Exogenous Activation of BMP-2 Signaling Overcomes TGFbeta-Mediated Inhibition of Osteogenesis in Marfan Embryonic Stem Cells and Marfan Patient-Specific Induced Pluripotent Stem Cells.

Marfan syndrome (MFS) is a hereditary disease caused by mutations in the gene encoding Fibrillin-1 (FBN1) a large protein component of extracellular cell matrix. This syndrome is characterized by a number of skeletal abnormalities, including susceptibility to bone fracture, osteopenia and exaggerated growth of long bone and fingers. Severe forms of MFS give rise also cardio-vascular pathologies, such as aortic root dilatation and aneurysm. Sometimes this syndrome affects eyes as well, specifically the lens. We have previously demonstrated that unique skeletal defects observed in human embryonic stem cells derived from a Marfan embryo are faithfully recapitulated by stem cells derived independently from MFS adult patient fibroblasts. These types of cells are known as “induced pluripotent-stem cells” (iPSCs) and are obtained using a technique recently developed. In the current study we have moved a step forward gaining further insights into the pathology of Marfan syndrome. We have unveiled additional molecular and cellular mechanism(s) responsible of skeletal defects observed in Marfan cells. Our recent results demonstrate that alteration (elevated activation) of a biochemical signaling called TGF-beta occurring in Marfan cells inhibits another biochemical/cellular signaling known as BMP signaling which is a key regulator of bone growth and development. Our results shed new light on the signaling cross-talk occurring in Marfan cells. Indeed, this study is an important step towards determining the biological potency of clinically-relevant, functional cell types derived from Marfan embryonic stem cells and Marfan iPSCs. Our findings could contribute to development of effective novel therapeutic strategies targeting both, TGF-beta and BMP signaling pathways for treatment of MFS patients. Moreover, this study advances our understanding of molecular mechanisms underlying the pathogenesis of bone loss/abnormal skeletogenesis in human diseases caused by genetic mutations.