Inflammation and Mechanical Stress Stimulate Osteogenic Differentiation of Human Aortic Valve Interstitial Cells

Background: Aortic valve calcification is an active proliferative process, where interstitial cells of the valve transform into either myofibroblasts or osteoblast-like cells causing valve deformation, thickening of cusps and finally stenosis. This process may be triggered by several factors including inflammation, mechanical stress or interaction of cells with certain components of extracellular matrix. The matrix is different on the two sides of the valve leaflets. We hypothesize that inflammation and mechanical stress stimulate osteogenic differentiation of human aortic valve interstitial cells (VICs) and this may depend on the side of the leaflet. Methods: Interstitial cells isolated from healthy and calcified human aortic valves were cultured on collagen or elastin coated plates with flexible bottoms, simulating the matrix on the aortic and ventricular side of the valve leaflets, respectively. The cells were subjected to 10% stretch at 1 Hz (FlexCell bioreactor) or treated with 0.1 μg/ml lipopolysaccharide, or both during 24 h. Gene expression of myofibroblast- and osteoblast-specific genes was analyzed by qPCR. VICs cultured in presence of osteogenic medium together with lipopolysaccharide, 10% stretch or both for 14 days were stained for calcification using Alizarin Red. Results: Treatment with lipopolysaccharide increased expression of osteogenic gene bone morphogenetic protein 2 (BMP2) (5-fold increase from control; p = 0.02) and decreased expression of mRNA of myofibroblastic markers: α-smooth muscle actin (ACTA2) (50% reduction from control; p = 0.0006) and calponin (CNN1) (80% reduction from control; p = 0.0001) when cells from calcified valves were cultured on collagen, but not on elastin. Mechanical stretch of VICs cultured on collagen augmented the effect of lipopolysaccharide. Expression of periostin (POSTN) was inhibited in cells from calcified donors after treatment with lipopolysaccharide on collagen (70% reduction from control, p = 0.001), but not on elastin. Lipopolysaccharide and stretch both enhanced the pro-calcific effect of osteogenic medium, further increasing the effect when combined for cells cultured on collagen, but not on elastin. Conclusion: Inflammation and mechanical stress trigger expression of osteogenic genes in VICs in a side-specific manner, while inhibiting the myofibroblastic pathway. Stretch and lipopolysaccharide synergistically increase calcification.

[1]  G. Sullivan,et al.  Valve Interstitial Cells: The Key to Understanding the Pathophysiology of Heart Valve Calcification , 2017, Journal of the American Heart Association.

[2]  K. Stensløkken,et al.  Osteoblast Differentiation at a Glance , 2016, Medical science monitor basic research.

[3]  M. Dweck,et al.  Calcification in Aortic Stenosis: The Skeleton Key. , 2015, Journal of the American College of Cardiology.

[4]  Matthew E. Ritchie,et al.  limma powers differential expression analyses for RNA-sequencing and microarray studies , 2015, Nucleic acids research.

[5]  Xianzhong Meng,et al.  Ligation of ICAM-1 on human aortic valve interstitial cells induces the osteogenic response: A critical role of the Notch1-NF-κB pathway in BMP-2 expression. , 2014, Biochimica et biophysica acta.

[6]  Marie-Chloé Boulanger,et al.  Molecular biology of calcific aortic valve disease: towards new pharmacological therapies , 2014, Expert review of cardiovascular therapy.

[7]  Xianzhong Meng,et al.  Augmented Osteogenic Responses in Human Aortic Valve Cells Exposed to oxLDL and TLR4 Agonist: A Mechanistic Role of Notch1 and NF-κB Interaction , 2014, PloS one.

[8]  Y. Bossé,et al.  Inflammation Is Associated with the Remodeling of Calcific Aortic Valve Disease , 2013, Inflammation.

[9]  R. Nerem,et al.  Strain Magnitude-Dependent Calcific Marker Expression in Valvular and Vascular Cells , 2013, Cells Tissues Organs.

[10]  T. Gasser,et al.  Biomechanical factors in the biology of aortic wall and aortic valve diseases , 2013, Cardiovascular research.

[11]  J. Cleveland,et al.  Cross-Talk Between the Toll-Like Receptor 4 and Notch1 Pathways Augments the Inflammatory Response in the Interstitial Cells of Stenotic Human Aortic Valves , 2012, Circulation.

[12]  J. Leopold Cellular Mechanisms of Aortic Valve Calcification , 2012, Circulation. Cardiovascular interventions.

[13]  C. García-Rodríguez,et al.  Viral and bacterial patterns induce TLR-mediated sustained inflammation and calcification in aortic valve interstitial cells. , 2012, International journal of cardiology.

[14]  K. J. Grande-Allen,et al.  Calcific aortic valve disease: not simply a degenerative process: A review and agenda for research from the National Heart and Lung and Blood Institute Aortic Stenosis Working Group. Executive summary: Calcific aortic valve disease-2011 update. , 2011, Circulation.

[15]  K. Masters,et al.  Can valvular interstitial cells become true osteoblasts? A side-by-side comparison. , 2011, The Journal of heart valve disease.

[16]  Craig A Simmons,et al.  Cell–Matrix Interactions in the Pathobiology of Calcific Aortic Valve Disease: Critical Roles for Matricellular, Matricrine, and Matrix Mechanics Cues , 2011, Circulation research.

[17]  R. Weiss,et al.  Calcific Aortic Valve Stenosis: Methods, Models, and Mechanisms , 2011, Circulation research.

[18]  Craig A Simmons,et al.  The aortic valve microenvironment and its role in calcific aortic valve disease. , 2011, Cardiovascular pathology : the official journal of the Society for Cardiovascular Pathology.

[19]  S. Motomura,et al.  Tumor Necrosis Factor-α Accelerates the Calcification of Human Aortic Valve Interstitial Cells Obtained from Patients with Calcific Aortic Valve Stenosis via the BMP2-Dlx5 Pathway , 2011, Journal of Pharmacology and Experimental Therapeutics.

[20]  J. Cleveland,et al.  Microfilaments facilitate TLR4-mediated ICAM-1 expression in human aortic valve interstitial cells. , 2011, The Journal of surgical research.

[21]  R. Hinton,et al.  Heart valve structure and function in development and disease. , 2011, Annual review of physiology.

[22]  Ajit P Yoganathan,et al.  Elevated cyclic stretch induces aortic valve calcification in a bone morphogenic protein-dependent manner. , 2010, The American journal of pathology.

[23]  R. Sainger,et al.  Insights into the use of biomarkers in calcific aortic valve disease. , 2010, The Journal of heart valve disease.

[24]  R. Markwald,et al.  Lack of periostin leads to suppression of Notch1 signaling and calcific aortic valve disease. , 2009, Physiological genomics.

[25]  F. Mohr,et al.  Mechanical strain and the aortic valve: influence on fibroblasts, extracellular matrix, and potential stenosis. , 2009, The Annals of thoracic surgery.

[26]  J. Cleveland,et al.  Bone morphogenic protein 2 induces Runx2 and osteopontin expression in human aortic valve interstitial cells: role of Smad1 and extracellular signal-regulated kinase 1/2. , 2009, The Journal of thoracic and cardiovascular surgery.

[27]  Kristyn S Masters,et al.  Regulation of valvular interstitial cell calcification by components of the extracellular matrix. , 2009, Journal of biomedical materials research. Part A.

[28]  Craig A Simmons,et al.  Calcification by Valve Interstitial Cells Is Regulated by the Stiffness of the Extracellular Matrix , 2009, Arteriosclerosis, thrombosis, and vascular biology.

[29]  J. Cleveland,et al.  Pro-osteogenic phenotype of human aortic valve interstitial cells is associated with higher levels of Toll-like receptors 2 and 4 and enhanced expression of bone morphogenetic protein 2. , 2009, Journal of the American College of Cardiology.

[30]  Kristi S Anseth,et al.  Substrate properties influence calcification in valvular interstitial cell culture. , 2008, The Journal of heart valve disease.

[31]  J. Cleveland,et al.  Lipopolysaccharide stimulation of human aortic valve interstitial cells activates inflammation and osteogenesis. , 2008, The Annals of thoracic surgery.

[32]  Michael C. Wendl,et al.  Argonaute—a database for gene regulation by mammalian microRNAs , 2005, BMC Bioinformatics.

[33]  T. Imamura,et al.  [Bone formation and inflammation]. , 2005, Nihon rinsho. Japanese journal of clinical medicine.

[34]  Magdi H. Yacoub,et al.  Localization and pattern of expression of extracellular matrix components in human heart valves. , 2005, The Journal of heart valve disease.

[35]  J. Ramires,et al.  Mycoplasma pneumoniae and Chlamydia pneumoniae in calcified nodules of aortic stenotic valves. , 2002, Revista do Instituto de Medicina Tropical de Sao Paulo.

[36]  Emile R. Mohler,et al.  Bone Formation and Inflammation in Cardiac Valves , 2001, Circulation.

[37]  Meghan A Bowler,et al.  In vitro models of aortic valve calcification: solidifying a system. , 2015, Cardiovascular pathology : the official journal of the Society for Cardiovascular Pathology.

[38]  S. Motomura,et al.  Tumor Necrosis Factor-Accelerates the Calcification of Human Aortic Valve Interstitial Cells Obtained from Patients with Calcific Aortic Valve Stenosis via the BMP 2-Dlx 5 Pathway , 2011 .

[39]  J. Cleveland,et al.  Expression of functional Toll-like receptors 2 and 4 in human aortic valve interstitial cells: potential roles in aortic valve inflammation and stenosis. , 2008, American journal of physiology. Cell physiology.

[40]  D Kaspar,et al.  Tissue engineering of bone: effects of mechanical strain on osteoblastic cells in type I collagen matrices. , 2005, Biomaterials.

[41]  A. Ignatiusa,et al.  Tissue engineering of bone : effects of mechanical strain on osteoblastic cells in type I collagen matrices , 2004 .

[42]  I. Shbeeb,et al.  The aortic valve , 1984, Diseases of the colon and rectum.