Instruction Shear stress,caused by the parallel frictional drag force of blood flow,is a biomechanical force which plays an important role in the control of blood vessels growth and functions [1]. Clinical researches ...Instruction Shear stress,caused by the parallel frictional drag force of blood flow,is a biomechanical force which plays an important role in the control of blood vessels growth and functions [1]. Clinical researches had found out that atherosclerotic le-展开更多
To examine the effect of myogenin gene on the differentiation of bovine skeletal muscle satellite cell, we constructed small interfering RNA plasmid vector to obtain myogenin knockdown bovine skeletal muscle cells, th...To examine the effect of myogenin gene on the differentiation of bovine skeletal muscle satellite cell, we constructed small interfering RNA plasmid vector to obtain myogenin knockdown bovine skeletal muscle cells, then used cell transfection, real time RCR and Western Blot to detect the influence of myogenin to cell differentiation. Results showed that the knockdown of myogenin significantly decreased its expression and other muscle-specific genes. Compared to the control, it could differentiate into few myotubes when challenged by low serum in the medium. These findings provided an important theoretical basis for further explore of the genetic mechanism in adult skeletal muscle, the remedy of muscle injuries and the cultivation of high-yield transgenic cattle.展开更多
OBJECTIVE Pulmonary artery hypertension(PAH)is a severe disease characterized by the mean pulmonary artery pressure exceeding 25 mm Hg at rest.PAH could induce right heart failure and has a very high mortality rate.At...OBJECTIVE Pulmonary artery hypertension(PAH)is a severe disease characterized by the mean pulmonary artery pressure exceeding 25 mm Hg at rest.PAH could induce right heart failure and has a very high mortality rate.At present,several kinds of drugs have been used in the treatment of PAH.However,most of these drugs aim to relax pulmonary arteries and do not inhibit the injury of vessels.In other words,the drugs available for PAH treatment do not improve the survival rate of PAH patients and cannot satisfy the needs in clinic.To discover and develop novel candidate compounds effective on the treatment of pulmonary artery injury and remodeling will be very important.Based on these background,the present study aimed to study the protective effect of two novel Rho-kinases(Rho-associated coiledcoil forming protein serine/threonine kinase,ROCK)inhibitors,DL0805 derivatives(DL0805-1and DL0805-2),on pulmonary arterial cells and further evaluate the underlying mechanisms and the possibility of DL0805 derivatives become therapeutic drugs for PAH.METHODS The primary cultured pulmonary arterial cells including human pulmonary artery endothelium cells(HPAECs)and human pulmonary artery smooth muscle cells(HPASMCs)were used in this study.HPAECs were injured under hypoxia environment(1%O2)and treated with or without DL0805 derivatives.After 48 h,the proliferation and oxidative stress were observed.CCK8 was used to detect cell viability.DCFH-DA was used as probe for reactive oxygen species(ROS)under fluorescence imaging system.HPASMCs was stimulated by growth factors including platelet-derived growth factor-BB(PDGF-BB)and Fetal Bovine Serum(FBS).The proliferation was observed in the cells treated with or without DL0805 derivatives.HPASMCs treated with or without DL0805 derivatives were further incubated with endothelin(ET-1),the proliferation and cytoskeleton remodeling of cells were detected by immunofluorescence assay.At last,Western blotting(WB)and immunofluorescence assay were employed to analysis the underlying mechanisms in the above experiments.RESULTS 10μmol·L-1DL0805-2 could inhibit the proliferation of HPAECs induced by hypoxia.Each concentration of DL0805-1 and DL0805-2attenuated the production of ROS in HPAECs.Results from WB indicated that DL0805 derivatives decreased the injury of HPAECs induced by hypoxia through the inhibition of the expression of Rho A and the activity of ROCK.On HPASMCs,DL0805 derivatives reduced the proliferation induced by PDGF-BB and FBS and inhibited cytoskeleton remodeling induced by ET-1.Immunofluorescence assay showed that DL0805 derivatives inhibited ROCK activity and down regulated the phosphorylation levels of ROCK substrates.CONCLUSION DL0805derivatives exhibited protective effect on pulmonary arterial cells including endothelium cells and smooth muscle cells.Among the above experiments,DL0805-2 showed stronger potency than DL0805-1.These two compounds might protect the cells through the inhibition of Rho A/ROCK pathway and they probably have the potential in the treatment of PAH and deserve further evaluation.展开更多
Vascular remodeling,which can be found in atherosclerosis,restenosis after angioplasty,hypertension,and some other frequent and serious chronic diseases.Smooth muscle cell(SMC)phenotype change,which has been described...Vascular remodeling,which can be found in atherosclerosis,restenosis after angioplasty,hypertension,and some other frequent and serious chronic diseases.Smooth muscle cell(SMC)phenotype change,which has been described as converting from a contractile state into a synthetic phenotype,is a crucial event during vascular remodeling.Recently,micro RNAs(mi RNAs)a kind of small non-coding RNA molecules,has been proven to target critical genes of cell signaling pathways to regulate SMC phenotypic change.By searching the Pub Med,Embase,reviews,and reference listsof relevant papers,we systematically carried out a review of the literature to provide an overview of the mi RNAs and their target genes in cell signaling pathways,focus inthe pathways involving in SMC phenotype change.To be specific,mi RNAs that regulate genes involved in the MAPK signaling pathways(such as:mi R-155,mi R-92a,mi R-424/503,mi R-133,mi R-181b,mi R-31,mi R-1298,mi R-132,mi R-200c and mi R-483-3p),mi RNAs target genes involved in the TGF-βsignaling pathways(including mi R-24,mi R-17/92 cluster,mi R-599,mi R-21 and mi R-143/145),mi RNAs target the genes involved in the AMPK signaling pathways including mi R-144/451 and mi R-195,mi RNAs target the genes involved in the PI3K-Akt signaling pathways(including mi R-138,mi R-34c,mi R-223,mi R-761,mi R-10a,mi R-146a),mi R-199a-5ptargets the genes involved in the Wnt signaling pathways mi RNAs(mi R-221/222,mi R-15b,mi R-24/29a,mi R-224)involved in the PDGF signaling pathways and some mi RNAs(mi R-638,mi R-328,mi R-365,mi R-663,mi R-29b,mi R-130,mi R-142-5p,mi R-424/322)which regulate SMC phenotype change by other corresponding targets were in detailed discussed in our review.Exploring the regulation of miR NAs in key cellsignaling pathways-mediatedvascular remodeling wil have momentous impact on identifying novel therapeutic targets for its associated disease.展开更多
Muscle satellite cells,as muscle stem cells,play a critical role in the process of muscle regeneration,and effective muscle regeneration helps to restore muscle function and maintain the homeostasis of muscle tissues....Muscle satellite cells,as muscle stem cells,play a critical role in the process of muscle regeneration,and effective muscle regeneration helps to restore muscle function and maintain the homeostasis of muscle tissues.In damaged muscle,muscle satellite cells are activated to form new myofibers through the process of cell proliferation,migration,differentiation and fusion to complete muscle tissue regeneration.Meanwhile,this process is mainly affected by endogenous gene expression and many exogenous factors.Researches in recent years have shown that vitamins,as important nutrients,play an extremely important role in the process of muscle regeneration.Therefore,this article reviewed the roles of vitamins in the regeneration of muscle satellite cells,according to the latest research progress.It would provide more theoretical and data support for the regeneration and repair of muscle damage,muscle atrophy and other muscle diseases,so that it could be better applied in the field of muscle regeneration researches and serve human health.展开更多
OBJECTIVE Urocortins(UCNs)and transforming growth factor-β(TGF-β)have been demonstrated to participate in various cardiovascular diseases,many of which involve VSMCs proliferation.And cytosolic phospholipase A2(c PL...OBJECTIVE Urocortins(UCNs)and transforming growth factor-β(TGF-β)have been demonstrated to participate in various cardiovascular diseases,many of which involve VSMCs proliferation.And cytosolic phospholipase A2(c PLA2)-mediated arachidonic acid(AA)release is an important cause of vascular smooth muscle cells(VSMCs)proliferation.The work was to investigate the regulation of VSMCs proliferation by UCN/TGF-βand whether c PLA2 was a link between their signaling pathways.METHODS VSMC proliferation was measured by MTT assay and immunofluorescence microscopy.Using cell flow cytometry,the changes in the cell cycle phases were investigated.si RNA was used to knockdown Smad2 and smad3 genes.Lentiviral Vector Particle was performed to over express c PLA2 gene.RESULTS Both UCN and TGF-βinhibited VSMCs proliferation and an additive effect was observed when the cells were treated with UCN plus TGF-β.TGF-βincreased the percentage of cells in G1-phase while UCN increased the cell percentage in G2-phase with a concomitant decrease in S-phase.Neither knockdown of smad2 nor smad3 reversed the role of TGF-β.Furthermore,c PLA2expression was increased by TGF-βbut decreased by UCN and UCN attenuated TGF-β-induced c PLA2 expression.In primary VSMCs,TGF-βinduced c PLA2 phosphorylation,and this effect was also attenuated by UCN.Similar to UCN,the c PLA2 inhibitor,pyrrophenone(PYR),also played a role in enhancing TGF-β-mediated mitoinhibition.Inversely,over-expression of c PLA2 eliminated the effect of UCN on the mitoinhibition.CONCLUSION The pretreatment with UCN counteracted TGF-β-mediated c PLA2 expression and activation,thereby contributing to TGF-β-mediated mitoinhibition of VSMCs.展开更多
OBJECTIVE To explore the role of calpain in in pulmonary vascular remodeling in hypoxia induced pulmonary hypertension and the underlying mechanism.METHODS Sprague-Dawley rats were randomly divided into hypoxia group ...OBJECTIVE To explore the role of calpain in in pulmonary vascular remodeling in hypoxia induced pulmonary hypertension and the underlying mechanism.METHODS Sprague-Dawley rats were randomly divided into hypoxia group and normoxia control group.Right ventricular systolic pressure(RVSP)and mean pulmonary artery pressure(m PAP)were monitored by the method of right external jugular vein cannula.Right ventricular hypertrophy index was expressed as the ratio of right ventricular weight to left ventricular weight(left ventricle plus septum weight).Level of calpain-1,calpain-2and calpain-4 m RNA in pulmonary artery trunk were determined by real-time PCR.Expression of calpain-1,calpain-2 and calpain-4 protein was determined by Western Blot.Primary rat pulmonary arterial smooth muscle cells(PASMCs)were divided into 4 groups:normoxia control group,normoxia+MDL28170 group,hypoxia group and hypoxia+MDL28170 group.Cell proliferation was detected by MTS and flow cytometry.Level of Ki-67 and PCNA m RNA were determined by real-time PCR.RESULTS RVSP,m PAP and right ventricular remodeling index were significantly higher in the hypoxia group than those in the normoxia group.In the hypoxia group,pulmonary vascular remodeling occurred,and the expression of calpain-1,calpain-2 and calpain-4 m RNA and protein expression was increased in the pulmonary artery.MDL28170 significantly inhibited hypoxia-induced proliferation of PASMCs accompanied with decreased Ki-67and PCNA m RNA expression.CONCLUSION Calpain mediated vascular remodeling via promoting proliferation of PASMCs in hypoxia induced pulmonary hypertension.展开更多
Pathological vascular remodeling is characterized by thickening or thinning of the vessel wall through altering cellular and non-cellular components,which associates with various blood circulation disorders in brain,h...Pathological vascular remodeling is characterized by thickening or thinning of the vessel wall through altering cellular and non-cellular components,which associates with various blood circulation disorders in brain,heart,lung,and peripheral vasculatures. Pathological vascular remodeling occurs in response to a variety of vascular insults such as mechanical(angioplasty or stenting) or biological(lipids,diabetes,smoking,or virus) injuries. It is a polygenic process involving multiple cell types in the vessel wall or circulation,including endothelial cells(ECs),smooth muscle cells(SMCs),fibroblasts,leukocytes,and platelets. One of hallmarks is the transition of vascular smooth muscle cells(SMCs)from a differentiated/quiescent contractile phenotype to a myofibroblast-like dedifferentiated/active so-called synthetic phenotype. Synthetic SMCs are proliferatory,migratory,secretory and inflammatory,playing key roles in the pathogenesis of vascular remodeling. In the normal vessel,ECs synthesize and secrete biological substances such as prostacyclins(PGI_2) and nitric oxide(NO) that not only function as vasodilators but also inhibit SMC phenotype transition and other properties associated with the synthetic phenotype. Cyclic nucleotides cAMP and cGMP are primary mediators of PGI_2 and NO,respectively,and play critical roles in control vascular structural integrity and function. Cyclic nucleotides are controlled by selective activation or inhibition of distinct cyclic nucleotide phosphodiesterase(PDE) isozymes catalyzing the degradation reaction. To date,more than 60 different PDE isoenzymes derived from 22 genes are identified and grouped into 11 broad families(PDE1-PDE11). PDEs are expressed in a cell/tissue-specific manner and only a few enzymes are expressed in any single cell type. Through systematic assessment of the expression levels of all known PDE isoforms in contractile versus synthetic SMCs,we found that the expression levels of a number of PDE are significantly altered between two SMC phenotypes. We then explored the functional roles and underlying mechanisms of these altered PDEs in vascular SMCs pathogenesis and vascular remodeling in vitro and in vivo using a variety of gain-of-or loss-of-function approaches. For example,we found that Ca^(2+)/calmodulinstimulated cAMP/cGMP-hydrolyzing PDE 1C is selectively expressed in synthetic SMCs in vitro and in various vascular disease models in vivo. PDE 1C upregulation contributes to a number of pathogenic functions of synthetic SMCs,such as cell proliferation,migration,and matrix protein metabolism.PDE 1C deficiency markedly attenuates intimal hyperplasia,atherosclerosis,and aortic aneurysm in experimental mouse disease models. These findings suggest that PDE 1C functions as a key regulator of the synthetic SMC pathology in vascular remodeling. Inhibiting PDE 1C function may represent a novel therapeutic strategy for protecting against the pathogenesis of vascular diseases.展开更多
基金supported by grants from the National Natural Science Foundation of China,Nos10732070,10702043,30970703,10972140 and 30470432
文摘Instruction Shear stress,caused by the parallel frictional drag force of blood flow,is a biomechanical force which plays an important role in the control of blood vessels growth and functions [1]. Clinical researches had found out that atherosclerotic le-
基金Supported by the Ministry of Agricultural Nuarture of New Varieties Genetically Modified Organisms Significant Special Funding (2008ZX08007-002)
文摘To examine the effect of myogenin gene on the differentiation of bovine skeletal muscle satellite cell, we constructed small interfering RNA plasmid vector to obtain myogenin knockdown bovine skeletal muscle cells, then used cell transfection, real time RCR and Western Blot to detect the influence of myogenin to cell differentiation. Results showed that the knockdown of myogenin significantly decreased its expression and other muscle-specific genes. Compared to the control, it could differentiate into few myotubes when challenged by low serum in the medium. These findings provided an important theoretical basis for further explore of the genetic mechanism in adult skeletal muscle, the remedy of muscle injuries and the cultivation of high-yield transgenic cattle.
基金The project supported by Central Public Scientific Research Institution Fundamental Project(2016CX09)by National Natural Science Foundation of China(81573645)
文摘OBJECTIVE Pulmonary artery hypertension(PAH)is a severe disease characterized by the mean pulmonary artery pressure exceeding 25 mm Hg at rest.PAH could induce right heart failure and has a very high mortality rate.At present,several kinds of drugs have been used in the treatment of PAH.However,most of these drugs aim to relax pulmonary arteries and do not inhibit the injury of vessels.In other words,the drugs available for PAH treatment do not improve the survival rate of PAH patients and cannot satisfy the needs in clinic.To discover and develop novel candidate compounds effective on the treatment of pulmonary artery injury and remodeling will be very important.Based on these background,the present study aimed to study the protective effect of two novel Rho-kinases(Rho-associated coiledcoil forming protein serine/threonine kinase,ROCK)inhibitors,DL0805 derivatives(DL0805-1and DL0805-2),on pulmonary arterial cells and further evaluate the underlying mechanisms and the possibility of DL0805 derivatives become therapeutic drugs for PAH.METHODS The primary cultured pulmonary arterial cells including human pulmonary artery endothelium cells(HPAECs)and human pulmonary artery smooth muscle cells(HPASMCs)were used in this study.HPAECs were injured under hypoxia environment(1%O2)and treated with or without DL0805 derivatives.After 48 h,the proliferation and oxidative stress were observed.CCK8 was used to detect cell viability.DCFH-DA was used as probe for reactive oxygen species(ROS)under fluorescence imaging system.HPASMCs was stimulated by growth factors including platelet-derived growth factor-BB(PDGF-BB)and Fetal Bovine Serum(FBS).The proliferation was observed in the cells treated with or without DL0805 derivatives.HPASMCs treated with or without DL0805 derivatives were further incubated with endothelin(ET-1),the proliferation and cytoskeleton remodeling of cells were detected by immunofluorescence assay.At last,Western blotting(WB)and immunofluorescence assay were employed to analysis the underlying mechanisms in the above experiments.RESULTS 10μmol·L-1DL0805-2 could inhibit the proliferation of HPAECs induced by hypoxia.Each concentration of DL0805-1 and DL0805-2attenuated the production of ROS in HPAECs.Results from WB indicated that DL0805 derivatives decreased the injury of HPAECs induced by hypoxia through the inhibition of the expression of Rho A and the activity of ROCK.On HPASMCs,DL0805 derivatives reduced the proliferation induced by PDGF-BB and FBS and inhibited cytoskeleton remodeling induced by ET-1.Immunofluorescence assay showed that DL0805 derivatives inhibited ROCK activity and down regulated the phosphorylation levels of ROCK substrates.CONCLUSION DL0805derivatives exhibited protective effect on pulmonary arterial cells including endothelium cells and smooth muscle cells.Among the above experiments,DL0805-2 showed stronger potency than DL0805-1.These two compounds might protect the cells through the inhibition of Rho A/ROCK pathway and they probably have the potential in the treatment of PAH and deserve further evaluation.
基金The project supported by National Natural Science Foundation of China(81102445 and81670456)Beijing Natural Science Foundation(7162132)the PUMC Youth Fund and the Fundamental Research Funds for the Central Universities(33320140069)
文摘Vascular remodeling,which can be found in atherosclerosis,restenosis after angioplasty,hypertension,and some other frequent and serious chronic diseases.Smooth muscle cell(SMC)phenotype change,which has been described as converting from a contractile state into a synthetic phenotype,is a crucial event during vascular remodeling.Recently,micro RNAs(mi RNAs)a kind of small non-coding RNA molecules,has been proven to target critical genes of cell signaling pathways to regulate SMC phenotypic change.By searching the Pub Med,Embase,reviews,and reference listsof relevant papers,we systematically carried out a review of the literature to provide an overview of the mi RNAs and their target genes in cell signaling pathways,focus inthe pathways involving in SMC phenotype change.To be specific,mi RNAs that regulate genes involved in the MAPK signaling pathways(such as:mi R-155,mi R-92a,mi R-424/503,mi R-133,mi R-181b,mi R-31,mi R-1298,mi R-132,mi R-200c and mi R-483-3p),mi RNAs target genes involved in the TGF-βsignaling pathways(including mi R-24,mi R-17/92 cluster,mi R-599,mi R-21 and mi R-143/145),mi RNAs target the genes involved in the AMPK signaling pathways including mi R-144/451 and mi R-195,mi RNAs target the genes involved in the PI3K-Akt signaling pathways(including mi R-138,mi R-34c,mi R-223,mi R-761,mi R-10a,mi R-146a),mi R-199a-5ptargets the genes involved in the Wnt signaling pathways mi RNAs(mi R-221/222,mi R-15b,mi R-24/29a,mi R-224)involved in the PDGF signaling pathways and some mi RNAs(mi R-638,mi R-328,mi R-365,mi R-663,mi R-29b,mi R-130,mi R-142-5p,mi R-424/322)which regulate SMC phenotype change by other corresponding targets were in detailed discussed in our review.Exploring the regulation of miR NAs in key cellsignaling pathways-mediatedvascular remodeling wil have momentous impact on identifying novel therapeutic targets for its associated disease.
文摘Muscle satellite cells,as muscle stem cells,play a critical role in the process of muscle regeneration,and effective muscle regeneration helps to restore muscle function and maintain the homeostasis of muscle tissues.In damaged muscle,muscle satellite cells are activated to form new myofibers through the process of cell proliferation,migration,differentiation and fusion to complete muscle tissue regeneration.Meanwhile,this process is mainly affected by endogenous gene expression and many exogenous factors.Researches in recent years have shown that vitamins,as important nutrients,play an extremely important role in the process of muscle regeneration.Therefore,this article reviewed the roles of vitamins in the regeneration of muscle satellite cells,according to the latest research progress.It would provide more theoretical and data support for the regeneration and repair of muscle damage,muscle atrophy and other muscle diseases,so that it could be better applied in the field of muscle regeneration researches and serve human health.
基金The project supported by National Natural Science Foundation of China(81573424&81273510)Priority Academic Program Development of Jiangsu Higher Education Institutions
文摘OBJECTIVE Urocortins(UCNs)and transforming growth factor-β(TGF-β)have been demonstrated to participate in various cardiovascular diseases,many of which involve VSMCs proliferation.And cytosolic phospholipase A2(c PLA2)-mediated arachidonic acid(AA)release is an important cause of vascular smooth muscle cells(VSMCs)proliferation.The work was to investigate the regulation of VSMCs proliferation by UCN/TGF-βand whether c PLA2 was a link between their signaling pathways.METHODS VSMC proliferation was measured by MTT assay and immunofluorescence microscopy.Using cell flow cytometry,the changes in the cell cycle phases were investigated.si RNA was used to knockdown Smad2 and smad3 genes.Lentiviral Vector Particle was performed to over express c PLA2 gene.RESULTS Both UCN and TGF-βinhibited VSMCs proliferation and an additive effect was observed when the cells were treated with UCN plus TGF-β.TGF-βincreased the percentage of cells in G1-phase while UCN increased the cell percentage in G2-phase with a concomitant decrease in S-phase.Neither knockdown of smad2 nor smad3 reversed the role of TGF-β.Furthermore,c PLA2expression was increased by TGF-βbut decreased by UCN and UCN attenuated TGF-β-induced c PLA2 expression.In primary VSMCs,TGF-βinduced c PLA2 phosphorylation,and this effect was also attenuated by UCN.Similar to UCN,the c PLA2 inhibitor,pyrrophenone(PYR),also played a role in enhancing TGF-β-mediated mitoinhibition.Inversely,over-expression of c PLA2 eliminated the effect of UCN on the mitoinhibition.CONCLUSION The pretreatment with UCN counteracted TGF-β-mediated c PLA2 expression and activation,thereby contributing to TGF-β-mediated mitoinhibition of VSMCs.
基金The project supported by National Natural Science Foundation of China(81273512,81460010)by Natural Science Foundation of Jiangxi province(20142BAB215035)
文摘OBJECTIVE To explore the role of calpain in in pulmonary vascular remodeling in hypoxia induced pulmonary hypertension and the underlying mechanism.METHODS Sprague-Dawley rats were randomly divided into hypoxia group and normoxia control group.Right ventricular systolic pressure(RVSP)and mean pulmonary artery pressure(m PAP)were monitored by the method of right external jugular vein cannula.Right ventricular hypertrophy index was expressed as the ratio of right ventricular weight to left ventricular weight(left ventricle plus septum weight).Level of calpain-1,calpain-2and calpain-4 m RNA in pulmonary artery trunk were determined by real-time PCR.Expression of calpain-1,calpain-2 and calpain-4 protein was determined by Western Blot.Primary rat pulmonary arterial smooth muscle cells(PASMCs)were divided into 4 groups:normoxia control group,normoxia+MDL28170 group,hypoxia group and hypoxia+MDL28170 group.Cell proliferation was detected by MTS and flow cytometry.Level of Ki-67 and PCNA m RNA were determined by real-time PCR.RESULTS RVSP,m PAP and right ventricular remodeling index were significantly higher in the hypoxia group than those in the normoxia group.In the hypoxia group,pulmonary vascular remodeling occurred,and the expression of calpain-1,calpain-2 and calpain-4 m RNA and protein expression was increased in the pulmonary artery.MDL28170 significantly inhibited hypoxia-induced proliferation of PASMCs accompanied with decreased Ki-67and PCNA m RNA expression.CONCLUSION Calpain mediated vascular remodeling via promoting proliferation of PASMCs in hypoxia induced pulmonary hypertension.
文摘Pathological vascular remodeling is characterized by thickening or thinning of the vessel wall through altering cellular and non-cellular components,which associates with various blood circulation disorders in brain,heart,lung,and peripheral vasculatures. Pathological vascular remodeling occurs in response to a variety of vascular insults such as mechanical(angioplasty or stenting) or biological(lipids,diabetes,smoking,or virus) injuries. It is a polygenic process involving multiple cell types in the vessel wall or circulation,including endothelial cells(ECs),smooth muscle cells(SMCs),fibroblasts,leukocytes,and platelets. One of hallmarks is the transition of vascular smooth muscle cells(SMCs)from a differentiated/quiescent contractile phenotype to a myofibroblast-like dedifferentiated/active so-called synthetic phenotype. Synthetic SMCs are proliferatory,migratory,secretory and inflammatory,playing key roles in the pathogenesis of vascular remodeling. In the normal vessel,ECs synthesize and secrete biological substances such as prostacyclins(PGI_2) and nitric oxide(NO) that not only function as vasodilators but also inhibit SMC phenotype transition and other properties associated with the synthetic phenotype. Cyclic nucleotides cAMP and cGMP are primary mediators of PGI_2 and NO,respectively,and play critical roles in control vascular structural integrity and function. Cyclic nucleotides are controlled by selective activation or inhibition of distinct cyclic nucleotide phosphodiesterase(PDE) isozymes catalyzing the degradation reaction. To date,more than 60 different PDE isoenzymes derived from 22 genes are identified and grouped into 11 broad families(PDE1-PDE11). PDEs are expressed in a cell/tissue-specific manner and only a few enzymes are expressed in any single cell type. Through systematic assessment of the expression levels of all known PDE isoforms in contractile versus synthetic SMCs,we found that the expression levels of a number of PDE are significantly altered between two SMC phenotypes. We then explored the functional roles and underlying mechanisms of these altered PDEs in vascular SMCs pathogenesis and vascular remodeling in vitro and in vivo using a variety of gain-of-or loss-of-function approaches. For example,we found that Ca^(2+)/calmodulinstimulated cAMP/cGMP-hydrolyzing PDE 1C is selectively expressed in synthetic SMCs in vitro and in various vascular disease models in vivo. PDE 1C upregulation contributes to a number of pathogenic functions of synthetic SMCs,such as cell proliferation,migration,and matrix protein metabolism.PDE 1C deficiency markedly attenuates intimal hyperplasia,atherosclerosis,and aortic aneurysm in experimental mouse disease models. These findings suggest that PDE 1C functions as a key regulator of the synthetic SMC pathology in vascular remodeling. Inhibiting PDE 1C function may represent a novel therapeutic strategy for protecting against the pathogenesis of vascular diseases.
