Abstract
Thoracic aortopathy–aneurysm, dissection, and rupture–is increasingly responsible for significant morbidity and mortality. Advances in medical genetics and imaging have improved diagnosis and thus enabled earlier prophylactic surgical intervention in many cases. There remains a pressing need, however, to understand better the underlying molecular and cellular mechanisms with the hope of finding robust pharmacotherapies. Diverse studies in patients and mouse models of aortopathy have revealed critical changes in multiple smooth muscle cell signaling pathways that associate with disease, yet integrating information across studies and models has remained challenging. We present a new quantitative network model that includes many of the key smooth muscle cell signaling pathways and validate the model using a detailed data set that focuses on hyperactivation of the mechanistic target of rapamycin (mTOR) pathway and its inhibition using rapamycin. We show that the model can be parameterized to capture the primary experimental findings both qualitatively and quantitatively. We further show that simulating a population of cells by varying receptor reaction weights leads to distinct proteomic clusters within the population, and that these clusters emerge due to a bistable switch driven by positive feedback in the PI3K/AKT/mTOR signaling pathway.
Highlights
Smooth muscle cells (SMCs) of the arterial media serve as central nodes in vascular development, homeostasis, adaptation, and disease [1,2], acting in concert with endothelial cells of the intima and fibroblasts of the adventitia
We are interested in how vascular cells can change their phenotype in a way that exacerbates aortopathy, namely, the development of aneurysms, dissections, and rupture
Roles of mechanistic target of rapamycin (mTOR) signaling in thoracic aortopathy
Summary
Smooth muscle cells (SMCs) of the arterial media serve as central nodes in vascular development, homeostasis, adaptation, and disease [1,2], acting in concert with endothelial cells of the intima and fibroblasts of the adventitia. Given the complex interactions across many pathways, there is a pressing need to synthesize findings and to understand disease progression from transcript to tissue We suggest that such synthesis is possible conceptually, namely, by melding information available from detailed biomechanical phenotyping of the vascular wall [13], in vivo imaging that enables detailed calculations of hemodynamics as a function of local wall properties [14], information on effects of matrix turnover on evolving vascular geometry and properties [15], and details on changes in cell signaling [16]. We include the multiple pathways noted above while focusing on mTOR
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