Published online before print February 22, 2008, doi: 10.1161/CIRCRESAHA.107.159517
© 2008 American Heart Association, Inc.
Cellular Biology |
Periostin Is Required for Maturation and Extracellular Matrix Stabilization of Noncardiomyocyte Lineages of the Heart
From the Cardiovascular Development Group (P.S., J.W., R.R., A.L., F.L., D.A.I., L.F., A.B.F., S.J.C.), Herman B Wells Center for Pediatric Research, Indiana University School of Medicine, Indianapolis; Cincinnati Children’s Hospital (R.B.H., J.D.M.), Ohio; and Medical University of South Carolina (R.A.M.-R., D.M., R.M.), Charleston.
Correspondence to Simon J. Conway, Indiana University, 1044 W Walnut St, Indianapolis, IN 46202. E-mail siconway{at}iupui.edu
The secreted periostin protein, which marks mesenchymal cells in endocardial cushions following epithelial–mesenchymal transformation and in mature valves following remodeling, is a putative valvulogenesis target molecule. Indeed, periostin is expressed throughout cardiovascular morphogenesis and in all 4 adult mice valves (annulus and leaflets). Additionally, periostin is expressed throughout the fibrous cardiac skeleton and endocardial cushions in the developing heart but is absent from both normal and/or pathological mouse cardiomyocytes. Periostin (perilacZ) knockout mice exhibit viable valve disease, with neonatal lethality in a minority and latent disease with leaflet abnormalities in the viable majority. Surviving perilacZ-null leaflets are truncated, contain ectopic cardiomyocytes and smooth muscle, misexpress the cartilage proteoglycan aggrecan, demonstrate disorganized matrix stratification, and exhibit reduced transforming growth factor-β signaling. Neonatal perilacZ nulls that die (14%) display additional defects, including leaflet discontinuities, delamination defects, and deposition of acellular extracellular matrix. Assessment of collagen production, 3D lattice formation ability, and transforming growth factor-β responsiveness indicate periostin-deficient fibroblasts are unable to support normal valvular remodeling and establishment of a mature cardiac skeleton. Furthermore, pediatric stenotic bicuspid aortic valves that have lost normal extracellular matrix trilaminar stratification have greatly reduced periostin. This suggests that loss of periostin results in inappropriate differentiation of mesenchymal cushion cells and valvular abnormalities via a transforming growth factor-β–dependent pathway during establishment of the mature heart. Thus, perilacZ knockouts provide a new model of viable latent valve disease.
Key Words: heart development • periostin • cardiac skeleton • valve • mouse
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