Abstract
BackgroundAngiogenesis plays an important role in the survival of tissues, as blood vessels provide oxygen and nutrients required by the resident cells. Thus, targeting angiogenesis is a prominent strategy in many different settings, including both tissue engineering and cancer treatment. However, not all of the approaches that modulate angiogenesis lead to successful outcomes. Angiogenesis-based therapies primarily target pro-angiogenic factors such as vascular endothelial growth factor-A (VEGF) or fibroblast growth factor (FGF) in isolation, and there is a limited understanding of how these promoters combine together to stimulate angiogenesis. Targeting one pathway could be insufficient, as alternative pathways may compensate, diminishing the overall effect of the treatment strategy.MethodsTo gain mechanistic insight and identify novel therapeutic strategies, we have developed a detailed mathematical model to quantitatively characterize the crosstalk of FGF and VEGF intracellular signaling. The model focuses on FGF- and VEGF-induced mitogen-activated protein kinase (MAPK) signaling to promote cell proliferation and the phosphatidylinositol 3-kinase/protein kinase B (PI3K/Akt) pathway, which promotes cell survival and migration. We fit the model to published experimental datasets that measure phosphorylated extracellular regulated kinase (pERK) and Akt (pAkt) upon FGF or VEGF stimulation. We validate the model with separate sets of data.ResultsWe apply the trained and validated mathematical model to characterize the dynamics of pERK and pAkt in response to the mono- and co-stimulation by FGF and VEGF. The model predicts that for certain ranges of ligand concentrations, the maximum pERK level is more responsive to changes in ligand concentration compared to the maximum pAkt level. Also, the combination of FGF and VEGF indicates a greater effect in increasing the maximum pERK compared to the summation of individual effects, which is not seen for maximum pAkt levels. In addition, our model identifies the influential species and kinetic parameters that specifically modulate the pERK and pAkt responses, which represent potential targets for angiogenesis-based therapies.ConclusionsOverall, the model predicts the combination effects of FGF and VEGF stimulation on ERK and Akt quantitatively and provides a framework to mechanistically explain experimental results and guide experimental design. Thus, this model can be utilized to study the effects of pro- and anti-angiogenic therapies that particularly target ERK and/or Akt activation upon stimulation with FGF and VEGF.2Uswabfw1pT6JLX3vZ683iVideo
Highlights
Angiogenesis plays an important role in the survival of tissues, as blood vessels provide oxygen and nutrients required by the resident cells
Overall, the model predicts the combination effects of fibroblast growth factor (FGF) and vascular endothelial growth factor-A (VEGF) stimulation on Extracellular regulated kinase (ERK) and Protein kinase B (Akt) quantitatively and provides a framework to mechanistically explain experimental results and guide experimental design. This model can be utilized to study the effects of pro- and anti-angiogenic therapies that target ERK and/or Akt activation upon stimulation with FGF and VEGF
Co-stimulation with FGF and VEGF indicates a greater effect in increasing the maximum phosphorylated extracellular regulated kinase (pERK) compared to the summation of individual effects, which is not seen for maximum phosphorylated Akt (pAkt) levels
Summary
Angiogenesis plays an important role in the survival of tissues, as blood vessels provide oxygen and nutrients required by the resident cells. Targeting angiogenesis is a prominent strategy in many different settings, including both tissue engineering and cancer treatment. The essential role of blood vessels in delivering nutrients to tissues makes angiogenesis important in many different settings, including both physiological and pathological conditions. Targeting angiogenesis is a prominent strategy in many contexts, for example, in both tissue engineering and cancer treatment. Stimulating new blood vessel formation is an important strategy for tissue engineering [6]. On the other hand, inhibiting angiogenesis is a strategy for cancer treatment, as the formation of new blood vessels is important for cancer growth and metastasis. Understanding the angiogenesis process is very beneficial to current strategies that target vessel formation
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