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Bone Morphogenetic Proteins (BMPs) are key regulators for a lot of diverse cellular processes. During embryonic development these proteins act as morphogens and play a crucial role particularly in organogenesis. BMPs have a direct impact on distinct cellular fates by means of concentration-gradients in the developing embryos. Using the diverse signaling input information within the embryo due to the gradient, the cells transduce the varying extracellular information into distinct gene expression profiles and cell fate decisions. Furthermore, BMP proteins bear important functions in adult organisms like tissue homeostasis or regeneration. In contrast to TGF-ß signaling, currently only little is known about how cells decode and quantify incoming BMP signals. There is poor knowledge about the quantitative relationships between signal input, transducing molecules, their states and location, and finally their ability to incorporate graded systemic inputs and produce qualitative responses. A key requirement for efficient pathway modulation is the complete comprehension of this signaling network on a quantitative level as the BMP signaling pathway, just like many other signaling pathways, is a major target for medicative interference. I therefore at first studied the subcellular distribution of Smad1, which is the main signal transducing protein of the BMP signaling pathway, in a quantitative manner and in response to various types and levels of stimuli in murine c2c12 cells. Results indicate that the subcellular localization of Smad1 is not dependent on the initial BMP input. Surprisingly, only the phospho-Smad1 level is proportionally associated to ligand concentration. Furthermore, the activated transducer proteins were entirely located in the nucleus. Besides the subcellular localization of Smad1, I have analyzed the gene expression profile induced by BMP signaling. Therefore, I examined two endogenous immediate early BMP targets as well as the expression of the stably transgenic Gaussia Luciferase. Interestingly, the results of these independent experimental setups and read-outs suggest oscillating target gene expression. The amplitudes of the oscillations showed a precise concentration-dependence for continuous and transient stimulation. Additionally, even short-time stimulation of 15’ activates oscillating gene-expression pulses that are detectable for at least 30h post-stimulation. Only treatment with a BMP type I receptor kinase inhibitor leads to the complete abolishment of the target gene expression. This indicated that target gene expression oscillations depend directly on BMP type I receptor kinase activity.
Investigation on Distinct Roles of Smad Proteins in Mediating Bone Morphogenetic Proteins Signals
(2011)
Bone morphogenetic proteins (BMPs) belong to the transforming growth factor-β (TGF-β) superfamily and play important roles in numerous biological events in the development of almost all multi-cellular organisms. Dysregulated BMP signaling is the underlying causes of numerous heritable and non-heritable human diseases including cancer. The vast range of biological responses induced by BMPs converges on three closely related Smad proteins that convey intracellular signals from BMP receptors to the nucleus. The specificity of BMP signaling has been intensively investigated at the level of ligand-receptor interactions, but how the different Smad proteins contribute to differential signals elicited by BMPs remains unclear. In this work, we investigated the BMP/Smad signaling in different aspects. In search for an appropriate fluorescence reporter in zebrafish, we compared different photo-switchable proteins and found EosFP the best candidate this model system for its fast maturation and fluorescence intensity. We modified and created appropriate vectors enabling Tol2-transposon based trangenesis in zebrafish, with which transgenic zebrafish lines were generated. We combined fluorescence protein tagging with high resolution microscopy and investigate the dynamics of Smad proteins in model system zebrafish. We observed that Smad5 undergoes nucleo-translocation as BMP signal transmitter during zebrafish gastrulation. We explored the Smad involvement during myogenic-to-osteogenic conversion of C2C12 cell line induced by BMP4. We created transient loss-of-function of Smads by siRNA-mediated knockdowns and analyzed the effects on these coupled yet distinct procedures by quantitative real-time PCR and terminal marker staining. We found that different Smad-complex stoichiometry might be responsible for distinct cellular signals elicited by BMPs.