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目的:建立人真皮成纤维细胞(HDF)高糖老化模型,探讨人蜕膜间充质干细胞(dMSC)来源外泌体对高糖老化HDF增殖、迁移、凋亡的影响及其可能机制。方法:采用实验研究方法。收集2021年1—3月解放军总医院第四医学中心收治的4例男性包茎患者(18~22岁)环切术后废弃包皮组织,分离培养获取原代HDF。取第6代HDF,按照随机数字表法分为低糖组和高糖组,分别采用低糖完全培养基和高糖完全培养基进行每72小时换液、不传代培养,10 d后取细胞,于接种后24 h,采用β-半乳糖苷酶试剂盒检测细胞衰老情况;于接种后48 h,采用蛋白质印迹法检测细胞衰老相关蛋白p16、p53表达情况;于接种后24、48、72 h,采用细胞计数试剂盒8(CCK-8)法检测细胞增殖情况;于接种后48 h,采用脱氧尿嘧啶核苷(EdU)染色法检测细胞增殖情况,采用流式细胞术检测细胞周期及凋亡情况;于接种后24 h,采用Transwell实验测定细胞迁移能力。取人dMSC培养48~72 h,采用差速高速离心法获取其外泌体,采用透射电子显微镜观察dMSC外泌体形态,采用纳米颗粒追踪分析法检测dMSC外泌体的粒径分布,采用蛋白质印迹法检测dMSC外泌体标志蛋白CD9、肿瘤易感基因101(TSG101)的表达。取dMSC外泌体及前述高糖完全培养基诱导老化的HDF共孵育24 h,采用PKH67试剂盒检测细胞摄取外泌体的情况。取前述高糖完全培养基诱导老化的HDF,同前分为单纯高糖组、高糖+低浓度外泌体组、高糖+高浓度外泌体组,分别于高糖完全培养基中加入等体积的磷酸盐缓冲液、终质量浓度为50 μg/mL dMSC外泌体、终质量浓度为100 μg/mL dMSC外泌体进行常规细胞培养。分组后同前于对应时间点采用CCK-8法和EdU染色法、流式细胞术、Transwell实验分别检测细胞增殖、细胞周期和凋亡及细胞迁移情况。根据前述结果,另取经高糖完全培养基诱导老化的HDF,分为单纯高糖组、高糖+高浓度外泌体组并同前处理。分组培养48 h,采用实时荧光定量反转录PCR法检测单纯高糖组和高糖+高浓度外泌体组细胞衰老相关的微小RNA-145-5p(miR-145-5p)、miR-498、miR-503-5p及其靶基因钙/钙调素依赖性蛋白激酶1D(CAMK1D)、人第10号染色体缺失的磷酸酶及张力蛋白同源的基因(n PTEN基因)和细胞周期蛋白D1的mRNA表达情况。对数据行析因设计方差分析、单因素方差分析、LSD-n t检验和独立样本n t检验。n 结果:接种后24 h,高糖组HDF β-半乳糖苷酶阳性染色率为(38.4±4.2)%,明显高于低糖组的(16.5±2.2)%(n t=4.65,n P<0.01)。接种后48 h,高糖组HDF的衰老相关蛋白p16和p53的表达量均明显高于低糖组(n t值分别为11.85、3.02,n P<0.05或n P<0.01)。接种后24、48、72 h,高糖组HDF的增殖活性均明显低于低糖组(n t值分别为4.13、9.90、15.12,n P<0.01)。接种后48 h,高糖组HDF的EdU阳性染色率明显低于低糖组(n t=3.83,n P<0.05)。接种后48 h,高糖组HDF周期的G2/M+S亚群在3个亚群(G0/G1、S和G2/M)的占比明显低于低糖组(n t=8.74,n P<0.01)。接种后24 h,高糖组HDF穿过Transwell滤膜到达下室的细胞数量为(37±6)个,明显少于低糖组的(74±7)个(n t=8.42,n P<0.01)。接种后48 h,高糖组HDF凋亡率明显高于低糖组(n t=8.48,n P<0.01)。dMSC外泌体为边缘清晰、大小分布均匀的杯状或者圆形囊泡,粒径基本处于80~200 nm。dMSC外泌体标志性蛋白CD9、TSG101表达均呈阳性。共孵育24 h,外泌体被HDF摄入胞内,主要分布于细胞核周围。分组培养24、48、72 h,高糖+低浓度外泌体组和高糖+高浓度外泌体组HDF增殖活性均明显高于单纯高糖组(n t值分别为6.36、6.10、7.76,8.92、12.17、10.74,n P<0.01),高糖+高浓度外泌体组HDF增殖活性均明显高于高糖+低浓度外泌体组(n t值分别为7.92、4.82、4.72,n P<0.01)。分组培养48 h,与单纯高糖组比较,高糖+低浓度外泌体组和高糖+高浓度外泌体组HDF EdU阳性染色率均明显升高(n t值分别为5.32、9.88,n P<0.01);与高糖+低浓度外泌体组比较,高糖+高浓度外泌体组HDF EdU阳性染色率显著升高(n t=5.27,n P<0.01)。分组培养48 h,与单纯高糖组比较,高糖+低浓度外泌体组和高糖+高浓度外泌体组HDF中的G0/G1期亚群占比均显著降低(n t值分别为3.81、4.31,n P<0.05),G2/M+S亚群占比均明显升高(n t值分别为3.81、4.31,n P<0.05)。分组培养24 h,与单纯高糖组相比,高糖+低浓度外泌体组和高糖+高浓度外泌体组HDF穿过滤膜的数量均明显增多(n t值分别为10.14、13.39n ,P<0.01);与高糖+低浓度外泌体组相比,高糖+高浓度外泌体组HDF穿过滤膜的数量明显增多(n t=6.27n ,P<0.01)。分组培养48 h,与单纯高糖组比较,高糖+低浓度外泌体组和高糖+高浓度外泌体组HDF凋亡率均明显降低(n t值分别为3.72、5.53,n P<0.05或n P<0.01)。分组培养48 h,与单纯高糖组相比,高糖+高浓度外泌体组HDF的miR-145-5p、miR-498 mRNA表达量均明显上升(n t值分别为13.03、8.90,n P<0.01),miR-503-5p mRNA表达量明显下降(n t=3.85,n P<0.05);高糖+高浓度外泌体组中HDF的CAMK1D、n PTEN基因mRNA表达量均明显低于单纯高糖组(n t值分别为8.83、5.97,n P<0.01),细胞周期蛋白D1 mRNA表达量明显高于单纯高糖组(n t=4.03,n P<0.05)。n 结论:人dMSC来源外泌体可显著提高高糖老化HDF的增殖和迁移能力,抑制其凋亡。这可能与HDF内miR-145-5p和miR-498表达增高抑制了CAMK1D和n PTEN基因的表达及miR-503-5p表达下降促进了细胞周期蛋白D1的表达有关。n “,”Objective:To establish a high glucose senescent model of human dermal fibroblasts (HDFs), and to investigate the effects of exosomes derived from human decidua mesenchymal stem cells (dMSCs) on the proliferation, migration, and apoptosis of senescent HDFs and possible mechanism.Methods:The experimental research method was used. From January to March 2021, discarded foreskin tissue was collected for isolation and culture of primary HDFs from 4 male phimosis patients (aged 18-22 years) admitted for circumcision in the Fourth Medical Center of the PLA General Hospital. The 6th passage of HDFs were taken and divided into low glucose group and high glucose group according to the random number table, and subsequently cultured in low-glucose complete medium and high-glucose complete medium, respectively, with medium changed every 72 h without subculturing. After 10 days of culture, the cells were taken and measured for cellular senescence using the β-galactosidase kit at 24 h after seeding; the expression of senescence-related proteins p16 and p53 was assessed by Western blotting at 48 h after seeding; cell proliferation was detected at 24, 48, and 72 h after seeding using the cell counting kit 8 (CCK-8) method; the cell proliferation was evaluated by 5-ethynyl-2\'-deoxyuridine (EdU) staining method, cell cycle and apoptosis were measured by flow cytometry after 48 h of seeding; Transwell experiment was used for the calculation of cell migration rate at 24 h after seeding. The human dMSCs were taken and cultured for 48-72 h from which the exosomes were extracted by differential high speed centrifugal method. The morphology of dMSC exosomes was observed by transmission electron microscopy, the particle size distribution of dMSC exosomes was measured by nanoparticle tracking analysis, and the expression of dMSC-exosomes marker proteins CD9 and tumor susceptibility gene101 (TSG101) were detected by Western blotting. The dMSC exosomes and high-glucose complete medium-induced senescent HDFs were co-cultured for 24 hours, then PKH67 kit was used to detect the uptake of exosomes by HDFs. High-glucose complete medium-induced senescent HDFs were taken and divided into high glucose alone group, high glucose+low concentration of exosomes group, and high glucose+high concentration of exosomes group according to the same method above. The high-glucose complete medium with equal volume of phosphate buffered saline, dMSC exosomes with final concentration of 50 μg/mL, and dMSC exosomes with final concentration of 100 μg/mL were added to the corresponding groups for conventional cell culture, respectively. After grouped, the cell proliferation, cell cycle and apoptosis as well as cell migration were detected by CCK-8 method and EdU staining method, flow cytometry, and Transwell experiment at the corresponding time points as before, respectively. Based on the previous results, high-glucose complete medium-induced senescent HDFs were taken and divided into high glucose alone group and high glucose+high concentration of exosomes group for the same treatment. After being grouped and cultured for 48 h, real-time fluorescent quantitative polymerase chain reaction was used to evaluate the mRNA expression of senescent-related microRNA (miR)-145-5p, miR-498, miR-503-5p, calcium/calmodulin dependent protein kinase 1D (CAMK1D), phosphates and tensin homologue deleted on chromosome ten (n PTEN) gene, and Cyclin D1 in high glucose alone group and high glucose+high concentration of exosomes group. Data were statistically analyzed with analysis of variance for factorial design, one-way analysis of variance, least significant difference n t test, and independent sample n t test.n Results:At 24 h after seeding, the rate of β-galactosidase-positive staining of HDF in high glucose group was (38.4±4.2)%, which was significantly higher than (16.5±2.2)% of low glucose group (n t=4.65, n P<0.01). At 48 h after seeding, the expression levels of senescence-related proteins p16 and p53 both were significantly higher in HDFs of high glucose group than those in low glucose group (withn t values of 11.85 and 3.02, respectively, n P<0.05 orn P<0.01). At 0, 24, 48, and 72 h after seeding, the cell proliferation viability of HDFs in high glucose group was all significantly lower than in low glucose group (withn t values of 4.13, 9.90, and 15.12, respectively, n P<0.01). At 48 h after seeding, the rate of EdU-positive staining of HDFs in high glucose group was obviously lower than that of low glucose group (n t=3.83, n P<0.05). At 48 h after seeding, the percentage of G2/M+S subpopulations in three subpopulations (G0/G1, S, and G2/M) of HDF cycle was significantly lower in high glucose group than that in low glucose group (n t=8.74, n P<0.01). At 24 h after seeding, the number of HDFs migrated through the filter membrane to the lower chamber was 37±6 in high glucose group, which was significantly less than 74±7 in low glucose group (n t=8.42, n P<0.01). At 48 h after seeding, the HDF apoptosis rate was significantly higher in high glucose group than in low glucose group (n t=8.48, n P<0.01). The dMSC exosomes were cup-shaped or round vesicles with well-defined edges and uniform size distribution. The size of dMSC exosomes was basically in the range of 80-200 nm. Exosomal markers including CD9 and TSG101 were positively presented on the dMSC exosomes. After being co-cultured for 24 hours, the dMSC exosomes were taken up intracellularly by HDFs and mainly distributed around the nucleus of HDFs. After being grouped and cultured for 24, 48, and 72 h, the HDF proliferation viabilities in high glucose+low concentration of exosomes group and high glucose+high concentration of exosomes group were both significantly higher than in high glucose alone group (withn t values of 6.36, 6.10, 7.76, 8.92, 12.17, and 10.74, respectively, n P<0.01), the HDF proliferation viability in high glucose+high concentration of exosomes group was significantly higher than in high glucose+low concentration of exosomes group (withn t values of 7.92, 4.82, and 4.72, respectively, n P<0.01). After being grouped and cultured for 48 h, the percentages of EdU-positive HDFs in high glucose+low concentration of exosomes group and high glucose+high concentration of exosomes group were both significantly higher than in high glucose alone group (withn t values of 5.32 and 9.88, respectively, n P<0.01), the percentage of EdU-positive HDFs in high glucose+high concentration of exosomes group was notably higher than in high glucose+low concentration of exosomes group (n t=5.27, n P<0.01). After being grouped and cultured for 48 h, the proportion of G0/G1 subpopulation in both high glucose+low concentration of exosomes group and high glucose+high concentration of exosomes group was distinctly lower (withn t values of 3.81 and 4.31, respectively, n P<0.05), while the proportion of G2/M+S subpopulation was markedly higher (withn t values of 3.81, 4.31, respectively, n P<0.05) than in high glucose alone group. After being grouped and cultured for 24 h, the number of HDFs migrated through the filter membrane in both high glucose+low concentration of exosomes group and high glucose+high concentration of exosomes group was significantly higher than in high glucose alone group (withn t values of 10.14 and 13.39, respectively, n P<0.01), the number of HDFs migrated through the filter membrane in high glucose+high concentration of exosomes group was significantly increased than in high glucose+low concentration of exosomes group (n t=6.27, n P<0.01). After being grouped and cultured for 48 h, the HDF apoptosis rates in high glucose+low concentration of exosomes group and high glucose+high concentration of exosomes group were both significantly lower than in high glucose alone group (withn t values of 3.72 and 5.53, respectively, n P<0.05 orn P<0.01). After being grouped and cultured for 48 h, compared with those in high glucose alone group, the mRNA expression levels of miR-145-5p and miR-498 were both obviously higher (withn t values of 13.03 and 8.90, respectively, n P<0.01), while the mRNA expression level of miR-503-5p was significantly lower (n t=3.85, n P<0.05) in high glucose+high concentration of exosomes group. After being grouped and cultured for 48 h, compared with those in high glucose alone group, the mRNA expression levels of CAMK1D and PTEN gene were both significantly lower (withn t values of 8.83 and 5.97, respectively, n P<0.01), while the mRNA expression level of Cyclin D1 was significantly higher in high glucose+high concentration of exosomes group (n t=4.03, n P<0.05).n Conclusions:The dMSC exosomes are capable of improving cell proliferation and migration, and inhibiting cell apoptosis of high-glucose senescent HDFs. This may be related to the mechanism by which the increased expressions of intracellular miR-145-5p and miR-498 inhibit the expression of CAMK1D and n PTEN gene, and the decreased expression of miR-503-5p promote the expression of Cyclin D1.n