肥厚性瘢痕患者(男2例,女1例,年龄3556岁),均为烧伤后812个月。术中切取瘢痕组织及瘢痕边缘正常皮肤组织,进行免疫组织化学染色,观察Meox1蛋白表达分布。数据采用单因素方差分析和独立样本t检验进行统计学分析。(1)培养72小时后,两组间共有843个基因明显差异表达,涉及组织修复、细胞迁移、炎症细胞趋化诱导过程以及肿瘤坏死因子、白细胞介素17、细胞外基质受体等潜在信号通路。RNA测序显示,空白对照组细胞中Meox1的TPM值为45.9±1.9,显著低于TGF-β(1)刺激组的163.1±29.5(P=6.88,P<0.01)。培养72小时后,空白对照组细胞中Meox1 mRNA表达水平为1.00±0.21,显著低于TGF-β(1)刺激组的11.00±3.61(P=4.79,P<0.01)。(2)培养48小时后,Smad2 OE组、Smad3 OE组和Smad4 OE组细胞中Meox1 mRNA表达水平分别为198.70±11.02、35.47±4.30、20.27±2.50,均显著高于空质粒组的1.03±0.19(P=31.07、13.80、13.12,P<0.01)。(3)培养72小时后,TGF-β(1)刺激组细胞中Smad2、Smad3和Smad4蛋白在Meox1启动子上的富集分别显著高于空白对照组(P=12.99、41.47、29.10,P<0.01)。(4)培养48小时后,阴性干扰组细胞中Smad2蛋白在Meox1启动子上的富集为(0.200 000±0.030 XXX)%,显著高于siRNA-Smad2组的(0.000 770±0.000 013)%(P=11.67,P<0.01);空质粒组细胞中Smad2蛋白在Meox1启动子上的富集为(0.200 000±0.040 XXX)%,显著低于Smad2 OE组的(0.700 000±0.090 XXX)%(P=8.85,P<0.01)。阴性干扰组细胞中Smad3蛋白在Meox1启动子上的富集为(0.500 0±0.041 3)%,显著高于siRNA-Smad3组的(0.006 0±0.001 3)%(P=17.79,P<0.01);空质粒组细胞中Smad3蛋白在Meox1启动子上的富集为(0.470 0±0.080 0)%,显著低于Smad3 OE组的(1.100 0±0.070 0)%(P=9.93,P<0.01)。阴性干扰组细胞中Smad4蛋白在Meox1启动子上的富集与siRNA-Smad4组相似(P=2.11,P>0.05);空质粒组细胞中Smad4蛋白在Meox1启动子上的富集与Smad4 OE组相似(P=0.60,P>0.05)。(5)划痕后24小时,siRNA-Meox1组细胞划痕愈合宽度窄于阴性干扰组,Meox1 OE组细胞划痕愈合宽度宽于空质粒组。培养24小时后,阴性干扰组迁移细胞数显著高于siRNA-Meox1组(P=9.12,P<0.01),空质粒组迁移细胞数显著低于Meox1 OE组(P=8.99,P<0.01)。(6)肥厚性瘢痕患者瘢痕组织中Meox1蛋白表达显著高于正常皮肤。TGF-β(1)通过Smad2/3转录调控HDF-a细胞中Meox1的表达,从而促进细胞迁移。
