Interleukin 17A(IL-17A)was previously shown to be a key pro-inflammatory factor in diabetes mellitus and associated complications.However,the role of IL-17A in diabetic encephalopathy remains poorly understood.In this...Interleukin 17A(IL-17A)was previously shown to be a key pro-inflammatory factor in diabetes mellitus and associated complications.However,the role of IL-17A in diabetic encephalopathy remains poorly understood.In this study,we established a mouse model of diabetic encephalopathy that was deficient in IL-17A by crossing Il17a-/-mice with spontaneously diabetic Ins2^(Akita)(Akita)mice.Blood glucose levels and body weights were monitored from 2-32 weeks of age.When mice were 32 weeks of age,behavioral tests were performed,including a novel object recognition test for assessing short-term memory and learning and a Morris water maze test for evaluating hippocampus-dependent spatial learning and memory.IL-17A levels in the serum,cerebrospinal fluid,and hippocampus were detected with enzyme-linked immunosorbent assays and real-time quantitative polymerase chain reaction.Moreover,proteins related to cognitive dysfunction(amyloid precursor protein,β-amyloid cleavage enzyme 1,p-tau,and tau),apoptosis(caspase-3 and-9),inflammation(inducible nitric oxide synthase and cyclooxygenase 2),and occludin were detected by western blot assays.Pro-inflammatory cytokines including tumor necrosis factor-α,interleukin-1β,and interferon-γin serum and hippocampal tissues were measured by enzyme-linked immunosorbent assays.Microglial activation and hippocampal neuronal apoptosis were detected by immunofluorescent staining.Compared with that in wild-type mice,mice with diabetic encephalopathy had higher IL-17A levels in the serum,cerebrospinal fluid,and hippocampus;downregulation of occludin expression;lower cognitive ability;greater loss of hippocampal neurons;increased microglial activation;and higher expression of inflammatory factors in the serum and hippocampus.IL-17A knockout attenuated the abovementioned changes in mice with diabetic encephalopathy.These findings suggest that IL-17A participates in the pathological process of diabetic encephalopathy.Furthermore,IL-17A deficiency reduces diabetic encephalopathy-mediated neuroinflammation and cognitive defects.These results highlight a role for IL-17A as a mediator of diabetic encephalopathy and potential target for the treatment of cognitive impairment induced by diabetic encephalopathy.展开更多
Summary:Interleukin 17A(IL 17A)is reported to be involved in many inflammatory processes,but its role in aortic valve diseases remains unknown.We examined the role of IL17A based on an ApoE^-/-mouse model with strateg...Summary:Interleukin 17A(IL 17A)is reported to be involved in many inflammatory processes,but its role in aortic valve diseases remains unknown.We examined the role of IL17A based on an ApoE^-/-mouse model with strategies as fed with high-fat diet or treated with ILI7A monoclonal antibody(mAb).12 weeks of high-fat diet feeding can elevate cytokines secretion,inflammatory cells infiltration and myofibroblastic transition of valvular interstitial cells(VICs)in aortic valve.Moreover,diet-induction accelerated interleukin 17 receptor A(IL17RA)activation in VICs.In an IL17A inhibition model,the treatment group was intra-peritoneally injected with anti-IL17A mAb while controls received irrelevant antibody.Functional blockade of IL17A markedly reduced cellular infiltration and transition in aortic valve.To investigate potential mechanisms,NF-kB was co-stained in IL17RA^+VICs and IL17RA macrophages,and further confirmed by Western blotting in VICs.High-fat diet could activate NF-kB nuclear translocation in IL17RA^+VICs and IL17RA^+macrophages and this process was depressed after IL17A mAb-treatment.In conclusion,high-fat diet can lead to IL17A upregulation,VICs myofibroblastic transition and inflammatory cells infiltration in the aortic value of ApoE^-/-mice.Blocking IL17A with IL17A mAb can alleviate aortic valve inflammatory states.展开更多
BACKGROUND Advanced glycation end products(AGE)are a marker of various diseases including diabetes,in which they participate to vascular damages such as retinopathy,nephropathy and coronaropathy.Besides those vascular...BACKGROUND Advanced glycation end products(AGE)are a marker of various diseases including diabetes,in which they participate to vascular damages such as retinopathy,nephropathy and coronaropathy.Besides those vascular complications,AGE are involved in altered metabolism in many tissues,including adipose tissue(AT)where they contribute to reduced glucose uptake and attenuation of insulin sensitivity.AGE are known to contribute to type 1 diabetes(T1D)through promotion of interleukin(IL)-17 secreting T helper(Th17)cells.AIM To investigate whether lean adipose-derived stem cells(ASC)could be able to induce IL-17A secretion,with the help of AGE.METHODS As we have recently demonstrated that ASC are involved in Th17 cell promotion when they are harvested from obese AT,we used the same co-culture model to measure the impact of glycated human serum albumin(G-HSA)on human lean ASC interacting with blood mononuclear cells.IL-17A and pro-inflammatory cytokine secretion were measured by ELISA.Receptor of AGE(RAGE)together with intercellular adhesion molecule 1(ICAM-1),human leukocyte Antigen(HLA)-DR,cluster of differentiation(CD)41,and CD62P surface expressions were measured by cytofluorometry.Anti-RAGE specific monoclonal antibody was added to co-cultures in order to evaluate the role of RAGE in IL-17A production.RESULTS Results showed that whereas 1%G-HSA only weakly potentiated the production of IL-17A by T cells interacting with ASC harvested from obese subjects,it markedly increased IL-17A,but also interferon gamma and tumor necrosis factor alpha production in the presence of ASC harvested from lean individuals.This was associated with increased expression of RAGE and HLA-DR molecule by cocultured cells.Moreover,RAGE blockade experiments demonstrated RAGE specific involvement in lean ASC-mediated Th-17 cell activation.Finally,platelet aggregation and ICAM-1,which are known to be induced by AGE,were not involved in these processes.CONCLUSION Thus,our results demonstrated that G-HSA potentiated lean ASC-mediated IL-17A production in AT,suggesting a new mechanism by which AGE could contribute to T1D pathophysiology.展开更多
基金supported by the Natural Science Foundation of Jiangsu Province of China, No.BK20180948(to ZL)Nantong Applied Research Program of China, No.MS12019011(to XXF)Science and Technology Project of Nantong University of China, No.TDYXY2019007(to XXF)
文摘Interleukin 17A(IL-17A)was previously shown to be a key pro-inflammatory factor in diabetes mellitus and associated complications.However,the role of IL-17A in diabetic encephalopathy remains poorly understood.In this study,we established a mouse model of diabetic encephalopathy that was deficient in IL-17A by crossing Il17a-/-mice with spontaneously diabetic Ins2^(Akita)(Akita)mice.Blood glucose levels and body weights were monitored from 2-32 weeks of age.When mice were 32 weeks of age,behavioral tests were performed,including a novel object recognition test for assessing short-term memory and learning and a Morris water maze test for evaluating hippocampus-dependent spatial learning and memory.IL-17A levels in the serum,cerebrospinal fluid,and hippocampus were detected with enzyme-linked immunosorbent assays and real-time quantitative polymerase chain reaction.Moreover,proteins related to cognitive dysfunction(amyloid precursor protein,β-amyloid cleavage enzyme 1,p-tau,and tau),apoptosis(caspase-3 and-9),inflammation(inducible nitric oxide synthase and cyclooxygenase 2),and occludin were detected by western blot assays.Pro-inflammatory cytokines including tumor necrosis factor-α,interleukin-1β,and interferon-γin serum and hippocampal tissues were measured by enzyme-linked immunosorbent assays.Microglial activation and hippocampal neuronal apoptosis were detected by immunofluorescent staining.Compared with that in wild-type mice,mice with diabetic encephalopathy had higher IL-17A levels in the serum,cerebrospinal fluid,and hippocampus;downregulation of occludin expression;lower cognitive ability;greater loss of hippocampal neurons;increased microglial activation;and higher expression of inflammatory factors in the serum and hippocampus.IL-17A knockout attenuated the abovementioned changes in mice with diabetic encephalopathy.These findings suggest that IL-17A participates in the pathological process of diabetic encephalopathy.Furthermore,IL-17A deficiency reduces diabetic encephalopathy-mediated neuroinflammation and cognitive defects.These results highlight a role for IL-17A as a mediator of diabetic encephalopathy and potential target for the treatment of cognitive impairment induced by diabetic encephalopathy.
基金This project was supported by grants from the National Key Research and Development Program of China(No.2016YFA0101100)National Natural Science Foundation of China(No.81700339 and No.31330029)Scientific Research Training Program for Young Talents sponsored by Union Hospital,Tongji Medical College,Huazhong University of Science and Technology。
文摘Summary:Interleukin 17A(IL 17A)is reported to be involved in many inflammatory processes,but its role in aortic valve diseases remains unknown.We examined the role of IL17A based on an ApoE^-/-mouse model with strategies as fed with high-fat diet or treated with ILI7A monoclonal antibody(mAb).12 weeks of high-fat diet feeding can elevate cytokines secretion,inflammatory cells infiltration and myofibroblastic transition of valvular interstitial cells(VICs)in aortic valve.Moreover,diet-induction accelerated interleukin 17 receptor A(IL17RA)activation in VICs.In an IL17A inhibition model,the treatment group was intra-peritoneally injected with anti-IL17A mAb while controls received irrelevant antibody.Functional blockade of IL17A markedly reduced cellular infiltration and transition in aortic valve.To investigate potential mechanisms,NF-kB was co-stained in IL17RA^+VICs and IL17RA macrophages,and further confirmed by Western blotting in VICs.High-fat diet could activate NF-kB nuclear translocation in IL17RA^+VICs and IL17RA^+macrophages and this process was depressed after IL17A mAb-treatment.In conclusion,high-fat diet can lead to IL17A upregulation,VICs myofibroblastic transition and inflammatory cells infiltration in the aortic value of ApoE^-/-mice.Blocking IL17A with IL17A mAb can alleviate aortic valve inflammatory states.
文摘BACKGROUND Advanced glycation end products(AGE)are a marker of various diseases including diabetes,in which they participate to vascular damages such as retinopathy,nephropathy and coronaropathy.Besides those vascular complications,AGE are involved in altered metabolism in many tissues,including adipose tissue(AT)where they contribute to reduced glucose uptake and attenuation of insulin sensitivity.AGE are known to contribute to type 1 diabetes(T1D)through promotion of interleukin(IL)-17 secreting T helper(Th17)cells.AIM To investigate whether lean adipose-derived stem cells(ASC)could be able to induce IL-17A secretion,with the help of AGE.METHODS As we have recently demonstrated that ASC are involved in Th17 cell promotion when they are harvested from obese AT,we used the same co-culture model to measure the impact of glycated human serum albumin(G-HSA)on human lean ASC interacting with blood mononuclear cells.IL-17A and pro-inflammatory cytokine secretion were measured by ELISA.Receptor of AGE(RAGE)together with intercellular adhesion molecule 1(ICAM-1),human leukocyte Antigen(HLA)-DR,cluster of differentiation(CD)41,and CD62P surface expressions were measured by cytofluorometry.Anti-RAGE specific monoclonal antibody was added to co-cultures in order to evaluate the role of RAGE in IL-17A production.RESULTS Results showed that whereas 1%G-HSA only weakly potentiated the production of IL-17A by T cells interacting with ASC harvested from obese subjects,it markedly increased IL-17A,but also interferon gamma and tumor necrosis factor alpha production in the presence of ASC harvested from lean individuals.This was associated with increased expression of RAGE and HLA-DR molecule by cocultured cells.Moreover,RAGE blockade experiments demonstrated RAGE specific involvement in lean ASC-mediated Th-17 cell activation.Finally,platelet aggregation and ICAM-1,which are known to be induced by AGE,were not involved in these processes.CONCLUSION Thus,our results demonstrated that G-HSA potentiated lean ASC-mediated IL-17A production in AT,suggesting a new mechanism by which AGE could contribute to T1D pathophysiology.
