[小gtp结合蛋白GDP解离刺激剂对小鼠脂肪细胞肥大和糖代谢紊乱的影响]。

T Xiong, T Wang, X W Chen, Y X Yang, Z W Ma, B Y Zuo, D X Wang
{"title":"[小gtp结合蛋白GDP解离刺激剂对小鼠脂肪细胞肥大和糖代谢紊乱的影响]。","authors":"T Xiong,&nbsp;T Wang,&nbsp;X W Chen,&nbsp;Y X Yang,&nbsp;Z W Ma,&nbsp;B Y Zuo,&nbsp;D X Wang","doi":"10.3760/cma.j.cn112138-20230209-00072","DOIUrl":null,"url":null,"abstract":"<p><p><b>Objective:</b> To explore the effect and mechanism of small GTP-binding protein GDP dissociation stimulator (SmgGDS) on the development of obesity. <b>Methods:</b> (1) 8-week-old C57BL/6J mice were randomly assigned to normal diet and high fat diet group, with 6 mice in each group. They were fed regular feed and a high fat diet containing 60% fat for 4 months, respectively. The expression of SmgGDS in epididymal adipose tissue (eWAT), liver, and skeletal muscle were measured using Western-blot. (2) 6-week-old wild-type (WT) and SmgGDS knockdown (KD) mice were divided into four groups, each receiving high fat diet for 4 months (7 in each group) and 7 months (9 in each group). Glucose tolerance test (GTT) and insulin tolerance test (ITT) were conducted; The weight, adipose tissue, and liver weight of mice were recorded; HE staining examined adipose tissue structural changes; Western-blot determined extracellular signal-regulated kinase (ERK) 1/2 phosphorylation levels in eWAT; Real time fluorescence quantitative polymerase chain reaction (RT-qPCR) was used to detect mRNA levels of CCAAT/enhancer binding protein α (C/EBPα), C/EBPβ and peroxisome proliferator activated receptor γ (PPARγ) in eWAT. (3) Mouse embryonic fibroblasts (MEFs) extracted from WT and KD mice were induced for differentiation. Oil red O staining and Western-blot were used to detect lipid droplet and expression of SmgGDS and phospho-ERK; C/EBPα, C/EBPβ and PPARγ mRNA levels were measured using RT-qPCR. (4) 10-week-old C57BL/6J mice were randomly assigned into two groups, with 7 mice in each group. Mice were infected with SmgGDS overexpressing adeno-associated virus (AAV-SmgGDS) or empty vector intraperitoneally, then fed with high fat diet. After 4 weeks, performed GTT and ITT; Recorded the weight and adipose tissue weight of mice; HE staining was used to analyze structural changes of eWAT; Western-blot was used to detect the phosphorylation level of ERK in eWAT. <b>Results:</b> (1) The expression of SmgGDS was significantly upregulated in eWAT of high fat diet fed mice (normal diet group: 0.218±0.037, high fat diet group:0.439±0.072, <i>t</i>=2.74, <i>P</i>=0.034). (2) At 4 months of high fat diet intervention, the glucose tolerance (60 minutes after glucose injection, WT group: 528 mg/dl±21 mg/dl, KD group: 435 mg/dl±17 mg/dl, <i>t</i>=3.47, <i>P</i>=0.030; 90 minutes, WT group: 463 mg/dl±24 mg/dl, KD group: 366 mg/dl±18 mg/dl, <i>t</i>=3.23, <i>P</i>=0.047;120 minutes, WT group: 416 mg/dl±21 mg/dl, KD group: 297 mg/dl±16 mg/dl, <i>t</i>=4.49, <i>P</i>=0.005) and insulin sensitivity (15 minutes after insulin injection, WT group: 77.79%±3.45%, KD group: 54.30%±2.92%, <i>t</i>=3.49, <i>P</i>=0.005; 30 minutes, WT group: 62.27%±5.31%, KD group: 42.25%±1.85%, <i>t</i>=2.978, <i>P</i>=0.024; 90 minutes, WT group: 85.69%±6.63%, KD group: 64.71%±5.41%, <i>t</i>=3.120, <i>P</i>=0.016) of KD mice were significantly improved compared to the WT group, with an increase in eWAT weight ratio (WT: 4.19%±0.18%, KD: 5.12%±0.37%, <i>t</i>=2.28, <i>P</i>=0.042), but a decrease in average adipocyte area (WT group: 5221 μm²±241 μm², KD group: 4410 μm²±196 μm², <i>t</i>=2.61, <i>P</i>=0.026). After 7 months of high fat diet, the eWAT weight ratio of KD mice decreased (WT: 5.02%±0.20%, KD: 3.88%±0.21%, <i>t</i>=3.92, <i>P</i>=0.001) and adipocyte size decreased (WT group: 6 783 μm²±390 μm², KD group: 4785 μm²±303 μm², <i>t</i>=4.05, <i>P</i>=0.002). The phospho-ERK1 in eWAT increased (WT group: 0.174±0.056, KD group: 0.588±0.147, <i>t</i>=2.64, <i>P</i>=0.025), and mRNA level of PPARγ significantly decreased (WT group: 1.018±0.128, KD group: 0.029±0.015, <i>t</i>=7.70, <i>P</i>=0.015). (3) The expression of SmgGDS was significantly increased in differentiated MEF (undifferentiated: 6.789±0.511, differentiated: 10.170±0.523, <i>t</i>=4.63, <i>P</i>=0.010); SmgGDS knock-down inhibited lipid droplet formation in MEF (WT group: 1.00±0.02, KD group: 0.88±0.02, <i>t</i>=5.05, <i>P</i>=0.007) and increased ERK1 (WT group: 0.600±0.179, KD group: 1.325±0.102, <i>t</i>=3.52, <i>P</i>=0.025) and ERK2 (WT group: 2.179±0.687, KD group: 5.200±0.814, <i>t</i>=2.84, <i>P</i>=0.047) activity, which can be reversed by ERK1/2 inhibitor. (4) SmgGDS over expression resulted in weight gain, increased eWAT weight (control group: 3.29%±0.36%, AAV-SmgGDS group: 4.27%±0.26%, <i>t</i>=2.20, <i>P</i>=0.048) and adipocyte size (control group: 3525 μm²±454 μm², AAV-SmgGDS group: 5326 μm²±655 μm², <i>t</i>=2.26, <i>P</i>=0.047), impaired insulin sensitivity(30 minutes after insulin injection, control group: 44.03%±4.29%, AAV-SmgGDS group: 62.70%±2.81%, <i>t</i>=3.06, <i>P</i>=0.019), and decreased ERK1 (control group: 0.829±0.077, AAV-SmgGDS group: 0.326±0.036, <i>t</i>=5.96, <i>P</i>=0.001)and ERK2 (control group: 5.748±0.287, AAV-SmgGDS group: 2.999±0.845, <i>t</i>=3.08, <i>P</i>=0.022) activity in eWAT. <b>Conclusion:</b> SmgGDS knockdown improves obesity related glucose metabolism disorder by inhibiting adipogenesis and adipose tissue hypertrophy, which is associated with ERK activation.</p>","PeriodicalId":24000,"journal":{"name":"Zhonghua nei ke za zhi","volume":"62 ","pages":"833-840"},"PeriodicalIF":0.0000,"publicationDate":"2023-06-09","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"[Effects of small GTP-binding protein GDP dissociation stimulator on adipocyte hypertrophy and glucose metabolism disorder in mice].\",\"authors\":\"T Xiong,&nbsp;T Wang,&nbsp;X W Chen,&nbsp;Y X Yang,&nbsp;Z W Ma,&nbsp;B Y Zuo,&nbsp;D X Wang\",\"doi\":\"10.3760/cma.j.cn112138-20230209-00072\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p><b>Objective:</b> To explore the effect and mechanism of small GTP-binding protein GDP dissociation stimulator (SmgGDS) on the development of obesity. <b>Methods:</b> (1) 8-week-old C57BL/6J mice were randomly assigned to normal diet and high fat diet group, with 6 mice in each group. They were fed regular feed and a high fat diet containing 60% fat for 4 months, respectively. The expression of SmgGDS in epididymal adipose tissue (eWAT), liver, and skeletal muscle were measured using Western-blot. (2) 6-week-old wild-type (WT) and SmgGDS knockdown (KD) mice were divided into four groups, each receiving high fat diet for 4 months (7 in each group) and 7 months (9 in each group). Glucose tolerance test (GTT) and insulin tolerance test (ITT) were conducted; The weight, adipose tissue, and liver weight of mice were recorded; HE staining examined adipose tissue structural changes; Western-blot determined extracellular signal-regulated kinase (ERK) 1/2 phosphorylation levels in eWAT; Real time fluorescence quantitative polymerase chain reaction (RT-qPCR) was used to detect mRNA levels of CCAAT/enhancer binding protein α (C/EBPα), C/EBPβ and peroxisome proliferator activated receptor γ (PPARγ) in eWAT. (3) Mouse embryonic fibroblasts (MEFs) extracted from WT and KD mice were induced for differentiation. Oil red O staining and Western-blot were used to detect lipid droplet and expression of SmgGDS and phospho-ERK; C/EBPα, C/EBPβ and PPARγ mRNA levels were measured using RT-qPCR. (4) 10-week-old C57BL/6J mice were randomly assigned into two groups, with 7 mice in each group. Mice were infected with SmgGDS overexpressing adeno-associated virus (AAV-SmgGDS) or empty vector intraperitoneally, then fed with high fat diet. After 4 weeks, performed GTT and ITT; Recorded the weight and adipose tissue weight of mice; HE staining was used to analyze structural changes of eWAT; Western-blot was used to detect the phosphorylation level of ERK in eWAT. <b>Results:</b> (1) The expression of SmgGDS was significantly upregulated in eWAT of high fat diet fed mice (normal diet group: 0.218±0.037, high fat diet group:0.439±0.072, <i>t</i>=2.74, <i>P</i>=0.034). (2) At 4 months of high fat diet intervention, the glucose tolerance (60 minutes after glucose injection, WT group: 528 mg/dl±21 mg/dl, KD group: 435 mg/dl±17 mg/dl, <i>t</i>=3.47, <i>P</i>=0.030; 90 minutes, WT group: 463 mg/dl±24 mg/dl, KD group: 366 mg/dl±18 mg/dl, <i>t</i>=3.23, <i>P</i>=0.047;120 minutes, WT group: 416 mg/dl±21 mg/dl, KD group: 297 mg/dl±16 mg/dl, <i>t</i>=4.49, <i>P</i>=0.005) and insulin sensitivity (15 minutes after insulin injection, WT group: 77.79%±3.45%, KD group: 54.30%±2.92%, <i>t</i>=3.49, <i>P</i>=0.005; 30 minutes, WT group: 62.27%±5.31%, KD group: 42.25%±1.85%, <i>t</i>=2.978, <i>P</i>=0.024; 90 minutes, WT group: 85.69%±6.63%, KD group: 64.71%±5.41%, <i>t</i>=3.120, <i>P</i>=0.016) of KD mice were significantly improved compared to the WT group, with an increase in eWAT weight ratio (WT: 4.19%±0.18%, KD: 5.12%±0.37%, <i>t</i>=2.28, <i>P</i>=0.042), but a decrease in average adipocyte area (WT group: 5221 μm²±241 μm², KD group: 4410 μm²±196 μm², <i>t</i>=2.61, <i>P</i>=0.026). After 7 months of high fat diet, the eWAT weight ratio of KD mice decreased (WT: 5.02%±0.20%, KD: 3.88%±0.21%, <i>t</i>=3.92, <i>P</i>=0.001) and adipocyte size decreased (WT group: 6 783 μm²±390 μm², KD group: 4785 μm²±303 μm², <i>t</i>=4.05, <i>P</i>=0.002). The phospho-ERK1 in eWAT increased (WT group: 0.174±0.056, KD group: 0.588±0.147, <i>t</i>=2.64, <i>P</i>=0.025), and mRNA level of PPARγ significantly decreased (WT group: 1.018±0.128, KD group: 0.029±0.015, <i>t</i>=7.70, <i>P</i>=0.015). (3) The expression of SmgGDS was significantly increased in differentiated MEF (undifferentiated: 6.789±0.511, differentiated: 10.170±0.523, <i>t</i>=4.63, <i>P</i>=0.010); SmgGDS knock-down inhibited lipid droplet formation in MEF (WT group: 1.00±0.02, KD group: 0.88±0.02, <i>t</i>=5.05, <i>P</i>=0.007) and increased ERK1 (WT group: 0.600±0.179, KD group: 1.325±0.102, <i>t</i>=3.52, <i>P</i>=0.025) and ERK2 (WT group: 2.179±0.687, KD group: 5.200±0.814, <i>t</i>=2.84, <i>P</i>=0.047) activity, which can be reversed by ERK1/2 inhibitor. (4) SmgGDS over expression resulted in weight gain, increased eWAT weight (control group: 3.29%±0.36%, AAV-SmgGDS group: 4.27%±0.26%, <i>t</i>=2.20, <i>P</i>=0.048) and adipocyte size (control group: 3525 μm²±454 μm², AAV-SmgGDS group: 5326 μm²±655 μm², <i>t</i>=2.26, <i>P</i>=0.047), impaired insulin sensitivity(30 minutes after insulin injection, control group: 44.03%±4.29%, AAV-SmgGDS group: 62.70%±2.81%, <i>t</i>=3.06, <i>P</i>=0.019), and decreased ERK1 (control group: 0.829±0.077, AAV-SmgGDS group: 0.326±0.036, <i>t</i>=5.96, <i>P</i>=0.001)and ERK2 (control group: 5.748±0.287, AAV-SmgGDS group: 2.999±0.845, <i>t</i>=3.08, <i>P</i>=0.022) activity in eWAT. <b>Conclusion:</b> SmgGDS knockdown improves obesity related glucose metabolism disorder by inhibiting adipogenesis and adipose tissue hypertrophy, which is associated with ERK activation.</p>\",\"PeriodicalId\":24000,\"journal\":{\"name\":\"Zhonghua nei ke za zhi\",\"volume\":\"62 \",\"pages\":\"833-840\"},\"PeriodicalIF\":0.0000,\"publicationDate\":\"2023-06-09\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Zhonghua nei ke za zhi\",\"FirstCategoryId\":\"1085\",\"ListUrlMain\":\"https://doi.org/10.3760/cma.j.cn112138-20230209-00072\",\"RegionNum\":0,\"RegionCategory\":null,\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"\",\"JCRName\":\"\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Zhonghua nei ke za zhi","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3760/cma.j.cn112138-20230209-00072","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0

摘要

目的:探讨小gtp结合蛋白GDP解离刺激剂(SmgGDS)在肥胖发生中的作用及机制。方法:(1)将8周龄C57BL/6J小鼠随机分为正常饮食组和高脂饮食组,每组6只。分别饲喂常规饲料和脂肪含量为60%的高脂饲料4个月。采用Western-blot法检测SmgGDS在附睾脂肪组织(eWAT)、肝脏和骨骼肌中的表达。(2) 6周龄野生型(WT)和SmgGDS敲低(KD)小鼠分为4组,每组高脂饮食4个月(每组7只)和7个月(每组9只)。进行葡萄糖耐量试验(GTT)和胰岛素耐量试验(ITT);记录小鼠体重、脂肪组织、肝脏重量;HE染色检测脂肪组织结构变化;Western-blot检测eWAT细胞外信号调节激酶(ERK) 1/2磷酸化水平;采用实时荧光定量聚合酶链反应(RT-qPCR)检测eWAT中CCAAT/增强子结合蛋白α (C/EBPα)、C/EBPβ和过氧化物酶体增殖物激活受体γ (PPARγ) mRNA水平。(3)分别从WT和KD小鼠中提取小鼠胚胎成纤维细胞(mef)进行诱导分化。油红O染色、Western-blot检测脂滴及SmgGDS、phospho-ERK的表达;RT-qPCR检测C/EBPα、C/EBPβ和PPARγ mRNA水平。(4)将10周龄C57BL/6J小鼠随机分为两组,每组7只。用过表达腺相关病毒(AAV-SmgGDS)或空载体腹腔感染小鼠,饲喂高脂饲料。4周后行GTT和ITT;记录小鼠体重和脂肪组织重量;HE染色分析eWAT的结构变化;Western-blot检测eWAT中ERK的磷酸化水平。结果:(1)高脂饲粮小鼠eWAT中SmgGDS表达显著上调(正常饲粮组:0.218±0.037,高脂饲粮组:0.439±0.072,t=2.74, P=0.034)。(2)高脂饮食干预4个月时,糖耐量(葡萄糖注射后60分钟,WT组:528 mg/dl±21 mg/dl, KD组:435 mg/dl±17 mg/dl, t=3.47, P=0.030;90分钟,WT组:463 mg/dl±24 mg/dl, KD组:366 mg/dl±18 mg/dl, t=3.23, P=0.047;120分钟,WT组:416 mg/dl±21 mg/dl, KD组:297 mg/dl±16 mg/dl, t=4.49, P=0.005)胰岛素敏感性(胰岛素注射后15分钟,WT组:77.79%±3.45%,KD组:54.30%±2.92%,t=3.49, P=0.005;30分钟,WT组:62.27%±5.31%,KD组:42.25%±1.85%,t=2.978, P=0.024;90分钟,WT组:85.69%±6.63%,KD组:64.71%±5.41%,t=3.120, P=0.016), KD小鼠的eWAT重量比增加(WT: 4.19%±0.18%,KD: 5.12%±0.37%,t=2.28, P=0.042),但平均脂肪细胞面积减少(WT组:5221 μ²±241 μ²,KD组:4410 μ²±196 μ²,t=2.61, P=0.026)。高脂饮食7个月后,KD组小鼠eWAT体重比降低(WT: 5.02%±0.20%,KD: 3.88%±0.21%,t=3.92, P=0.001),脂肪细胞大小减小(WT组:6 783 μ²±390 μ²,KD组:4785 μ²±303 μ²,t=4.05, P=0.002)。eWAT组织磷酸化erk1升高(WT组:0.174±0.056,KD组:0.588±0.147,t=2.64, P=0.025), PPARγ mRNA水平显著降低(WT组:1.018±0.128,KD组:0.029±0.015,t=7.70, P=0.015)。(3) SmgGDS在分化MEF中的表达显著增加(未分化:6.789±0.511,分化:10.170±0.523,t=4.63, P=0.010);SmgGDS敲除抑制MEF (WT组:1.00±0.02,KD组:0.88±0.02,t=5.05, P=0.007)脂滴形成,提高ERK1 (WT组:0.600±0.179,KD组:1.325±0.102,t=3.52, P=0.025)和ERK2 (WT组:2.179±0.687,KD组:5.200±0.814,t=2.84, P=0.047)活性,ERK1/2抑制剂可逆转。(4) SmgGDS过表达导致体重增加,eWAT体重增加(对照组:3.29%±0.36%,AAV-SmgGDS组:4.27%±0.26%,t=2.20, P=0.048),脂肪细胞大小增加(对照组:3525 μ²±454 μ²,AAV-SmgGDS组:5326 μ²±655 μ²,t=2.26, P=0.047),胰岛素敏感性降低(胰岛素注射后30分钟,对照组:44.03%±4.29%,AAV-SmgGDS组:62.70%±2.81%,t=3.06, P=0.019), ERK1降低(对照组:0.829±0.077,AAV-SmgGDS组:0.829±0.077);0.326±0.036,t=5.96, P=0.001)和ERK2(对照组:5.748±0.287,AAV-SmgGDS组:2.999±0.845,t=3.08, P=0.022)活性。结论:SmgGDS敲低可通过抑制脂肪生成和脂肪组织肥大改善肥胖相关糖代谢紊乱,而脂肪生成和脂肪组织肥大与ERK激活有关。
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[Effects of small GTP-binding protein GDP dissociation stimulator on adipocyte hypertrophy and glucose metabolism disorder in mice].

Objective: To explore the effect and mechanism of small GTP-binding protein GDP dissociation stimulator (SmgGDS) on the development of obesity. Methods: (1) 8-week-old C57BL/6J mice were randomly assigned to normal diet and high fat diet group, with 6 mice in each group. They were fed regular feed and a high fat diet containing 60% fat for 4 months, respectively. The expression of SmgGDS in epididymal adipose tissue (eWAT), liver, and skeletal muscle were measured using Western-blot. (2) 6-week-old wild-type (WT) and SmgGDS knockdown (KD) mice were divided into four groups, each receiving high fat diet for 4 months (7 in each group) and 7 months (9 in each group). Glucose tolerance test (GTT) and insulin tolerance test (ITT) were conducted; The weight, adipose tissue, and liver weight of mice were recorded; HE staining examined adipose tissue structural changes; Western-blot determined extracellular signal-regulated kinase (ERK) 1/2 phosphorylation levels in eWAT; Real time fluorescence quantitative polymerase chain reaction (RT-qPCR) was used to detect mRNA levels of CCAAT/enhancer binding protein α (C/EBPα), C/EBPβ and peroxisome proliferator activated receptor γ (PPARγ) in eWAT. (3) Mouse embryonic fibroblasts (MEFs) extracted from WT and KD mice were induced for differentiation. Oil red O staining and Western-blot were used to detect lipid droplet and expression of SmgGDS and phospho-ERK; C/EBPα, C/EBPβ and PPARγ mRNA levels were measured using RT-qPCR. (4) 10-week-old C57BL/6J mice were randomly assigned into two groups, with 7 mice in each group. Mice were infected with SmgGDS overexpressing adeno-associated virus (AAV-SmgGDS) or empty vector intraperitoneally, then fed with high fat diet. After 4 weeks, performed GTT and ITT; Recorded the weight and adipose tissue weight of mice; HE staining was used to analyze structural changes of eWAT; Western-blot was used to detect the phosphorylation level of ERK in eWAT. Results: (1) The expression of SmgGDS was significantly upregulated in eWAT of high fat diet fed mice (normal diet group: 0.218±0.037, high fat diet group:0.439±0.072, t=2.74, P=0.034). (2) At 4 months of high fat diet intervention, the glucose tolerance (60 minutes after glucose injection, WT group: 528 mg/dl±21 mg/dl, KD group: 435 mg/dl±17 mg/dl, t=3.47, P=0.030; 90 minutes, WT group: 463 mg/dl±24 mg/dl, KD group: 366 mg/dl±18 mg/dl, t=3.23, P=0.047;120 minutes, WT group: 416 mg/dl±21 mg/dl, KD group: 297 mg/dl±16 mg/dl, t=4.49, P=0.005) and insulin sensitivity (15 minutes after insulin injection, WT group: 77.79%±3.45%, KD group: 54.30%±2.92%, t=3.49, P=0.005; 30 minutes, WT group: 62.27%±5.31%, KD group: 42.25%±1.85%, t=2.978, P=0.024; 90 minutes, WT group: 85.69%±6.63%, KD group: 64.71%±5.41%, t=3.120, P=0.016) of KD mice were significantly improved compared to the WT group, with an increase in eWAT weight ratio (WT: 4.19%±0.18%, KD: 5.12%±0.37%, t=2.28, P=0.042), but a decrease in average adipocyte area (WT group: 5221 μm²±241 μm², KD group: 4410 μm²±196 μm², t=2.61, P=0.026). After 7 months of high fat diet, the eWAT weight ratio of KD mice decreased (WT: 5.02%±0.20%, KD: 3.88%±0.21%, t=3.92, P=0.001) and adipocyte size decreased (WT group: 6 783 μm²±390 μm², KD group: 4785 μm²±303 μm², t=4.05, P=0.002). The phospho-ERK1 in eWAT increased (WT group: 0.174±0.056, KD group: 0.588±0.147, t=2.64, P=0.025), and mRNA level of PPARγ significantly decreased (WT group: 1.018±0.128, KD group: 0.029±0.015, t=7.70, P=0.015). (3) The expression of SmgGDS was significantly increased in differentiated MEF (undifferentiated: 6.789±0.511, differentiated: 10.170±0.523, t=4.63, P=0.010); SmgGDS knock-down inhibited lipid droplet formation in MEF (WT group: 1.00±0.02, KD group: 0.88±0.02, t=5.05, P=0.007) and increased ERK1 (WT group: 0.600±0.179, KD group: 1.325±0.102, t=3.52, P=0.025) and ERK2 (WT group: 2.179±0.687, KD group: 5.200±0.814, t=2.84, P=0.047) activity, which can be reversed by ERK1/2 inhibitor. (4) SmgGDS over expression resulted in weight gain, increased eWAT weight (control group: 3.29%±0.36%, AAV-SmgGDS group: 4.27%±0.26%, t=2.20, P=0.048) and adipocyte size (control group: 3525 μm²±454 μm², AAV-SmgGDS group: 5326 μm²±655 μm², t=2.26, P=0.047), impaired insulin sensitivity(30 minutes after insulin injection, control group: 44.03%±4.29%, AAV-SmgGDS group: 62.70%±2.81%, t=3.06, P=0.019), and decreased ERK1 (control group: 0.829±0.077, AAV-SmgGDS group: 0.326±0.036, t=5.96, P=0.001)and ERK2 (control group: 5.748±0.287, AAV-SmgGDS group: 2.999±0.845, t=3.08, P=0.022) activity in eWAT. Conclusion: SmgGDS knockdown improves obesity related glucose metabolism disorder by inhibiting adipogenesis and adipose tissue hypertrophy, which is associated with ERK activation.

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